Report 1232-03-81-OR
Final Draft Guidance for Subpart H
Of the interim Status Standards
For Owners and Operators Of Hazardous
Waste Treatment, Storage and Disposal Facilities
Prepared By:
Robert E. Burr
Robin Rodensky Severn
Nickolaus Leggett
Richard Meyer
Harvey Epstein
Karry Chriaman
November 1981
MANAGEMENTSYSTEMS D.VlSIOfJ
GENERAL
CORPORATION
A SUBSIDIARY OF FLOW GENERAL INC.
7655 Old Springhouse Road, McLean, Virginia 22102
Prepared For:
The Environmental Protection Aqency
Under EPA Concrrict Mo. 68-01-5794
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Report 1232-03-81-CR
Final Draft Guidance for Subpart H
Of the Interim Status Standards
For Owners and Operators Of Hazardous
Waste Treatment, Storage and Disposal Facilities
Prepared By:
Robert E. Burt
Robin Rodensky Severn
Nickolaus Leggett
Richard Meyer
Harvey Epstein
Kerry Chrisman
November 1981
MANAGEMENT SYSTEMS DIVISION
GENERAL
Kt3tAK\_H 3© CORPORATION
A SUBSIDIARY OF FLOW GENERAL INC.
7655 Old Springhouse Road, McLean, Virginia 22102
Prepared For:
The Environmental Protection Agency
Under EPA Contract No. 68-01-5794
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PREFACE
This draft guidance document has been prepared by the International
Research and Technology Corporation. In preparing this document, we
have sought and incorporated the advice of the Office of Solid Waste,
Environmental Protection Agency (EPA). The Regional Offices, the Office
of General Counsel, and the Office of Enforcement have not yet reviewed
this draft guidance document; therefore, this document does not repre-
sent EPA's final views and opinions.
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TABLE OF CONTENTS
Page
PREFACE i
TABLE OF CONTENTS ;
LIST OF TABLES v
1. 0 INTRODUCTION !_!
2.0 BASIC RULES FOR THE CLOSURE COST ESTIMATE 2-1
3.0 BASIC RULES FOR THE POST-CLOSURE COST ESTIMATE 3-1
4.0 PREPARING AND DOCUMENTING THE CLOSURE AND POST-
CLOSURE COST ESTIMATES 4-1
4.1 Costs Based upon Experience of the Owner or
Operator 4-1
4.2 Contractor Estimates 4-2
4.3 Cost Estimating Handbooks 4-3
4.4 Workups from Labor, Material and Equipment
Requirements 4-4
5.0 ADEQUACY OF THE CLOSURE COST ESTIMATE 5-1
5.1 Activities Relevant to All Facilities 5-4
5.1.1 Treating, Disposing or Removing Inventory 5-4
5.1.2 Decontaminating tne Facility 5-6
5. 1.3 Monitoring 5-5
5.1.4 Professional Engineer Certification 5-6
5.2 Costs Required Only of Landfills and Surface
Impoundments 5-7
5. 2.1 Cover 5-7
5. 2. 2 Vegetation 5-3
5.2.3 Optional Measures 5-9
6.0 ADEQUACY OF THE POST-CLOSURE COST ESTIMATE 6-1
6.1 Inspections and Facility Visits 6-3
6.2 Reestablishing Cover and Vegetation 6-5
6.3 Fertilizing 6-5
6. 4 Mowing ' 6-5
6.5 Ground-water Monitoring 6-6
6.6 Maintaining and Replacing Fences 6-6
6.7 Collecting, Removing and Treating Leachate 6-6
7.0 REVISING THE CLOSURE AND POST-CLOSURE COST ESTIMATES 7-1
iii
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8.0 ADJUSTING THE COST ESTIMATES TO ACCOUNT FOR INFLATION 8-1
9.0 SAMPLE COST ESTIMATES 9-1
9.1 Introduction 9-1
9.2 Example - Surface Impoundments 9-2
9.3 Example - Land Treatment Facilities 9-31
9.4 Example - Landfills 9-56
9.5 Example - Incinerators 9-75
9.6 Example - Multiple Process Facility With Tanks
and Surface Impoundments 9-91
9.7 Example - Post-Closure Cost Estimates 9-114
iv
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LIST OF TABLES
Table Page
5-1 CLOSURE COST ESTIMATE RAPID CHECKS 5-3
6-1 COSTS OF SELECTED POST-CLOSURE ACTIVITIES 6-4
8-1 HYPOTHETICAL SAMPLE PAGE OF SURVEY OF CURRENT
BUSINESS 3_3
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-.0 INIRCDUCIIJN
EPA has developed standards for financial requirements for owners
or operators of hazardous waste facilities as part of the Interim Status
Standards Subpart H Financial Requirements. This guidance document
covers only those portions of Subpart H promulgated on 19 May 1980 and
the technical amendments to those regulations. These portions require
the owner or operator to prepare cost estimates for closure and post-
closure. At later dates, Subpart H will also contain final regulations
covering liability requirements and financial assurance mechanisms.
The purpose of the cost estimation requirements is to determine
the amount of financial assurance needed. These requirements are pre-
sented in 40 CFR §265.142 for closure and 40 CFR §265.144 for post-
closure. Each of these sections contains a requirement for a written
cost estimate available on the premises (40 CFR §265.142(a) and 40 CFR
§265.144(a)), a requirement for revisions in the cost estimate whenever
changes are made in the applicable plans (40 CFR i265.142(b) and 40
CFR §265.144(b)) and a requirement for annual adjustments in the closure
and post-closure cost estimates to reflect inflation (40 CFR §265.142(c)
and 40 CFR 1265.144(c)). All owners or operators of hazardous waste
facilities, except those facilities owned or operated by states and the
federal government, must prepare closure cost estimates. All owners or
operators of facilities in which hazardous wastes will remain after
closure, except those facilities owned or operated by states and the
federal government, must prepare a post-closure cost estimate. The
closure cost estimates must be available on the premises on the effective
i
date of these regulations, i.e., November 19, 1980, for chose facilities
not required co have a post-closure plan. Owners or operators of land
disposal facilities, or facilities closed as such, will not be required
to have their closure and post-closure cost estimates available until
six months from the effective date of these regulations, i.e., May 19,
1981, because of the complexities involved in developing plans and
estimates for these types of facilities.
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The purpose of this documenc is co assist the Regional Offices in
implementing those sections of the interim status regulations relevant
to closure and post-closure cost estimates. Since the bases for the
cost estimates are the closure and post-closure plans, this section
should be "read in association with the guidance for closure and post-
closure plans. The remainder of this document is divided into eight
sections: basic rules for the closure cost estimate; basic rules for
the post-closure cost estimate; preparing and documenting the closure
and post-closure cost estimates; adequacy of the closure cost estimate;
adequacy of the post-closure cost estimate; revising the closure and
post-closure cost estimates; adjusting the cost estimates to account
for inflation; and sample cost estimates for various types of facilities,
The emphasis throughout this document is upon interim status. This is
particularly important to the sections on adequacy of cost estimates,
vhich are designed for rapid review and inspection.
Sample cose estimates have been developed for several kinds of
facilities in nhe final section of this document. The purpose of these
samples is co illustrate the concepts involved in closure and post-
closure cost estimates and the formats which might be appropriate. The
samples are developed through a series of worksheets designed to illus-
trate an appropriate format for demonstrating the scope and nature of
the activities involved and the key unit cost elements used in arriving
at the final estimate. Closure and post-closure costs will be highly
site-specific, and as a result, these worksheets should be viewed as
only general guidance and are unlikely to be applicable in any specific
case. In no case should the unit cpsts used in the samples be regarded
as proper and accurate costs to be used in developing cost estimates.
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2.0 BASIC RULES FOR THE CLOSURE COST ESTIMATE
In developing closure cost estimates for interim status, the
following concepts should be used for guidance.
2.1 The closure cost estimate is based upon the methods described
in the closure plan.
A cost estimate should be prepared for each activity or sub-activity
listed in the closure plan. The cost estimate is based upon the ac-
tivities, quantities and methods indicated in the closure plan. For
example, a cost estimate should be prepared for treating, disposing or
removing inventory. It must account for managing the maximum inventory
expected as indicated in the closure plan. The method used for treating,
disposing or removing the inventory vould be identical to that indicated
in the closure plan. For example, if the closure plan indicates managing
1000 tons of waste, of which 800 tons are to be disposed or treated
on-site and 200 tons removed to an off-site TSDF, the cost estimate
must include estimates for these respective costs.
2.2 "The estimate must equal the cost of closure at the point in the
facility's operating life when the extent and manner of its opera-
tion would make closure the most expensive, as indicated by its
closure plan."*
The goal of the cost estimate is to ensure that if at any point in
time a facility had to begin closure for reasons unrelated to a catas-
trophe at the site, the costs of the closure would not exceed the cost
estimate. Thus, the conditions on which the cost estimate is predicated
will probably differ significantly from anticipated conditions at the end
of normal facility life with respect to amounts of undisposed or un-
treated wastes on-hand, status of processing equipment, and area of the
facility in disturbed condition.
*EPA Interim Status Standards, 40 CFR §265.142(a)
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For example, for purposes of Che cost estimate, the estimate of
maximum inventory on-site should include the maximum normally expected
on-site. This estimate should take account of any long-term cycle of
inventory on-hand, and should take account of predictable events which
may occur over the life of the facility, such as adverse weather condi-
tions preventing normal activity at a landfill and "down time" to
periodically rebrick the refractory of an incinerator. The initial
estimate need not, however, include provisions for highly unusual
contingencies unless they exist at the time the facility submits its
initial cost estimate. For example, the cost estimate need not include
provision for such unusual contingencies as the effects of the 50-year
storm or the failure of a liner in a major trench calling for removal of
all waste in that trench. If such events occur over the life of the
facility and cause the original maximum inventory estimate to be
exceeded, the owner or operator should revise the closure plan to
reflect the current situation unless he can immediately correct the
situation so that his original estimate of maximum inventory is not
exceeded. In cases of doubt, the Regional Administrator's office should
be contacted as to the advisability of revising the cost estimate. In
no case, however, should the initial cost estimate list a maximum inven-
tory less than that actually on-site. If normal operating procedures
include steps which would reduce closure costs, such as dredging of an
impoundment or capping portions of a landfill, it should be assumed that
closure will occur just before these activities. Thus, in the closure
cost estimate all costs associated with such procedures should be
included. This assumption is to ensure adequate funds in the closure
cost estimate for the situation of forced closure due to an unforeseen
event such as business failure of the facility's owner or operator.
If experience shows that the initial cost estimate over- or under-
estimated the most expensive conditions likely to occur over the life
of the facility, or if those conditions are no longer possible, then
revisions may be made in the cost estimate as appropriate (see Section
7.0). For example, if late in the life of the facility the total
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disturbed area is only 10 acres but had exceeded 20 acres earlier, it
would be appropriate to revise the cost estimate downward.
2.3 Cost estimates are to be based upon the operating costs to the
owner or operator of carrying out the planned activities.
This means that in developing the cost estimate the owner's or
operator's depreciation costs, capital recovery factors, and interest on
debt need not be included as part of the costs. For example, capital
recovery and depreciation factors for earth-moving equipment owned by
the owner or operator and costs of land already owned need not be
considered as part of the costs of disposing of inventory at a landfill.
If equipment must be rented to complete closure activities, however, the
costs of this rental must be part of the cost estimate. If the owner or
operator plans to contract out a specific activity (e.g., sandblasting
and steam-cleaning the equipment on-site, planting vegetation), the full
costs of that contract would be the correct cost estimate.
2-4 The cost estimates should include all associated costs necessary to
carry out closure procedures.
A cost estimate for a given activity must include all costs asso-
ciated with this activity, including fully loaded labor costs (i.e.,
including fringe benefits and overhead), any costs of supervision, fuel
and maintenance costs for the equipment used, administrative costs, and
provisions for normal contingencies. Administrative costs include all
costs associated with taxes and insurance, as well as costs of routine
administration, paperwork and reporting. "Provisions for normal contin-
gencies" means that the cost estimates should include a factor for
unforeseen events that may increase costs, such as those routinely put
into most initial cost estimates. Such contingencies include adverse
weather and other unanticipated complications. Given the absence in the
closure plan of detailed engineering designs, the uncertain nature of
precise facility conditions at the time of closure, and the lack of
provision for inflation during the closure period (which, in some cases,
can be quite lengthy), the provision for contingencies should be
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generous. Standard engineering practice shows that in most cases
a provision for contingencies could reasonably be expected to fall
within the range of 15 to 25 percent. The lower end of the range
is appropriate for smaller facilities which require a short closure
period and have fewer uncertain variables. The higher end of the
range accounts for larger.facilities which may require extensive
activities and a longer closure period, for which unusual weather
conditions or uncertain decontamination needs could seriously affect
the cost of closure.
A cost estimate for treating inventory in an incinerator would
include fully loaded labor costs, supervision, maintenance, utilities,
any chemicals and catalysts employed, administration, and provisions
for contingencies. Although the cost estimate should include all of
these cost elements, they need not be documented separately. Thus, for
example, well documented unit costs for treating inventory are
appropriate even if they do not include separate documentation for
maintenance, utilities, or all energy costs. This point is further
discussed in Section 4.0 and examples of an appropriate approach
are shown in Section 9.0.
j
2.5 The cost estimates should be based upon costs in the year in which
the estimate is prepared; there is no need to provide for inflation
in developing the cost estimate, as this will be provided for in
the adjustment procedure.
Costs should be based upon current costs. For practical purposes,
this means costs within one year of the time of preparation of the cost
estimate. There is no need to adjust data or cost estimates based
upon data within the current year to the exact month for which the
cost estimate is dated.
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3.0 BASIC RULES FOR THE POST"CLOSURE COST ESTIMATE
In developing a post-closure cost estimate for interim status, the
following concepts should be used for guidance.
3.1 A post-closure cost estimate must be prepared for all facilities
at which hazardous wastes remain on-site after closure.
Post-closure cost estimates are required for landfills and surface
impoundments and land treatment systems at which any hazardous wastes
remain on-site following final closure. If an owner or operator of
a surface impoundment originally plans to close it as a storage or
treatment facility by removing all hazardous waste, but later decides to
close it as a disposal facility, he must immediately prepare a post-closure
plan for the facility. In similar fashion, if the owner or operator of a
land treatment facility originally prepares a closure plan based on the
assumption that treatment will render the waste non-hazardous but tests
show this is not the case, he must immediately prepare a post-closure
plan and cost estimate.
3-2 The post-closure cost estimate is based upon the methods described
in the post-closure plan.
The post-closure cost estimate is based upon the activities, quan-
tities, and methods indicated in the post-closure plan. A cost estimate
should be prepared for each activity or sub-activity listed in the post-
closure plan. For example, a cost estimate should be prepared to cover
maintenance activities. It must reflect the methods to be used in the
post-closure plan and the rates of fertilization, mowing, sprinkling,
and other activities listed in the post-closure plan.
3-3 The post-closure cost estimate should be prepared for the entire
area expected to contain hazardous waste at the time of final
closure.
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The post-closure estimate should provide for post-closure care for
the entire facility as it is expected to exist at the time of final
closure. Thus, if a 180-acre facility is expected to be filled at a
rate of 10 acres per year, the initial post-closure cost estimate must
reflect the costs of post-closure care for the full 180 acres.
2.4 The post-closure cost estimate should reflect the costs nf
purchasing all necessary labor, materials and equipment to carry
out post-closure requirements. Unlike the closure cost estimate,
it may not be assumed that the owner or operator already has
adequate equipment for the purpose.
It is highly uncertain whether the entire period of post-closure
care will be carried out by the owner or operator himself, and whether
on-site labor and equipment will be available. Therefore, the cost esti-
mate should assume that all services required for post-closure must be
contracted for in order to ensure financial adequacy. The post-closure
cost estimate must therefore include adequate allowance for profits on
the post-closure care services. For example, if regular mowing is part
of the post-closure plan, the costs must reflect the costs of hiring a
service to carry out this mowing, rather than the cost of having a laborer
of the owner or operator using mowing equipment already in use elsewhere
by the owner or operator. Similarly, monitoring costs must be estimated
assuming it is necessary to hire outside help both to take the necessary
samples and to conduct the necessary laboratory tests.
3.5 The post-closure cost estimate must be complete and include all
associated costs necessary to carry out post-closure procedures.
A cost estimate for a given activity must include all costs asso-
ciated with this activity, including fully loaded labor costs, any costs
of supervision, fuel and maintenance costs for equipment used, adminis-
trative costs, and provisions for normal contingencies. Administrative
costs include all costs associated with taxes and insurance, as well
as costs of routine administration, paperwork and reporting. "Provisions
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for normal contingencies" means that the cost estimates should include a
factor for unforeseen events that may increase costs, such as those
routinely put into most initial cost estimates. Such contingencies
include adverse weather and other unanticipated complications. Given
the absence in the post-closure plan of detailed engineering designs,
the uncertain nature of precise facility conditions at the time of post-
closure, and the uncertainty of the kinds of maintenance to be required
during the post-closure period, the provision for contingencies should
be generous. Standard engineering practice shows that the provision
for contingencies could reasonably be expected to fall within the
range of 15 to 25 percent. As with closure costs, the documentation
for the cost estimate need not break out all of these headings
separately; they must, however, be included in any unit or activity
cost estimates (see Sections 4.0 and 9.0). It is particularly important
in the case of post-closure care to include supervision and inspection
requirements that normally might be neglected in the cost estimate.
Since labor may no longer be readily available on-site, such routine
functions as facility inspection and supervision and review of work
must be explicitly included.
3-6 The jost-closure cost estimate covers the period beginning at the
completion of closure of the facility and lasts for 30 years there-
after.
The post-closure cost estimate does not cover the cost of main-
taining any partially closed portions of the facility during facility
Life., However, the fact that partial closure has occurred for portions
of the facility does not in any way shorten the period of post-closure
care required for the purposes of the post-closure cost estimates. The
post-closure period begins with the professional engineer's certifica-
tion of adequate closure. As a result, provision should be made for any
normal remedial measures early in the post-closure period, such, as
significant portions of the vegetation failing to develop adequately.
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3. 7 Pose-closure expenditures can be expected to occur in cwo cate-
gories: regular annual expenditures and expenditures chat occur
with less than annual frequency. The written estimate of Che
annual cost of pose-closure monitoring and maintenance is equal co
Che sum of regular annual expenditures plus the expected number of
non-annual expenditures times their costs.
This can be written as the following formula:
where P is the annual post-closure cost estimate, A is the size of
expenditures occurring annually, Ft is the number of times over 30 years
non-annual expenditure i is expected to occur, and N£ is the cost of
non-annual expenditure i. There may, of course, be several kinds of
annual expenditures and several kinds of non-annual expenditures.
Specific types of non-annual expenditures that need to be considered
include provisions for special activities resulting from unusual
weather, replacement of equipment, and provisions for replanting and
other similar activities in the two to five years following closure.
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4.0 PREPARING AND DOCUMENTING THE
CLOSURE AND POST-CLOSURE COST ESTIMATES
Although written closure and post-closure cost estimates are
required, the regulation -does not specify format or documentation suit-
able for this cost estimate. As a result, the ultimate requirements in
this area will be up to the discretion of the Regional Administrator.
Certain general guidance may, however, prove useful. The cost estimate
must ultimately contain at least enough detail so that the Regional
Office can make a reasonable evaluation of its validity at the time
of inspections during interim status.
The overall goal of the cost estimate and its documentation is to
provide an estimate of the costs and the documentation necessary
to demonstrate the reasonableness of the estimate. It is not
required that the cost estimate have the kind of detail and accuracy
appropriate to a contractor preparing a bid for a job. There is little
need for a highly polished cost estimate since these cost estimates are
for a hypothetical task that is to take place in che rather distant
future.
Four basic approaches which might be used in developing costs for
the activities listed in the closure plan are:
Costs based upon experience of the owner or operator
Contractor estimates
« Cost estimation handbooks
Workups from labor, material and equipment requirements
4.1 COSTS BASED UPON EXPERIENCE OF THE OWNER OR OPERATOR
The most directly relevant source of cost information, in many
cases, will be the experience of the owner or operator in operating the
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facilicy. An example would be the costs of treating or disposing of
inventory on-site, which will normally be a simple continuation of the
normal operating practices of the business. In the simplest case, cost
of treating or disposing of inventory may be computed as the annual
operating costs divided by the fraction of a year required for adequately
treating or disposing of inventory. Such an estimate could then be
documented by the past year's accounts, the amount of material treated
or disposed over that year, and evidence that the year had involved
relatively typical activities (e.g., if, for a landfill, no trench
had to be dug or covered over the course of the year, then the year
might not be considered a suitable example from the viewpoint of
assuming the most expensive closure conditions likely to occur over the
life of the facility) . Given that the requirement that a cost estimate
be available on-site is either six or twelve months after notification
of the cost estimation requirement, a variety of closure activities could
be documented from noting the costs of the activity as they occur over
the interim period.* For example, for a landfill, the costs and activities
involved in partial closures could be documented and used as a base for
unit cost estimates of the cost of final cover.
Similarly, costs of monitoring tests during post-closure will be
similar to the costs of monitoring tests during facility life, though
gathering samples will be more expensive due to the need to assume
purchased labor and travel to the facility. Possibly the best source
for costs and frequency of many kinds-of post-closure non-routine
expenditures is the actual experience in maintaining currently partially
closed portions of a landfill.
4.2 CONTRACTOR ESTIMATES
A variety of costs, particularly if services are to be purchased
from a contractor or contractors by the owner or operator, may be
*As discussed in Section 1.0, owners or operators of land disposal
facilities are not required to nave their cost estimates available
until twelve months after the effective date of these regulations.
Owners or operators of other facility types must have an estimate'
available within six months of the effective date of these regulations,
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obtained from contractor estimates. For example, an owner or operator
could ascertain the costs of certification by an independent professional
engineer by asking several professional engineers for estimates of the
costs of certifying the completion of activities listed in the closure
plan. If an owner or operator plans to send either inventory or con-
taminated residues to an off-site TSDF, inquiries to ascertain distances,
hauling costs, and treatment or disposal costs would be in order. It is
not necessary for purposes of documenting, to have written and validated
cost estimates. Adequate documentation could note who was contacted
and their approximate estimates.
4.3 COST ESTIMATING HANDBOOKS
There are a variety of commercial engineering cost estimation manuals
that provide guides to equipment and labor needs and unit costs of
specific operations that may be relevant to various activities associated
with closing hazardous waste facilities. Such manuals may be reasonably
used as a source for cost estimates for closure costs. Care must be
taken in using such manuals. They vary widely with respect to whether
or not unit costs cited include such factors as administration, normal
contingencies, profits, and whether or not allowances must be made to
adjust theoretical work rates to normal field conditions.
From the owner's or operator's view, care should be taken that an
overestimate is not produced by using estimates which allow for profits
and capital recovery on equipment when this is not required if he is using
his own equipment for closure. Distinct underestimates are possible if
attention is not given to the indicated need for adjustment of theore-
tical work rates to normal field conditions and for administrative costs.
As a result, suitable documentation for a cost estimate for an activity
based upon such a handbook would be a copy of the relevant pages of the
handbook, including those pages providing instructions as to the use of
the unit cost estimates and any adjustments from the cited costs used in
arriving at the unit cost estimate employed in the cost estimate itself.
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4.4 WORKUPS FROM LABOR, MATERIAL AND EQUIPMENT REQUIREMENTS
In some cases, there may be no way to arrive at a useful cost
estimate other than by a detailed workup of the costs. Such a workup
would include an estimate of the labor, equipment, energy and material
needs for the activity to.be estimated, the basis for these assumptions,
and the total time required for the activity. Allowance would then
need to be made for supervision and administrative costs and any
necessary adjustments for fully loaded labor and equipment costs.
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5.0 ADEQUACY OF THE CLOSURE COST ESTIMATE
For Che closure cost estimate to be judged adequate, It must meet
the following criteria:
1. The closure cost estimate must contain cost estimates for all
activities presented in the closure plan. The cost estimate must also
reflect the quantities and methods associated with all of the activities
presented in the closure plan. (Note that the adequacy of the cost
estimate is therefore dependent on the adequacy of the closure plan.)
2. The closure cost estimate must be documented in order that the
bases for the cost estimate can be checked.
3. The resulting cost estimate must reflect the actual costs of
carrying out closure. This can be determined by a check of the sources
listed for documentation providing that Rule 2 has been met. A cross-
check can be made by using alternative sources, i.e., if the owner's or
operator's cost estimate is based upon a contractor estimate, this may
be checked through reference to a cost estimation manual, experience of
other owners or operators, or inquiries to other contractors.
The cost estimate must be available upon the premises for inspec-
tion during interim status. As a result, it will be useful to have
available simple and rapid checks as to the adequacy of the cost esti-
mate. The remainder of this discussion is devoted, in part, to a discus-
sion of simple checks that could be accomplished in less than an hour or
two with the aid of the closure plan and a visit to the facility to deter-
mine the adequacy of the closure plan (see Section 12.Oof the draft
guidance for Subpart G, Closure and Post-Closure Care). These checks
are not intended for use by owners or operators and may not be used as a
method for developing a cost estimate.
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If an initial check raises questions as to the adequacy of the cost
estimate, several steps may be taken. First, a copy of the complete
cost estimate may be required and reviewed, and a check made of the
documentation. It is quite possible that the cost estimate could be
accurate and fall outside the ranges indicated in the discussion below.
If, after review, the cost-estimate still seems inadequate, the owner or
operator could be specifically requested to make the desired alterations.
If this approach fails to result in a satisfactory cost estimate, there
are two possible recourses during interim status. The Regional Adminis-
trator could bring an enforcement case or he could request part B of the
permit application and thus revise the cost estimate as part of the permit
application process.
Unfortunately, the annual report of the facility, though it must
include the cost estimate, does not contain adequate information to
determine the accuracy of the cost estimate. For example, the amount
of inventory on-hand is not a required element of the permit application.
Therefore, in order to check on the accuracy of the cost estimate, it
may be necessary to visit the facility. An inspector could then obtain
copies of the closure plan and cost estimate, and conduct a quick review
of the key variables for the closure plan, as discussed in Section 12.C
of the draft guidance for Subpart G, Closure and Post-Closure Care.
Table 5-1 shows the key elements involved in verifying the closure
cost estimate, listed by major '-ypes of activity involved. For each
activity, the major elements required to check the adequacy are the
activity indicator (the variable that determines the degree of the
activity, e.g., quantity of inventory, volume of contaminated soil),
unit costs (estimates of the unit costs for each activity of the facility
in question) , and sources for variation in unit costs from facility to
facility. Also included in this table are current typical costs of each
required activity. A relatively wide range is used due to variations
depending upon the region and upon the nature of the wastes (e.g., high
hazard wastes have greater costs than lower hazard wastes). As these
costs are national averages, more accurate estimates would be obtained
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TABLE 5-1
CLOSURE COST ESTIMATE KAl'lD CHECKS
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-------�
using average costs for the specific area. These costs also must be
adjusted annually for inflation. A mechanism for making this inflation
adjustment is discussed in Section 8.0.
For example, to check the adequacy of the cost estimate of treating
or disposing of inventory,'one would:
(1) Determine the adequacy of the estimated amount of inventory
(this could most readily be done by examining the closure plan
and facility conditions to determine whether the closure plan
adequately reflects inventory needs of the facility);
(2) Determine whether, in the case of treatment facilities (including
incinerators), provision has been made for treating, disposing,
or removing residues off-site which result from treating inventory;
(3) Multiply the quantity of inventory in the closure plan by the
unit costs given in the Table; and
(4) Consult the variability factors listed in the Table (e.g.,
throughput, type of facility, nature of waste, on- or off-site
disposal), to determine whether the facility should be at the
high or low end of the range for unit costs.
5.1 ACTIVITIES RELEVANT TO ALL FACILITIES
5.1.1 Treating. Disposing, or Removing Inventory
For facilities not engaged in disposal requiring post-closure care
(all types of facilities except landfills, and surface impoundments and
land treatment facilities in which hazardous wastes remain after closure),
treating, disposing or removing inventory will frequently be the largest
single cost element. The exceptions to this rule of thumb will normally
be situations in which unusual decontamination problems occur, such as
large amounts of waste water accumulating at the facility. The key unit
parameters in determining the costs of treating, disposing or removing
inventory to an off-site TSDF are the amount of inventory on-hand and,
for incineration and processes involving treatment, the relationships
3-4
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between inventory processes and residues co be disposed of or treated
on-site or removed to an off-site TSDF. The quantity of inventory on-
hand will vary enormously depending on the type of facility, the annual
throughput of the facility, and management practices. For some types of
facilities, inventory can be minimal. For example, some landfills accept
only trucked-in wastes on a space-available basis. For such a landfill,
there would very seldom be any inventory at all. It is also possible,
however, that start-up problems or, in the case of landfills, failure of
a major cell or cells could lead to a situation in which there is an
enormous amount of inventory which cannot be quickly worked off, and this
would have to be accounted for in the cost estimate.
The unit costs of removing inventory are dependent upon whether the
inventory is to be disposed of or treated on-site or removed to an off-
site TSDF. In the vast majority of cases at disposal facilities, the
disposing or treating of inventory will take place on-site. If disposal
or treatment takes place on-site, the unit costs can be expected to
fall between 30 and 80 percent of the prevalent Regional costs for
remo"ing the inventory to an off-site TSDF. On-site costs will be less
than off-site costs because closure costs r.eed only include the immediate
operating costs of disposing or treating inventory and not factors for
capital recovery, land, etc. The variation will depend upon the type of
facility, its normal throughput (because of economies of scale, small
facilities will have higher unit costs than large facilities for almost
all types of facilities) , the quality and safety of disposal practices
at the facility, and the nature of the wastes. For a landfill which always
maintains adequate open trench capacity, inventory disposal costs could
be a very small fraction cf normal off-site landfill disposal costs. This
is because the costs of building the trench would not need to be included,
and the costs of cover and vegetation are covered separately. Under these
circumstances, costs for treating or disposing of inventory could
be lower than the 30 percent indicated. For inventory or residue that
must be removed to an off-site TSDF, unit costs will be 100 percent of
normal off-site costs in the Region, plus appropriate hauling costs.
5-5
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5.1.2 Decontaminating the Facility
Under certain circumstances, decontaminating the facility could be
the largest cost element for the facility. This could be the case if
large quantities of soil are contaminated, as might occur at any poorly
run facility or at many improperly run surface impoundments, or if large
amounts of waste water have accumulated at the facility. For many
facilities, however, decontamination will be a relatively minor cost
element requiring only general cleanup of equipment and facilities. The
key activity indicators for decontaminating the facility are: quantity
of contaminated soil; quantity of contaminated waste water; and amount
of equipment and facilities requiring cleaning.
For contaminated soil and waste water, the relevant unit costs will
be those cited for disposing or treating inventory, i.e., costs for
disposing or treating the soil and water on-site or off-site. For
equipment and facilities, the costs will depend uoon cleaning costs
themselves and whether or not the residues resulting from cleaning will
require treatment as hazardous waste.
5.1.3 Monitoring
A facility must continue monitoring practices during the closure
period; therefore, some costs must be included for monitoring. The
costs may be estimated using the current lab costs for the tests in
the Region and will vary regionally and according to the monitoring plan
in place for the facility.
5.1.4 Professional Engineer Certification
The closure cost estimate must include provisions for the costs of
certification by an independent professional engineer. Like monitoring,
this will normally be a relatively minor cost element. The activity
indicator for certification is the hours spent on-site by the professional
engineer, which will normally depend upon the length of the closure period
and the amount of activity which must take place. The unit cost parameter
is dollars per hour of professional engineer time in the Region.
5-6
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5.2 COSTS REQUIRED ONLY OF LANDFILLS AND SURFACE EIPOUNDMENTS
5.2.1 Cover
Some form of cover will usually be required for both landfills and
surface impoundments which have hazardous wastes remaining after
closure. Cover and the associated vegetation (see Section 5.2.2) will
normally be the dominating element in determining the costs of closure
for a landfill or surface impoundment.
The materials to be used will depend on the types of soil available
on-site as well as the conditions of the facility. Since purchasing
soil off-site is costly, it is likely that most owners or operators
will use soil available on-site, if at all possible, for the final cover,
i.e., the layer with low permeability and the layer capable of supporting
vegetation, if applicable. It is possible to improve the quality of
available soil by blending various soils, using soil additives, or making
other provisions which would provide equivalent protection. For example,
soil blending and synthetic additives may decrease the permeability of
the on-site soil as well as make certain soils more capable of supporting
vegetation. In addition to improving the quality of available soil,
the Agency anticipates that many owners or operators will use membrane
liners protected above and below by buffer soil layers instead of com-
pacted clay for the layer of the cover with low permeability. These
membrane liners may be cost effective if adequate on-site soil material
is unavailable or an acceptable degree of compaction is not possible at
a particular facility, given the wastes disposed or facility conditions.
When clay is used as a liner material, the key activity indicators
are acres not yet covered and the depth of the cover. As noted in the
closure plan, decisions as to the depth of the cover and the adequacy of
on-site materials are dependent on engineering judgment and are not
covered in this guidance document. The costs associated with such cover
may vary from S500 to $1500 per foot per acre of cover. The key sources
of variation are:
5-7
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(1) The amount and nature of terracing to be used in the cover;
(2) The depth of the area to be filled in the case of surface
impoundments;
(3) The nature of the cover, including whether or not treatment
is required to achieve proper degrees of impermeability; and
(4) The design of the cover.
For synthetic liners, the key activity indicator is the acres not
covered. The costs associated with such covers vary widely, depending
on the type of material chosen and the thickness needed to ensure adequate
low permeability. It is not the purpose of this document to assess
alternative materials or to provide guidance as to the level of per-
meability which is acceptable. The costs associated with installed
liner material per acre vary from $5,000 to 320,000 per acre. The key
sources of variation are:
(1) The amount and nature of terracing to be used in the cover;
(2) Type of liner material chosen; and
(3) Thickness of material necessary to achieve desired degree of
permeability.
5.2.2 Vegetation
For most facilities, some vegetation will be required in order to
stabilize the cover and prevent erosion problems. The key activity
indicators are the number of acres in need of vegetation (which may include
areas previously seeded but for which vegetation has not properly
developed) and the type of vegetation to be employed. Unit costs can
be expected to range from $400 to $1,500 per acre. The lower end of
the range would represent the costs of minimum fertilization and planting
with no provision for reseeding and replanting of any kind. The maximum
costs would represent the costs of providing a lawn-type cover. Other
key variables in determining cost of vegetation are:
5-8
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(1) The type of soil (including determining the degree of
fertilizer required); and
(2) The type of seed used.
Establishing complete vegetation within the 90 days to six months over
which closure will normally take place cannot be attained. As a result,
some costs associated with developing and establishing vegetation will
probably take place early in the post-closure period. Therefore, the
adequacy of the closure plan with respect to vegetation should be checked
in coordination with an examination of the provisions for maintaining
vegetation in the early years of the post-closure plan.
5.2.3 Optional Measures
Three kinds of optional measures, bearing significant costs, may be
necessary at some facilities: collection, removing and treating leachate;
collecting gas; and additional measures required to protect human health
and the environment. Even for facilities with leachate collection systems,
the cost of leachate collection, removal, treatment and disposal for
closure will normally be the relatively minor cost of occasionally
collecting the leachate and hauling it away to an off-site TSDF. In
certain rare cases, leachate build-up may be great enough to require
an extensive on-site treatment and disposal system. If this is the
case, this could be a significant cost during the closure period.
Maintaining an existing gas collection system normally will be a rela-
tively minor cost. At certain facilities, additional activities may
be required to ensure the protection of human health or the environment,
such as those discussed in Section 9.0 of the draft guidance for Subpart G.
Such measures could be extremely expensive and would constitute a large
share of closure costs; however, the exact combination of necessary
measures will be extremely site-specific.
5-9
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6.0 ADEQUACY OF THE POST-CLOSURE COST ESTIMATE
For the pose-closure cose estimate to be judged adequate, It must
meet the following criteria:
1. The post-closure cost estimate must contain cost estimates for
all activities presented in the post-closure plan. The cost estimate
must also reflect the quantities and methods associated with all of the
activities.presented in the post-closure plan. (Note that the adequacy
of the cost estimate is therefore dependent on the adequacy of the post-
closure plan.)
2. The post-closure cost estimate must be documented so that the
bases for the cost estimate can be checked. Documentation may be
performed in a variety of ways; however, it must be provided in such
a way that the sources can be reviewed and judged by an outside party.
For example, if an owner or operator states that a cost estimate was
taken from an engineering cose estimation manual, the estimate could
be easily verified.
3. The resulting cost estimate must reflect the actual costs of
carrying out post-closure activities. This can be determined by a check
of the sources listed for documentation providing that Rule 2 has been
met. A cross-check can be made by using alternative sources, i.e., if
the owner's or operator's cost estimate is based upon a contractor
estimate, this may be checked through reference to a cost estimation
nanual, experience of other owners or operators, or inquiries to other
contractors.
The cost estimate must be available on the premises for inspection
during interim status. As a result, it will be useful to have available
simple and rapid checks as to the adequacy of the cost estimate. The
remainder of this section is devoted to a discussion of simple checks
of the costs of specific activities that could be used with the aid of
the closure plan and a visit to the facility to determine the adequacy
of the post-closure plan (see Section 12.0 of the draft guidance for
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Subpart G, Closure and Pose-Closure Care). These checks are not
intended for use by owners and operators and may not be used as a method
for developing a cost estimate.
If an initial check raises questions as to the adequacy of the cost
estimate, several steps may be taken. First, a copy of the complete
cost estimate may be requested and reviewed, and a check made of the
documentation. It is quite possible that the cost estimate could be
accurate and fall outside the ranges indicated in the discussion below.
If, after review, the cost estimate still seems inadequate, the owner or
operator could be specifically requested to make the desired altera-
tions. If this approach fails to result in a satisfactory cost estimate,
there are two possible recourses during interim status. If the cost
estimate is-obviously completely inadequate, the Regional Administrator
may start an enforcement action or he may request part B of the permit
application and revise the cost estimate as part of the permit applica-
tion process.
Unfortunately, the annual report of the facility, though it must
include the cost estimate, does not contain adequate information to
determine the accuracy of the cost estimate. Therefore, in order to
check on the adequacy of the cost estimate, it may be necessary to visit
the facility. An inspector could then obtain copies of the post-closure
plan and cost estimate and conduct a quick review of the key variables
for the post-closure plan, as discussed in Section 12.0 of the draft
guidance for Subpart G, Closure and Post-Closure Care.
Table 6-1 shows the costs of certain activities which may be asso-
ciated with post-closure cost estimates. This is a list of selected
major activities, and is not intended to reflect all possible post-
closure activities. These activities have been broken down by key cost
elernencs rather than by elements of the post-closure plan. For example,
one heading in Table 6-1 is "Inspections and Facility Visits." The table
simply shows the expected costs of such visits per hour on-site. Deter-
mining the number of inspections and facility visits required will be
6-2
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highly site-specific and will depend upon the post-closure plan. Further,
these inspections and facility visits may serve a variety of purposes in
the post-closure plan. For example, inspections and facility visits may
be for the purpose of ensuring adequate erosion control, maintaining
surveyed benchmarks, obtaining ground-water monitoring samples, or check-
ing the adequacy of leachate collection facilities.
Table 6-1, for each activity indicated, shows an estimate of unit
costs and notes the sources of variation in these unit costs. The unit
costs are given in 1980 dollars. In order to maintain the accuracy of
Table 6-1, it should be updated on an annual basis to reflect inflation.
A. discussion of the methods for adjusting the cost estimates to account
for inflation is provided in Section 8.0. The sources of variation in
unit costs are specific to the headings listed. Two generic sources of
variation, however, have not been noted. First, all costs can be
expected to vary regionally and locally. Ideally, these national esti-
mates of unit costs should be replaced by costs developed from experience
for the region or state in which the facility is located. Second, all
costs will vary with the remoteness of the facility. Since most post-
closure activities are relatively small in scale and may involve only
a few days on-site, significant travel time to and from the facility
will have a noticeable effect on almost all costs.
5.1 INSPECTIONS AND FACILITY VISITS
As noted above, inspections and facility visits may be needed for a
variety of purposes. The unit costs given will thus be relevant in
checking the costs of a variety of activities. The estimated unit costs
in 1980 dollars are $20 to $100 per hour on-site. The chief source of
variation in these unit costs will be the professional level of the
personnel involved. It will normally be useful to have an inspection or
facility visit by a professional engineer at least once a year. Inspections
and facility visits by less technically qualified personnel will depend upon
Che specifics of the post-closure plan, the climate, and the size and
nacure of the facility.
6-3
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TABLE 6-1
COSTS OF SELECTED POST-CLOSURE ACTIVITIES
ACTIVITY
UNIT COSTS*
SOURCE OF VARIATION
IN UNIT COSTS**
1. Inspection/Facility
Visits
2. Reestablishing
Cover and Vegetation
3. Fertilizing
&. Mowing
5. Ground-water
Monitoring
6. Maintaining ana
Replacing Fences
7. Collecting, Removing
and Treating Leachate
$20-100/hr. on-site Professional level
of personnel
S300-1500/acre
$50-200/acre
$10-30/acre
S200-600/well
S.20-.80/f=./yr.
S. 20-.80/gallon
Amount of erosion
Nature of cover
Type of soil
Amount & density
of seed
Amount of fertilizer
Method of spreading
Monitoring plan
requirements
Type of fence
Climate
Chemical composition
1980 dollars.
**
All costs of all activities vary by region and with the remoteness
of the facility.
6-4
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6.2 REESTABLISHING COVER AND VEGETATION
Reestablishing cover and vegetation may be necessary for a variety
of purposes, including:
Replanting to establish vegetation not adequately established
during closure;
Replanting to repair minor erosion or rodent control
problems ;
Reestablishing cover lost as a result of a major contin-
gency, such as a major storm or flood; and
Reestablishing cover to correct for subsidence problems.
The costs of this activity in 1980 dollars may range from S300 to
$1,500 per acre. This cost will vary according to the nature of the
cover, the type of soil used, and the amount and density of seed. In
addition, the costs can be expected to vary according to the amount of
erosion or subsidence which necessitates replacing the topsoil or cover
material. The lowest costs are for simple replanting, and the highest
are for reestablishing and compacting as well as reseeding substantial
portions of the clay cover and topsoil.
6.3 FERTILIZING
Depending upon the vegetation, topsoil employed, and climate, some
fertilization may be necessary. The frequency will be highly variable.
The estimated range of costs for this activity is $50 to S200 per acre
with the variation dependent upon the amount of fertilizer and the
method of spreading it.
6.4 MOWING
Mowing is necessary in any climate in which deep rooted vegetation
Jiay readily be established. In most cases, it will be the most cost
effective means of preventing such deep rooted vegetation. In some
6-5
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climates, mowing requirements may be minimal or tnere may be more cost
effective methods than mowing for ensuring that deep rooted vegetation
does not become established. The estimated range of costs in 1980
dollars is S10 to $30 per acre.
6.5 GROUND-WATER MONITORING
At all facilities, a ground-water monitoring program of some kind
will be required. In addition to the costs of associated site visits
to gather samples, these costs will be based on the average costs of
the tests required, which are the result of the monitoring plan require-
ments .
6.6 MAINTAINING AND REPLACING FENCES
Many facilities will be required to have some kind of fence as
security during the post-closure period. Assuming the use of some type
of chain link fence, provision will need to be made for replacing the
fence at least once over the 30-year post-closure period. In addition,
some provision must be made for inspecting and maintaining the fence.
It is estimated that the cost of such maintenance and replacement will
be S.20 to S.80 per linear foot of fence per year. The variation is
dependent upon the type of fence used and the severity of the climate.
6.7 COLLECTING, REMOVING, AND TREATING LEACHATE
At some facilities, a system for collecting, removing, and treating
leachate may be required during post-closure. The estimate given here is
based on the assumption that a small amount of leachate will be collected
periodically and removed to an off-site TSDF. The costs of an extensive
leachate collection system requiring treatment on-site would normally be
much higher. The estimated range in costs is from $.20 to $.80 per
gallon of leachate removed, with the range in the costs depending in part
upon the chemical composition of the leachate.
6-6
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7.0 REVISING THE CLOSURE AND POST-CLOSURE COST ESTIMATES
The closure and post-closure cost estimates must be revised when-
ever a. change in the closure or post-closure plan is made that affects
the costs of closure or post-closure care. Changes to closure and post-
closure plans are discussed in Sections 11.1 and 11.2 of the guidance
for Subpart G of the Interim Status standards. Changes in the closure
plan which may cause a revision in the closure cost estimate include:
Change in facility size and/or capacity;
Changes in technology that may affect treatment and disposal or
decontamination techniques, type of cover chosen, etc.;
Changes in the closure schedule which alter the length of
the closure period by greater than one month (e.g., severe
weather conditions may halt construction activities and
extend the closure period by more than one month);
Changes in the schedule of periodic activities which
affect activities required at closure (e.g., failure to
partially close a facility would mean that a larger area
than previously estimated would need to be closed at
closure; the closure plan must always account for the
maximum extent of the operation open at any time over the
life of Che facility);
Changes in types and/or quantities of wastes chat affect
activities required at closure (e.g., the type and/or
quantity of waste on-site at closure will affect the
choices of treatment and disposal; for example, the amount
of waste removed to an off-site TSDF by the owner or operator of
an incinerator depends on the types and quantities of resid-
uals that remain after burning the wastes. The
types and quantities of waste can also affect monitoring
requirements and cover requirements);
7-1
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Change in maximum quantity of inventory ever expected on-
site;
Change in cover requirements from what was originally
proposed;
Changes in ground-water monitoring requirements as a result
of an owner's or operator's operating experience or new data
which was not available when the plan was written. The ground-
water monitoring regulations stipulate that all or part of the
requirements may be waived if there is a low potential for
pollution (§265.90). Revisions will also be likely when the
EPA provides more guidance and technical engineering data on
the kinds of monitoring appropriate for hazardous wast3 facil-
ities; and
Operating contingencies during closure which may affect closure
requirements (e.g. , inclement weather causes construction
problems; more contaminated soil needs to be disposed
at closure than anticipated as a result of problems occurring
during operation) .
Changes in the post-closure plan which niay cause a revision m cne
post-closure cost estimate include:
Change in facility size which will affect the extent of
maintenance required;
Changes in monitoring requirements as a result of an
owner's or operator's operating experience, new data which was not
available when the plan was written or modifications approved by
the Regional Administrator (e.g., changes in the number of wells
monitored and samples, the frequency of analyses, types of
analyses required) . During the 30-year post-closure
period, the owner or operator may petition the Regional
Administrator to discontinue or alter the monitoring
requirements; alternatively, under certain circumstances,
7-2
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the Regional Administrator may require an owner or operator
to continue monitoring beyond 30 years. Revisions will also
be likely when the EPA provides more guidance and technical
engineering data on the kinds of monitoring appropriate
during post-closure;
Changes in annual"routine maintenance, including changes
in the nature and frequency of the activities required
(e.g., a more extensive erosion control program may be
required than originally anticipated);
Changes in activities required on an intermittent basis
or changes in the frequency of these activities (e.g., an
accelerated replanting schedule or more frequent replace-
ment of wells than anticipated);
Operating contingencies which occur during the life of the
facility or pose-closure which affect post-closure ac-
tivities (e.g., severe weather conditions affecting acti-
vities required for erosion control, cover maintenance,
or maintenance of diversion structures);
Changes in surrounding land use (e.g., if the population
density increased, the measures needed to maintain
facility security might change; ground-water monitoring
program might be affected);
Changes in monitoring and maintenance technology; and
Modifications approved by the Regional Administrator; the
owner or operator may petition the Regional Administrator
to allow some or all of the requirements for post-closure
to be discontinued or altered before the post-closure period
is ended; any such changes can only be made after the
post-closure period begins and would constitute a revision
to the post-closure plan made during post-closure.
7-3
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Revisions may be desirable chat either raise or lower the closure
and post-closure cost estimates. For example, the closure cost estimate
may need to be revised and increased if partial closure schedules are
not met or if there is unexpected accumulation of inventory due to
temporary problems at the facility. It is quite possible, however, that
the cost estimate may need to be revised downward. A facility may have
very large inventory due to temporary start-up problems at the time the
cost estimate is first developed which is later reduced to a more normal
inventory. In such a situation, revising the closure cost estimate
downward would be reasonable. It is also possible, given the rapid
development in some types of hazardous waste disposal, that new technol-
ogies may offer much less expensive means of carrying out certain
activities than are now envisioned. This would also be a legitimate
cause for revisions of the plan and cost estimate.
7-4
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8.0 ADJUSTING THE COST ESTIMATES
TO ACCOUNT FOR INFLATION
Subpart H of the Interim Status Standards requires that both the
closure and post-closure cost estimates be adjusted annually for infla-
tion. This adjustment is to take place on the anniversary of the
effective date of the regulations, November 19, 1980. Although owners
or operators of land disposal facilities are not required to have
estimates available until May 1981 (six months from the effective date
of these regulations) , all owners or operators are required to adjust
their estimates beginning in November 1981 and annually thereafter.
Adjustments of the post-closure cost estimate for inflation need not
take place once the facility is closed.
Data for calculating the inflation adjustment factor must be ob-
tained from the "...annual Implicit Price Deflator for Gross National
Product as published by the U.S. Department of Commerce."* This price
deflator is published in the Survey of Current Business, a U.S. Depart-
ment of Commerce, Bureau of Economic Analysis, publication, and in
Economic Indicators, a Council of Economic Advisors publication. These
documents are published monthly and subscriptions may be obtained from
Superintendent of Documents,-U.S. Government Printing Office,
Washington, D.C., 20402. This information also may be obtained by
calling the Bureau of Economic Analysis, U.S. Department of Commerce.
The GNP price deflator was chosen as an appropriate inflation index
and is more, accurate than the more readily available Consumer Price
Index and Wholesale Price Index. However, it is not as widely published
as the other two indices. Thus, the typical hazardous waste facility
owner or operator, in the normal course of his business, will not have
data on the implicit price deflator for GNP or copies of the Survey of
Current Business or Economic Indicators. Copies of these publications
*EPA Interim Status Standards, 40 CFR §265.142(c)
8-1
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also may not be readily available in small libraries co which the
owner or operator might have easy access. As a result, the EPA
Regional personnel must have available the most recent editions of
che Survey of Current Business or Economic Indicators and provide the
necessary adjustment factor to owners or operators who telephone or
write for this information.
Table 8-1 shows a sample of the section in the Survey of Current
Business in which the GNP implicit price deflator may be Eound. The
table is constructed to show how this section might appear on 19 Novem-
ber 1981, the "first anniversary of the effective date of the regula-
tion." The numbers shown are hypothetical, as this guidance document is
being written in May 1980. The implicit price deflator to be used is
the first for which numbers appear, i.e., the one labeled Gross National
Product as underlined in Table 8-1. The note "Index, 1972=100" may be
ignored. The method of calculating the inflation adjustment factor
required by the regulation makes the index year chosen and changes in
the index year irrelevant. The regulation states:
"The inflation factor must be calculated by dividing the
latest published annual Deflator by the Deflator for the
previous year."*
GNP deflators are normally developed both quarterly and annually. The
regulation requires the use of the deflator listed in the column headed
"annual totals." The quarterly data should be ignored entirely. The
calculation of the inflation adjustment factor should use, for the
Latest published annual implicit price deflator, the deflator for 1980
(circled in the chart). The deflator for the previous year will then be
EPA Interim Status Standards, 40 CFR §265.142(c).
8-2
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TABLE 8-L
HYPOTHETICAL SAMPLE PACK OF SURVEY OF CURRENT BUSINESS
^
oo
OJ
is in
ri/'j
IWII
Alum 1 1 I..I il
I'llH
III IV
I'l/'J
1
I.IIIIKAI iinsiiii". i mill. MI IK:,
I Iv '.iMsiuiil ly Ail|.islr,l )
iiii|.iii ii |u i i- .ii-ri ui'.i .
tin ! Ni l..iil |.i,..lii,l hull i., llli'Hnl
HIM il.i i. ....i ... . ,i,,
ii i.u ill i: . ,i..
' 1 Vl, . . ,|,, .
i.i,... pi 1 v.i . .l.,ini. .1 I, luv. Hliiii'iil .
1 1 hi' 1 luv 1 1 . «|,i
II. .111 .1.1. il 1 il . ,|,,
((.-.I I. ul l.il . . . ,).,
*»IVI Ill 1*. Ill |..l,l.l . .111,1 M'lvllts .1.1
'I. Il . .1.,
Si .il 1 li>. 1 1 ,),,
(T/sjj,
IM /,;
I Mi All
K.II II
II
1(1 1 II ll'l 1
IM rtl
III 1 IV
I'dllP
~f M
"in"
IV
(.
1
II
V SIM 1.". -('.ml liiui .1
\hl H\
I/O II,
l/ll /'
I/ . I/,
'"' '''
I// Ml
IIH II
ll'l 1,1,
;
i
1
IHI M.
-------�
che deflator cor 1979 (also circled LI che chare).* Using che example
provided, che inflacion adjusCmenc faccor is Chen calculated as che
annual implicic GNP deflacor for 1980 divided by che annual iraplicic GNP
deflator for 1979, as follows:
175.13
165.50
resulting in an inflation adjustment faccor of 1.058. This number is
Chen multiplied by the last cost estimate to obtain the new current cost
estimate. These numbers are hypothetical and do not represent actual
1981 data; they are presented solely to illustrate how to use the Survey
of Current Business to make che necessary calculation.
*The GNP implicit price deflator for a given year may be subject to
revision. If the figure cited in a previous issue is different from
the figure cited for the same quarter in che current issue, the owner
or operator should use the current figure. If the owner or operator
is requesting this information by telephone, he should ask for the GNP
implicit price deflator for the previous year and for the year prior
to the previous year.
8-4
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9.0 SAMPLE COST ESTIMATES
9.1 INTRODUCTION
This section provides samples of cost estimates for closure of
surface impoundments, land treatment facilities, landfills, inciner-
ators, and a multiple process facility with tanks and small surface
impoundments. A sample post-closure cost estimate for landfills is also
provided. The purpose of these sample cost estimates is to illustrate
the concepts involved in a proper cost estimate and suitable formats
which might be employed. However, neither the cost estimates in total
nor the unit costs are designed to be applicable to any specific
facility. Neither the total costs nor the unit costs used in
these cost estimates should be considered targets when the owner or
operator prepares his own cost estimate.
The cost estimates are prepared in the form of a series of work-
sheets. This was considered the simplest mechanism for providing a
careful, easily checked cost estimate. In the sample cost estimates
given, each worksheet is accompanied by an explanation of each item on
the worksheet. These explanations are designed to help indicate how the
worksheet was developed. Explanations of this type would not be appro-
priate in the cost estimate prepared by the owner or operator. Instead,
the owner or operator would include, for each item in the cost estimate,
reference to the appropriate section of the closure or post-closure plan
as applicable, and any necessary documentation as to the accuracy of
specific unit costs.
9-1
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9.2 EXAMPLE - SURFACE IMPOUNDMENTS
Sludge from an industrial wastewacer treatment plant is pumped to
a four-acre surface impoundment for stabilization. It is assumed that
at the time of closure, the contents of the impoundment will measure a
depth of 3 feet; this material will be 90 percent water and 10 percent
solid sludges. The total depth of the impoundment will be 5 feet
(allowing 2 feet of freeboard above the surface of the liquids) . It
is further assumed that all necessary equipment required to complete
closure will have to be rented, as none is available on-site (the
costs of equipment rental and manpower will be factored into the unit
cost estimates for various operations). The costs of closure are
developed for two options: 1) completely disposing of wastes on-site,
and 2) removing all hazardous materials from the facility prior to
closure.
9-2
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SAMPLE CLOSUR^ COST ESTIMATING WORKSHEETS:
SURFACE IMPOUNDMENTS IN WHICH WASTES REMAIN AT CLOSURE
A- Removing Free Liquid and Decontaminating the Facility
In this case, it is assumed that free liquids can be removed by
evaporation. Alternative possibilities that might be necessary and would
result in somewhat different cost estimates are the transporting of free
liquids to an off-site TSDF and the disposing of free liquids into surface
waters after suitable treatment, either through a treatment facility already
in place or a package treatment facility. For this example, all contam-
inated soil is disposed of in the impoundment; therefore, no additional
costs are associated with decontaminating the soil.
1. Method used: As noted above, the method used for removing the
free liquid is evaporation.
2. Time required to evaporate liquid: The calculations to justify
this time would be taken from the closure plan. It is assumed that 70 days
would be required for evaporation of free liquids.
3. Cost of routine operations per day: This includes the cost of
inspecting the facility required once a week and any minor maintenance
work that would need to be done as a result of these inspections.
4. Cost of maintenance during evaporation (Line 2 x Line 3): Cost
of routine operations at S10 per day times 70 days results in a total cost
of maintenance of S700.
5. Volume of remaining sludge: The volume of the remaining sludge
is given as 1936 cu. yds. based on the initial assumption that the liquid
in the pond is 10 percent sludge.
6. Source of sorbent materials: In this case, the sludge is to be
solidified and buried on-site in the surface impoundment. As a result,
sorbent materials are needed. It is assumed, for the example, that sorbent
materials must be purchased off-site.
7. Cost of sorbent materials: Assume that sorbent materials (e.g.,
cement kiln dusts) are needed on a one-to-one ratio to the sludge and must
be purchased with a delivered cost of S3.25 per cu. yd. The total cost
is 36,292.
8. Unit cost of mixing and stabilization: The unit cost of mixing
soroent material with sludge is assumed to be SI.60 per cu. yd.
9-3
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9. Cose of mixing and stabilization: This is calculated as 1936 cu.
yds. of sludge plus 1936 cu. yds. of sorbent material, for a total of 3872
cu. yds. This is multiplied times $1.60 per cu. yd., to give a total cost
of $6,195.
10. Total cost of removing free liquids and sludge stabilization
(Line 4 + Line 7 + Line 9): The sum of the above costs is $13,187.
11. Decontaminate equipment: The assumed costs for decontaminating
equipment is $500.
12. Decontaminate and flush any pumps or liquid lines: The assumed
costs for decontaminating equipment is S2000.
13. Disposing or treating residues from decontamination: Assume that
the costs for disposing or treating liquids and residues from the above
decontamination processes is $1000.
14. Total costs of all activities on Worksheet A (Line 10 + Line 11 +
Line 12 + Line 13): The sum of these activities is $16,687.
3. Placing Final Cap
1. Area to be capped: The area directly requiring a cap is 4 acres
(19,360 sq. yds.) In addition, it is assumed that an additional acre of
land area (4840 sq. yds.) surrounding the impoundment, containing dikes,
etc., will require vegetation and, therefore, must undergo some prepara-
tion.
2. Required impermeable material: It is assumed that 25,813 cu. yds.
of impermeable material will be required (19,360 sq. yds. x 4 ft. depth).
3. Source of impermeable material: It is assumed that suitable
impermeable material can be obtained through bulldozing dikes and other
appurtenances on-site.
4. Cost of material: Since the material is available on-site, there
will be no cost.
5. Required topsoil: At the sample facility, it is assumed that 2 feet
of the topsoil will be required in order to ensure adequate cover so chat
roots of the vegetation will not penetrate the cap. It is, therefore,
assumed that 16,133 cu. yds. of topsoil (24,200 sq. yds. x 2/3 yd. depth)
will be required.
6. Source of topsoil: In this case, it is assumed that topsoil is
available on-site at a relatively short haul.
9-4
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7. Cost of topsoil: Since the copsoil is available on-site, there
will be no cost.
8. Cost per cubic yard for hauling, compacting and grading:
It is assumed in this case that the unit cost of those services is
$1.60.
9. Cost of placing impermeable portion of cap (Line 2 x Line
8): The result of these assumptions is that the cost of the cap
in place (with suitable grading) is $41,301.
10. Cost of placing topsoil (Line 5 x Line 8): The cost of
placing the topsoil, given the above assumptions, is $25,813.
11. Total cost of cap (Line 4 + Line 7 + Line 9 + Line 10):
Summing the above elements, the total cost for the capping operation
is 567,114.
C. Planting Final Vegetation
1. Area to be vegetated: The area to be vegetated is assumed to
be 5 acres.
2. Type of vegetation to be used: The closure plan specifies that
coarse field grass (a mixture of rye grasses and Kentucky fescue) will
be employed for final vegetation.
3. Quantity of seed per acre: Based on discussions with facility
operators, we assume that 150 pounds of seed will be used per acre.
4. Cost of seed per pound: Calls to local suppliers determined
that seed is available at $.50 per pound.
5. Total cost of seed (Line 1 x Line 3 x Line 4): Given the
above assumptions, the total cost of seed will be $375.
6. Type of fertilizer to be used: Given the topsoil and
climatic conditions at the sample site, 10/10/10 fertilizer is
assumed to be adequate.
7. Quantity of fertilizer per acre: Discussions with local
suppliers indicated that .25 tons per acre would be a reasonable
fertilizer application rate.
8. Cost of fertilizer per ton: Calls to local suppliers determined
that fertilizer is available for S200 per ton.
9. Total cost of fertilizer (Line 1 x Line 7 x Line 8): Given
the above assumptions, the total cost of fertilizer will be $250.
1-5
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10. Cost of soil preparation per acre: Soil preparation, including
both disking and fertilizing, is assumed to be $135 per acre (including
equipment rental costs).
11. Total cost of preparing soil (Line 1 x Line 10): The total cost
of preparing soil (excluding materials) is assumed to be $675.
12. Cost per acre for seeding: It is assumed that seeding the
sample site will cost $200 'per acre (including equipment rental costs).
13. Total cost of seeding (Line 1 x Line 12): The total cost of
seeding (excluding materials) is assumed to be $1000.
14. Cost per acre of mulching: The cost per acre of purchasing
and applying a hay mulch is assumed to be $140.
15. Total cost of mulching (Line 1 x Line 14): The total costs of
mulching (including the costs of hay) are assumed to be $700.
16. Total costs for vegetation (sum of Lines 5, '9, 11, 13, and 15):
Total costs for establishing vegetation are $2950.
D. Ground-water Monitoring
Assume that closure of the surface impoundment will require a total
of 90 days. In order to determine the maximum possible ground-water
monitoring costs, the most extensive monitoring needed at closure is
assumed. Assuming that ground-water quality analyses are required
annually and ground-water contamination analyses are required semi-
annually, the most expensive case is that in which both sets *of analyses
are required during the 90-day closure period.
1. Number of wells monitored: For the sample surface impoundment,
it is assumed that six wells would need to be monitored.
2. Number of samples per well: One sample is taken per well for
both analyses.
3. Total number of samples (Line 1 x Line 2): Given the above
assumptions, six samples are required.
4. Number of hours required for collecting the sample: It is
assumed that experience has shown that two hours are sufficient to gather
samples from each well.
5. Total number of hours required for collecting the samples
(Line 3 x Line 4): For six samples, 12 hours would be required for
collecting the samples.
9-6
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6. Number of hours required for preparing and delivering the sample:
It is assumed for the example that this can be done in two hours.
7. Person-hour costs for collecting samples: Assume that the fully-
loaded costs for labor required for sample collection, preparation and
delivery averages $15 per hour.
8. Total sample and. collection costs ((Line 5 + Line 6) x Line 7):
This results in total sampling and collection costs of S210.
9. Number of ground-water quality analyses: One analysis must
be made for each well sample, for a total of six.
10. Number of ground-water contamination analyses: One analysis
must be made for each well sample, for a total of six.
11. Unit cost of ground-water quality analysis: It is assumed
that the cost of an analysis for the following parameters is $77 per
sample:
Chloride - $6.00 per sample
Iron - $12.00 per sample
Manganese - $12.00 per sample
Phenols - $25.00 per sample
Sodium - $12.00 per sample
Sulfate - S10.00 per sample
12. Unit cost of ground-water contamination analyses: It is
assumed that the cost of an analysis for the following parameters is
$108 per sample:
pH - S4.00 per sample
Specific Conductance - $4.00 per sample
Total Organic Carbon - $25.00 per sample
Total Organic Halogen - $75.00 per sample
13. Total ground-water quality analysis costs (Line 9 x Line 11):
For six samples at $77 per analysis, this yields a total cost of $462.
14. Total ground-water contamination analysis costs (Line 10 x
Line 12): For six samples at $108 per analysis, this yields a total
cost of $648.
15. Total analyses costs (Line 13 + Line 14): The total analyses
costs, therefore, are $1,110.
9-7
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16. Number of technical hours for administration: This includes all
time necessary to administer and report the data from the analysis and is
estimated as eight hours.
17. Person-hour technical costs: The fully-loaded cost required
for this work is assumed to be $30 per hour.
18. Total technical costs for administration (Line 16 x Line 17):
Given the above assumptions, total costs for administering the tests are
assumed to be S240.
19. Number of clerical hours: Assume for this case that five hours
of clerical time are required to produce the necessary reports.
20. Person-hour clerical costs: Assume the fully-loaded costs for
clerical work are $8 per hour.
21. Total clerical costs (Line 19 x Line 20): Given the above
assumptions, the total clerical costs are $40.
22. Total administrative costs (Line 18 + Line 21): The sum of
technical and clerical costs are then $280.
23. Monitoring equipment maintenance: It is assumed that an
average of $150 is required for a 90-day period to ensure adequate
maintenance of adnitoring equipment and ,wells.
24. Total monitoring costs (Sum of Lines 8, 15, 22, and 23):
Total monitoring costs, excluding administration and contingencies, are
then S1750.
E. Fence Maintenance
In this case, it is assumed that the area to be enclosed is 5 acres
(24,200 sq. yd.). Assuming that the site is square, each side is 156
yards. The perimeter of the site is then 624 yards.
1. Length of fence to be replaced: Since this facility is to retain
hazardous compounds, the integrity of its security fence is important.
Our estimate is that 10% of the existing perimeter security fence will
have to be replaced due to wear and corrosion.
2. Unit cost of replacing fence: The security fence is a galvanized
6-foot high chain link fence made of #9 wire. The installed unit cost
of replacement sections is $13.06 per linear foot.
9-8
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3. Total cost of replacing fence (Line 1 x Line 2):
The cost of replacing the damaged fence sections is the product of the
length of fencing needing replacement and the unit cost of replacing
the fence, for a total of $2429.
F. Professional Certification
1. Number of person-hours required for inspections: It is assumed
that 80 hours are required for periodically inspecting all aspects of
closure of the surface impoundment.
2. Cost per person-hour: In this case, assume that a registered
independent professional engineer may be hired at a cost of $75 per hour.
3. Total costs of independent professional engineer's time (Line
1 x Line 2): This yields a total cost of $6000 for the independent
professional engineer.
4. Number of technical hours required for administrative duties:
Assume that eight hours are required from the owner's or operator's staff
for administrative duties connected with employing an independent
professional engineer.
5. Person-hour costs for technical administrative duties: It is
assumed that the total fully-loaded costs for the owner's or operator's staff
are S30 per hour.
6. Total administrative costs for technical labor (Line 4 x Line
5): Given the above assumptions, the total administrative costs for
technical labor are $240.
7. Number of clerical hours required for administrative duties:
Assume that five hours of clerical time are required for the necessary
typing and certification.
8. Person-hour costs for clerical administrative duties: Fully-
loaded costs of clerical time are assumed to be $8.
9. Total administrative costs for clerical labor (Line 7 x Line 8):
Given the above assumptions, total clerical costs are $40.
10. Total administrative costs (Line 6 + Line 9): Summing '
technical and clerical labor, the total administrative costs are $280.
11. Total certification costs (Line 3 + Line 10): The total costs
for certification, including the engineer's fees and administrative costs,
is then S6280.
9-9
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G. Total Costs Including Administration and Contingencies
Items 1 through 6 give the costs of all activities on each of the
preceding worksheets. Line 7 is the total of Lines 1 through 6,
397,210.
8. Administration: For administrative tasks, including taxes,
insurance, and administration and supervision not included elsewhere,
a total of 15 percent of total costs from Line 6 is used.
9. Contingencies: A general provision for contingencies of 15
percent of Line 6 has been included.
10. Total costs of closure (Line 7 + Line 8 + Line 9): The
estimated total costs for closing the surface impoundment for the situation
in which all wastes remain in the impoundment are estimated for the sample
case to be 3126,373.
9-10
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SURFACE IMPOUNDMENTS
(All wastes remain in impoundment)
WORKSHEET A - REMOVING FREE LIQUID
AND DECONTAMINATING THE FACILITY
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
Method used
Time required to evaporate liquid
Cost of routine operations per day
Cost of maintenance during evaporation
(Line 2 x Line 3)
Volume of remaining sludge
Source of sorbent materials
Cost of sorbent materials
($3.25/cu. yd.; 1.1 ratio)
Unit cost of mixing
Cost of mixing and stabilization
Total cost of removing free liquids and sludge
stabilization (Line 4 + Line 7 + Line 9)
Decontaminating equipment
Decontaminating and flushing pumps and liquid
liners
Disposing or treating residues from
decontamination
Total costs of all activities
(Line 10 + Line 11 + Line 12 + Line 13)
Evaporation
70 days
$10
$700
1936 cu. yds.
Off-site
$6292
$1.60/cu. yd.
S6195
313,187
SSOO
$2000
$1000
$16 -, 687
9-11
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SURFACE IMPOUNDMENTS
(All wastes remain in impoundment)
WORKSHEET B - FINAL CAP
1. Area to be capped 19,360 sq. yds.
2. Required impermeable material (including 25,813 cu. yds.
provision for suitable slope)
3. Source of material On-site
4. Cost of material 0
5. Required topsoil 16,133 cu. yds.
6. Source of topsoil On-site
7. Cost of topsoil 0
8. Cost per cu. yd. of hauling, compacting, and $1.60
grading impermeable material
9. Cost of impermeable portion of cap $41,301
(Line 2 x Line 8)
10. Cost of placing topsoil (Line 5 x Line 8) $25,813
11. Total cost of cap (Line 4 + Line 7 + Line 9 4- Line 10) $67.114
9-12
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SURFACE IMPOUNDMENTS
(All wastes remain in impoundment)
WORKSHEET C - PLANTING FINAL VEGETATION
1. Area to be vegetated
2. Type of vegetation to be used
3. Quantity of seed per acre
4. Cost of seed per pound
5. Total cost of seed (Line 1 x Line 3 x Line 4)
6. Type of fertilizer to be used
7. Quantity of fertilizer per acre
8. Cost of fertilizer per ton
9. Total cost of fertilizer (Line 1 x Line 7 x
Line 8)
10. Cost of soil preparation per acre (excluding
materials)
11. Total cost of preparing soil (Line 1 x Line 10)
12. Cost per acre of seeding (excluding materials)
13. Cost of seeding (Line 1 x Line 12)
14. Cost per acre of mulching
15. Total mulching costs (Line 1 x Line 14)
16. Total costs for vegetation
(Line 5 + Line 9 + Line 11 + Line 13 -I- Line 15)
5 acres
Coarse grass
150 Ibs.
$.50/lb.
$375
10/10/10
.25 tons
$200/ton
$250
S135
$675
$200
$1000
$140
$700
$2950
9-13
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SURFACE IMPOUNDMENTS
(All wastes remain in impoundment)
WORKSHEET D - GROUND-WATER MONITORING
1. Number of wells monitpred
2. Number of samples per well
3. Total number of samples (Line 1 x Line 2)
4. Number of hours required for collecting the
sample (per sample)
5. Total number of hours required for collecting
the samples (Line 3 x Line 4)
6. Number of hours required for preparing and
delivering samples
7. Person-hour costs for collecting samples
8. Total sampling and collection costs
((Line 5 + Line 6) x Line 7)
9. Number of ground-water quality analyses
10. Number of ground-water contamination analyses
11. Unit cost of ground-water quality analysis
12. Unit cost of ground-water contamination
analysis
13. Total ground-water quality analysis costs
(Line 9 x Line 11)
14. Total ground-water contamination analysis costs
(Line 10 x Line 12)
15. Total analyses costs (Line 13 + Line 14)
16. Number of technical hours for administration
(e.g., reporting data to EPA)
17. Person-hour technical costs
18. Total technical costs for administration
(Line 16 x Line 17)
19. Number of clerical hours
20. Person-hour clerical costs
21. Total clerical costs (Line 19 x Line 20)
6 wells
1 sample
6 samples
2 hrs.
12 hrs.
2 hrs.
$15
$210
6 analyses
6 analyses
$77
$108
$462
$648
$1110
8 hrs.
$30
$240
5 hrs.
$8
$40
9-14
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WORKSHEET D (continued)
22. Total administrative costs (Line 18 + Line 21) $280
23. Monitoring equipment maintenance $150
24. Total monitoring costs $1750
(Line 8 + Line 15 + Line 22 + Line 23)
9-15
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SURFACE IMPOUNDMENTS
(All wastes remain in impoundment)
WORKSHEET E - FENCE MAINTENANCE
1. Length of fence to be replaced 186 feet
2. Unit cost of replacing fence $13.06/linear ft.
3. Total cost of replacing fence $2429
(Line 1 x Line 2)
9-16
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SURFACE IMPOUNDMENTS
(All wastes remain in impoundment)
WORKSHEET F - PROFESSIONAL CERTIFICATION
1. Number of person-hours required for inspections 80 hrs.
2. Cost per person-hour $75
3. Total costs of independent professional engineer $6000
certification (Line 1 x Line 2)
4. Number of technical hours required for administrative 8 hrs.
duties
5. Person-hour costs for technical administrative $30
duties
6. Total administrative costs for technical labor $240
(Line 4 x Line 5)
7. Number of clerical hours required for administrative 5 hrs.
duties
8. Person-hour costs for clerical administrative duties S8
9. Total administrative costs for clerical labor $40
(Line 7 x Line 8)
i
10. Total administrative costs (Line 6 + Line 9)
11. Total certification costs (Line 3 + Line 10)
9-17
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SURFACE IMPOUNDMENTS
(All wastes remain in impoundment)
WORKSHEET G - TOTAL COSTS INCLUDING ADMINISTRATION AND CONTINGENCIES
1. Cost of removing free liquid and decontaminating $ 16,687
the surface and ancillary facilities (From Worksheet A)
2. Cost of final cap (From Worksheet B) $ 67,114
3. Cost of planting final vegetation (From Worksheet C) $ 2,950
4. Cost of ground-water monitoring (From Worksheet D) $ 1,750
5. Cost of fence maintenance (From Worksheet E) $ 2,429
6. Cost of professional certification (From Worksheet F) $ 6,280
7. Total of Line 1 through Line 6 $ 97,210
8. Administration $ 14,581.50
9. Contingencies $ 14,581.50
10. Total costs of closure (Line 7 + Line 8 + Line 9) $126.373
9-18
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SAMPLE CLOSURE COST ESTIMATING WORKSHEETS:
SURFACE IMPOUNDMENTS FROM WHICH WASTES ARE REMOVED AT CLOSURE
A. Removing All Free Liquids and Sludge
It is assumed in che sample case chac free liquids will be removed
through evaporation and that sludge will be placed in a tank truck and
disposed off-site. A variety of other options are available. For removing
free liquids, both transporting to an off-site TSDF and treating and
discharging to surface waters are other options that could be used. For
removing sludge, solidification could take place at the site, and the
solidified sludge either disposed in an off-site landfill or in a landfill
on-site, if there was one with interim status or a permit on-site.
1. Method used: As noted above, it is assumed in this case that
evaporation is the method used to remove free liquids.
2. Time required to evaporate liquid: Based on calculations that
would be shown in the closure plan, it is assumed for the sample case that
70 days would be required to evaporate liquid.
3. Cost of routine operations per day: This factor includes the
required weekly inspection of the surface impoundment and a minimum allot-
ment for necessary maintenance revealed by such inspections. This is esti-
mated to be S10 per day.
4. Cost of maintenance during evaporation (Line 2 x Line 3): The
total cost of maintenance of the surface impoundment is equal to 70 times
$10 for a total of $700.
5. Estimated volume of sludge: Given the size of the surface impound-
ment and the assumption of 10 percent sludge, 1936 cu. yds. of sludge will
remain after evaporation of free liquids.
6. Cost per cu. yd. of removing sludge off-site: It is assumed
that off-site removal of sludges can be obtained for 340 per cu. yd. This
cost takes into account the fact that the off-site TSDF facility will
have to mix and stabilize the sludges, and assumes that they will, therefore,
charge a premium for this service.
7. Removal costs per cu. yd.: It is assumed for the sample facility
that removal costs are SI.60 per cu. yd. (including equipment rental).
9-19
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8. Hauling costs per cu. yd.: It is assumed that the nearest land-
fill is 20 miles away. Unit costs of trucking the sludge- from the impound-
ment to the landfill is assumed to be S3/cu. yd., based on discussions
with trucking industry personnel.
9. Total costs (per cu. yd.) of disposal (Line 6 + Line 7 + Line 8):
Total costs of off-site disposal are S44.60 per cu. yd.
10. Cost of removing sludge (Line 5 x Line 9): Given these assumptions,
the cost of removing sludge is 386,346.
11. Total costs (Line 4 + Line 10): Total costs for removing free
liquids and sludges is $87,046.
B. Decontaminating the Facility
1. Surface area of contaminated soil: It is assumed that 19,360
sq. yds. (the entire surface area of the surface impoundment) has contami-
nated soil.
2. Depth of removal: It is assumed in the sample case that this soil
must be removed to a depth of 1 foot to ensure that no soil contaminated
vith hazardous waste remains in the surface impoundment.
3. Total volume to be removed (Line 1 x Line 2): The resulting total
volume to be removed is 6453 cu. yds.
4. Cose of removal per cu. yd. : The assumed cost of removing soil is
SI.60 per cu. yd. (including costs of renting equipment).
5. Total cost of removal (Line 3 x Line 4): The resulting costs for
the sample case of removing the contaminated soil are $10,325.
6. Cost of hauling to off-site landfill per cu. yd.: The assumed
hauling costs to an off-site landfill for final disposal of the contaminated
soil are $3 per cu. yd.
7. Total cost of hauling (Line 3 x Line 6): The resulting total
costs of hauling are $19,359.
8. Fee per cu. yd. for disposal in off-site landfill: It is assumed
that the charge per cu. yd. for off-site disposal at the chosen landfill
has been determined to be $30 per cu. yd.
9. Total cost of disposal (Line 3 x Line 8): The total costs for
disposal, excluding hauling and soil removal, are then $193,590.
9-20
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10. Decontaminating equipment: It is assumed that equipment can be
decontaminated for $500.
11. Decontaminating and flushing pump and liquid lines: Assume that
this can be done at the sample facility for $2000.
12. Disposing or treating residues from decontamination: It is
assumed that residues resulting from the above decontamination steps
must be disposed of at a cost of $1000.
13. Total costs (sum of Lines 5, 7, 9, 10, 11, and 12): The total
costs for decontaminating the surface and ancillary facilities
are $226,744.
C. Ground-water Monitoring
Assume that closure of the surface impoundment will require a total
of 90 days. In order to determine the maximum possible ground-water
monitoring costs, the most extensive monitoring needed during closure is
assumed. Assuming that ground-water quality analyses are required annually
and ground-water contamination analyses are required semi-annually, the
most expensive case is that in which both sets of analyses are required
during the 90-day closure period.
1. Number of veils monitored: For the sample surface impoundment, it
is assumed that six wells would need to be monitored.
2. Number of samples per well: One sample is taken per well for
both analyses.
3. Total number of samples (Line 1 x Line 2): Given the above
assumptions, six samples are required.
4. Number of hours required for collecting the sample: It is assumed
that experience has shown that two hours are sufficient to gather samples
from each well.
5. Total number of hours required for collecting the samples: (Line 3
x Line 4): For six samples, 12 hours would be required for collecting
the samples.
6. Number of hours required for preparing and delivering the samples:
It is assumed for the example that experience has shown that this can
be done in two hours.
9-21
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5. Person-hour coses for technical administrative duties: It is
assumed that the total fully loaded costs for the owner's or operator's
staff are S30 per hour.
6. Total administrative costs for technical labor (Line 4 x Line 5):
Given the above assumptions, the total administrative costs for technical
labor are S240.
7. Number of clerical hours required for administrative duties: Assume
that five hours of clerical time are required for the necessary typing and
certifications.
8. Person-hour costs for clerical administrative duties: Fully-loaded
costs of clerical time are assumed to be S8.
9. Total administrative costs for clerical labor (Line 7 x Line 8):
Given the above assumptions, total clerical costs are S40.
10. Total administrative costs (Line 6 + Line 9): Summing technical
and clerical labor, the total administrative costs are S280.
11. Total certification costs (Line 3 + Line 10): The total costs for
certification, including the engineer's fees and administrative costs, is
then $4780.
£. Total Costs of Closure Including Ad-iniscration ar.c Cor.tinser.c.es
Items 1 through 4 summarize the costs of the activities on each of
.the previous worksheets.
5. Total of Lines 1 through 4: The total costs for the activities
listed in Lines 1 through 4 are 3320,350.
6. Administration: The costs for administration, which includes
insurance, taxes, and supervision and administration not included elsewhere,
are assumed to be 15 percent of Line 5.
7. Contingencies: A provision for contingencies of 15 percent of
Line 5 has been included.
8. Total costs of closure (Line 5 + Line 6 + Line 7): The total
costs of closure including administration and contingencies for the sample
surface impoundment, in the case where all wastes are removed from the
impoundment, are 5416,455.
9-22
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7. Person-hour coses for collecting samples: Assume that the fully-
loaded costs for labor required for collecting, preparing and delivering
the samples averages $15 per hour.
8. Total sample and collection costs ((Line 5 + Line 6) x Line 7):
This results in total sampling and collection costs of S210.
9. Number of ground-water quality analyses: One analysis must be
made for each well sample, for a total of six.
10. Number of ground-water contamination analyses: One analysis must
be made for each well sample, for a total of six.
11. Unit cost of ground-water quality analyses: It is assumed
that the cost of an analysis for the following parameters is $77 per
sample.
Chloride - $6.00 per sample
Iron - $12.00 per sample
Manganese - $12.00 per sample
Phenols - $25.00 per sample
Sodium - $12.00 per sample
Sulfate - $10.00 per sample
12. Unit cost of ground-water contamination analysis: It is assumed
the cost of an analysis for the following parameters is $108 per
sample.
pH - $4.00 per sample
Specific Conductance - S4.00 per sample
Total Organic Carbon - $25 per sample
Total Organic Halogen - $75.00 per sample
13. Total ground-water quality analysis costs (Line 9 x Line 11):
For six samples at $77 per analysis, this yields a total cost of $462.
14. Total ground-water contamination analysis costs (Line 10 x
Line 12): For six samples at $108 per analysis, this yields a total
cost of $648.
15. Total analyses costs (Line 13 + Line 14): The total analyses
costs, therefore, are $1110.
16. Number of technical hours for administration: This includes
all time necessary to administer and report the data from the analysis
and is estimated as eight hours.
9-23
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17. Person-hour cechnical coses: The fully-loaded cost required for
Chis work is assumed Co be 330 per hour.
18. Total technical costs for administration (Line 16 x Line 17):
Given the above assumptions, total costs for administering the tests are
assumed to be S240.
19. Number of clerical hours: Assume for this case that five hours
of clerical time are required to produce the necessary reports.
20. Person-hour clerical costs: Assume the fully-loaded costs for
clerical work are S8 per hour.
21. Total clerical costs (Line 19 x Line 20): Given the above
assumptions, the total clerical costs are $40.
22. Total administrative costs (Line 18 + Line 21): The sum of
technical and clerical costs are then $280.
23. Monitoring equipment maintenance: It is assumed that an average
of S150 is required for a 90-day period to ensure adequate maintenance
of monitoring equipment and wells.
24. Total monitoring costs (sum of Lines 8, 15, 22, and 23): Total
monitoring costs, excluding administration and contingencies, are then
S1750.
D. Professional Certification
1. Number of person-hours required for inspections: It is assumed
that 60 hours are required for periodic inspections of all aspects of
closing the surface impoundment.
2. Cost per person-hour: In this case, assume that a registered
independent professional engineer may be hired at a cost of $75 per
hour.
3. Total costs of independent professional engineer's time (Line
1 x Line 2) : This yields a total cost of $4500 for the independent
professional engineer.
4. Number of technical hours required for administrative duties:
Assume that eight hours-are-required from the owner's or operator's staff
for administrative duties connected with employing an independent
professional engineer.
9-24
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SURFACE IMPOUNDMENTS
(All wastes removed from impoundment)
WORKSHEET A - REMOVING ALL FREE LIQUIDS AND SLUDGE
1. Method used Evaporation
2. Time required to evaporate liquid 70 days
3. Cost of routine operations per day $10
4. Cost of maintenance during evaporation S700
(Line 2 x Line 3)
5. Estimated volume of sludge 1936 cu< yds.
6. Cost of removing sludge off-site per cu. yd. 540
7. Removal costs per cu. yd. $1.60
8. Hauling costs per cu. yd. $3.00
9. Total costs per cu. yd. of disposal $44.60
(Line 6 + Line 7 + Line 8)
10. Costs of removing sludge (Line 5 x Line 9) 586,346
11. Total costs (Line 4 + Line 10) $87.046
9-25
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SURFACE IMPOUNDMENTS
(All wastes removed from impoundment)
WORKSHEET B - DECONTAMINATING SURFACE AND ANCILLARY FACILITIES
1. Surface area of contaminated soil
2. Depth of removal
3. Total volume to be removed (Line 1 x Line 2)
4. Cost of removal per cu. yd.
5. Total cost of removal (Line 3 x Line 4)
6. Cost of hauling to off-site landfill per cu. yd.
7. Total cost of hauling (Line 3 x Line 6)
8. Fee per cu. yd. for disposing in off-site landfill
9. Total cost of disposal (Line 3 x Line 8)
10. Decontaminating equipment
11. Decontaminating and flushing pump and liquid lines
12. Disposing of residues from decontamination
13. Total costs (sum of Lines 5, 7, 9, 10, 11, and
12)
19,360 sq. yds,
1 ft.
6453 cu. yds.
$1.60
$10,325
$3
$19,359
$30
$193,590
$500
$2000
$1000
$226,774
9-26
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SURFACE IMPOUNDMENTS
(All wastes removed from impoundment)
WORKSHEET C - GROUND-WATER MONITORING
1. Number of wells monitored 6 wells
2. Number of samples per well 1 sample
3. Total number of samples (Line 1 x Line 2) 6 samples
4. Number of hours required for collecting the 2 hrs.
sample (per sample)
5. Total number of hours required to collect 12 hrs.
the samples (Line 3 x Line 4)
6. Number of hours required for preparing and 2 hrs.
delivering samples
7. Person-hour costs for collecting samples $15
8. Total sampling and collection costs ((Line $210
5 + Line 6) x Line 7)
9. Number of ground-water quality analyses 6 analyses
10. Number of ground-water contamination analyses 6 analyses
11. Unit cost of ground-water quality analysis $77
12. Unit cost of ground-water contamination analysis $108
13. Total ground-water quality analysis costs $462
(Line 9 x Line 11)
14. Total ground-water contamination analysis costs $648
(Line 10 x Line 12)
15. Total analyses costs (Line 13 + Line 14) $1110
16. Number of technical hours for administration 8 hrs.
(e.g., reporting data to EPA)
17. Person-hour technical costs $30
18. Total technical costs for administration $240
(Line 16 x Line 17)
19. Number of clerical hours 5 hours
20. Person-hour clerical costs $8
21. Total clerical costs (Line 19 x Line 20) $40
22. Total administrative costs (Line 18 + Line 21) $280
9-27
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23. Monitoring equipment maintenance
24. Total monitoring costs
(Line 8 + Line 15 + Line 22 + Line 23)
9-28
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SURFACE IMPOUNDMENTS
(All wastes removed from impoundment)
WORKSHEET D - PROFZSSIGNAL CERTIFICATION
1. Number of person-hours required for inspections
2. Cost per person-hour
3. Total costs of independent professional engineer
certification (Line 1 x Line 2)
4. Number of technical hours required for administrative
duties
5. Person-hour costs for technical administrative duties
6. Total administrative costs for technical labor
(Line 4 x Line 5)
7. Number of clerical hours required for administrative
duties
8. Person-hour costs for clerical administrative duties
9. Total administrative costs for clerical labor
(Line 7 x Line 8)
10. Total administrative costs (Line 6 -t- Line 9)
11. Total certification costs (Line 3 + Line 10)
60 hrs.
$75
$4500
8 hrs.
$30
$240
5 hrs.
38
$40
9-29
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SURFACE IMPOUNDMENTS
(All wastes removed from impoundment)
WORKSHEET E - TOTAL COSTS OF CLOSURE INCLUDING
ADMINISTRATION AND CONTINGENCIES
1. Cost of removing free liquids and sludge $ 87,046
(From Worksheet A)
2. Cost of decontaminating facility (From $226,774
Worksheet B)
3. Cost of ground-water monitoring (From Worksheet C) $ 1,750
4. Cost of professional certification (From $ 4,780
Worksheet D)
5. Total of Line 1 through Line 4 $320,350
6. Administration 5 48,052.50
7. Contingencies $ 48,052.50
8. Total costs of closure (Line 5 + Line 6 + Line 7) $416.455
9-30
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9-3 EXAMPLE - LAND TREATMENT FACILITIES
The following cost estimates were developed for a land treatment
facility consisting of 50 acres of active fields for the processing of
biodegradable hazardous waste. In addition to the disposal fields, the
land treatment facility is equipped with a surface impoundment for waste
storage and a separate surface impoundment for collecting run-off water.
The land treatment facility is designed to receive organic industrial
sludge of high liquids content. This waste is applied to the land treat-
ment fields at an application rate of 100 wet tons/acre (solids applica-
tion rate ~5 tons/'acre) .
Waste received by the facility is stored in a lined surface impound-
ment. The surface impoundment is 5 feet deep (3 feet of waste and 2 feet
of freeboard) and has a surface area of 1.23 acres. This corresponds to
a waste holding capacity of 160,700 cubic feet. A pump system is avail-
able for transferring this liquid waste to the tank trucks.
The waste from the waste storage surface impoundment is spread on
the fields using tank trucks. During the first 90 days of the planned
closure period, all of the waste inventory will be disposed on the fields.
This disposal will require one application to the field. Later in the
closure period, run-off water from the separate run-off water surface
impoundment will be disposed of in the same manner. This run-off water
will have a very low concentration of hazardous vastes. Disking of the
fields will be conducted shortly after each spreading to mix the waste
with the soil and a second disking will be done two to three weeks after
each spreading. Periodic disking will continue on a bimonthly basis
thereafter.
During this prolonged closure period, the surface impoundments will
be closed as well. Each of the two surface impoundments has its own
closure plan as shown elsewhere in this guidance document. Therefore,
the costs of decommissioning the surface impoundments are not computed
in this example.
9-31
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SAMPLES CLOSURE COST ESTIMATING WORKSHEETS:
LAND TREATMENT FACILITIES
A. Disposing of Waste Inventory
1. Maximum inventory to be disposed: For this case, the waste
storage surface impoundment is filled to its maximum capacity of 5000
tons of low solids waste (or 1,198,878 gallons with a waste density
similar to water).
2. Amount of run-off water to be disposed: a similar
amount of somewhat contaminated water is expected to be disposed of
from the surface water run-off impoundment. This mildly contaminated
water is to be disposed of in the same manner as the inventory.
3. Total material to be disposed (Line 1 + Line 2): All of these
impounded liquids (waste and run-off) are to be disposed of on-site by
spreading on the land treatment facility fields.
4. Application rate: The waste is to be applied to the field by
aeans of tank trucks equipped with spray bars. The application rate of
100 tons/acre corresponds to a solids application rate of 5 tons/acre.
This application rate has been found to be acceptable based on tne
operating experience of the facility.
5. Acreage utilized: All 50 acres of the land treatment facility
are in active operation and will be available for the disposal of the
waste inventory and run-off. This is the lowest cost option for disposing
inventory available to this facility.
6. -Number of applications in the closure period: Two applications
are planned. One application is the liquid waste inventory which will
be completed within the first 90 days of the closure period as required
by the interim status regulations. Subsequently, an application of the
captured run-off water is planned.
7. Unit cost of spreading: The unit cost of spreading the
liquids on the land treatment fields is $0.48 per ton or S48 per acre
at the application rate of 100 tons per acre.
8. Total cost of spreading (Line 5 :: Line 6 x Line 7): The total
cost of spreading the waste inventory and the captured run-off water is
the product of the acreage treated, the number of applications and the
unit per acre cost of spreading.
9-32
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9. Number of diskings required: A total of ten diskings will be
required throughout the closure period. Four of the diskings will be
carried out in the first part of the closure period (immediately after
each of the two applications and several weeks after each application).
Six additional diskings will be conducted throughout the rest of the
closure period.
10. Unit cost of disking: The unit cost for disking the land treat-
ment fields is the sum of tractor and implement costs and equipment
operator labor costs. The equipment cost for disking is $.79 per acre.
The cost is for both the tractor and the tandem disk. It includes
insurance, taxes, repairs, fuel and lubrication but it does not include
interest and depreciation. The labor cost (fully-loaded) is $20 per
hour. The disking is accomplished at the rate of .167 hours per acre.
*
In addition, excra labor time is required for related handling and care
of the equipment. Thus, the actual labor time per acre is 1.2 times the
inclement time, yielding a labor rate of $4.01 per acre.
11. Total cost of disking (Line 5 x Line 9 x Line 10): The cost of
disking the land treatment fields is the product of the acreage utilized,
the number of diskings required during closure and the unit cost of
disking.
12. Total costs for disposing of inventory (Line 8 + Line 11):
The total cost for disposing of the waste inventory and run-off water is
the sum of the total spr&ading costs and the total disking costs. After
completing the land treatment, the hazardous waste will be completely
decomposed.
B. Decontaminating the Land Treatment Facility
1. Area of facility contaminated: It should be noted that the
1200 sq. yds. of contaminated soil does not include any of the land
treatment fields where controlled decomposition is occurring.
2. Depth of material removed: The contaminated soil is removed
to a depth of 1 foot (.33 yds.). The soil at this land treatment facility
is relatively impermeable. This makes a depth of 1 foot realistic for
tne excavation for the contaminated soil (since the mobility of the
hazardous waste is restricted). The soil density is 90 Ibs./cu. ft.
9-"
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3. Unit cost for removal: The contaminated soil is removed and
loaded into spreaders using rented earth-moving equipment. This excava-
tion and loading operation is estimated to cost $1.60 per cu. yd. of
contaminated soil.
4. Cost of removing contaminated soil (Line 1 x Line 2 x Line 3):
The cost of excavating, removing and loading the contaminated soil is
the product of the volume of the soil handled and the unit cost of the
operation.
5. Quantity disposed on-site: All of the contaminated soil is to
be disposed on the land treatment fields (on-site). The contamination
in the disposed soil will decompose under supervised conditions. This
contaminated soil will be spread after the waste inventory has been dis-
posed. The contaminated soil will be spread on the fields at least
several weeks after the last of the waste inventory is spread.
6. Quantity disposed off-site: No contaminated soil is to be
disposed off-site due to the much higher cost of off-site disposal and
the availability of the land treatment fields.
7. Application rate: An application rate of 10 tons of contami-
nated soil per acre is used. This solids application rate is acceptable
because the waste concentration in the soil is quite low.
8. Acreage utilized: The contaminated soil is spread on the
entire 50 acres of the land treatment facility.
9. Number of applications: Only one application is required to
dispose of the entire volume of contaminated soil.
10. Unit cost of spreading: The unit cost for the spreading of
the contaminated soil is the sum of tractor and implement costs and
equipment operator labor costs. The equipment cost for1spreading the
waste is S.95 per acre. This cost is for both the tractor and the spreader.
It includes insurance, taxes, repairs, fuel and lubrication but it does
not include interest and depreciation. The labor cost (fully-loaded) is
S20 per hour. The spreading of the waste is accomplished at the rate of
.211 hours per acre. In addition, extra labor time is required for re-
lated handling and care of the equipment. Thus, the actual labor time
per acre is 1.2 times the implement time, yielding a labor rate of $5.06
oer acre.
9-34
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11. Total cose of spreading (Line 8 x Line 9 x Line 10): The cost
of spreading che soil is the product of the acreage and the unit cost
per acre.
12. Number of diskings: The spread soil is disked to mix it with
the soil of the land treatment fields. This one disking is conducted
shortly after the contaminated soil is spread on the fields.
13. Unit cost of disking: The unit cost for disking is $4.08/acre.
This cost includes equipment costs of $.79 per acre for the tractor and
the tandem disk. This cost includes insurance, taxes, repairs, fuel and
lubrication; but it does not include interest and depreciation. Labor
cost is included at a cost of $20 per hour.
14. Total cost of disking (Line 8 x Line 12 x Line 13): The total
cost for this disking is the product of the acres disked and the unit
cost per acre.
15. Total cost of disposing of contaminated soil (Line 4 + Line
11 + Line 14): The total cost of disposing of the contaminated soil is
the sura of the cost of removing the soil, spreading the soil, and disking
the spread soil.
16. Cost of decontaminating equipment: At the end of the closure
period, the equipment used on-site will be decontaminated by washing
with detergents. The run-off cleaning water will be collected for dis-
posal. A cost of S1000 is estimated for this task.
17. Disposing or treating of residues from equipment decontamina-
tion: The wastewater from the washing and other cleaning residues will
be disposed off-site at a cost of approximately $1000. Off-site disposal
of this residue is required because the land treatment facility is
ceasing operation.
18. Total cost of decontaminating the facility Line 15 + Line 16 +
Line 17): The total cost of decontaminating the land treatment facility
is the sum of the costs of soil disposal, equipment decontamination,
and decontamination residue disoosal.
9-35
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C. Monitoring Activities (Ground-Water and Soil)
Ground-Water Monitoring
It is assumed that closure of the land treatment facility will re-
quire a total of 15 months. In order to determine the maximum possible
ground-water monitoring costs, the most extensive monitoring needed
during closure is assumed.- Assuming that ground-water quality analyses
are required annually and ground-water contamination analyses are required
semi-annually, the most expensive case is that in which two ground-water
quality analyses and three ground-water contamination analyses are required
during the 15-month closure period.
1. Number of wells monitored: Eight sampling wells are operated
to monitor the composition of the ground-water at the land treatment
site. Seven of the wells are downgradient from the land treatment fields
and one well is upgradient.
2. Number of samples taken: Three "cycles" of ground-water samp-
ling will be conducted during the 15-month long closure period. Two
ground-water quality analyses and three ground-water contamination
analyses are to be carried out. One sample may be used for both the
ground-water quality and the ground-water contamination analysis. There-
fore, during the closure period, a total of three samples are taken
from each well.
3. Total number of samples (Line 1 x Line 2): The total number
of ground-water samples taken during the closure period is the product
of the number of monitoring wells and the number of samples taken from
each well.
4. Number of hours for collecting the sample (per sample): Taking
ground-water samples is a rather time-consuming practice. The well is
pumped dry and allowed to refill. Then a sample is taken. The land
treatment facility experience is that approximately two hours are re-
quired for each ground-water sample (including some time for moving about
the fields).
5. Total number of hours for collecting the samples (Line 3 x
Line 4): During the extent of the closure period, 24 samples will have
to be collected, requiring 48 hours of labor.
9-36
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6. Number of hours for preparing and delivering che sample: The
ground-water samples must also be prepared and delivered to the labora-
tory for analysis. This work requires about three hours for a set of
eight samples (one from each monitoring well).
7. Total number of hours for preparing and delivering the sample
(Line 2 x Line 6): The to'tal number of ground-water sample preparation
and delivery hours in the closure period is the product of the number
of sets of samples (cycles) and the unit operation requirement of three
hours labor.
8. Person-hour costs for collecting and handling samples: The
person-hour fully-loaded labor rate for taking and handling the ground-
water sample is $15 per hour. This is the same labor rate as during
the operating period of the land treatment facility.
9. Total ground-water sampling and collection costs ((Line 5 +
Line 7) x Line 8): The total cost of ground-water sampling is computed
by multiplying the hours required by the labor rate of $15 per hour.
10. Number of ground-water quality analyses: Sixteen ground-water
quality analyses are required during the closure period. Two analyses
are required for each well.
11. Number of ground-water contamination analyses: Twenty-four
ground-water contamination analyses are required during the closure
period. Three analyses are required for each well.
12. Unit cost of ground-water quality analysis. It is assumed
that the cost of an analysis for the following parameters is S77 per
analysis.
Chloride $ 6/sample
Iron $12/sample
Manganese $12/sample
Phenols $25/sample
Sodium $12/sample
Sulfate $10/sample
13. Unit cost of ground-water contamination analysis: It is
assumed chat the cost of an analysis for the following parameters is
$108 per analysis:
9-37
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pH S 4/sample
Specific Conductance S 4/sample
Total Organic Carbon $25/sample
Total Organic Halogen $75/sample
14-16. Total ground-water chemical analyses costs: The unit costs
per analysis are multiplied by the number of analyses to yield the costs
for each type of analysis. These two costs are added together to compute
the total analyses costs.
Soil Monitoring
17. Number of soil core samples: Soil core samples are taken
throughout the closure period. Four samples are taken in each quarter
of the first year. In the fifth quarter of the closure period, 50
core Samples are taken (one from each acre of the land treatment facility).
This last set of 50 samples confirms that the waste has decomposed during
the closure period. Thus, a total of 66 soil core samples are taken in
the closure period (15 months in duration). Most of these samples are
taken below the zone of waste incorporation to monitor any waste movement
:3':ards the vater taole. A few of the samples are taken from the zone
of incorporation as well to monitor the decomposition of the waste material.
18. Labor hours required for each core sample: The taking of a
soil core sample is a relatively simple process. Most of the time allo-
cated to taking each sample is movement between the sample-taking locations.
19. Labor unit cost for collecting core samples: The unit cost of
the labor for soil core sampling is S15 per hour fully-loaded.
20. Total cost of collecting the soil samples (Line 17 x Line 18 x
Line 19) : The total cost for taking soil core samples is the product of
the number of samples taken, the hours required for each sample, and the
labor rate.
21. Unit soil core sample analysis cost: The chemical analysis of
each soil sample involves the measurement of 10 parameters (organic matter,
total dissolved solids, total nitrogen, cadmium, arsenic, lead, mercury,
chromium, zinc, and copper). Preparing each sample costs $10 and each
parameter costs S5. Thus, the net cost per soil sample is S60.
9-38
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22. Total soil core sample chemical analysis cost (Line 17 x Line 21):
The total chemical analysis cost for the soil core samples is the product
of the number of samples taken and the unit.analysis cost per sample.
Lysimeter Sampling of Soil Moisture
23. Number of lysimeter samples: Soil moisture samples are taken by
means of a lysimeter. This extracted water is then analyzed for contami-
nation in the same way that the ground-water sanples are chemically analyzed.
Four soil moisture samples are taken during each quarter of the closure
period. Since there are 5 quarters, a total of 20 samples are taken.
24. Labor hours required for each lysimeter collection of soil
moisture: One hour of labor is required for collecting and handling each
sample. This includes time spent moving about the field.
25. Labor unit cost for collecting samples: The unit: labor cost for
collecting these samples is S15 per hour fully-loaded.
26. Total sampling cost for lysimeter collection of soil moisture
(Line 23 x Line 24 x Line 25) : The total cost for collecting soil moisture
0
samples is the product of the number of samples taken, the labor required
for each sample, and the labor rate.
27. Unit cost for moisture sample analysis: The unit cost for each
chemical analysis is S150. This is based on the land treatment facility's
experience with ground-water contamination analysis and soil moisture
chemical analysis.
28. Total cost for moisture sample chemical analysis (Line 23 x
Line 27): The total cost for the soil moisture chemical analysis is
the product of the number of samples taken and the cost of chemically
analyzing each sample.
Administrative Costs
29. Number of technical hours for administration: The land treat-
ment facility also requires the allocation of some technical supervisory
labor to administer the closure monitoring program. Approximately two
days of such supervisory labor will be required in small blocks of time
expended throughout the closure period.
9-39
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30. Person-hour technical coses: The fully-loaded labor cose for
chese technically qualified employees is $30 per hour.
31. Total technical costs for administration (Line 29 x Line 30):
The cost of this technical administration is the product of the required
technical administration hours and the technical labor rate.
32. Number of clerical hours: Clerical support is required for the
monitoring administration activity. Two days of clerical labor will be
needed in small blocks of time expended throughout the closure period.
33. Person-hour clerical cost: The fully-loaded labor rate for
clerical labor at the land treatment facility is $8 per hour.
34. Total clerical costs (Line 32 x Line 33): The total clerical
costs for administering the monitoring activity is the product of the
hours required and the clerical labor rate.
35. Total administrative costs (Line 31 + Line 34): The technical
and clerical administrative costs are added together to yield the total
administrative costs for the monitoring program (both soil and ground-
water) for the entire closure period.
Maintenance Costs
36. Monitoring well maintenance: The cost of maintaining the ground-
-.vater monitoring wells is estimated to be S750 for the entire closure
period. No well replacements are anticipated during the closure period.
Cost Summaries for Monitoring
37. Total cost of ground-water monitoring (Line 9 + Line 16 T Line
36) : The total cost for ground-water monitoring is the sum of the costs
of sample collection, chemical analyses, and monitoring well maintenance.
38. Total cost of soil core sample monitoring (Line 20 + Line 22):
The total cost of soil core sample monitoring is the sum of the costs
of collecting the samples and chemically analyzing the samples.
39. Total cost for soil moisture (lysimeter) monitoring (Line 26 +
Line 28): The total cost for soil moisture monitoring by means of lysimeter
samples is the sum of the costs of collecting che samples and chemically
analyzing the samples.
9-40
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40. Total administrative coses (Line 35): The total administrative
costs, both clerical and technical, for the monitoring program are repeated
here.
41. Total monitoring costs (Line 37 + Line 38 + Line 39 + Line 40):
The total cost for the entire closure period monitoring program is the
sum of the costs of ground-water monitoring, soil core testing, lysimeter
testing, and the administrative costs. All of these costs are reliably
known from the operating experience of the facility.
D. Fence Maintenance
For a land treatment facility consisting of 50 acres of active fields,
assuming that the site is square, each side is 1475.8 feet. The perimeter
of the site is then 5903.2 feet.
1. Length of fence to be replaced: Since the land treatment facil-
ity has a prolonged closure period and possible post-closure activities,
it is necessary to maintain the security fence along the field perimeters
in good condition. We have estimated that 10% of the fencing will be
corroded and damaged to the point of requiring replacement.
2. Unit cost of replacing fence: The security fence is a galvanized
metal 6-foot high chain link fence made of #9 wire. The installed unit
cost of replacement sections is $13.06 per linear foot.
3. Total cost of replacing fence (Line 1 x Line 2): The cost of
replacing the damaged fence sections is the product of the length of the
fence needing replacement and the unit cost of replacement, for a total
of S7705.
E. Repair of Drainage Channels
1. Length of drainage channels: The land treatment facility's
drainage channels are an important part of the containment system. They
channel run-off water to a surface impoundment. Our estimate is that
500 feet of these channels will have to be replaced during the closure
period.
2. Channel volume per unit length: The channels have a square
cross sectional area measuring 3 feet by 3 feet. This results in a
volume of 0.33 cu. yds. per linear foot of channel length.
9-41
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3. Channel excavation unit cost: The unit cost of excavating the
channels with a backhoe is $.67 per cu. yd. This work would be performed
by a contractor and is based on contractor estimates.
4. Total channel excavation cost (Line 1 x Line 2 x Line 3): This
total cost is the product of the length of the drainage channels required,
the volume per unit length, and the unit excavation cost.
5. Unit cost of hand grading: The inner surface of the channels
must be shaped and prepared for seeding. This work is performed by hand
at a unit cost of $.02 per sq. ft. This work will be performed by a
contractor and is based on contractor estimates.
6. Channel surface area: The inside surface of the new channel
is approximately 4500 sq. ft. in area. All of this area must be shaped
and prepared.
7. Total cost of hand grading (Line 5 x Line 6): The total cost
of this hand grading is the product of the unit cost and the surface
area of the channels.
8. Total replanting cost: The total cost of seeding, fertilizing
and mulching the channel surface is estimated at $50 by a contractor.
9. Total channel repair cost (Line 4 + Line 7 + Line 8): The
total cost of cnannel repair is the sum of the e::cavacion cost, hand grac-
ing cost and replanting cost.
^ Management Inspection of Land Treatment Facility Operations
1. Number of technical management person-hours required for each
inspection : The prolonged closure period for the land treatment facility
and the recurring operations of spreading and disking necessitate an
inspection program conducted by facility management throughout the closure
period. Each one of these inspections requires 8 hours of technical manage-
ment time.
2. Inspection frequency: The inspections are conducted once per
month throughout the closure period. On each inspection, the manager
checks the progress of the facility operations: spreading, disking,
sampling, decontamination, etc.
3. Duration of closure period: To allow the hazardous waste to
decompose, the closure period-must be 15 months in duration.
9-42
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4. Total technical management person-hours required for inspections
(Line 1 x Line 2 x Line 3): The technical hours required for the actual
inspections are the product of the number of hours for each inspection
and the total number of inspections required.
5. Person-hour costs for technical management duties: The person-
hour cost for this technical supervisory labor is $30 per hour (fully-
loaded labor rate).
6. Total technical management costs for inspections (Line 4 x Line
5) : The technical cost for. the inspections conducted throughout the
closure period is the product of the total inspection technical hours
and the technical labor rate.
7. Additional technical management labor required: A small amount
of additional technical time will be required for managerial tasks
associated with the inspections (such as writing reports). Approximately
8 percent to 10 percent of the inspection time is required for this
additional work.
8. Total cost of additional technical management labor (Line 5 x
Line 7): The cost of this additional technical labor is the product of
the additional hours required and the tecnnical labor rate.
9. Total cost of technical nanagenent labor (Line 6 + Line 8):
The total cost of all the technical labor required is the sum of the
labor directly spent on inspections and the labor related to inspections.
10. Mumber of clerical hours required: Clerical labor is needed to
support the periodic inspections of the land treatment facility. Only
a modest amount of clerical labor is required.
11. Person-hour costs for clerical labor: The labor rate for
clerical labor at this facility is $8 per hour. (This is a fully-loaded
labor rate.)
12. Total cost for clerical labor (Line 10 x Line 11): The total
cost for the needed clerical labor is the product of the clerical hours
and the clerical labor rate.
13. Total inspection cost (Line 9 + Line 12): The total cost of the
inspection program is the sum of the technical labor costs and the cleri-
cal labor costs.
9-43
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G. Professional Certification
1. Number of person-hours required for inspections: Approximately
one week of professional time will be required to certify the proper
closure of the land treatment facility. Most of this professional work
will be an independent professional engineer as specified by the interim
status regulations. The professional engineer will be assisted by a soil
specialist who will evaluate the soil samples taken during the closure
period.
2. Cost per person-hour: The contracted cost of these professionals
is $75 per hour based on their current quotes for these services.
3. Total costs of professional engineer's time (Line 1 x Line 2):
The total cost for these contracted professional services is the product
of the number of hours required and the quoted hourly rate.
4. Number of technical hours required for administrative duties:
The land treatment facility technical staff will need to devote 8 hours
of time to administering this certification.
5. Person-hour costs for technical administrative duties: The
fully-loaded labor rate for the technical staff is S30/hour.
6. Total administrative costs for technical labor (Line 4 x Line 5):
The technical administrative costs for the land treatment facility is the
product of the number of technical hours required and the technical labor
rate.
7. Number of clerical hours required for administrative duties:
Eight hours of clerical work are required to support the administration
of the certification.
8. Person-hour costs for clerical administrative duties: The
fully-loaded labor rate for clerical workers .at this facility is $8/hour.
9. Total administrative costs for clerical labor (Line 7 x Line 8):
The total clerical labor costs are the product of the labor rate and
the number of hours required.
10. Total administrative costs (Line 6 + Line 9): The total adminis-
trative costs are the sum of the technical labor cost and the clerical
labor cost.
11. Total certification costs (Line 3 + Line LO): The total cost
for certification is the sum of the costs of the professional engineer
9-44
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and che administrative costs.
H- Total Costs Plus Administration and Contingencies
Items 1 through 7 give the costs of each major closure function on
each of the preceding worksheets. Line 8 is the total of Lines 1 through
7, $39,389.
7. Administration: All additional administration costs are com-
puted by multiplying the subtotal (Line 8) by 15 percent.
8. Contingencies: Allowance for contingencies is computed by
multiplying che subtotal (Line 8) by 15 percent.
9. Total costs of closure (Line 8 + Line 9 + Line 10): A grand
total for land treatment facility closure costs is computed by adding
together the costs from the worksheets and the allowances for additional
administration and other contingencies.
9-45
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LAND TREATMENT FACILITIES
WORKSHEET A - DISPOSING OF WASTE INVENTORY
Method of Disposal: Spreading on the Land Treatment Fields
1. Maximum inventory to be disposed
2. Run-off water to be disposed
3. Total material to be disposed (Line 1 + Line 2)
4. Application rate (wet weight)
5. Acreage utilized
6. Number of applications in the closure period
7. Unit cost of spreading
8. Total cost of spreading (Line 5 x Line 6 x Line 7)
9. Nuzrber of diskings required during the
closure period (excluding one disking for
decontamination)
10. Unit cost of disking (equipment cost and labor)
11. Total cost of disking (Line 5 x Line 9 x Line 10)
12. Total cost for disposing of inventory and
run-off water (Line 8 + Line 11)
5000 tons of
liquid waste
5000 tons
10,000 tons
100 tons/acre
50 acres
2
$48/acre
$4800
10
$4.80/acre
$2400
$7200
9-46
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LAND TREATMENT FACILITIES
WORKSHEET B - DECONTAMINATING THE FACILITY
1. Area of facility contaminated
2. Depth of material removed
3. Unit cost for removal (including machinery rental)
4. Cost of removing the contaminated soil
(Line 1 x Line 2 x Line 3)
5. Quantity of contaminated soil disposed on-site by
landspreading
6. Quantity of contaminated soil disposed off-site
7. Application rate
8. Acreage utilized
9. Number of applications
10. Unit cost of spreading (equipment cost and labor)
11. Total cost for spreading the contaminated soil
on the land treatment fields (Line 8 x Line 9
:: Line 10)
12. Nunmer of diskings carried out to assist
in disposing of contaminated soil
13. Unit cost of disking (equipment cost and labor)
14. Total cost for disking the spread soil into the
land treatment soil (Line 8 x Line 12 x Line 13)
15. Total cost of disposing of the contaminated soil
(Line 4 + Line 11 + Line 14)
16. Cost of decontaminating equipment
17. Disposing of residues from equipment decon-
tamination
18. Total cost of decontaminating the facility
(Line 15 + Line 16 -I- Line 17)
1200 sq. yds.
.33 yds. (1 ft.)
$1.60/cu. yd.
$633.60
396 cu. yds.
(481 tons)
0
10 tons/acre
50 acres
1
$6/acre
$300
$4.80/acre.
$240
31173.60
$1000
$1000
$3173.60
9-47
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LAND TREATMENT FACILITIES
WORKSHEET C - MONITORING ACTIVITIES
(GRQUHD-WATER AND SOIL MONITORING)
Ground-r7acer Monitoring
8
9
10
11
12
13
14
15
16
Number of wells monitored
Number of samples taken at each well (1 per cycle)
Total number of samples (Line 1 x Line 2)
Number of hours for collecting the sample (per sample)
Total number of hours for collecting the samples
(Line 3 x Line 4)
Number of hours for preparing and delivering sample
(per each sampling cycle of eight wells)
Total number of hours for preparing and delivering
sample (Line 2 x Line 6)
Person-hour costs for collecting and handling samples
Total ground-water sampling and collection costs
((Line 5 + Line 7) x Line 8)
Number of ground-water quality analyses
Number of ground-water contamination analyses
Unit cost of ground-water quality analysis
Unit cost of ground-water contamination analysis
Total ground-water quality analysis costs
(Line 10 x Line 12)
Total ground-water contamination analysis costs
(Line 11 x Line 13)
Total ground-water chemical analyses costs
(Line 14 + Line 15)
Soil Monitoring
Soil Core Sampling:
Number of soil core samples taken during the
closure period
Labor hours required for each core sample
(includes movement between sampling locations)
Labor unit cost for collecting core sample
17
18
19.
3 wells
3 samples
?4 samples
2 hours
48 hours
3 hours
9 hours
$15/hour
$855
16 analyses
24 analyses
$77
$108
$1232
$2592
$3824
66 samples
.5 hours
S15/hour
9-48
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WORKSHEET C (continued)
20.
21.
22,
23.
24.
25.
26.
27.
28.
Total cost of collecting soil samples for the entire
closure period (Line 17 x Line 18 x Line 19)
Unit soil core sample analysis cost (10 parameters)
Total soil core sample chemical analysis cost
(Line 17 x Line 21)
Lysimeter Sampling of Soil Moisture;
Number of lysimeter samples taken during the
closure period
Labor hours required for each lysimeter collection
of soil moisture
Labor unit cost for collecting samples
Total sampling cost for lysimeter collection
of soil moisture (Line 23 x Line 24 x Line 25)
Unit cost for moisture sample analysis
Total cost for moisture sample chemical analysis
(Line 23 x Line 27)
Administrative Costs
29. Number of technical hours for administration
30. Person-hour technical costs
Total technical costs for administration
(Line 29 x Line 30)
Number of clerical hours
Person-hour clerical cost
Total clerical costs (Line 32 x Line 33)
Total administrative costs (Line 31 + Line 34)
Maintenance Costs
36. Monitoring well maintenance (includes maintenance
of associated equipment)
Cost Summaries for Monitoring
37. Total cost of ground-water monitoring for the
closure period (Line 9 + Line 16 + Line 36)
38. Total cost of soil core sample monitoring for
the closure period (Line 20 + Line 22)
31,
32,
33.
34,
35.
$495
$60
$3960
20
1 hour
$15/hour
$300
$150
$3000
16 hours
$30/hpur
$480
16 hours
$8
$128
$608
$750
$5429
S4455
9-49
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WORKSHEET C (continued)
39. Total cost for soil moisture (lysimeter) monitoring S3300
for the closure period (Line 26 + Line 28)
40. Total administrative costs (Line 35) $608
41. Total monitoring costs for the entire closure . $13,792
period (Line 37 + Line 38 + Line 39 + Line 40)
9-50
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LAND TREATMENT FACILITIES
WORKSHEET D - FENCE MAINTENANCE
1. Length of fence Co be replaced 590 feet
2. Unit cost of replacing fence S13.06/linear ft
3. Total cost of replacing fence (Line 1 x Line 2) $7705
9-51
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LAND TREATMENT FACILITY
WORKSHEET E - REPAIR OF DRAINAGE CHANNELS
1. Length of drainage channels requiring excavation
2. Channel volume per unit length
3. Channel excavation unit cost
4. Total channel excavation cost
(Line 1 x Line 2 x Line 3)
5. Unit cost for hand grading
6. Channel surface area to be prepared by hand
7. Total cost of hand grading (Line 5 x Line 6)
8. Total replanting cost (including seed,
fertilizer and mulch)
9. Total channel repair cost
(Line 4 + Line 7 + Line 8)
500 feet
.33 cu. yds.
per linear ft.
$.67/cu. yd.
$11.05
$.02/sq. ft.
4500 sq. ft.
$90
$50
$250.55
9-52
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LAND TREATMENT FACILITIES
WORKSHEET F - MANAGEMENT INSPECTION OF LAND
TREATMENT FACILITY OPERATIONS
1. Number of technical management person-hours
required for each inspection of the land treatment
facility
2. Inspection frequency
3. Duration of closure period
4. Total technical management person-hours required
for inspections during the closure period
(Line 1 x Line 2 x Line 3)
5. Person-hour costs for technical management duties
6. Total technical management costs for land treatment
facility inspections (Line 4 x Line 5)
7. Additional technical management labor required
related to the inspection program
8. Total cost of the additional technical management
labor (Line 5 x Line 7)
9. Total cost of technical management labor
(Line 6 + Line 8)
10. Number of clerical hours required
11. Person-hour costs for clerical labor
12. Total cost for clerical labor (Line 10 x Line 11)
13. Total inspection cost (Line 9 + Line 12)
8 hours
1 per month
15 months
120 hours
$30 '
$3600
10 hours
S300
$3900
9-53
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LAND TREATMENT FACILITIES
WORKSHEET G - PROFESSIONAL CERTIFICATION
1. Number of person-hours required for inspecting
the land treatment facility and its operating records
2. Cost per person-hour
3. Total costs of professional engineer's time
(Line 1 x Line 2)
4. Number of technical hours required for administrative
duties
5. Person-hour costs for technical administrative duties
6. Total administrative costs for technical labor
(Line 4 x Line 5)
7. Number of clerical hours required for administrative
duties
8. Person-hour costs for clerical administrative duties
9. Total administrative costs for clerical labor
(Line 7 x Line 8)
10. Total administrative costs (Line 6 + Line 9)
11. Total certification cost (Line 3 + Line 10)
40 hours
$75
S3000
8 hours
$30
$240
8 hours
$8/hour
$64
9-54
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LAND TREATMENT FACILITIES
WORKSHEET H - TOTAL COSTS PLUS ADMINISTRATION
AND CONTINGENCIES
1. Cost of disposing of inventory (From Worksheet A) $ 7,200
2. Cost of decontaminating the facility (From Worksheet B) $ 3,173
3. Cost of monitoring (From Worksheet C) $13,792
4. Cost of fence maintenance (From Worksheet D) $ 7,705
5. Cost of repairing drainage channels (From Worksheet E) $ 251
6. Cost of management inspections (From Worksheet F) $ 3,964
7. Cost of professional certification of closure $ 3,304
(From Worksheet G)
8. Total of Line 1 through Line 7 $39,389
9. Administration $ 5,908
10. Contingencies $ 5,908
11. Total costs of closure (Line 8 + Line 9 + Line 10) $51,205
9-55
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9.4 EXAMPLE - LANDFILLS
For illustrative purposes, a sample cost estimate has been developed
for a landfill with the following characteristics: the landfill has been
in operation for 10 years and covers approximately 75 acres. Sixty-five
acres have been partially -closed (i.e., they have been filled with waste,
an adequate cap and vegetative cover established and maintained). Ten
acres of the landfill are currently in active use and have not received
final cap or cover but are largely filled. Of the 65 acres which have
received final cap and cover, it is assumed that approximately 5 acres
are in need of revegetation due to failure of original vegetation over
the life of the facility. The landfill accepts hazardous solid waste re-
ceived in trucks. Waste is received for this site in 55-gallon drums.
9-56
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SAMPLE CLOSURE COST ESTIMATING WORKSHEETS: LANDFILLS
A. Disposing of Inventory
1. Volume of waste when processed for landfill disposal: It is
estimated from the closure plan that the most expensive closure conditions
likely to occur over the life of facility would result in 900 55-gallon drums
of waste to be disposed and no trench yet constructed for their disposal.
This situation would occur when existing trenches had been filled but not
yet capped, and waste continued to be accepted for further disposal.
This estimate should be based on the volume of the waste after conducting
the necessary processing prior to disposal. For example, if sludge is
taken in, the proper volume to be used is that of solidified sludge, not
the volume of the sludge as it enters the facility. In this case, since
waste is accepted in drums only, there is no need for further calculation.
2. Estimated volume of contaminated soil residues disposed
of through on-site landfill operations: This volume is determined from
Worksheet B.
3. Total volume of wastes to landfills on-site (Line 1 + Line 2):
In this case, the total volume to be landfilled on-site is the volume of
inventory (800 cu. yds.) plus the estimate volume of residues and con-
taminated material to be disposed of on-site from Worksheet B (600 cu.
,-ds.). It is possible in some cases that not all inventory could be
disposed of on-site. For example, if two wastes normally are neutralized
by combination, and there is inadequate volume of one of the wastes to
complete neutralizing the second waste at the time closure commences,
some portion of the second waste would have to be disposed of off-site.
4. Estimated cost of constructing a trench: The cost of construct-
ing a trench adequate for 1400 cu. yds. of material of the type indicated,
including adequate liner, is estimated as $18,000, based upon past trench
construction experience at the facility.
5. Estimated cost of placing wastes in trench (excluding final
cover and vegetation): Based on the annual volume and operating costs
of the facility (excluding profits and depreciation), it is estimated
that the costs of placing this waste will be $6000.
9-57
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6. Total cost of disposing of inventory (Line 4 + Line 5): The
total cost of disposing of inventory are then the sum of Lines 4 and 5.
B. Decontaminating the Facility
1. Area of facility contaminated: It is assumed in the example that
at the end of facility life, approximately 1800 sq. yds. of the surface of
the facility will show sufficient contamination to justify its disposal
as hazardous waste.
2. Depth of material removed: It is assumed that removal to 1 foot
will be necessary.
3. Cost of removal: The assumed cost of removing this material
is $1.40 per cu. yd. for a total cost of $840. This does not include
the costs of disposing of the material.
4. Quantity disposed on-site: For the sample problem, it is
assumed that all 600 cu. yds. will be disposed on-site.
5. Quantity disposed at an off-site TSDF: None of the material
removed will be disposed off-site.
6. Cost to decontaminate equipment: It is assumed that $1000 will be
sufficient for decontaminating equipment.
7. Volume of waste resulting from decontaminating equipment: It
is estimated that 25 cu. yds. of material will need to be disposed of
as a result of decontaminating equipment.
8. Unit cost of off-site disposal: Contact with other area
hazardous waste disposal facilities indicates that land disposal for
these wastes would currently cost $40/cu. yd.
9. Unit cost of hauling: Hauling this small quantity of residue
20 miles to nearest landfill will cost $10 per cu. yd. according to
local trucking concerns.
10. Total cost of off-site disposal (Line 7 x Line 8): Total costs
of disposing residue are then $1000.
11. Total cost of hauling (Line 7 x Line 9): Total cost of hauling
is then the unit cost of hauling times the total volume of residues to
be disposed.
12. Total cost of decontaminating the facility (Line 3 ! Line 6 + Line
10 + Line 11): Total costs are then $2850.
9-58
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C. Placing Final Cap
As noted in the summary of this example, it has been assumed that
the equipment for all necessary earth work is available on-site. As a
result, costs for placing a final cap over the fill area include only
labor, operating costs, and materials, not costs associated with rent-
ing equipment or capital recovery factors for purchased equipment.
1. Area to be capped: The example assumed that 10 acres, or 48,400
sq. yds., will remain open and require both a clay cap and topsoil.
2. Type of material used for impermeable layer: Clay is the
impermeable material specified in the closure plan.
3. Depth of impermeable layer: It is assumed that 2 ft. of clay
will provide an adequate cap.
4. Volume of material required (Line 1 x Line 3): The amount of
clay required is 32,428 yds. (48,400 x .67 yds.).
5. Source of impermeable material: It is assumed that clay is
available on-site as a result of previous excavations, at a haul distance
of 800 yds. or less.
6. Cost of impermeable material: Because the material is available
on-site, the cost is zero.
7. Depth of topsoil required: It is assumed that 2 ft. of topsoil
will be adequate to ensure that the roots from vegetation of the fill
area do not penetrate the clay cap.
8. Volume of topsoil required (Line 1 x Line 7): The amount of
topsoil required is 32,423 cu. yds.
9. Source of topsoil: Again, it is assumed that adequate topsoil
is available on-site from previous excavations.
10. Cost of topsoil: The cost in this case is zero, since the
material is available on-site. (If topsoil were not available on-site,
a cost estimate would have to be developed through discussions with local
suppliers, etc.)
11. Cost per cu. yd. for hauling, spreading and compacting clay and
topsoil: In the example, it is assumed that this can be done for $1.20
per cu. yd.
12. Cost of placing impermeable portion of cap (Line 4 x Line 11):
Based on these assumptions, the costs of placing the impermeable portion
9-59
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of che cap would be $38,914.
13. Cost of placing topsoil (Line 8 x Line 11): Based on the assump-
tions, the costs of placing topsoil are also $38,914.
14. Total costs of final cap (sum of Lines 6, 10, 12, and 13): The
total costs of the final capping operation will be $77,828. This does
not include administrative- expenses or contingency planning, both of
which are calculated on Worksheet G.
D- Planting Final Vegetation
As in the above worksheets, it is assumed that all necessary equip-
ment is available on-site, but that material and labor costs will be
accrued during the closure exercise.
1. Area not yet vegetated: The area remaining open at the time
of closing is 10 acres.
2. Area already closed but requiring replanting: It is assumed
in this case that 5 acres of the closed portion of the landfill require
replanting, due to the failure of original vegetation efforts.
3. Total area to be planted (Line 1 + Line 2): . The sample
case provides for 15 acres to be planted during closure.
4. Type of vegetation to be used: In this example, it is assumed
that coarse field grass (a mixture of rye grass and Kentucky fescue)
will be employed for final vegetation.
5. Quantity of seed used per acre: According to industry suppliers,
150 Ibs. of seed should be applied per acre.
6. Cost of seed per pound: Calls to local suppliers determined that
seed is available at $.50/lb.
7. Total cost of seed (Line 3 x Line 5 x Line 6): Given the above
assumptions, the total cost of seed will be $1125.
8. Type of fertilizer to be used: Given the topsoil and climatic
conditions, 10/10/10 fertilizer is assumed to be adequate.
9. Quantity of fertilizer per acre: .25 tons is assumed to be
reasonable, given the quality of topsoil and the climatic conditions.
10. Cost of fertilizer per ton: According to local suppliers,
fertilizer is available for $200/ton.
9-60
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11. Total cost of fertilizer (Line 3 x Line 9 x Line 10): Given
the above assumptions, the total cost of fertilizer is $750.
12. Cost of soil preparation per acre: Preparing the soil includes
both disking and fertilizing and is assumed to be $100 per acre.
13. Total cost of preparing soil (Line 3 x Line 12): The total
cost of preparing soil, excluding materials such as fertilizers, is,
given the above assumptions, $1500.
14. Cost per acre of seeding (excluding cost of seed): It is
assumed for the sample facility that seeding will cost $150 per acre.
15. Total cost of seeding (excluding seed) (Line 3 x Line 14):
Given the above assumptions, the total cost of seeding for the facility is
$2250.
16. Cost per acre of mulching: The cost per acre of purchasing and
applying a hay mulch is assumed to be $120.
17. Total mulching costs (Line 3 x Line 16): Given the above assump-
tions, total mulching costs, including costs of hay, are $1800 for the
18. Total costs for vegetation (sum of Lines 7, 11, 13, 15, and 17):
The total costs for establishing vegetation are $7425.
E. Gjround-water Monitoring
Assume that closure of the landfill will require a total of 90 days.
In order co determine the maximum possible ground-water monitoring costs,
the most extensive monitoring needed at closure is assumed. Assuming
that ground-water quality analyses are required annually and ground-water
contamination analyses are required semi-annually, the most expensive
case is that in which both sets of analyses are required during the 90-
day closure period.
1. Number of wells monitored: For the sample landfill, it is assumed
that eight wells would need to be monitored.
2. Number of samples per well: One sample is taken per well for
both analyses.
3. Total number of samples (Line 1 x Line 2): Given the above
assumptions, eight samples are required.
9-61
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14. local ground-water contamination analysis costs (Line 10 x
Line 12): For eight samples at $108 per analysis, this yields a total
cost of $864.
15. Total analysis costs (Line 13 + Line 14): The total analyses
costs, therefore, are $1480.
16. Number of technical hours for administration: This includes
all time necessary to administer and report the data from the analyses
and is estimated as 8 hours.
17. Person-hour technical costs: The fully-loaded cost required
for this work is assumed to be $30 per hour.
18. Total technical costs for administration (Line 16 x Line 17):
Given the above assumptions, total costs for administering the tests
are assumed to be $240.
19. Number of clerical hours: Assume for this case that 5 hours oJ
clerical time are required to produce the necessary reports.
20. Per-hour clerical costs: Assume the fully-loaded costs for
clerical work are $8 per hour.
21. Total administrative costs (Line 19 x Line 20): Given the above
assumptions, the total clerical costs are S40.
22. Total administrative costs (Line 18 +'Line 21): The sum of
technical and clerical costs are then S280.
23. Monitoring equipment maintenance: It is assumed that an average
of S150 is required for a 90-day period to ensure adequate maintenance of
monitoring equipment and wells.
24. Total monitoring costs (sum of Lines 8, 15, 22, and 23): Total
monitoring costs, excluding administration and contingencies, are then
$2195.
F. Fence Maintenance
For a 75-acre site, assuming that the site is square, each side of
the site is 1807 feet in length. The perimeter of the site is then
7228 feet.
1. Length of fence to be replaced: It is expected that some
sections of Che facility's security fence will have corroded and will
have to be replaced. Our estimate is that 10% of the perimeter fence
will have to be replaced.
9-63
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2. Unit cost of replacing fence: The security fence around the
facility perimeter is a galvanized metal chain link fence 6 feet high.
This fence is made of #9 wire. The unit replacement cost for this
fence is $13.06 per linear foot.
3. Total cost of replacing fence (Line 1 x Line 2): The cost of
fence replacement is the product of the length of fence needing re-
placement and the unit cost of replacement, for a total of $9442.
G- Professional Certification
1. Number of person-hours required for inspections: It is
assumed that 80 hours are required for periodically inspecting all as-
pects of closure of the landfill.
2. Cost per person-hour: In this case, assume that a registered
independent professional engineer may be hired at a cost of $75 per hour.
3. Total costs of independent professional engineer's time (Line
1 x Line 2) : This yields a total cost of S6000 for the independent
professional engineer.
4. Number of technical hours required for administrative duties:
Assume that 8 hours are required from the owner/operator's staff for
administrative duties connected with employing an independent professional
engineer.
5. Person-hour costs for technical administrative duties: It is
assumed that the total fully-loaded costs for the owner/operator's rtaff
are $30 per hour.
6. Total administrative costs for technical labor (Line 4 x Line 5):
Given the above assumptions, the total administrative costs for technical
labor are S240.
7. Number of clerical hours required for administrative duties:
Assume that 5 hours of clerical time are required for the necessary typing
and certifications.
8. Person-hour costs for clerical administrative duties: Fully-
loaded costs of clerical time are assumed to be $8.
9. Total administrative costs for clerical labor (Line 7 x Line 8):
Given the above assumptions, total clerical costs are $40.
9-64
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10. local administrative coses (Line 6 + Line 9): Summing technical
and clerical labor, the cocal administrative costs are $280.
11. Total certification costs (Line 3 + Line 10; : The total costs
for certification, including the engineer's fees and administrative costs
1 a r lia,i CfiOQn '
is then
H* T°tal Closure Costs Including Adminisrration and Contingencies
Lines 1 through 7 of this Worksheet simply summarize the total closure
costs, excluding administration and contingencies, from each of the prior
worksheets.
8. Total of Lines 1 through 7: The total costs for the activities
listed in Lines 1 through 7 are $130.020.
9. Administration: For administrative tasks, including taxes,
insurance, and administration and supervision not included elsewhere,
a total of 15 percent of total costs from Line 8 is used.
10. Contingencies: A general provision for contingencies of 15
percent of total costs has been included.
11. Total closure costs (Line 8 + Line 9 + Line 10): The estimated
total closure costs are then $169,026.
9-65
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LANDFILLS
WORKSHEET A - DISPOSING OF INVENTORY
1. Volume of waste when processed for disposal ' 800 cu. yds.
2. Estimated volume of residue and contaminated 600 cu. yds.
soil to be disposed through on-site landfill
operation
3. Total volume of waste to be landfilled on-site 1400 cu. yds.
(Line 1 + Line 2)
4. Estimated cost of constructing trench $18,000
5. Estimated cost of placing waste in $ 6,000
trench
6. Total cost of disposing of inventory $24 000
(Line 4 + Line 5)
9-66
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LANDFILLS
WORKSHEET B - DECONTAMINATING THE FACILITY
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
Area of facility contaminated
Depth of material removed
Cost of removal
Quantity disposed on-site (see Worksheet A
to develop cost)
Quantity disposed off-site
Cost to decontaminate equipment
Volume of waste resulting from decontaminating
equipment
Unit cost of off-site disposal ($/cu. yd.)
Unit cost of hauling ($/cu. yd.)
Total cost of disposing off-site (Line 7 x Line 8)
Total cost of hauling (Line 7 x Line 9)
Total costs of decontaminating the facility
(Line 3 + Line 6 + Line 10 + Line 11)
1800 sq. yds.
.33 yd. (1 ft.)
$840
600 cu. yds.
0
$1000
25 cu. yds.
9-67
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LANDFILLS
WORKSHEET C - PLACING FINAL CAP
Area Co be capped (include sum of all portions
of Che facility remains open and any portions of
the facility opened to dispose of inventory and
wastes from- the process of decontamination)
Type of material used for impermeable layer
48,400 sq. yds.
(10 acres)
Clay with perm-
eability of 10~7
Depth of material of impermeable layer
Volume of material to be used for impermeable
layer (Line 1 x Line 3)
Source of impermeable material
6. Cost of impermeable material
7. Depth of topsoil
8. Volume of topsoil (Line 1 x Line 7)
9. Source of toosoil
10. Cost of topsoil
11. Cost per cu. yd. for hauling, spreading and
compacting
12. Cost of impermeable portion of cap
(Line 4 x Line 11)
13. Cost of placing topsoil (Line 8 x Line 11)
14. Total costs (Line 6 + Line 10 4- Line 12 + Line 13)
.667 yds. (2 ft.)
32,428 cu. yds.
On-site from
previous exca-
vations
0
.667 yds. (2 ft.)
32,428 cu. yds.
On-site from
previous exca-
vations
0
$1.20
$38,914
$38,914
$77.828
9-68
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LANDFILLS
WORKSHEET D - PLANTING FINAL VEGETATION
1. Area not yet vegetated (should be approximately
equivalent to area remaining open)
2. Area already closed but in need of some replanting
prior to final closure
3. Total area to be planted (Line 1 + Line 2)
4. Type of vegetation to be used
5. Quantity of seed per acre
6. Cost of seed per pound
7. Total cost of seed (Line 3 x Line 5 x Line 6)
8. Type of fertilizer to be used
9. Quantity of fertilizer per acre
10.. Cost of fertilizer per ton
11. Total cost of fertilizer (Line 3 x Line 9 x
Line 10)
12. Cost of soil preparation per acre
13. Total cost of preparing soil (excluding
materials) (Line 3 x Line 12)
14. Cost per acre of seeding (less materials)
15. Cost of seeding (Line 3 x Line 14)
16. Cost per acre of mulching
17. Total mulching costs (Line 3 x Line 16)
18. Total costs for vegetation
(Line 7 + Line 11 -I- Line 13 + Line 15 + Line 17)
10 acres
5 acres
15 acres
Coarse grass
150 Ibs.
$.50
$1125
10/10/10
.25 tons
$200
$750
$100
$1500
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LANDFILLS
WORKSHEET E - GROUND-WATER MONITORING
1. Number of wells monitored 8 wells
2. Number of samples per- well 1 sample
3. Total number of samples (Line 1 x Line 2) 8 samples
4. Number of hours required for collecting sample 2 hours
(per sample)
5. Total number of hours required for collecting samples 16 hours
(Line 3 x Line 4)
6. Number of hours required for preparing and delivering 3 hours
samples
7. Person-hour costs for collecting samples $15
8. Total sampling and collection costs $285
((Line 5 + Line 6) x Line 7)
9. Number of ground-water quality analyses 8 analyses
10. Number of ground-water contamination analyses 8 analyses
11. Unit cost of ground-water quality analysis S77
12. Cost of ground-water contamination analysis , S108
13. Total ground-water quality analysis costs $616
(Line 9 x Line 11)
14. Total ground-water contamination analysis costs $864
(Line 10 x Line 12)
15. Total analyses costs (Line 13 + Line 14) $1480
16. Number of technical hours for administration (e.g. ,
reporting data to EPA)
17. Person-hour technical costs S30
18. Total technical costs for administration S240
(Line 16 x Line 17)
19. Number of clerical hours 5 hours
20. Person-hour clerical costs $8
21. Total clerical costs (Line 19 x Line 20) $40
22. Total administrative costs (Line 18 + Line 21) $280
9-70
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WORKSHEET E - continued
23. Monitoring equipment maintenance
24. Total monitoring costs (Line 8 + Line 15
Line 22 -I- Line 23)
9-71
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LANDFILLS
WORKSHEET F - FENCE MAINTENANCE
1. Length of fence to be replaced 723 feet
2. Unit cost of replacing fence $13.067
linear ft.
3. Total cost of replacing fence $9442
(Line 1 x Line 2)
9-72
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LANDFILLS
WORKSHEET G - PROFESSIONAL CERTIFICATION
1. Number of person-hours required for inspections
2. Cost per person-hour
3. Total costs of independent professional engineer
certification (Line 1 x Line 2)
4. Number of technical hours required for administrative
duties
5. Person-hour costs for technical administrative duties
6. Total administrative costs for technical labor
(Line 4 x Line 5)
7. Number of clerical hours required for administrative
duties
8. Person-hour costs for clerical administrative duties
9. Total administrative costs for clerical labor
(Line 7 x Line 8)
10. Total administrative costs (Line 6 + Line 9)
11. Total certification costs (Line 3 + Line 10)
80 hrs,
$75
$6000
8 hrs.
$30
$240
5 hrs.
$8
$40
9-73
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LANDFILLS
WORKSHEET H - TOTAL COSTS OF CLOSURE INCLUDING
ADMINISTRATION AND CONTINGENCIES
1. Cost of disposing of inventory (From Worksheet A) $ 24,000
2. Cost of decontaminating the surface and ancillary $ 2,850
facilities (From Worksheet B)
3. Cost of placing the final cap (From Worksheet C) $ 77,828
4. Cost of planting final vegetation (From Worksheet D) $ 7,425
5. Cost of ground-water monitoring (From Worksheet E) $ 2,195
6. Cost of fence maintenance (From Worksheet F) $ 9,442
7. Cost of professional certification (From Worksheet G) $ 6,280
8. Total of Line 1 through Line 7 $130,020
9. Administration $ 19 f503
10. Contingencies $ 19,503
11. Total costs of closure (Line 8 + Line 9 + Line 10) $169,026
9-74
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9.5 EXAMPLE - INCINERATORS
A 12-acre incinerator facility has bulk storage facilities for 120,000
gallons of slop oil, 120,000 gallons of phenolic wastewater, and 1,000,000
gallons of organic sludge. Waste is also delivered in 55-gallon drums; a
maximum of 600 drums may be stored at the facility. In addition to these
delivered wastes, the facility normally contains an inventory of 50 drums
of non-combustible ash from the incinerator.
The incinerator is designed to operate at 16 gpm with the following
feed mixture: 4 gallons of slop oil, 4 gallons of wastewater, and 8 gallons
of sludge (a 1/1/2 ratio). The total operating horsepower of the incinerator
(including pollution control equipment in the form of a caustic scrubber
used to remove chlorinated compounds emitted from the slop oil) is 350 HP.
The following worksheets are based on this facility description.
9-75
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SAMPLE CLOSURE COST ESTIMATING WORKSHEETS: INCINERATORS
A. Characterizing the Waste Inventory
Worksheet A is used to describe each waste accepted at the site. For
the example, worksheets must be prepared for each of the following wastes:
slop oil, phenolic wastewater, and biological treatment sludges. For each
vaste product accepted, the following information is required:
1. Describing the waste: Describing the origin and general nature
of the waste.
2. Chemical composition: Chemical composition should be expressed
in weight percents for major components and parts per million (ppm) for
trace components. This information should be readily available to the
operator from the bill of lading for each waste shipment.
3. Physical state of the waste: This describes whether the waste is
a liquid, solid, or mixture. This information is utilized in making estimates
of solid .residues requiring disposal (Worksheet B).
4. Heat of combustion of the waste: The heat content (expressed in
BTU/lb., or BTU/gal.) of the waste products. This information is used in
determining auxiliary fuel requirements (if any) on Worksheet C.
5. Specific gravity of the waste: The specific gravity of the waste
at 60 F referenced to water at 60 F is used in the example problem.
6. Closure inventory: For the example, it has been assumed that the
operator has identified from experience that the maximum inventory he has
ever had stored on-site was a 14-day backlog. We will assume that this
inventory is comprised of the total components: 224 drums of slop oil
(12,320 gallons), 224 drums of phenolic wastewater (12,320 gallons) and
152 drums of sludges (8,360 gallons); the bulk storage tanks contain 28,000
gallons of slop oil, 28,000 gallons of phenolic wastewater, and 233,560
gallons of organic sludges. Under these conditions, the incinerator will
be able to treat its inventory through seven days of burning its optimum
feed mixture, and seven days of burning sludges alone (through the addition
of auxiliary fuels) .
9-76
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B. Treating the Inventory
It is assumed that the inventory on-hand at the time of closure will
be incinerated on-site. All equipment necessary for the operation of the
incinerator is assumed to be in complete working order.
1. Time required for treating the inventory: It will require 336 hours
(322,560 gallons of waste ^ 960 gallons throughput per hour). If it is
further assumed that the incinerator is on-stream 90% of the time, the total
time required for treating on-site inventory is 373 hours.
2. Manpower requirements for treating the inventory: The total number
*
of personnel required to operate this facility (including plant operators,
equipment operators, guards, maintenance persons, and laboratory personnel)
is estimated as six. Therefore, total man-hour requirement for treating
the inventory is 2238 hours.
3. Cost of manpower: The average hourly wage rate of a plant operator
(including fringe benefits and labor burdens) is assumed to be $20.
4. Total costs of operating labor during inventory treatment (Line 2
x Line 3): Given the above assumptions, labor costs for this phase of
closure are $44,760.
5. Fuel requirements for treating the inventory: These represent both
the cost of utilities consumed in order to treat the waste inventory, plus
any auxiliary fuels which had to be purchased. Each of these items is
.separately costed below.
6. Electricity requirenents for treating the inventory: The inciner-
ator is actually in operation for 336 hours. Electricity requirements for
WTJ
the example are equal to 350 HP x .746 ^- x 336 hours = 87,730 Sewn.
7. Costs of electricity: Electricity is assumed to be available at
a cost of $.06/kwh.
i
8. Total costs of electricity (Line 6 x Line 7): Total electricity
costs for the example are $5264.
9. Auxiliary fuel requirements: During the first 168 hours of inven-
tory treatment, the incinerator will be receiving an input feed of 25% slop
oil, 25% phenolic wastewater, and 50% organic sludges. This feed has a
heat value of 2900 BTU/lb. and will burn autogenously. During the remaining
168 hours, the feed will be comprised entirely of sludges, with a heat
value of 700 BTU/lb.; this mixture does require auxiliary fuel inputs.
9-77
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10. Type of auxiliary fuel used: It is assumed that i?6 fuel oil is
used as the auxiliary fuel.
11. Quantity of fuel required: Using engineering analysis, and
assuming an average heat value of 154,000 BTU/gal. for fuel oil, total
auxiliary fuel requirements are estimated at 10,456 gallons.
12. Cost of auxiliary fuel: It is assumed that #6 fuel oil is available
to the operator at $.90 per gallon.
13. Total cost of auxiliary fuels (Line 11 x Line 12): The total
cost of auxiliary fuel inputs is $9410.
14. Total fuel costs (Line 8 + Line 13): Total fuel costs are $14,674.
15. Chemical requirements: This category includes all chemicals,
catalysts, adsorbents, and other supplies consumed during inventory treat-
ment. In the example, the only chemical required is the caustic consumed
during flue gas scrubbing of chlorine entrained in the incinerator waste
stream.
16. Type of chemicals used: It is assumed that the caustic will be
purchased as a 50% solution.
17. Quantity of chemicals required: There are 40,320 gallons of sloo
oil in the waste inventory assumed to be present at the time of closure.
This is equivalent to 319,334 Ibs. of slop oil (40,320 x .95 specific
gravity of slop oil x 8.34 Ibs./gal. water). Since the chlorine content
of the slop oil is assumed to be no greater than 3 percent, the maximum
quantity of chlorine to be scrubbed is 9,580 Ibs. (270 moles). Assuming
that 1 mole of NaOH is required to neutralize 1 mole of chlorine, 270 moles
x 40 Ibs. NaOH/mole = 10,800 Ibs. NaOH-consumption.
18. Cost of chemicals required: Caustic is assumed to cost $.08257
dry Ib.
19. Total cost of chemicals (Line 17 x Line 18): The total cost of
chemicals consumed during inventory treatment is S891.
20. Disposing or treating residues generated during inventory treatment:
The residue generated during inventory treatment is a powdery solid, inciner-
ator ash. The ash has a specific gravity of 2.5.
21. Amount of residue on-site after treating the inventory: There
are 50 55-gallon drums of ash stored on-site at the point of closure (each
weighing 1150 Ibs., for a total of 57,500 Ibs.). In addition, residues
9-78
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are generated by processing the waste inventory. The sludges incinerated
in the example are assumed to be 10 percent solids; one-third of the solids
are assumed to be non-combustible. The slop oil and wastewaters processed
by the incinerator produce no ash. Therefore, the amount of new residue
generated = (total amount of sludge in inventory times specific gravity
of the non-combustible por.tion of the materials times the portion of the
sludge that is non-combustible), or:
241,920 x (2.5 x 8.34) x .0333 - 167,968 Ibs.
Total residue to be disposed of is equal to 167,968 Ibs. and 57,500 Ibs. =
225,468 Ibs.
22. Method of disposing of ash: It is assumed that the incinerator
ash is put into drums and transported to a secure landfill. The residue
generated during inventory treatment can be placed in 146 drums, making
the total number of drums to be disposed of 196.
23. Unit costs of disposing of residue: The costs of disposing in
a landfill are assumed to be $50/drum, according to industry specialists.
24. Total costs of disposing of residue (Line 21 x Line 23): Total
costs for the sample case are $9800.
25. Costs of hauling residue to landfill for disposal: In the examole,
it is assumed that the nearest landfill that will accept the drummed
residue is 50 miles away, and that trucks with a carrying capacity of 40
drums are rented at an hourly cost of $60. At a speed of 40 mph, and
assuming four hours for loading/unloading each trip, the total hauling
costs are estimated at $1950.
26. Total cost of treating and disposing of inventory (sum of Lines
4, 14, 19, 24, and 25): Given the above assumptions, the total cost of
inventory disposal will be $72,075.
C. Decontaminating the Facility
In order to completely decontaminate the incinerator facility, the opera-
tor must see to it that all storage tanks and liquid waste feed lines are
cleaned, that wastewaters from the cleaning process are properly disposed
or treated, that all equipment structures and containers left on-site are
decontaminated, and that all contaminated soil is removed properly. These
various activities are individually costed below.
9-79
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Tank Cleaning
1. Storage tank cleaning: The total volume of storage capacity to
be cleaned is 1,240,000 gallons (120,000 gallons of slop oil storage,
120,000 gallons of phenolic wastewater storage, and 1,000,000 gallons of
organic sludge storage).
2. Method used: The cleaning method selected for the sample case
is steam-cleaning.
3. Unit cost of cleaning: Renting equipment, labor, and operating
costs for 1600 gal./hour of cleaning equipment are assumed to be approxi-
mately $.02/gal. of capacity cleaned, based on information from the Means
construction cost guide.
4. Total costs of storage tank cleaning (Line 1 x Line 2): Total
costs of steam-cleaning the storage facility are $24,800, given the above
assumptions.
5. Cleaning residue generation: According to closure guidelines for
waste treatment sites issued by the Texas Department of Water Resources,
tne amount of contaminated washwaters produced by steam-cleaning can be
assumed to be equal to .125 times the volume of the tank being cleaned.
6. Quantity of cleaning residue generated (Line 1 x Line 5):
155,000 gallons of contamined washwater are generated in the example.
7. Method of disposing of residue: In the sample case, residues are
assumed to be transported by tank truck to a surface impoundment for
evaporation.
8. Unit costs for disposing of residues: Based on waste disposal
industry estimates, it will cost $.05/gal. to dispose of residues in an
impoundment.
9. Total costs for disposing of residues (Line 6 x Line 8): Total
costs of cleaning residue disposal, given these assumptions, are $7750.
10. Hauling costs for residues: In the example, hauling cost esti-
mates are based on the following assumptions - the distance between the
incinerator and the surface impoundment is 100 miles one-way, a 7000-gallon
trailer is used, the average trip speed is 40 mph, and the hourly rental
cost of truck and driver is $60. The cost of one round trip is $300.
11. Number of trips required: The number of trips required for the
case is 23.
9-80
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12. Total hauling costs for residues (Line 10 x Line 11): The hauling
costs for residue disposal are estimated at $6900.
Decontaminating the Facility
13. Flush out liquid waste feed lines: The estimated cost of flush-
ing out all liquid residues from feed lines on the facility (before the
storage areas and incinerators are cleaned) is assumed to be roughly one-
eighth of the costs of tank cleaning, or $3000.
14. Pump out and backfill sumps: Sumps are to be decontaminated to
prevent the possibility of rain water accumulating and contaminating these
portions of the facility. The estimated costs of this activity are
$2000.
15. Removing contaminated soils: Because of spills and other
accidental releases, certain areas of the waste disposal site such as
the dikes in areas around storage tanks may be contaminated. We have
assumed in this example problem that 2.5 percent of the area of the site
(exclusive of reservoirs, ponds, and basins) is contaminated.
Contaminated area = .025 x 12 acres x 4840 sq. yd./acre
= 1452 sq. yds.
16. Depth of soil removal: For this example, the assumed depth of
soil removal is one foot.
17. Total amount of soil removed (Line 15 x Line 16): The total
amount of soil removed in this example is (1452 x .333), or 484 cu. yds.
18. Unit cost of removing soil: Costs of removing soil (including
equipment rental) are estimated at $1.60/cu. yd.
19. Total cost of soil removal (Line 17 x Line 18): Given the above
assumptions, the cost of removing the contaminated soil from the inciner-
ator site is $774.
20. Costs for disposing of contaminated soils: The contaminated soil
is assumed to be disposed in a sanitary landfill. Based on current esti-
mates, the soil can be landfilled at a cost of $30/ton.
21. Total cost of disposing of soil (Line 17 x Line 20): The cost
of disposing of the contaminated soil is 314,520.
22. Hauling costs for contaminated soil: In this example, the
nearest landfill is assumed to be 50 miles away, the truck used for haulins
9-81
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has a carrying capacity of 44,000 Ibs. , and is rented at a hourly cost
of S60.
23. Number of trips required: Assuming an average speed of 40 mph,
22 trips will be required.
24. Total hauling costs for contaminated soil (Line 22 x Line 23):
Given the above assumptions, the total costs for hauling the contaminated
soil are $3300.
25. Total costs of decontaminating the facility (sum of Lines 4, 9,
12, 13, 14, 19, 21, and 24): The total costs of decontaminating the
sample incinerator are $63,044.
D. Monitoring
1. Cost of air sampling during inventory treatment: In order to
ensure that the incinerator remains in compliance with Clean Air Act
regulations during the closure period, it was assumed that daily sampling
cost of $25 are incurred while the incinerator is operating.
2. Number of samples required: The inventory treatment, phase of
closure is estimated to take 16 days at the sample site.
3. Total costs of monitoring (Line 1 x Line 2): Given the above
assumptions, monitoring costs will be equal to $400.
E. Professional Certification
1. Number of person-hours required for inspections: It is assumed
that 20 hours are required for periodically inspecting all aspects of
incinerator closure.
2. Cost per person-hour: In this case, assume that a registered
independent professional engineer may be hired at a cost of $75 per hour.
3. Total costs of independent professional engineer's time (Line 1
x Line 2) : This yields a total cost of $1500 for the independent profes-
sional engineer.
4. Number of technical hours required for administrative duties:
Assume that eight hours are required from the owner's or operator's staff for
administrative duties connected with employing an independent professional
engineer.
9-82
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5. Person-hour coses for technical administrative duties: It is
assumed that the total fully-loaded costs for the owner's or operator's staff
are $30 per hour.
6. Total administrative costs for technical labor (Line 4 x Line 5):
Given the above assumptions, the total administrative costs for technical
labor are $240.
7. Number of clerical hours required for administrative duties:
Assume that five hours of clerical time are required for the necessary
typing and certifications.
8. Person-hour costs for clerical administrative duties: Fully-
loaded costs of clerical time are assumed to be $8.
9. Total administrative costs for clerical labor (Line 7 x Line 8):
Given the above assumptions, total clerical costs are $40.
10. Total administrative costs (Line 6 -I- Line 9): Summing technical
and clerical labor, the administrative costs are $280.
11. Total certification costs (Line 3 + Line 10): The total costs for
certification, including engineer's fees and administrative costs, are
$1780.
F- Total Costs Including Administration and Contingencies
Line 1 through 4: These lines simply require the transfer of the
cost information supplied in Worksheets 3 through E.
5. Preliminary closure cost estimate (sum of Lines 1 through 4):
For the sample facility, total worksheet costs are qual to $137,299.
6. Administration: The costs for administration, which include
insurance, taxes, and supervision and administration not included else-
where, are assumed to be 15 percent of Line 5.
7. Contingencies: A provision for contingencies of 15 percent of
Line 5 has been included.
8. Total costs of closure (Line 5 + Line 6 4- Line 7): The total
costs of closure, including administration and contingencies, for the
sample incinerator are $178,489.
9-83
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INCINERATORS
WORKSHEET A - CHARACTERIZING THE WASTE (#2)
This worksheet should be used to describe each waste accepted at the facility,
1. Description of ths waste:
Phenolic wastewater
2. Chemical composition of the waste:
1000 ppm phenols
3. Physical state of the waste:
Liquid
4. Heat of combustion of Che waste:
0
5. Specific gravity of the waste:
1.0
6. Closure inventory:
40,320 gal.
9-84
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INCINERATORS
WORKSHEET A - CHARACTERIZING THE WASTE (#3)
This worksheet should be used Co describe each waste accepted at the facility,
1. Description of the waste:
Waste activated sludge
2. Chemical composition of the waste:
3. Physical state of the waste:
Mixture (suspension) - 10% solids, 90% water
4. Heat of combustion of the waste:
700 BTU/lb.
5. Specific gravity of the waste:
1.06
6. Closure inventory:
241,920 gal.
9-85
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INCINERATORS
WORKSHEET B - TREATING THE INVENTORY
1,
2,
3.
4.
5.
6.
7.
8.
. 9.
10.
11.
12.
13.
14.
15.
16.
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
Time required for treating the inventory
Manpower requirements for treating the inventory
Unit cost of labor
Total cost of labor - treating the inventory
(Line 2 x Line 3)
-Fuel requirements
Electricity requirements
Unit cost of electricity
Total costs of electricity (Line 6 x Line 7)
Auxiliary fuel requirements
Type of fuel used
Quantity of fuel required
Unit cost of fuel oil
Total cost of auxiliary fuels
(Line 11 x Line 12)
Total fuel costs for treating inventory
(Line 8 -S- Line 13)
Chemical requirements
Type of chemicals used
Quantity of chemicals used
Unit cost of chemicals
Total cost of chemicals (Line 17 x Line 18)
Residues generated during inventory treatment
Amount of residue generated
Method of treatment
Unit cost of disposing of residue
Total costs of disposing of residue
(Line 21 x Line 23)
Hauling coses for disposing of residue
Total costs of treatine and disposing of
inventory (sum of Lines 4, 14, 19, 24, and 25)
9-86
373 hours
2238 man-hours
S20/hr.
$44,760
Yes
87,730 kwh
$.06/kwh
$5264
Yes, for input
feed B
#6 fuel oil
10,456 gal.
S.90/sal.
$9410
$14,674
Yes
Caustic, 50% solution
10,800 Ibs.
$.0825/lb.
$891
Incinerator ash
225,468 Ibs.
(196 drums)
Landfill
S50/drum
$9800
$1950
$72,075
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INCINERATORS
WORKSHEET C - DECONTAMINATING THE FACILITY
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17.
18.
19.
20.
21.
22.
23.
24.
25.
Volume to be cleaned
Method used
Unit costs of cleaning
Total costs of tank cleaning (Line 1 x Line 2)
Cleaning residue generation rate
Amount of residue generated (Line 1 x Line 5)
Method of disposal
Unit cost for disposing of residue
Total costs for disposing of residue
(Line 6 x Line 8)
Unit cost for hauling residues
Number of trips required
Total costs of hauling residues
(Line 10 x Line 11)
Cost of flushing liquid waste feed lines
Cost to pump out and backfill sumps
Amount of contaminated soil area
Depth of soil removal
Total amount of soil removed (Line 15 x Line 18)
Unit cost of removing soil
Total cost of removing soil (Line 17 x Line 18)
Costs for disposing of contaminated soils
Total cost of disposing of soil (Line 17 x Line 20)
Unit costs of hauling contaminated soils
Number of trips required
Total cost of hauling soils (Line 22 x Line 23)
Total costs of decontamination (sum of Lines
4, 9, 12, 13, 14, 19, 21, and 24)
1,240,000 gal.
S team-cleaning
$.02/gal. capacity
$24,800
.125 x volume of tank
155,000 gal.
Surface impoundment
$.05/gal.
$7750
$300/trip
23
$6900
$3000
$2000
1452 sq. yds.
1 ft.
$774
$1.60/cu. yd.
$774
$30/ton
$14,520
$150
22
$3300
$63,044
9-87
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INCINERATORS
WORKSHEET D - MONITORING
1. Cose of air sampling
2. Number of samples required
3. Total coses of air monitoring (Line 1 x Line 2)
9-88
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INCINERATORS
WORKSHEET E - PROFESSIONAL CERTIFICATION
1. Number of person-hours required for inspecting the 20
facility
2. Cost per person-hour $75
3. Total costs of independent professional engineer $1500
certification (Line 1 x Line 2)
4. Technical hours required for administrative 8 hrs,
duties
5. Person-hour costs for technical administrative duties $30
6. Total administrative costs for technical labor $240
(Line 4 x Line 5)
7. Number of clerical hours required for administrative 5 hrs.
duties
8. Person-hour costs for clerical administrative duties $8
9. Total administrative costs for clerical labor $40
(Line 7 x Line 8)
10. Total administrative costs (Line 6 + Line 9)
11. Total certification costs (Line 3 + Line 10)
9-89
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INCINERATORS
WORKSHEET F - TOTAL COSTS INCLUDING ADMINISTRATION AND CERTIFICATION
1. Costs of creating and disposing inventory (From $ 72,075
Worksheet B)
2. Costs of decontaminating the facility (From $ 63,044
Worksheet C)
3. Costs of monitoring (From Worksheet D) $ 400
4. Costs of professional certification (From $ 1,780
Worksheet E)
5. Estimated basic costs of closure (sum of Lines $137,299
1, 2, 3, and 4)
6. Administration $ 20,595
7. Contingencies $ 20,595
8. Total costs of closure $178,489
9-90
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9-6 EXAiMPLE - MULTIPLE PROCESS FACILITY WITH TANKS
AND SURFACE IMPOUNDMENTS-
A 2-acre hazardous waste treatment and storage facility has storage
tanks for 60,000 gallons of waste solvents and 10,000 gallons of slop
oil. Waste is received at. the facility both from tank trucks and in
55 gallon drums; the facility has a maximum storage capacity of 200
drums. There are two treatment processes undertaken at the facility.
There is a 30,000 gallon (50* x 20' x 4') concrete-lined surface
impoundment used for the gravity separation of oily wastes into solvent,
slop oil, and sludge phases. The normal composition of the oil wastes
accepted is 80 percent solvent, 15 percent oil, and 5 percent sludge.
There is a 30,000-gallon clay-lined surface impoundment (also 50* x 20'
x 4') for solidifying pickling liquor wastes. A storage pile holds
up to 8,000 cu. ft. of solidified pickling wastes; it is surrounded
by a clay-lined surface impoundment that collects drainage and run-off.
9-91
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SA.-1PLE CLOSURE COST ESTIMATING WORKSHEETS: MULTIPLE PROCESS FACILITY*
A. Characterizing the Waste
Worksheet A is used to describe each waste accepted at the facility.
For example, separate worksheets must be prepared for each of the following
wastes: oily wastes and pickling liquor wastes (the two types of wastes
processed at the storage facility) and the three end products of the treat-
ment actions performed (waste organic solvents, slop oil, and solidified
pickling liquor wastes). For each waste product specified, the following
information is required:
1. Describing the waste: Describe the origin and general nature
of the waste.
2. Chemical composition: Chemical composition should be expressed
in weight percents for the various Tajor components, and in parts per million
(ppm) for any trace components. This information may be readily available
to the operator from the bill of lading for each waste shiament.
3. Physical state: This describes whether the waste is a liquid,
solid, or mixture. This information is used in making estimates of solid
residues requiring disposal (Worksheet B).
£. Heat of comousticn of ;ne vaste: Represents cne neat content
(expressed in BTU/lb. or BTU/gal.) of the waste products. The information
is used to determine auxiliary fuel requirements if the waste is to be
disposed of through incineration.
5. Specific gravity of the waste: The specific gravity of the waste
at 60 F referenced to water at 60°F.
6. Closure inventory: The operator must identify the maximum quan-
tity of each waste that can be present at the facility in storage tanks,
drums, or surface impoundments, during any point in the facility's active
life. In the example, it is assumed that there are times in which the stor-
age capacity of this facility is completely utilized. This would therefore
represent the maximum inventory for developing the closure cost estimate.
In the sample case, the closure inventory would consist of 65,500 gallons
of waste solvents, 10,000 gallons of slop oil, 35,000 gallons of oily waste,
30,000 gallons of pickling liquor waste and 8,000 cu. ft. of solidified
pickling wastes.
9-92
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3. Treating Inventory
1. Waste inventory: As noted in the waste characterization section
of this example, the sample facility is assumed to have the following waste
products on-site at the time of disposal: 35,500 gallons of oily waste,
30,000 gallons of pickling liquor wastes, 65,500 gallons of recovered waste
solvent, 10,000 gallons of-recovered slop oils, and 8,000 cu. ft. of solidi-
fied pickling wastes.
2. Methods of treatment or removal: These materials will be removed
of in a variety of ways, as indicated below:
a. Solvents - it is assumed that the facility can find other manu-
facturing/commercial establishments that will use the waste solvents (which
have a BTU content of 135,000 BTU/gal.) as boiler fuel.
b. Slop Oils - pumped out of storage and hauled to an incinerator.
c. Oily Wastes - placed in surface impoundment for separation
into its component parts. Solvents and slop oils recovered from this pro-
cess are disposed of in the same manner as (a) and (b) above. Sludges left
in the basin are to be dredged, stabilized and hauled to a landfill.
d. Pickling Liquor Wastes - solidify with cement and transfer
the resulting solid vasie co a lanafiii.
e. Solidified Pickling Liquor Wastes - transfer to a land-
fill.
Since treatnsnt of inventory categories (c) and (d) will generate
additional waste products in categories (a), (b) and (e), these preliminary
processing phases will be discussed first.
Disposing of Oily Waste
3. Composition of oily wastes: It is assumed that the normal compo-
sition of the oily wastes is 80 percent solvent, 15 percent slop oil, and
5 percent sludge.
4. Amount of wastes produced after settling: Using this percentage
mix, settling out the inventory of oily wastes will produce 28,400 gallons
of solvent, 5,325 gallons of slop oil, and 1,775 gallons of sludge.
5. Sorbent requirements: It is assumed that the sludge will be mixed
withan equal volume of sorbent material, with a specific gravity of 1.8.
The specific gravity of the sludge is estimated at 1.2.
6. Cost of sorbent: It is assumed that sorbent material is available
on-site for no cost.
9-93
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7. Amount of residue generated: After stabilization, approximately
22 tons of residue will need to be landfilled.
8. Unit cost of disposing of residue: It is assumed that a land-
fill will charge $50/ton to dispose of the stabilized residues.
9. Total costs of disposing of residue (Line 7 x Line 8): Given
these assumptions, the total cost of disposing of facility sludge resi-
dues will be $1100.
10. Costs of hauling residue: It is assumed that the nearest land-
fill is 100 miles one-way from the site. Trucks with a 44,000-lb.
capacity can be rented at a cost of $60 per hour (including driver);
the average traveling speed of the truck is 40 mph. For one round trip,
the cost of residue hauling is $300.
11. Number of hauls required: With 22 tons of waste (line 7), only
one trip by a 44,000 Ib. capacity truck will be required.
12. Total cost of hauling residue (Line 10 x Line 11): Given
these assumptions, the total cost of- hauling residue is $300.
13. Cost of disposing of oily waste (Line 6 + Line 9 +-Line 12):
The total cost of disposing of oily waste is then the sum of sorbent
material costs, costs of disposal, and costs of hauling for a total of S1400,
Disposing of Pickling Liquor Waste
14. In order to solidify the pickling liquor wastes in the closure
inventory, the waste must be mixed with cement. It is estimated that
one sack (94 Ibs/sack) of cement will solidify 10 gallons of waste.
15. Amount of cement required: To dispose of on-site inventory,
3,000 sacks of cement (282,000 Ibs.) will be required.
16. Cost of cement: Cement is estimated to cost $2.50/sack.
17. Total cost of materials (Line 15 x Line 16): Given the above
assumptions, total material costs for solidifying the inventoried
pickling liquor waste are 37,500.
18~.~ Total amount of residues produced: Given a specific gravity
of pickling wastes of 1.05, and the proportions of cement co waste
assumed, the total solid residues produced by inventory disposed is
272.4 tons.
9-94
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Liquor = 30,000 gal x 1.05 S.G. x 8.34 (water weight) =
262,800 Ib.
Cement = 3,000 sacks x 94 Ibs/sack = 282,000 Ibs.
262,000 Ibs + 282,000 Ibs = 544,800 Ibs =
272.4 tons
19. Other on-site residues: Waste category (e) represents
previously solidified pickling wastes stored on-site. It is assumed
that there is 8,000 cu. ft. of this material currently in storage, and
that the material weighs approximately 135 Ib/cu. ft (similar to a
mortar-like cement). Therefore, the total weight of this residue
would be 1,080,000 Ibs. (540 tons).
20. Total amount of pickling residue (Line 18 + Line 19): Total
solid residues from treatment of the pickling wastes are 812.4 tons.
21. unit cost of disposing of residue: As in Line 8 above, it is
assumed that a landfill will charge $50/ton to dispose of such residues.
22. Total cost of disposing of residue (Line 20 x Line 21): Total
disposal costs are estimated to be 340,620.
23. Costs of hauling residues: The costs and method of hauling
residues are the same as Line 10 above.
24. Number of hauls required: Given truck capacity of 44,000 Ibs.
(22 tons), it will take 37 round trips to haul the solidified pickling
wastes.
25. Total cost of hauling residues: Given the above assumptions,
the total hauling costs will be $11,100.
26. Cost of disposing of pickling liquor waste (Line 17 -H Line 22
+ Line 25): The total cost of disposing of pickling liquor waste is
then the sum of costs of materials, residue disposal and hauling, for a
total of $59,220.
27. Amount of solvent on-site: Including the solvents recovered
during the settling of inventoried oily waste, the total inventory of
waste solvents at the sample facility are 60,000 gal. (storage tank) +
5,500 gal. (drums) + 28,400 gal. (surface impoundment) = 93,900 gal.
28. Method of disposal: It is assumed that the waste solvents can
be provided to manufacturers as a boiler fuel.
9-95
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29. Cost of disposal: It is assumed that the users of the solvents
will pay the costs of pumping and hauling the solvents to their facilities,
No additional credit is awarded to the owner/operator of the tank facility.
Treating Slop Oil
30. Amount of slop oil on-site: Including the slop oils recovered
during the settling of inventoried oily waste, the total inventory of
slop oils are 10,000 gal. (storage tank) + 5,325 gal. (surface impound-
ment) = 15,325 gal.
31. Method of treatment: It is assumed that the slop oils will he
trucked to an incinerator.
32. Coat of treatment: The estimated fee paid to the incinerator
for treating the wastes is $0.60/gallon.
33. Total costs of treatment (Line 30 x Line 32): Given the above
assumptions, it will cost $9,195 to treat the slop oil inventory.
34. Costs of hauling: It is assumed that the nearest incinerator
is 50 miles away, that the wastes will be transported in a 7,000-gallon
capacity truck, at an average speed of 40 mph. The hourly rental cost
for truck and driver is S60.
35. Number of hauls required: Given trailer capacity, it will
require three trips to haul the slop oils to the incinerators.
36. Total costs of hauling: Given the above assumptions, hauling
costs are estimated at $450.
37. Total costs of treating slop oil (Line 33 + Line 36): The total
costs of treating slop oil are then the sum of the costs of disposal and
hauling, for a total of $9,645.
38. Total costs of disposing of inventory (sum of Lines 6, 9, 12,
17, 22, 25, 29, 33, and 36): The total costs of the above activities
are estimated to be $70,265.
9-96
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C. Decontaminating che Facility
Tank Cleaning
1. Cleaning method: In this example, the storage tanks are
steam cleaned.
2. Volume: In the sample case, there are 60,000 gallons of
solvent storage capacity and 10,000 gallons of oil storage capacity
to be cleaned, for a total of 70,000 gallons.
3. Unit cleaning costs: For a 2,000 gallon-per-hour steam cleaning
unit (capable of washing a 16,000-gallon area of storage capacity/hour),
costs of equipment rental, labor, and operation are equal to $.02/gallon
of capacity cleaned.
4. Total costs of steam cleaning (Line 2 x Line 3): Total cleaning
costs for the storage tanks is $1400.
5. Type and quantity of residues generated: Steam cleaning
generates residues in the form of contaminated washwaters. The rate of
residue generation is 1 gallon of waste/8 gallons of tank volume. In
*
the example, total residues are 70,000 * 8, or 8750 gal.
6. Method of disposal: It is assumed that the residues are hauled
to a surface impoundment and evaporated.
7. Cost of-disposal: Impoundment disposal of washwaters is
estimated to cost $.OS/gallon.
8. Total cost of disposal (Line 5 x Line 7): Costs of disposing
of these cleaning residues will be $438.
9. Cost of hauling cleaning residues: For one round trip, the
.cost of hauling residues is $600. The cleaning residues will be hauled
in a 7,000-gallon tank truck, with an average truck speed of 40 mph.
The hourly rental cost for truck and driver is $60; the nearest
available surface impoundment is assumed to be 200 miles away.
10. Number of hauls required: Given the assumption on residue
generation and truck capacity, two trips will be required, at $600/trip.
11. Total costs of hauling: Total hauling costs are $1200.
12. Total costs: The sum of the costs of steam cleaning, disposal
and hauling yields a total of $3038.
9-97
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Decontaminating the Impoundment
13. Cleaning method for Impoundment 1: It is assumed that the
concrete-lined impoundment will be sandblasted.
14. Area of concrete impoundment to be cleaned: The area requiring
sandblasting, based on the sample facility description, is equal to the
base area (50* x 20', or 100 sq. ft.) plus the area of the site
walls (2* x 50' x 4' +2' x 20' x 4', or 560 sq. ft.), for a total of
1560 sq. ft.
15. Costs of sandblasting: A 6 cu. ft. capacity compressor will
be used in the sample estimate. The unit rents for a $100/week, and
costs $1.75/hour to operate; labor costs are estimated at $20/hour.
The unit can clean 40 sq. ft. of concrete/hour. Consequently, sand-
blasting costs are estimated at $.60/sq. ft.
16. Total costs of sandblasting (Line 14 x Line 15): Sandblasting
costs are estimated to be S936.
17. Type and quantity of residue generated: The residues will
consist of contaminated sands. It was assumed that 4000 Ibs. (2 tons)
of sand residue will be generated.
18. Unit costs of disposal: The sands will be landfilled at a
disposal cost of $507ton.
19. Total costs of disposal (Line 17 x Line 18): Total disposal
costs will be equal to S100.
20. Cleaning method for Impoundment 2: All contaminated clays
from the clay-lined impoundment will-be removed and hauled to a landfill.
21. Area of clay impoundment to be decontaminated: Since the dimen-
sions of this impoundment are the same as those of the concrete-lined
impoundment discussed above, the surface area to be contaminated is the
same as that estimated in Line 14 of this worksheet, or 1560 sq. ft.
22. Amount of clay removed: It is assumed that the clay in the
pickling liquor impoundment has been contaminated to a depth of one
foot. Therefore, 1560 cu. ft. of clay, or 57.8 cu. yds., must be
removed.
9-98
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23. Unit cost of removing clay: Clay removal will be performed
with a backhoe. Including costs of equipment rental and labor, the
costs of removing the clay is estimated to be $1.60/cu. yd.
24. Total costs of removing clay (Line 22 x Line 23): Given the
above assumptions, the costs of removing the soil are S92.
25. Disposing of contaminated clays: Clays will be hauled to a
landfill for disposal. The costs of disposal are estimated to be
$30/cu. yd.
26. Total costs of disposal (Line 22 x Line 25): The total costs
of disposal are S1734.
Removing Soil and >Iiscellaneous Activities
27. Removing contaminated soils: Because of spills and other
accidental releases, certain areas of the waste disposal facility, such
as diked-in areas around storage tanks will be contaminated. It is
assumed for the sample facility that 2.5 percent of the total site area
is contaminated.
Contaminated area = 2 acres x 4840 sq. yd./acre x .025
rate of contamination - 242 sq. yd.
28. Amount of soil removed: The depth of soil removal required
to remove all hazardous contaminants is assumed to be 1 foot. Thus,
the total amount of soil removed - 242 sq. yd. x .33 yd. = 80.7 cu. yds.
29. Unit cost of removing soil: As in Line 23, removing soil can
be accomplished at a cost of $1.60/cu. yd.
30. Total cost of removing soil (Line 28 x Line 29): Total cost
of removing soil is $129.
31. Disposing of contaminated soils: Contaminated soils are also
hauled to a landfill, where they may be disposed at a cost of S30/
cu. yd.
32. Total costs of disposal (Line 28 x Line 31): Given the above
assumptions, disposing of soils will cost $2421.
9-99
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33. Hauling costs for decontamination wastes: The wastes described
in Lines 17, 22, and 28 of this Worksheet will be hauled to the landfill
in a 44,000-lb. truck. The landfill is assumed to be 100 miles away; the
hourly cost of truck and driver is $60 and the average trip speed is
40 mph. Adequate dividers will be supplied so that mixed loads can be
carried.
34. Number of trips required: If it is assumed that a cu. yd. of
earth weighs approximately 2000 Ibs., the hauling of these waste residues
^will require seven trips.
35. Costs of hauling decontamination residues (Line 33 x Line 34):
At $300 per round trip, total hauling costs would be $2100.
36. Flush pumps and transfer lines: All pumps and piping used to
transfer hazardous waste are flushed to remove contaminants. This
process is assumed to cost $2000.
37. Decontaminate equipment: All materials handling equipment
used on-site must be decontaminated. This is assumed to cost $500.
38. Decontaminate containers: In the example, it is assumed that
all drums kept on-site will be crushed and buried in a landfill, at a
total cost of $1000.
39. Total costs of decontaminating facility (sum of Lines 4, 8,
11, 16, 19, 24, 26, 30, 32, 35-38): Total costs of decontaminating the
facility, based on the above assumptions, are estimated to be $14,070.
D. Professional Certification
1. Number of person-hours required for inspections: It is assumed
that 16 hours are required for periodically inspecting all aspects of
closing the tanks and impoundments.
2. Cost per person-hour: In this case, assume that a registered
independent professional engineer may be hired at a cost of $75 per hour.
3. Total costs of independent professional engineer's time (Line 1
x Line 2) : This yields a total cost of $1200 for the independent pro-
fessional engineer.
9-100
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4. Number of technical hours required for administrative duties:
Assume that 8 hours are required from the owner's or operator's staff for
administrative duties connected with employing an independent professional
engineer.
5. Person-hour costs for technical administrative duties: It is
assumed that the total fully-loaded costs for the owner's or operator's
staff are $30 per hour.
6. Total administrative costs for technical labor (Line 4 x Line 5):
Given the above assumptions, the total administrative costs for technical
labor are $240.
7. Number of clerical hours required for administrative duties:
Assume that 5 hours of clerical time are required for the necessary
typing and certifications.
8. Person-hour costs for clerical administrative duties: Fully-
loaded costs of clerical time are assumed to be $8 per hour.
9. Total administrative costs for clerical labor (Line 7 x Line 8):
Given the above assumptions, total clerical costs are $40.
10. Total administrative costs (Line 6 + Line 9): Summing technical
and clerical labor, the administrative costs are $280.
11. Total certification costs (Line 3 + Line 10): The total costs
for certification, including engineer's fees and administrative costs, are
$1480.
E- Total Costs Including Administration and Contingencies
Items 1 through 3 give the costs of all activities on each of the
preceding worksheets. Line 4 is the total of Lines 1 through 3, $85,815.
5. Contingencies: A general provision for contingencies of 15
percent of Line 4 has been included.
6. Administrative and supervisory cost: For administrative tasks,
including taxes, insurance, and administration and supervision not included
elsewhere, a total of 15 percent of total costs from Line 4 is used.
7. Total costs of closure (Line 4 + Line 5 + Line 6): The
total costs for closing the tanks, and impoundments are estimated for
the sample case to be $111,559.
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MULTIPLE PROCESS FACILITY
WORKSHEET A - CHARACTERIZING THE WASTE (#1)
Description of the waste
Organic solvent
Chemical composition
(Not given)
Physical state of the waste
Liquid
Heat of combustion of the waste
18,000 BTU/lb.(135,000 BTU/gal.)
Specific gravity of the waste
.9
Maximum inventory of the waste
60,000 gallons bulk storage
5,500 gallons in drums
ID numbers for areas holding these wastes
Tanks T-l to T-4
9-102
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MULTIPLE PROCESS FACILITY
WORKSHEET A - CHARACTERIZING THE WASTE (#2)
Description of Che waste
Slop oil
Chemical composition
(Not given)
Physical state of the waste
Liquid
Heat of combustion of the waste
16,000 BTU/lb (126,720 BTU/gal.)
Specific gravity of the waste
.95
Maximum inventory of the waste
10,000 gallons bulk storage
ID numbers for areas holding these wastes
Tank T-5
9-103
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MULTIPLE PROCESS FACILITY
WORKSHEET A - CHARACTERIZING THE WASTE (#3)
Description of the waste
Oily wastes
Chenical composition
(Not given)
Physical state of the waste
Mixture (95% liquids, 57, sludge)
Heat of combustion of the waste
(Not given)
Specific gravity of the waste
(Not given) ,
Maximum inventory of the waste
30,000 gallons in holding basin
5,500 gallons in drums
ID numbers for areas holding these wastes
Impoundment S-l
9-104
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MULTIPLE PROCESS FACILITY
WORKSHEET A - CHARACTERIZING THE WASTE (#4)
1. Description of the waste
Pickling liquor waste
2. Chemical composition
(Not given)
3. Physical state of the waste
Liquid
4. Heat of combustion of the waste
0
5. Specific gravity of the waste
1.05
6. Maximum inventory of the waste
30,000 gallons in holding basin
7. ID numbers for areas holding these wastes
Impoundment B-l
9-105
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MULTIPLE PROCESS FACILITY
WORKSHEET A - CHARACTERIZING THE WASTE (#5)
1. Description of the waste
Solidified pickling liquor wastes
2. Chemical composition
(Not given)
3. Physical state of the waste
Solid
4. Heat of combustion of the waste
(Not given)
5. Specific gravity of the waste
2.2
6. Maximum inventory of the waste
8,000 cu. ft. in storage pile
7. ID numbers for areas holding these wastes
None
9-106
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MULTIPLE PROCESS FACILITY
WORKSHEET 3 - TREATING THE INVENTORY
Waste inventory at time of closure
Waste solvents
Slop oil
Oily wastes
Pickling liquor wastes
Solidifed pickling wastes
Methods of treatment or removal
Waste solvents
Slop oil
Oily wastes
Pickling liquor wastes
Solidified pickling wastes
Disposing of Oily Waste
65,500 gal.
10,000 gal.
35,500 gal.
30,000 gal.
8,000 cu. ft.
Reuse as boiler fuel
Incinerate
Separate; recover solvents,
incinerate slop oils, landfill
sludges
Solidify, landfill
Landfill
7.
8.
9.
10.
11.
12.
13.
Composition of waste
80% solvent, 15% slop oil, 57, sludge
Amount of waste produced
28,400 gal. solvent, 5,325 gal. slop oil,
Amount of sorbent used in sludge treatment
Cost of sorbent used
a. Cost of materials
Amount of residue generated
Unit cost of disposing or removing residue
Total cost of disposing or removing residue
(Line 7 x Line 8)
Costs of hauling residue
Number of trips required
Total cost of hauling residue (Line 7 x Line 10)
Costs of disposing or removing oily waste
(Line 6 + Line 9 + Line 11)
1,775 gal. sludge
1:1 ratio with oils
0
0
22 tons
$50/ton
$1100
5300/trip
1
$300
S1400
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WORKSHEET B (continued)
Treating or Removing Pickling Liquor Waste
14. Amount of cement required for solidification
15. Total amount of cement required
Cost of cement
Cost of materials (Line 15 x Line 16)
Amount of residues produced by treating inventory
Amount of other residues already on-site
16
17
18
19
20
Total amount of pickling residues
(Line 18 + Line 19)
21. Unit cost of disposing or removing residue
22. Total cost of disposing or removing residue
(Line 20 x Line 21)
23. Costs of hauling residues
24. Number of trips required
25. Total costs of hauling (Line 23 x Line 24)
26. Costs of disposing or removing pickling liquor
waste (Line 17 + Line 22 + Line 25)
Removing Waste Solvent
27. Amount of waste solvent
a.
b.
28.
Amount of solvent in inventory
Amount of solvent obtained from oily
waste inventory treatment
Method of removal
29. Cost of removal
Treating Slop Oil
30. Amount of slop oil on-site
a. Amount in inventory
31.
32.
b. Amount generated from disposing or
treating oil waste inventory
Method of treatment
Unit cost of treatment
33. Total cost of treatment (Line 30 x Line 32)
34. Unit costs of hauling residues
1 sack/10 gal.
3000 sacks
$2.50/sack
$7,500
272.4 tons
540 tons
812.4 tons
$50/ton
$40,620
$300/trip
37
$11,100
$59,220
93,900 gal.
65,500 gal.
28,400 gal.
Recovery and reuse
as boiler fuel
0
15,325 gal.
10,000 gal.
5,325 gal.
Incinerate
$0.60/gal.
$9,195
$150/trip
9-108
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WORKSHEET B (continued)
35. Number of trips required - 3
36. Total costs of hauling (Line 34 x Line 35) $450
37. Costs of treating slop oil $9,645
38. Total costs of treating inventory $70,265
(Sum of Lines 6, 9, 12, 17, 22, 25, 29,
33 and 36)
9-109
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MULTIPLE PROCESS FACILITY
WORKSHEET C - DECONTAMINATING THE FACILITY
Tank Cleaning
1. Cleaning method used .
Capacity to be cleaned
Unit cleaning coses
Total costs of steam cleaning
(Line 2 x Line 3)
Quantity and type of residues generated
2.
3.
4.
5.
6. Method of disposal
7. Cost of disposal
8. Total cost of disposal
(Line 5 x Line 7)
9. Cost of hauling residues
10. Number of trips required
II. Total costs of hauling (Line 9 x Line 10)
12. Total costs of tank cleaning
Decontaminating the Impoundment
13,
14,
15. Unit costs of sandblasting
16. Total costs of sandblasting
(Line 14 x Line 15)
Quantity of .residues generated
Unit costs of disposing of residue
Cleaning method used - Surface Impound-
Area to be cleaned
17
18
19
20,
21.
22.
23.
24.
Total costs of disposing of residue
(Line 17 x Line 18)
Cleaning method used - Surface Impound-
ment 2
Area to be cleaned
Amount of clay removed
Unit cost of removing clay
Total cost of removing clay
(Line 22 x Line 23)
Steam cleaning
70,000 gallons
5.02/gallon
$1,400
8,750 gallons of contaminated
washwaters
Surface impoundment
$.05/gallon
$438
$600/trip
2
$1200
$3038
Sandblasting
1560 sq. ft.
$.60/sq. ft.
$936
2 tons of contaminated sand
$50/ton
S100
Clay removal and landfill
disposal
1560 sq. fc.
57.8 cu. yds.
31.60/cu. yd.
$92
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WORKSHEET C (continued)
25. Unit cost of disposing of residue (clay)
26. Total costs of disposal
(Line 22 x Line 25)
Soil Removal and Miscellaneous Site Cleanup
27. Soil area contaminated
28.
29.
30.
31.
32.
33.
35.
36.
37.
38.
39.
Amount of soil removed
Unit cost of removing soil
Total cost of removing soil
(Line 28 x Line 29)
Unit costs of contaminated soil
disposal
Total costs of disposing of soil
(Line 28 x Line 31)
Hauling costs for decontamination
wastes (including impoundment cleanup)
Number of trips required
Total costs of hauling
Costs of flushing pump and transfer
lines
Decontaminate equipment
Decontaminate containers
Total costs of decontaminating the
facility
530/cu. yd.
$1734
2.5% of site area
(242 sq. yd.)
80.7 cu. yd.
$1.60/cu. yd.
$129
$30/cu. yd.
$2421
S300/trip
7
S2100
$2000
$500
$1000
314,070
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MULTIPLE PROCESS FACILITY
WORKSHEET D - PROFESSIONAL CERTIFICATION
1. Number of person hours required for inspections
2. Cost per person-hour: engineer
3. Total costs of independent professional engineer's
time (Line 1 x Line 2)
4. Number of technical hours required for
administration
5. Cost per person-hour: technical
6. Total administrative costs for technical
labor (Line 4 x Line 5)
7. Number of clerical hours required for
administration
8. Costs per person-hour: clerical
9. Total administrative costs for clerical labor
(Line 7 x Line 8)
10. Total administrative costs (Line 6 - Line 9)
11. local certification costs >,Line 3 T Line 10)
16 hours
S75
$1200
8 hours
$30
$240
5 hours
$8
$40
9-112
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MULTIPLE PROCESS FACILITY
WORKSHEET E - TOTAL COSTS INCLUDING
ADMINISTRATION AND CONTINGENCIES
1. Costs of disposing of- inventory $ 70,265
(From Worksheet B)
2. Costs of decontaminating the facility (From $ 14,070
Worksheet C)
3. Costs of professional certification (From $ 1,480
Worksheet D)
4. Subtotal $ 85,815
5. Contingencies $ 12,872
6. Administration $ 12,872
7. Total closure costs $111,559
(Line 4 + Line 5 + Line 6)
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9.7 EXAMPLE - POST-CLOSURE COST ESTIMATES
A large flat landfill of 200 acres has been closed in accordance
with the EPA interim status regulations. This landfill consists
of rather closely spaced narrow trenches that are protected by clay
covers and cover vegetation. The facility soil is a soil which is
mostly clay in content. All of the facility is planted with grass to
resist erosion.
The post-closure operations at this facility have been planned to
carry out the requirements of the interim status regulations. The ac-
tivities planned are as follows:
periodically inspecting the facility
mowing
routine erosion repairs
replacing security fences (as needed)
fertilizing
leachate pumping and disposal
ground-water monitoring
monitoring well replacement (as needed)
repair of severe erosion caused by storms
post-closure administrative services
These activities are costed in the attached annotated worksheets. All of
these activities are costed based on the assumption that the facility is
completely closed and that no "free" assistance is available from an
active portion of the facility. This means that some of the supporting
facilities such as office space that are available during closure are
not automatically available during the post-closure period.
9-114
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SAMPLE POST-CLOSURE COST ESTIMATING WORKSHEETS
A. Periodically Inspecting the Facility
1. Number of technical management person-hours required for each
inspection: Each inspection at this closed hazardous waste facility
will be conducted by two people in a rented vehicle. We are of the
opinion that two people are needed to conduct the inspection of the
large closed waste disposal area (200 acres) and that an extra measure
of safety is afforded by having two inspectors. Each inspection takes
a full day of work by two technically trained managers.
2. Annual number of routine inspections: Six routine inspections
will be conducted during each year of the post-closure period. These
will be conducted on a bimonthly basis.
3. Person-hour costs for technical management labor: The fully-
loaded labor rate for this technically trained labor is $30 per hour.
4. Technical labor costs for annual routine inspections (Line 1 x
Line 2 x Line 3): The technical labor cost for these annual routine
inspections is the product of the person-hours required for each inspec-
tion, the number of inspections planned, ar.d che technical labor rate.
5. Annual numoer of engineer-supported inspections: In addition
to the routine inspections described above, two annual engineer-supported
inspections are planned. These inspections use a team of professional
engineers and one of our technical managers. The engineer is a state-
certified professional engineer from an independent firm that is contracted
to supply professional services to the-hazardous waste disposal facility.
6. Number of independent state-certified engineering hours for each
engineer-supported inspection: For each inspection, eight hours of the
engineer's time is required.
7. Number of technical management hours for each engineer-supported
inspection: For each inspection, eight hours of technical labor is
required. This requirement is in addition to the engineering labor that
is required.
8. Person-hour cost for a professional engineer: The quoted cost
of engineering services is $75 per hour. These services will be obtained
from an independent engineering firm.
9-115
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9. Engineering labor coses for che engineer-supported inspections
(Line 5 x Line 6 x Line 8): The cost of the engineering labor is the
product of the number of engineer-supported inspections, the number of
engineering hours needed for each inspection, and the person-hour cost
of engineering services.
10. Technical labor costs for the engineer-supported inspections
(Line 3 x Line 5 x Line 7) : The technical managerial labor costs for
the engineer-supported inspections is the product of the labor rate for
technical labor, the number of inspections required, and the technical
labor hours required for each inspection.
11. Labor costs for the engineer-supported inspections (Line 9 +
Line 10) : The total labor costs for the engineer-supported inspections
is the sum of the engineering labor and technical labor costs.
12. Cost of renting the truck for each inspection: A rented pick-
up truck is used for transporting the inspectors throughout the hazardous
waste disposal facility. The quoted rate for the truck is $25 per day and
$.14 per mile. In addition, the renter must supply gasoline. The mileage
for each inspection is 50 miles including the trips between the facility
and the rental agency. This results in a total cost for the truck of
$36 per day ($25 rental, $7 mileage, and $4 gasoline). The gasoline '
value is estimated based on a truck mileage of 15 mpg and a gasoline
price of SI.20 per gallon.
13. Annual cost of renting the truck for inspections (Line 2 - Line
5 x Line 12) : The total annual truck rental cost is the product of the
total number of inspections needed (both routine and engineer-supported)
and the daily truck rental cost.
14. Total annual inspection cost (Line 4 -! Line 11 + Line 13): The
total cost of conducting this post-closure inspection program is the sum
of the annual total labor costs for the routine inspections, the annual
labor costs for the engineer-supported inspections, and the annual rental
costs for the truck.
9-116
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B- Routine Monicoring and Maintenance Activities
Mowing Operations
1. Facility acreage: The waste disposal area of this hazardous
waste facility is 200 acres. This area includes the cover of the waste
disposal trenches and land close to the trenches.
2. Mowing labor: The waste disposal area is to be mowed periodically
to promote the growth of cover vegetation and to inhibit the growth of
large deep-rooted vegetation such as young trees. This mowing is to be
carried out on a contract basis by a mowing service. The quoted labor
rate for this service is $14.28 per acre mowed.
3. Mowing equipment: The quoted rate for the mowing equipment is
$5.37 per acre mowed. This rate includes fuel and all equipment costs.
4. Unit mowing cost (Line 2 + Line 3): Adding the labor rate and
the equipment rate yields the total contracted mowing rate (unit cost) for
each acre mowed. Cheaper agricultural methods cannot be used because of
the impact of the heavier equipment on.the cover.
5. Annual frequency of mowing: Mowing of the waste disposal area
is required once a year during the post-closure period. This frequency
of mowing will encourage the growth of cover vegetation and will suppress
the growth of trees and other deep-rooted vegetation.
6. Annual cost of mowing (Line 1 x Line 4 x Line 5): The annual
cost of mowing is the product of the facility acreage, the unit mowing
cost, and the annual frequency of mowing.
Routine Erosion Damage Repair
7. Annual routine erosion rate: The annual routine loss of soil
from the facility is computed using the Universal Soil Loss Equation
(USLE).
A = RKLSCP
A = Average soil loss, tons/acre
R = Rainfall and run-off erosivity index
K = Soil erodibility factor
»
L = Slope - length factor
S = Slope - steepness factor
C = Cover/management factor (type of vegetative cover)
9-117
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P = Practice factor (terracing, contour plowing)
This equation computed for the sample facility's location yields an
annual soil loss of 0.12 tons per acre. With a soil density of approxi-
mately 100 Ibs. per cu. ft., 0.089 cu. yds. are lost from each acre. In
our subsequent computations, we make the very conservative assumption
that all of the lost soil will have to be replaced and reseeded.
8. Total annual routine erosive loss (Line 1 x Line 7): The total
annual routine soil loss is the product of the acreage times the annual
soil loss per acre.
9. Unit cost for land excavation of soil: Replacement soil will be
obtained on-site at the facility. Since the amount of soil required is
very small compared to the daily capacity of earth-moving machinery,
hand labor will be used to excavate the soil. The rate stated here is
a fully-loaded rate for union labor working for an independent contractor.
This unit cost is based on contractor quotes.
10. Unit cost for on-site transportation of soil: The excavated
soil is transported by truck on-site to the location where the erosion
repair is to be made. This service will be provided by an independent
contractor.
11. Unit cost for compacting the soil by hand: The unit cost of
hand compacting the new soil as a repair for erosion damage is estimated
to be the same as for hand excavation of the soil. This service will
be provided by an independent contractor.
12. Unit cost of seeding: The cost of seeding is a function of
the surface area of the new bare soil. In our estimates, we assume
that a small gully (or gullies) have formed. The ratio of surface area
to soil volume is small. This new soil is seeded with the same type of
grass as is used for the original cover vegetation.
13. Aggregate unit cost of repairing routine soil erosion damage
(Line 9 + Line 10 + Line 11 + Line 12): The aggregate unit cost of
repairing the routine soil erosion is the sum of the excavation unit
cose, the on-site trucking, the hand compacting of the soil, and hand
seeding of the bare soil.
14. Total annual cost for repairing erosive damage of a routine
nature (Line 8 x Line 13) : The total annual cost of such routine erosive
9-118
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repairs under average rainfall conditions is the product of the amount
of soil lost and the unit aggregate cost for erosion damage repairs.
15. Adjustment factor to account for unusually wet seasons: The
above cost (Line 14) is computed for average rainfall conditions at the
facility location. A safety factor of 2 is applied which is the equiva-
lent of increasing the rainfall and runoff erosivity index (within the
Universal Soil Loss Equation) from 150 to 300. This changes the facility's
rainfall from its actual mid-Atlantic level to the high southern levels.
This conservative assumption is required to allow for the annual variation
in routine rainfall-caused erosion.
16. Adjusted annual cost for repairing routine erosion damage (Line
14 x Line 15): The adjusted annual cost for erosion repair of a routine
nature is the product of the average annual cost and the adjustment fac-
tor.
Replacing the Fence
17. Frequency of replacing the fence: Security at the facility is
provided by a 6-ft. high chain link fence that has been established along
*
the encore perimeter of the facility (11,808 ft. in length). This fence
is made of galvanized #9 wire. Operating experience at this hazardous
waste facility indicates that the fence must be replaced every 15 years.
Thus, during the anticipated 30-year duration of-the closure period, the
fence will have to be replaced once.
18. Facility perimeter: The length of the security fence is the
length of che facility oerimeter (11,808 ft.).
19. Unit cost of replacing the fence: Quotes were obtained from
fencing suppliers for a new fence of equal specifications. The value
given here is a unit cost per linear foot for an installed fence.
20. Total cost of fence replacement (Line 18 x Line 19): The cost
of replacing the perimeter security fence is the product of the perimeter
footage and the unit cost of the installed fencing.
21. Pro-rated annual cost of fence replacement: The total cost of
replacing the security fence is pro-rated to each year by dividing the
total cost (Line 20) by the number of years in the post-closure period
(30 years).
9-119
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Fertilizing
22. Unit cost of fertilizing: The hazardous waste disposal facility
has relatively poor soil resulting in the experienced necessity of annual
fertilizer applications until che vegetation has become established, & periodic
applications thereafter. Type 10/6/4 fertilizer costing $0.12 per Ib. (in
50-lb. bags) is applied at'a rate of 500 Ibs. per acre. This corresponds
to a nitrogen application rate of 50 Ibs. per acre. The unit cost of ferti-
lization is the sume of the labor, materials and equipment costs.
Labor $69.10/acre
Materials $60.00/acre
Equipment $ 5 .00/acre
Previous experience at this facility has shown that this application
rate for fertilizer is satisfactory to maintain the vegetation.
23. Number of applications of fertilizer for the first 3 years: One
application of fertilizer is needed each year for a total of 3 applications.
24. Number of applications of fertilizer for remaining years of post-
closure (Years 4 through 30): One application of fertilizer is needed every
5 years, or a total of 5 applications for the remainder of post-closure.
25. Total costs of fertilizing for the first 3 years of post-
closure (Line 1 x Line 22 x Line 23): The cost of fertilizing for the
first 3 years is the product of the acreage fertilized, the unit cost of
fertilization and the frequency of application during the first 3 years.
The costs of fertilizing for the first 3 years are then $80,460.
26. Total costs of fertilization for years 4 through 30 of post-
closure (Line 1 x Line 22 x Line 24): The cost of fertilizing is the
product of the acreage fertilized, the unit cost of fertilizing, and
the frequency of application during the years 4 through 30. The costs
for fertilizing for the remainder of post-closure is then 3134,100.
27. Total costs of fertilizing during post-closure (Line 25 + Line
26): The total fertilization costs are the sum of the costs for ferti-
lizing during the first 3 years and the 5 applications required during
the remainder of post-closure. The total costs for fertilizing for
the entire 30-year period are then $214,560.
28. Total annual costs of fertilizing (Line 27 4- 30): The
total costs for fertilizing for the 30-year period is divided by the
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30
years of the post-closure period to yield an annual cost of $7152.
Ground-Water Monitoring Well Replacement^
29. Unit cost for well replacement: The lowest observed depth of
the water table has been closer to the surface than 50 ft. throughout the
active operation of the facility. A replacement well to a depth of
aprpoximately 50 ft. will cost $425 when installed by an independent
contractor ($8.50 per vertical linear ft.). This quoted price includes
a suitable casing.
30. Number of wells needing replacement: The monitoring wells have
a relatively long useful lifetime as do residential wells. It is antici-
pated that two wells will have to be replaced during the post-closure
period.
31. Total cost of monitoring well replacement (Line 29 x Line 30):
The total post-closure period cost of well replacement is the unit cost
of each well multiplied by the number of wells required in the post-
closure period.
Leachate Pumping and Disposal
32. Frequency of removing the leachate: Leachate is removed perio-
dically from the hazardous waste facility risers by means of a vacuum truck.
Every month, the truck circulates to each riser pumping out the collected
leachate. This service is performed by an independent contractor.
33. Average total monthly leachate withdrawal: Since the facility's
cover system is quite effective in reducing infiltration, only 2000 gals.
of leachate (average value) will have to be removed each month. This
leachate is removed to an off-site disposal area.
34. Unit cost of removing the leachate to an active off-site disposal
area: The unit cost of removing the leachate includes driving the vacuum
truck to each riser at the facility and removing the leachate and deliver-
ing the truckload of leachate to the off-site disposal area. A relatively
high per-gallon removal cost is quoted because of the necessity of collec-
ting a small amount of leachate from each of the widely dispersed risers
throughout the large facility. This cost includes transportation to the
TSDF.
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35. Total annual cost of removing the leachate (Line 32 x Line 33 x
Line 34 x 12): The annual leachace removal cost is the product of the
monthly leachate volume removed, the number of months in a year, and the
unit cost per gallon removed.
36. Unit cost for removing leachates to an off-site TSDF: The unit
cost for off-site disposal of the leachate material is $.05/gal. This
material is disposed of in a surface impoundment.
37. Annual costs for off-site disposal (Line 32 x Line 33 x Line 36
x 12) : The cost of disposing of the material in the off-site surface
impoundment is the product of the amount of leachate disposed and the
unit cost for the disposal.
38. Total annual cost for removing and disposing of leachates (Line
35 + Line 37) : The total cost for leachate removal and disposal is the
sum of the removal' cost and the disposal cost.
Ground-Water Monitoring
39. Number of wells monitored: This hazardous waste facility has
12 ground^water monitoring wells. One well is upgradient and 11 wells
are downgradient from the disposal area.
40. Number of samples taken per well (annual): Two "cycles" of
ground-water sampling will be conducted annually. One ground-water
quality analysis and two ground-water contamination analyses are to be
carried out. One sample may be used for both the ground-water quality
and ground-water contamination analyses. Therefore, two samples are
taken from each well annually.
41. Total number of samples (annual) (Line 39 x Line 40): The total
number of ground-water samples taken annually is the product of the
number of monitoring wells and the number of samples taken annually from
each well.
42. Number of hours for collecting the sample (per sample): Each
sample requires two hours of collection time. The well must be pumped
dry and allowed to refill. Then a sample is taken. The facility ex-
perience is that approximately two hours are required for each well
sampling (including some time for moving about the fields).
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43. Total number of hours for collecting the sample (Line 41 x
Line 42): Annually, 24 samples will have to be collected, requiring
48 hours of labor.
44. Total number of hours for preparing and delivering the sample:
The total number of hours required for packaging and delivering the
samples is six hours per year.
45. Total sample handling hours (Line 43 + Line 44): The annual
total time for collecting and delivering the ground-water samples is
54 hours.
46. Person-hour costs for handling ground-water samples: The
person-hour costs for handling the samples is based on the facility ex-
perience of $15 per hour fully-loaded.
47. Total sample handling costs (Line 45 x Line 46): The total
labor cost for handling the samples is the product of the hours required
and the unit labor costs.
48. Unit cost of ground-water quality analysis: The unit cost
of an analysis for the following parameters is $77 per analysis:
Chloride $ 6/sample
Iron $12/sample
Manganese $12/sample
Phenols $25/sample
Sodium $12/sample
Sulfate $10/sample
49. Unit cost of ground-water contamination analysis: The unit
cost of an analysis for the following parameters is $108 per analysis:
pH $ 4/sample
Specific Conductance $ 4/sample
Total Organic Carbon $25/sample
Total Organic Halogen $75/sample
50. Total cost of ground-water quality analysis (annual) (Line 39
x Line 48): The annual cost for analysis of water quality is the product
of the number of wells and the unit cost of the analysis.
51. Total cost for ground-water contamination analysis (annual)
(Line 41 x Line 49): The annual cost for analysis for ground-water
contamination is the product of the number of sample sets to be analyzed
and the unit cost of the analysis.
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52. Total annual ground-water nonitoring coses (Line 49 + Line 50 +
Line 51) : The total annual cost for ground-water analysis is the sum of
the ground-water quality analysis cost, Che ground-water contamination
analysis cost, and the sample handling cost.
Routine Maintenance Summation
53-60. The annual cost for each of the routine maintenance and
monitoring operations are added together to yield the total cost (annual).
This cost does not include administrative costs which are computed on a
separate worksheet (Line 53 + Line 54 + Line 55 + Line 56 + Line 57 +
Line 58 + Line 59).
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c- Erosion Damage Contingency Scenario
1. Percentage of vegetation removed: Some unplanned events that
will create additional demands for care will occur during the duration of
the post-closure period. This worksheet computes the additional cost
that would result from such an unplanned event that removes 30% of the
vegetative cover from the hazardous waste facility. After the vegetation
is removed, the soil remains bare for one month exposed to normal rainfall.
Resulting erosive damage is repaired and the bare acreage is revegetated.
The one month lapse between the damaging event and the revegetation allows
for delays in the discovery of the damage and the time required for the
revegetation steps.
2. Facility acreage: The entire facility is impacted by the event.
3. Acreage reduced to bare soil (Line 1 x Line 2): The acreage
stripped of vegetation is the product of the percentage of vegetation
removed and the total acreage of the facility.
4. Annual per acre soil loss rate (without vegetative cover): The
annual soil loss for each acre of bare soil is computed using the Univer-
sal Soil Loss Equation (USLE).
A = RKSLCP
A = Average soil loss, tons/acre
R = Rainfall and run-off erosivity index
K = Soil erodibility factor
L = Slope - length factor
S => Slope - steepness factor
C = Cover/management factor (type of vegetative cover)
P = Practice factor (terracing, contour plowing)
This equation is for erosion resulting from rainfall subsequent to the
event that removed the vegetation.
5. Monthly bare ground soil loss rate: The annual loss rate
computed in Line A is converted to a one month loss rate. This conver-
sion is accomplished by dividing the annual loss rate by 12.
6. Amount of soil lost before repairs are instituted: The amount
of soil lost from the bared ground is the product of the monthly loss
rate per acre and the acreage of the facility that is exposed. This
product is then multiplied by two to allow for soil lost during the
9-125
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removal of the vegetation. The ground is assumed to be bare for about
one month before the repairs and replanting are completed. The conversion
to volume of soil lost is carried out assuming a soil density of 100 Ibs.
per cu. ft.
7. Unit cost for excavating and loading soil: The unit cost for
excavating and loading replacement soil is computed using a 2 cu. yd.
front end loader. This operation will be performed under contract.
8. On-site haul of excavated soil to the area needing repair: The
excavated soil is transported on-site over a 2000 ft. distance by trucks
operating under contract.
9. Filling and compacting eroded areas of the facility: The replace-
ment soil is filled and compacted into the eroded areas using a dozer
operating under contract.
10. Total unit cost for replacing soil (Line 7 + Line 8 + Line 9):
The total unit cost of replacing soil is the sum of the excavation-
loading, hauling and filling unit costs. These unit costs were obtained
from estimates made by a local contractor.
11. Cost of replacing the lost soil (Line 6 x Line 10): The total
cost for replacing the lost soil is the product of the amount of soil
lost times the unit cost for soil replacement.
12. Unit cost for seeding the bare soil: The unit cost for seeding
the bare acreage is computed from the sum of the labor, materials and
equipment costs.
Labor $69.10/acre
Materials $13.90/acre
Equipment $ 5.00/acre
The grass .planted is Kentucky bluegrass available from a local supplier
at $0.32 per Ib. in 50-lb. bags. The application rate for this seed is
1 Ib. per 1000 sq. ft. (or 43.56 Ibs. per acre). This is less than one-
third of the seed application rate used for home lawns. Experience has
shown this seeding rate to be satisfactory.
13. Unit cost for fertilizing: Since the soil at this hazardous
waste facility is quite poor, fertilization is necessary. Type 10/6/4
fertilizer costing $0.12 per Ib. (in 50-lb. bags) is applied at a rate
of 500 Ibs. per acre. This corresponds to a nitrogen application rate
9-126
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of 50-lbs. per acre. The unit cost of fertilization is the sum of the
labor, materials and equipment costs.
Labor $69.10/acre .
Materials S60.00/acre
Equipment $ 5.00/acre
Previous experience at this facility has shown that this application
rate for fertilizer is satisfactory.
14. Unit cost for mulching with.straw: Since the soil is bare, pro-
tection from erosion must be provided while the grass starts to grow.
This is achieved by using straw mulch at an application rate of 1 ton
per acre. The unit cost of mulching is the sum of the labor, materials
and equipment costs.
Labor $34.50/acre
Materials $85.00/acre
Equipment $ 5.00/acre
15. Total unit replanting cost (Line 12 + Line 13 + Line 14): The
total unit replanting cost is the sum of the seeding, fertilizing, and
mulching costs. Lime is not applied at this facility because it is not
recommended by the Agricultural Extension Service (USDA).
16. Total replanting costs (Line 3 x Line 15): The total replanting
cost for the facility is the product of the acreage to be replanted and
the unit cost of replanting each acre.
17. Number of erosive incidents expected in the post-closure period:
It is anticipated that such highly erosive incidents will occur twice
during the post-closure period. These- will be either major storms or
floods.
18. Total cost for repairing damage from erosive incidents (Line 11
+ Line 16 x Line 17): The total post-closure cost for repairing the damage
from such incidents is the sum of the repair costs for each incident
(soil and vegetation) multiplied by the number of incidents expected in
the 30-year post-closure period.
19. Total annual cost for repairs required by erosive incidents
(Line 18 r 30 years): The total cost of repairing the damage from the
two incidents is divided by the 30 years of the post-closure period to
yield the annual cost for contingency repairs.
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D. Initial Replanting Co Establish Vegecation
1. Percentage failure of vegetation per year: It is estimated
that in this climate, 10 percent of the vegetation will fail per year due
to inadequate initial establishment.
2. Number of years required for full vegetation: It is estimated
that three years will be necessary for full establishment of vegetation
to the point replanting will no longer be necessary.
3. Facility acreage: Facility acreage is 200 acres.
4. Total acres to be replanted due to initial failure of vegetation
(Line 1 x Line 2 x Line 3) : Total acres to be replanted are then 60
acres.
5. Annual per acre soil loss: The annual soil loss for each acre
of bare soil is computed using the Universal Soil Loss Equation (USLE).
A - RKLSCP
A => Average soil loss, tons/acre
R = Rainfall and run-off erosivity index
K = Soil erodibility factor
L = Slope - length factor
S = Slope - steepness factor
C = Cover/management factor (type of vegetative cover)
P = Practice factor (terracing, contour plowing)
This equation is for erosion resulting from rainfall subsequent to the
event that removed the vegetation.
6. Monthly bare ground soil loss rate: The annual loss rate com-
puted in Step 4 is converted to a one-month loss rate. This conversion
is accomplished by dividing the annual loss rate by 12.
7. Amount of soil lost before repairs are instituted (Line 4 x
Line 6) : The amount of soil lost from the bared ground is the product
of the monthly loss rate per acre and the acreage of the facility that
is exposed. This product is then multiplied by two to allow for soil
lost during the removal of the vegetation. The ground is assumed to be
bare for about one month before the repairs and replanting are completed.
The conversion to volume of soil lost is carried out assuming a soil
density of 100 Ibs. per cu. ft.
9-128
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8. Unit cost for excavating and loading soil: The unit cost for
excavating and loading replacement soil is computed using a 2 cu. yd.
front end loader. This operation will be performed under contract.
9. On-site Haul of excavated soil to area needing repair: The
excavated soil is transported on-site over a 2000 ft. distance by trucks
operating under contract.
10. Filling and compacting eroded areas of the facility: The replace-
ment soil is filled and compacted into the eroded areas using a dozer
operating under contract.
11. Total unit cost for soil replacement (Line 8 + Line 9 + Line 10):
The total unit cost of soil replacement is the sum of the excavation-
loading, hauling and filling unit costs. These unit costs were obtained
from estimates made by a local contractor.
12. Cost of soil replacement (Line 7 x Line 11): The total cost for
replacing the lost soil is the product of the amount of soil lost times
the unit cost for soil replacement.
13. Unit cost for seeding bare soil: The unit cost for seeding the
bare acreage is computed from the sum of the labor, materials and equip-
ment costs.
Labor $69.10/acre
Materials $13.90/acre
Equipment $ 5.00/acre
The grass planted is Kentucky bluegrass available from a local supplier
at $0.32 per Ib. in 50-lb. bags. The application rate for this seed is
1 Ib. per 1000 sq. ft. (or about 40 Ibs. per acre). This is less than one-
third of the seed application rate used for home lawns. Experience has
shown this seeding rate to be satisfactory.
14. Unit cost for fertilizing: Since the soil at this hazardous
waste facility is quite poor, fertilization is necessary. Type 10/6/4
fertilizer costing $0.12 per Ib. (in 50-lb. bags) is applied at a rate
of 500 Ibs. per acre. This corresponds to a nitrogen application rate
of 50 Ibs. per acre. The unit cost of fertilizing is the sum of the
labor, materials and equipment costs.
Labor $69.10/acre
Materials $60.00/acre
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Equipment $ 5.00/acre
Previous experience at this facility has shown that this application
rate for fertilizer is satisfactory.
15. Unit cost for mulching with straw: Since the soil is bare,
protection from erosion must be provided while the grass starts to grow.
This is achieved by using straw mulch at an application rate of 1 ton
per acre. The unit cost of mulching is the sum of the labor, materials
and equipment cos ts.
Labor $34.50/acre
Materials $85.00/acre
Equipment $ 5.00/acre
16. Total unit replanting cost (Line 13 + Line 14 + Line 15) : The
total unit replanting cost is the sum of the seeding, fertilizing, and
mulching costs. Lime is not applied at this facility because it is not
recommended by the Agricultural Extension Service (USDA).
17. Total replanting costs (Line 4 x Line 16): The total replanting
costs for the entire 30-year period are then $20,796.
18. Total costs for initial replanting to establish vegetation (Line
12 + Line 17) : The total costs for the initial replanting to establish
vegetation are then $20,847.
19. Total annual cost (Line 18 4- 30): The total cost for the initial
replanting to establish vegetation is divided by the 30 years of the post-
closure period to yield the total annual cost, for a total of $695.
E. Administrative Services
1. Number of technical hours required for administrative duties
(annual) : Since the facility is closed, all of the required administration
is an extra cost that must be carefully accounted for. This facility esti-
mates that an average of three weeks of labor by a manager is required to
administer the complete set of specified post-closure activities. This
average administrative requirement includes the administration of the
occasional contingent events described in Worksheet C.
2. Person-hour cost for technical administrative duties: The labor
rate for facility technical labor is $30 per hour fully-loaded.
3. Total administrative costs for technical labor (Line 1 x Line 2):
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The total cost for administrative technical labor is the product of the
hours required and the labor rate.
4. Number of clerical hours required for administrative duties:
Three weeks of clerical work is required to support the technical adminis-
trator.
5. Person-hour costs.for clerical administrative duties: The fully-
loaded labor rate for clerical labor at the facility is $8 per hour.
6. Total administrative costs for clerical labor (Line 4 x Line 5):
The total cost for administrative clerical labor is the product of the
hours required and the labor rate.
7. Office or trailer rental: The total annual administrative cose
also includes the rental of office space during the busier times of each
post-closure year. This includes typewriter, telephone and supplies.
8. Total annual administrative costs for post-closure activities
(Line 3 + Line 6 + Line 7): The total cost of administration is the
sum of the costs of technical labor, clerical labor, and office rental.
F- Total Costs Including Administration and Contingencies
Items 1 through 5 summarize the total annual costs of the post-
closure functions taken from the cost worksheets. The erosion contingency
repair cost (Line 3) used is the annual cost of the two major erosion
events expected in the post-closure period (30 years).
6. Total of Lines 1 through 5: The total costs of the activities
listed in Lines 1 through 5 are $40,206.
7. Contingencies: Fifteen percent of the sum of the above costs is
taken as an allowance for contingencies. This contingency allowance is
made in addition to the costs expected from the two major post-closure
erosion events.
8. Administration: An additional 10 percent of Line 6 is included
for fees, insurance and related needs.
9. Total annual costs of post-closure (Line 6 + Line 7 + Line 8):
The total sum of the annual post-closure costs is $50,258.
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POST-CLOSURE
WORKSHEET A - PERIODIC FACILITY INSPECTION
1. Number of technical management person-hours 16 hours
required for each routine inspection of the
closed facility
2. Annual number of routine inspections 6
3. Person-hour costs for technical management labor $30
4. Technical labor costs for annual routine inspections $2880
(Line 1 x Line 2 x Line 3)
5. Annual number of engineer-supported inspections 2
6. Number of independent state-certified engineering 8 hours
hours for each engineer-supported inspection
7. Number of technical management hours for each 8 hours
engineer-supported inspection
8. Person-hour cost for a professional engineer $75
9. Engineering labor costs for the engineer-supported $1200
inspections (Line 5 x Line 6 x Line 8)
10. Technical labor costs for the engineer-supported $480
inspections (Line 3 x Line 5 x Line 7)
11. Labor costs for the engineer-supported inspections $1680
(Line 9 + Line 10)
12. Truck rental cost for each inspection $36
13. Annual truck rental cost for inspections $288
(Line 2 + Line 5 x Line 12)
14. Total annual inspection cost (Line 4 + Line 11 + $4848
Line 13)
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POST-CLOSURE
WORKSHEET B - ROUTINE MONITORING AND MAINTENANCE ACTIVITIES
Mowing Operations
1. Facility acreage
Mowing labor (per acre)
Mowing equipment (per acre)
Unit mowing cost (Line 2 + Line 3)
Annual frequency of mowing
Annual cost of mowing (Line 1 x Line 4 x Line 5)
Routine Erosion Damage Repair
7. Annual routine erosion rate
8.
9.
10.
11.
Total annual routine erosive loss (Line 1 x Line 7)
Unit cost for hand excavation of soil
Unit cost for transporting of soil on-site
Unit cost for hand compacting soil (repairing
erosive damage)
Unit cost of seeding
Aggregate unit cost of repairing routine soil
erosion damage (Line 9 + Line 10 + Line 11 -f- Line 12)
Total annual cost for repairing erosive damage of
a routine nature (Line 8 x Line 13)
Adjustment factor to account for unusually wet seasons
Annual cost for repairing routine erosive damage
(Line 14 x Line 15)
Fence Replacement
17. Frequency of replacing fence
12.
13.
14.
15.
16.
19.
Facility perimeter
Unit cost of replacing fence
200 acres
$14.28
$5.37
$19.65
Once a year
$3930
0.12 tons
per acre
(.089 cu.
yds./acre)
17.8 cu. yds.
$21.21/cu. yd.
$2.13/cu. yd.
$21.21/cu. yd.
$l/cu. yd.
345.55/cu. yd.
$810.79
S1621.58
Once during
post-closure
period
11,808 ft.
$13.06/linear
ft. (installed)
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WORKSHEET B (continued)
20. Total cost of fence replacement (Line 18 x Line 19)
21. Pro-rated annual cost of fence replacement
Fertilizing
22. Unit cost for fertilizing
23. Number of fertilizer applications for first 3 years
24. Number of fertilizer applications during remainder
of post-closure (Years 4-30)
25. Total costs of fertilizing for first 3 years
(Line 1 x Line 22 x Line 23)
26. Total costs of fertilizing for post-closure
years 4-30 (Line 1 x Line 22 x Line 24)
27. Total fertilizing costs (Line 25 + Line 26)
28. Annual cost of facility fertilization (Line 27 T 30)
Ground-water Monitoring Well Replacement
29. Unit cost for replacing well
30. Number of wells needing replacement during the
pose-closure period
31. Total cost of monitoring well replacement during
the entire post-closure period (Line 29 x Line 30)
Leachate Pumping and Disposal
32. Frequency of removing the leachates
33. Average monthly total leachate withdrawal
34. Unit cost of removing the leachate to an active
off-site TSDF
35. Total annual cost of removing leachate
(Line 32 x Line 33 x Line 34 x 12)
36. Unit cost for disposing of leachate off-site (at
a surface impoundment)
37. Annual costs for disposing off-site (Line 32 x
Line 33 x Line 36 x 12)
38. Total annual costs for removing and disposing of
leachates (Line 35 4- Line 37)
$154,212.48
S 5,140.41
$134.10/acre
3
5
$ 80,460
$134,100
$214,560
$ 7,152
$425/well
2
$850
Once/month
2000 gals.
50.18/gal.
'$4320
$.05/gal.
$1200
$5520
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WORKSHEET B (continued)
42.
43.
44.
45.
46.
47.
48.
49.
Ground-Water Monitoring
39. Number of wells monitored
40. Number of samples taken per well (annual)
41. Total number of samples per well (annual)
(Line 39 x Line 40)
Number of hours for collecting the samples (per
sample)
Total number of hours for collecting samples
(Line 41 x Line 42)
Total number of hours for preparing and delivering
samples
Total sample handling hours (Line 43 + Line 44)
Person-hour costs for handling ground-water samples
Total sample handling co.sts (Line 45 x Line 46)
Unit cost of ground-water quality analysis
Unit cost of ground-water contamination analysis
50. Total cost for ground-water quality analysis
(annual) (Line 39 x Line 48)
51. Total cost for ground-water contamination analysis
(annual) (Line 41 x Line 48)
52. Total annual ground-water monitoring cost (Line 49
+ Line 50 + Line 51)
Routine Maintenance Summation
53. Annual mowing cost (Line 6)
Annual cost for repairing routine erosive
damage (Line 16)
Annual cost for replacing fence (Line 21)
Annual cost for fertilizing (Line 28)
Annual cost for replacing well (Line 21 4- 30)
Annual cost for removing leachates (Line 38)
Annual cost for ground-water monitoring (Line 52)
Total annual cost for routine activities
54.
55.
56.
57.
58.
59.
60.
12 wells
2 samples
24 samples
2 hours
48 hours
6 hours
54 hours
$15
$810
$77
$108
$924
$2592
S4326
$3930
$1621.58
$5140.41
$7152
$28
$5520
$4326
S27.717.99
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POST-CLOSURE
WORKSHEET C - EROSION DAMAGE CONTINGENCY SCENARIO
1.
2.
3.
4.
10,
11.
12.
13.
14.
15.
16.
17.
18.
19.
Percentage of vegetation removed
Facility acreage
Acreage reduced to bare soil (Line 1 x Line 2)
Annual per acre soil loss rate (without
vegatative cover)
llonthly bare ground soil loss rate
Amount of soil lost before repairs are instituted
(Line 3 x Line 5x2) 'The factor of 2 adjusts for
immediate soil losses)
Unit cost for excavating and loading soil (on-site
operations using a 2-cu. yd. front end loader)
On-site haul of excavated soil to area needing
repair
Filling and compacting the eroded areas (using
a dozer)
Total unit cost for soil replacement
(Line 7 + Line 8 + Line 9)
Cost of replacing lost soil (Line 6 x Line 10)
Unit cost for seeding the bare soil
Unit cost for fertilizing
Unit cost for mulching with straw
Total unit replanting cost (Line 12 + Line 13 + Line
Total replanting cost (Line 3 x Line 15)
Number of erosive incidents expected in the post-
closure period
Total cost for repairing damage from erosive
incidents (Line 11 + Line 16 x Line 17
Total annual cost for repairs required by erosive
incidents (Line 18 4- 30)
30%
200 acres
60 acres
12 tons
per acre
1 ton per
acre
(.741 cu.
yds./acre)
120 tons
(89 cu. yds.)
50.21 per
cu. yd.
SO.85 per
cu. yd.
$1.25 per
cu. yd.
32.31 per
cu. yd.
$205.59
$88/acre
$134/acre
$124.50/acre
14) S346.50/acre
$20,790
2
.$41,580
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POST-CLOSURE
WORKSHEET D - INITIAL REPLANTING TO ESTABLISH VEGETATION
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17.
18.
19.
Percentage failure of vegetation per year
Number of years required for full vegetation
Facility acreage
Total acres to be replanted due to initial
failure of vegetation (Line 1 x Line 2 x Line 3)
Annual per acre soil loss rate (for areas with
inadequate vegetative cover)
Monthly bare ground soil loss rate
Amount of soil lost before repairs are
instituted (Line 4 x Line 6)
Unit cost for soil excavation and loading
(on-site operations using a 2-cu. yd. front end loader)
On-site haul of excavated soil to area needing
repair
Filling- and compacting eroded areas (-usinc a
dozer)
Total unit cost for soil replacement
(Line 8 -I- Line 9 -r Line 10)
Cost of soil replacement (Line 7 x Line 11)
Unit cost for seeding bare soil
Unit cost for fertilizing
Unit cost for mulching with straw
Total unit replanting cost (Line 13 + Line 14 + Line 15)
Total replanting costs (Line 4 x Line 16)
Total costs for initial replanting to establish
vegetation (Line 12 + Line 17)
Total annual cost (Line 18 4- 30)
10 percent
3
200 acres
60
6 tons/acre
.5 tons
(.3706 cu.
yd./acre)
30 tons
(22 cu. yds.)
$0.21 per
cu. yd.
SO.85 per
cu. yd.
SI.25 per
cu. yd.
$2.31 per
cu. yd.
$50.82
$88/acre
$134.10/acre
$124.50/acre
$346.60/acre
$20,796
$20,847
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POST-CLOSURE
WORKSHEET E - ADMINISTRATIVE SERVICES
1. Number of technical hours required for administrative
duties (annual)
2. Person-hour cost for technical administrative duties
3. Total administrative costs for technical labor
(Line 1 x Line 2)
4. Number of clerical hours required for administrative
duties
5. Person-hour costs for clerical administrative duties
6. Total administrative costs for clerical labor
(Line 4 x Line 5)
7. Office or trailer rental (includes equipment and
supplies)
8. Total annual administrative costs for the post-closure
activities (Line 3 + Line 6 + Line 7)
120 hours
§30
$3600
120 hours
$8
$960
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