united "tates
Environmeniai Protec'icn
Agency
Deveicpmert
Washington, DC 20460
C~" ce of
Enforcement
Washington, DC 20460
June 1993
Handbook on
Pollution Prevention
Opportunities for
Bleached Kraft
Pulp and Paper Mills
•^Ji Pnntefl on Recycled
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UNITED STATES ENVIRONMENTAL PROTECTION AGENCY
WASHINGTON, D.C, 20460
JUt ! 3J993
OFFICE OF ENFORCEMENT
MEMORANDUM
SUBJECTS Handbook On Pollution Prevention Opportunities For
Bleached Kraft Pulp and Paper Mills
FROM: Steven A.
Assistant Administrator *' * >"f "'Pi , ' <,
TO: Addressees • ***"' '*> ^< . „ •••*/•
Pursuant to the Pollution Prevention Act of 1990 ("PPA"),
the United states Environmental Protection Agency ("U.S. EPA") is
j directed to implement a source reduction training program for
j state and Federal enforcement officials and to facilitate
Qi adoption of source reduction techniques by businesses. Indeed,
as clearly expressed by Administrator Browner in Pollution
PreventionPolicy statement; New Directions for Environmental
n Protection (June 15, 1993), it is the policy of U.S. EPA to
S encourage pollution prevention as a means of compliance with
n environmental standards,
£ The purpose of this handbook is to familiarize environmental
enforcement personnel, the regulated community, and others with
currently available opportunities to prevent the formation of
pollutants generated by pulp and paper mills, with a particular
emphasis on the bleached kraft segment of the industry. The
handbook was developed by the Office of Research and Development
(ORD) in support of the enforcement program. The handbook is
C adapted from a more comprehensive in-depth ORD study of pollution
0 prevention technologies for the bleached kraft segment of the
~ pulp and paper industry, which relied on information generated
| through contacts with vendors, review of technical literature,
^ and reports from operators of bleached kraft pulp and paper mills
Q in the United States, Canada, and Europe,
•4
To promote the consideration of pollution prevention
opportunities by government and industry representatives in
enforcement proceedings, the handbook is intended to be easily
understandable, and to provide a basis for more detailed research
into feasible pollution prevention alternatives. The concept of
developing an industry-specific pollution prevention handbook for
the use by the enforcement program is new. We encourage
recipients to provide us with feed-back on the document, which
HEADQUARTERS LIBRARY
ENVIRONMENTAL PROTECTION AfiENCT
WASHINGTON, D.C. 20460 m.
GCQ Printed on Recycled Paper
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will allow us to assess its usefulness as a pollution prevention
promotional tool, and to consider whether additional industry-
specific handbooks would be helpful to enforcement personnel.
Comments should be directed to either Peter Fontaine (LE-134W)
(phone 202/260-6240; fax 202/260-4201) or Pete Rosenberg (LE-133)
(phone 202/260-8869; fax 202/260-7553), at the Office of
Enforcement, U.S. EPA, 401 M Street, S.W., Washington, D.C.
20460. A limited number of additional copies of the handbook can
be obtained by contacting the above persons.
The process of resolving noncompliance at regulated
facilities presents unique opportunities to influence the future
direction of residuals management at the facilities. In
resolving an enforcement action, enforcement officials and
facility operators must decide on the best means to return the
facility to compliance, usually through the investment in
additional treatment technologies or through some other means to
reduce pollution to authorized levels and preferably to levels
significantly below legal limits. This decision point is a
critical juncture in the overall process of implementing
environmental controls at a facility, as the outcome will
determine for years to come the magnitude, character, and
potential environmental impacts of pollutants released by the
industrial source.
However, information on feasible options to prevent
pollutant formation at industrial facilities, including kraft
pulp and paper mills, is not always readily available to industry
and government environmental managers. Furthermore, the
prevailing "end-of-pipe" culture of these same managers, in part
a product of the single-medium orientation of our environmental
protection statutes, regulatory programs,' and permitting and
compliance monitoring systems, is not subject to rapid change.
In short, instituting a prevention ethic both within EPA and the
regulated community, and developing the technical knowledge to
practice it, is an ongoing incremental process.
This handbook is designed to encourage the adoption of
source reduction options at pulp and paper facilities in
connection with environmental enforcement actions, in furtherance
of the PPA, U.S. EPA's "Interim Policy on the Inclusion of
Pollution Prevention and Recycling Provisions in Enforcement
Settlements" (February 25, 1991) ("Interim policy"), and U.S.
EPA's "Policy on the Use of Supplemental Environmental Projects
in EPA Settlements" (February 12, 1991) ("SEP policy").
The Interim and SEP policies encourage EPA enforcement
personnel and facility operators to consider pollution prevention
projects in resolving noncompliance. Essentially, the Interim
policy encourages the inclusion of pollution prevention projects
as the basis for injunctive relief (the measures necessary to
return a facility to compliance), while the SEP policy outlines
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the minimum prerequisites for acceptance of pollution prevention
projects as the basis for off-setting penalty liability.
Acceptable SEPs can include those that substantially reduce or
prevent the creation of pollutants through use reduction or
application of closed-loop processes, and projects that go
substantially beyond compliance with discharge limitations to
further reduce the amount of pollution that would otherwise be
discharged. All SEPs must have some nexus to the violation(s)
underlying the enforcement action.
The adoption of one or several of the pollution prevention
options discussed in this handbook has the potential to
significantly reduce pollution discharges to a number of
different environmental media, thereby reducing risks to human
health while improving the quality of the environment. For those
pulp and paper mills in violation of pollutant limits, the
options discussed in the handbook offer possible solutions to
noncompliance while also providing a basis for EPA enforcement
officials to consider reducing potential penalty liability,
assuming fulfillment of the requirements contained in the SEP
policy.
Addressees:
Deputy Regional Administrators
Regional Counsels
Region Counsel Branch Chiefs
Headquarters National Program Managers
Regional Program Division Directors
Regional Program Enforcement Branch Chiefs
Enforcement Counsel
Director, National Enforcement Investigations Center
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TABLE OF CONTENTS
SECTION ONE INTRODUCTION .,,....,...,..,..,. 1-1
SECTION ONE REFERENCES 1-4
SECTION TWO CONVENTIONAL BLEACHED KRAFT MILL
OPERATIONS . ............. 2-1
SECTION TWO REFERENCES . . . 2-5
SECTION THREE POLLUTION PREVENTION OPPORTUNITIES IN
WOODYARD AND CHIPPING OPERATIONS 3-1
3.1 Raw Material Selection 3-1
3.2 Recycle of Log Hume Water 3-1
3.3 Dry Debarking 3-1
3.4 Improved Chipping and Screening 3-3
3.5 Storm Water Management 3-3
SECTION THREE REFERENCES 3-5
SECTION FOUR POLLUTION PREVENTION OPPORTUNITIES IN
PULPING OPERATIONS 4-1
4.1 Extended Delignifieation 4-1
4.2 Oxygen Delignification 4-10
4,3 Ozone Delignification 4-16
4.4 Anthraquinone Catalysis 4-24
4.5 Black Liquor Spill Control and Prevention 4-25
4.6 Enzyme Treatment of Pulp 4-27
4.7 Improved Brownstock Washing 4-30
SECTION FOUR REFERENCES ,. 4-33
111
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TABLE OF CONTENTS (cont)
SECTION FIVE POLLUTION PREVENTION OPPORTUNITIES IN
BLEACHING OPERATIONS 5-1
5.1 High Chlorine Dioxide Substitution 5-1
5,2 Split Addition of Chlorine/Improved pH Control 5-9
5.3 Oxidative Extraction 5-10
5.4 Peroxide Extraction 5-12
SECTION rave REFERENCES ..... . 5-15
IV
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LIST OF TABLES
Page
Table 4-1 Installations of Extended Delignifieation Systems Worldwide 4-5
Table 4-2 U.S. Installations of Oxygen Delignifieation Systems 4-12
Table 4-3 Capital Cost Estimates for Oxygen Delignifieation Systems 4-14
Table 4-4 Pollutant Impacts of Oxygen Delignifieation Versus
Conventional Bleaching 4-15
Table 4-5 Ozone Pilot and Full-Scale Plants Worldwide 4-19
Table 4-6 Bleaching Chemical Costs of Ozone Versus Conventional Sequences
at Union Camp's Franklin, Virginia Mill 4-21
Table 4-7 Emissions from Ozone Bleach Line at Union Camp's
Franklin, Virginia Mill ...... 4-23
Table 4-8 Major Operating Cost Items for Existing Washing Line Versus
Three Modern Alternatives 4-32
Table 4-9 Annual Incremental Operating Costs Saved for Three Modern
Alternative Washing Systems 4-32
Table 5-1 Summary of Chlorine Dioxide Generation Processes 5-2
Table 5-2 North American Chlorine Dioxide Generators 5-5
Table 5-3 Cost and Environmental Comparison of Chlorine Dioxide Substitution ..... 5-6
Table 5-4 Cost and Environmental Comparison of Chlorine Dioxide Substitution
at a Greenfield Mill 5-8
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LIST OF FIGURES
Page
Figure 2-1 Flowsheet for conventional integrated bleached kraft mill 2-2
Figure 3-1 Debarking drum 3-2
Figure 3-2 Chip thickness slicer showing oversize chip being split 3-4
Figure 4-1 Equipment diagram for MCC extended cooking showing multiple
liquor addition points 4-2
Figure 4-2 Equipment diagram for MCC extended cooking showing multiple
liquor addition points and liquor addition to wash zone 4-3
Figure 4-3 Process flow for high-consistency (HC) oxygen delignification 4-11
Figure 4-4 Equipment for high-consistency (HC) ozone delignifcation 4-17
Figure 4-5 Spill control system flow design 4-26
Figure 4-6 Impact of xylanase on AOX 4-29
Figure 4-7 Impact of xylanase on brightness 4-29
Figure 5-1 North American consumption of sodium chlorate for
chemical pulp bleaching . 5-3
Figure 5-2 Modification of extraction stage for peroxide/oxygen reinforcement 5-13
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Pollution Prevention in Pulp and Paper
SECTION ONE
INTRODUCTION
This handbook examines the current state of the art, economics of adoption, and level of adoption of
selected pollution prevention technologies in the U.S. pulp and paper industry.1 The focus in the
handbook is on the bleached kraft segment of the industry, due to the heightened concern over its
environmental impacts. This concern is related primarily to the use of chlorine-based compounds in the
manufacturing of bleached pulps, and the nature of the byproduct pollutants associated with conventional
pulpmaMng processes. In particular, it is the persistence, non-biodegradability, and toxicity of some of
the chlorinated organic compounds formed during chlorine-based bleaching that explains the high level
of attention directed toward this segment of the industry. The bleached kraft segment accounts for
approximately 35 percent of the pulp mills and 47 percent of the pulp production capacity in the U.S.
industry (API, 1992).
The control of chlorinated pollutants from the bleached kraft process through end-of-pipe treatment is
difficult due to their persistence and low concentration in effluents. Conventional treatment technologies
are relatively ineffective at destroying such compounds and instead may result in their transfer to other
environmental media (e.g., wastewater treatment sludge). As a consequence, ftirther reductions must focus
on changes in the production process that can reduce or eliminate their formation. For prevention of
chlorinated organics, the available technologies include a variety of techniques that enable the, mill to
reduce the use of chlorine-based compounds in the bleaching process, Because these technologies enable
further recycle of the mill's effluent, they can also have a significant impact on more traditional pollutants
such as BODS, COD, and TSS, as well as on effluent color, an increasing concern in some areas.
Emissions of chloroform, an air toxic, are also reduced as a result of many of these technologies.
Recently, scientists in Canada and Scandinavia have suggested that non-chlorinated substances make a
significant contribution to the effects of biologically treated pulp mill wastes on the receiving waters. At
this time, there is little information available concerning these findings, although some of the results are
expected to be published shortly. Most of the pollution prevention technologies discussed in this
handbook, however, will also reduce the discharges of such non-chlorinated substances, particularly those
which involve routing wastes to the recovery boiler that would otherwise have been discharged to the
effluent treatment system.
The economics of adopting process changes are explored in detail in this handbook. An important
conclusion from reviewing available information is that, while it is possible to cite representative capital
and operating cost information, the actual costs and savings at an individual mill will be very site-specific.
Facility costs will depend closely on the age, type, and condition of the existing equipment at the mill.
A key consideration affecting the attractiveness of any of these options is the relative age and
obsolescence of equipment it will replace, and the future investments that may be avoided.
The costs presented in this handbook are for specific examples drawn from the literature for the purposes
of putting the economic aspects in perspective. Due to the wide variation in situations among mills, it
1 The technical information contained in this report is based upon a more detailed, peer-reviewed
technology report prepared for the Office of Pollution Prevention and Toxics (OPPT) under an Office of
Research and Development (ORD) contract (EPA, 1993b). A copy of the main report may be obtained
from Jocelyn Woodman (Mail Code 7409) of the Pollution Prevention Division, OPPT (202-260-4418).
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Pollution Prevention in Pulp and Paper
is recommended that evaluations of these technologies for a particular mill be based only on site-specific
engineering reports that clearly identify the scope of the project, detail the necessary capital equipment
and operating costs, and are explicit with regard to any savings assumed to accrue.
It should also be noted that a substantial amount of technical information and data presented in this
handbook is based on published and unpublished sources at equipment vendor and system supplier
companies. Since many of the technologies discussed hi the handbook are available from only a small
number of supplier companies, these suppliers offer a valuable and unique perspective on overall system
performance and economics. Mention of specific vendors in the context of this handbook does not,
however, constitute endorsement by the U.S. Environmental Protection Agency, nor does it imply that
those mentioned are the only companies capable of supplying the technology.
Regardless of the situation, most pollution prevention technologies for the pulp and paper industry result
in lower operating costs, but do not usually generate sufficient savings to justify the investment
themselves. Thus, environmental compliance or market factors often play a deciding role in whether to
go ahead with a project or not. In many cases, the decisiomnaking process of a mill will be substantially
affected by the market and/or regulatory environment it expects to face in the future. Many mills are
undoubtedly concerned about the future direction of environmental regulations in their industry and the
possible implications on the processes they use. Market forces are equally important. In particular, mills
that sell pulp or paper into more environmentally discerning international markets may be forced to adopt
further pollution prevention measures in order to comply with the demands of their customers for
"environmentally responsible" paper and pulp products.
One factor to consider when evaluating the viability of pollution prevention technologies is that operating
costs may be sensitive to the target pulp brightness level. This is especially true in totally chlorine-free
(TCP) processes, which may use expensive hydrogen peroxide in the final bleaching stage to bring pulp
to final brightness. The higher the producer's brightness requirements, the more peroxide must be used,
leading to higher bleaching costs.
Traditionally, mills that produce "market pulp" for sale to other mills have had to meet higher brightness
standards than most integrated mills ~ mills that produce pulp for their own use in papermaking - require.
Pollution prevention technologies involving non-chlorine bleaching stages are more competitive with
conventional processes in the 70 to 80 brightness range. Unless market pulp brightness levels fall,
therefore, integrated mills that can use lower brightness pulps will be better positioned than maret pulp
producers to take advantage of some of the pollution prevention technologies discussed in this handbook.2
Much of the information contained hi this handbook is by necessity very recent, Many of the current
concerns over the environmental impacts of the U.S. pulp and paper industry have arisen only since 1985,
with the discovery of dioxin in bleached kraft mill effluents and solid wastes (EPA, 1988). Although prior
to this some of these technologies were in use elsewhere in the world, only lately has there been an
incentive for U.S. producers to investigate them. Since the discovery of the dioxin problem, however, the
U.S. and international research and development effort has been impressive, and the rate of adoption of
many of these technologies has been increasing rapidly. Information on their use, effectiveness, and cost
2 The market issues surrounding pulp brightness and pollution prevention are addressed in several
papers contained in the proceedings from the EPA-sponsored International Symposium on Pollution
Prevention in the Manufacture of Pulp and Paper - Opportunities and Barriers (EPA, 1993a),
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Pollution Prevention in Pulp and Paper
has been spreading through all of the major trade publications and at numerous industry conferences. As
experience with the technologies grows, it is likely that costs will decline further and effluent quality will
further improve, providing additional incentives for adoption.
This handbook is organized into five sections. Section Two presents a brief overview of the unit
processes typically found at an integrated bleached kraft mill. Section Three covers technologies that can
be applied in the woodyard and chipping areas of the mill. Section Four identifies pollution prevention
opportunities in the pulping or pre-bleaehing stages of the process, while Section Five discusses pollution
prevention opportunities in the bleach plant of the mill.
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Pollution. Prevention in Pulp and Paper
SECTION ONE REFERENCES
API, 1992. American Paper Institute. 1992 Statistics of Paper, Paperboard, & Wood Pulp, New York,
EPA, 1988. U.S. EPA/Paper Industry Cooperative Dioxin Screening Study, U.S. Environmental
Protection Agency, Office of Water Regulations and Standards, Washington, D.C., March 1988.
EPA 440-1-88-025.
EPA, 1993a. International Symposium on Pollution Prevention in the Manufacture of Pulp and Paper -
Opportunities and Barriers, August 18-20, 1992, Washington, D.C. U.S. Environmental
Protection Agency, Office of Pollution Prevention and Toxics. EPA-744R-93-002. February
1993.
EPA, 1993b. Pollution Prevention Technologies far the Bleached Kraft Segment of the U.S. Pulp and
Paper Industry. U.S. Environmental Protection Agency, Office of Pollution Prevention and
Toxics, Washington, D.C. EPA/600/R-93/110. July, 1993.
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Pollution Prevention in Pulp and Paper
SECTION TWO
CONVENTIONAL BLEACHED KRAFT MILL OPERATIONS
This section briefly describes the unit operations common to most bleached kraft mills in North America
and introduces two terms — kappa number and pulp brightness — essential to an understanding of the
pollution prevention technologies discussed in this handbook.
The point of departure for this discussion is the typical bleached kraft mill as it existed in the mid- to late-
1980s. Since that time the configuration of the "typical" mill has been evolving gradually, however the
basic processes are still in place, perhaps with some modification, at most mills today.
Figure 2-1 shows the process flow for an integrated bleached kraft pulp mill. The mill operations are
segregated according to the following major process areas: (1) wood preparation, (2) pulping, (3)
bleaching, and (4) chemical recovery.
Wood Preparation/Pulping
In the wood preparation area, pulpwood (logs)1 are debarked in a rotating dram and then chipped to
uniform size and shape. The chips are steamed and mixed with cooking liquor (or white liquor), a mixture
of sodium hydroxide and sodium sulfide. The liquor-impregnated chips are then fed into a large reaction
vessel known as a digester. In the digester, the cooking chemicals react with the chips (at elevated
temperature and pressure) to break down lignin, the substance that holds the individual wood fibers
together.
The progress of the cook (as well as most downstream processes) is monitored via a parameter known as
the kappa number. The kappa number reflects the amount of lignin remaining in the pulp. Since it is
lignin that imparts color to the pulp and is responsible for yellowing and aging of paper, the primary
objective of the bleached kraft process is to reduce the pulp's lignin content (or kappa number) as much
as possible. While lignin removal can be enhanced using more severe process conditions (higher
temperature and pressure, longer cooking times), the process yield is generally an inverse function of these
variables. Thus, kraft mills must balance further lignin removal against the yield loss that may result.
Bleaching
Following discharge from the digester, the cooked pulp is washed and screened, at which point it is known
as brownstock. The brownstock moves on to the bleach plant, where it undergoes a series of acidic and
alkaline treatments. In the typical mill shown in Figure 2-1, the bleach sequence is as follows:
• Reaction with chlorine gas (C);
• Washing and extraction (E) with sodium hydroxide (caustic);
1 The diagram shows tree-length logs (roundwood) being used as feedstock for the pulping and
bleaching operations. In the modern kraft mill, fiber may be derived from a variety of sources including
logs, chips, and sawmill residues (including sawdust).
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Pollution Prevention in Pulp and Paper
* Reaction with chlorine dioxide (D);
" Caustic extraction (E);
« An additional chlorine dioxide stage (D);
« A final caustic extraction stage (E).
The letters representing each stage of the bleaching sequence are commonly used as a shorthand way to
describe the sequence used at a particular mill (e.g., CEDED),
The goal of the bleaching sequence is to remove additional lignin and to brighten (i.e., remove color from)
the pulp. Chlorine acts as a very powerful delignifying agent, while the first caustic extraction stage is
used to neutralize the pulp and facilitate removal of the dissolved lignin solids during washing. Chlorine
dioxide is a more "selective" brightening agent that destroys ehromophoric groups within the pulp without
attacking the individual cellulose fibers.
Pulp brightness is an objective measure of the amount of light reflected by the pulp and is determined
using standard measuring techniques and instruments.2 Brownstock pulp registers a brightness level of
15 to 30 percent and is basically the color of unbleached kraft paper (e.g., grocery sack). Most pulp mills
have traditionally applied bleaching chemicals to achieve a target brightness level of 90 percent. In
particular, market pulp (i.e., pulp sold to other mills for use in papermaking) has always been bleached
to 90 percent brightness according to the requirements of pulp buyers. Many integrated mills (i.e., mills
that produce pulp for their own use in papermaking) are able to make quality paper products using pulp
bleached to somewhat lower brightness levels (between 80 and 88, depending on the source). The target
brightness level for the bleach plant is important since many of the pollution prevention technologies
discussed in this handbook become more competitive at somewhat lower target brightness levels.
Chemical Recovery
The bottom half of Figure 2-1 shows the rather complex chemical recovery system that is characteristic
of all kraft mills. Chemical recovery begins with the spent cooking chemicals and solubilized lignin that
is flushed from the cooked pulp at the brownstock washers. This mixture, known as weak black liquor,
is concentrated in a series of multiple effect evaporators to form strong black liquor, with a solids content
of between 60 and 80 percent. The strong black liquor is fired into the recovery boiler, where the heat
content of the organic lignin solids is released to generate steam for process use.
Smelt from the bottom of the furnace (consisting of sodium/sulfur salts and inorganic chemicals) runs into
a dissolving tank where it is mixed with weak wash, the filtrate from lime mud washing (see below) to
form green liquor. The green liquor is clarified to remove carbonaceous ash residues and other impurities.
These dregs, as they are known, are washed to remove soluble sodium salts while the remaining residue
is removed and generally disposed of in a landfill. The clarified green liquor moves next to the calcining
system, where it is mixed with calcium hydroxide in the slaker to convert sodium carbonate to sodium
hydroxide (caustic), one of the principal pulping chemicals.
2 Several alternative techniques for measuring pulp brightness are used, including the GE, Elephro,
and ISO methods. The difference in readings obtained using these three methods is small, perhaps one
or two points on a scale of 0 to 100. In this handbook, brightness levels cited are obtained using the ISO
method unless otherwise indicated.
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Pollution Prevention in Pulp and Paper
Calcium carbonate precipitates out of the eausticizers and is removed in the white liquor clarifler. The
clarified solution then contains the two major cooking chemicals, sodium hydroxide and sodium sulfide.
The regenerated white liquor is now ready for use in the pulp digester(s).
The final stage hi the recovery process involves recycle of the precipitated calcium carbonate removed
from the white liquor clarifler. This mixture is thickened, washed, and introduced into the lime kiln,
which converts it to calcium oxide. The calcium oxide is recovered and used in the slaker, as described
above.
Wastewater Treatment
In Figure 2-1 it can be seen that filtrate from the bleach plant (the C-, D-, and E-stages) is not recycled
and instead is discharged, via the alkaline and acid sewers, to the wastewater treatment system. Most
North American mills operate both primary and secondary wastewater treatment facilities to treat these
wastes. Primary treatment removes suspended solids (as primary sludge) while secondary treatment uses
biological processes to remove dissolved and suspended solids from the effluent. Sludge from primary
and secondary treatment is often combined prior to dewatering and final disposal. Landfills are the most
common disposal method used for sludge, although surface impoundments, incineration, and land
application are also widely used.
Bleach plant effluent from chlorine-based bleaching stages cannot be recycled due to the potential for
corrosion of process equipment. From an environmental standpoint, there are two disadvantages to this.
First, additional organic solids washed from the pulp during bleaching cannot be recovered for their heat
value and are lost to the sewer system. Second, the chlorination of pulp in the first C-stage has been
linked to the formation of chlorinated organics, including dioxin and raran, which are difficult to remove
or destroy using conventional wastewater treatment Major efforts are underway within the industry to
either reduce the lignin content (kappa number) of the pulp prior to bleaching, or to substitute more
environmentally-benign chemicals for chlorine in the bleach plant. In the former case, reducing the kappa
number of the pulp entering the bleach plant means that (1) more effluent and solids can be recycled, and
(2) less bleaching chemicals (including chlorine) will be needed to reach a target brightness level. In the
latter case, reduction of chlorine will result in improved effluent quality but will not increase the level of
effluent closure within the mill. Strategies for achieving some of these benefits are discussed in detail in
Sections 4 and 5.
The remainder of this handbook discusses opportunities for prevention of pollution from the woodyard,
pulping, and bleaching areas of the mill. While the chemical recovery process also contributes to
emissions from the mill (especially to air), there are comparatively fewer opportunities for prevention of
pollutants.3 For a recent review of techniques to control emissions from the recovery process, the reader
is referred to the Office of Air Quality Planning and Standards (OAQPS) recent Background Information
Document, prepared in support of the proposed air and water regulations for the pulp, paper, and
paperboard industries (EPA, 1993).
3 The configuration and operation of the chemical recovery system does, however, impact the technical
and economic feasibility of adopting many of the pollution prevention technologies that are discussed here.
For this reason, reference to the chemical recovery system is made throughout the document
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Pollution Prevention in Pulp and Paper
SECTION TWO REFERENCES
EPA, 1993. Pulp, Paper and Paperboard Industry - Background Information for Proposed Air Emission
Standards, Preliminary Draft. April 1993. Office of Air Quality Planning and Standards,
Emissions Standards Division. Research Triangle Park NC.
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Pollution Prevention in Pulp and Paper
SECTION THREE
POLLUTION PREVENTION OPPORTUNITIES IN WOODYARD
AND CHIPPING OPERATIONS
The woodyard is the name given to the areas at the mlE where the raw pulping materials (logs,
chips, and, increasingly, sawdust and other sawmill residuals), are stored, prepared, and fed to the
pulping equipment This section reviews the operations in the pulp mill woodyard and identifies
opportunities for prevention of pollution associated with these activities.
3.1 RAW MATERIAL SELECTION
In the past, mills may have purchased wood, chips, or sawdust from sawmills that used preservatives such
as pentachlorophenol (PCP) to treat the wood for stain resistance. These chemicals were found to contain
CDDs/CDFs and CDD/CDF precursors which, following chlorinate! in the bleach plant, led to formation
of dioxins and furans. This problem has been widely recognized within the industry and most mills are
believed to have ceased purchasing treated wood.
3.2 RECYCLE OF LOG FLUME WATER
Log flumes are used to transport wood from storage areas to debarkers and chippers at some mills. The
water used in such systems can be recycled to the wastewater treatment plant at minimal cost
Alternatively, treated wastewater can be used in the flume. In both cases, bark and fiber collected in the
flume water can be removed and burned in "hogged" fuel boilers to recover energy values.
33 DRY DEBARKING
Wet debarkers rotate logs in a pool of water and remove bark by knocking the log against the side of the
drum. The water used in this process is recycled but a certain amount is lost as overflow to carry away
the removed bark. Resin acids and highly colored materials leach out of the bark and into this waste
water stream. The effluent is collected and routed to the wastewater treatment system, where it contributes
to BOD5 and TSS loadings.
Dry debarking methods such as dry drum debarkers (see Figure 3-1) or shearbarkers eliminate the water
stream and the pollutants associated with it. Water savings in the range of 2,000 to 3,000 gallons per ton
of wood barked can be obtained, and BOD5 and TSS loading reductions should be in the range of 6 to
55 pounds and 1 to 10 pounds per ton. Dry debarkers already dominate the industry, and wet systems
have been in the process of being phased out since the 1970s (Smook, 1982),
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Pollution Prevention in Pulp and Paper
Figure 3-1.
Source: Beak, 1978.
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Pollution Prevention in Pulp and Paper
The costs of dry drum debarkers should not differ significantly from a wet system. Costs for replacing
both types of equipment are in the range of $10 to 20 million.
3.4 IMPROVED CHIPPING AND SCREENING
In most mills, chips are passed over a vibrating screen that removes undersized particles (fines) and routes
oversized chips for rechipping. Chips are normally segregated only according to chip length. Chip
thickness screening has become important as mills realize the need to extend delignificatton. Both
absolute chip thickness and thickness uniformity have a significant impact on delignifieation, since the
kraft cooking liquor can only penetrate the chip to a certain thickness ffikka et al, 1992), Thin chips
are easier to cook to lower kappa numbers. Uncooked cores from overly thick chips will lower the
average kappa of a cook, reducing yield and contributing to higher bleaching chemical demands. To
improve thickness uniformity, mills are adopting screening equipment that separates chips according to
thickness as well as length (Stakes and Bielgus, 1992). Chips that exceed the maximum acceptable
thickness can be diverted to a chip slicer, that cuts them radially and reintroduce them to the screening
system (see Figure 3-2).
Costs for chip thickness screening systems in a new installation may range from $200,000 to $400,000
(higher for a retrofit).
35 STORM WATER MANAGEMENT
Storm water runoff from wood storage and handling areas may contain significant amounts of BODS, TSS,
and color. Mills may control storm water discharges by installing curbs, dikes, and drainage collection
systems around wood and chip piles and wood processing areas. Collected stormwater can be collected
and transported to the wastewater treatment facility which should effectively remove the pollutants of
concern.
Costs for stormwater collection and treatment are variable and quite site-specific. They depend more on
the current configuration of the mill woodyard and location of treatment facility than on the particular type
of controls installed.
Page 3-3
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Pollution Prevention in Pulp and Paper
GAGE PLATE --
KNffE
CLftMF
DRUM SCGMENT
ROTOR ANVIL
Figure 3-2. Chip thickness slicer showing oversize chip being split
Source: Smook, 1982,
Page 3-4
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Pollution Prevention in Pulp and Paper
SECTION THREE REFERENCES
Beak, 1978. Technical, Economic and Environmental Aspects of Wet and Dry Debarking. Prepared by
Beak Consultants, Ltd. for the Water Pollution Control Directorate, Environmental Protection
Service, Fisheries and Environment Canada, Report No. EPS 3-WP-78-3. March, 1978.
Smook, 1982, Gary A. Smook. Handbook for Pulp and Paper Technologists, (TAPPI/CPPA,
Atlanta/Montreal).
Stakes and Bielgus, 1992. George Strakes and Joe Bielgus. "New Chip Thickness Screening System
Boosts Efficiency, Extends Wear Life," Pulp and Paper, My 1992, p, 93.
Tikka et al., 1992. "Chip Thickness vs. Kraft Pulping Performance, Part I: Experiments by Multiple
Hanging Baskets," Proceedings, 1992 TAPPI Pulping Conference, Boston MA, November 1992,
p. 555.
Page 3-5
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Pollution Prevention in Pulp «fe Paper
SECTION FOUR
POLLUTION PREVENTION
OPPORTUNITIES IN PULPING OPERATIONS
This section identifies pollution prevention technologies that may be applied in the kraft pulp mill
to effect environmental improvements. This section (and the rest of the report) retains the
traditional distinction between pulping and bleaching, which is to classify stages that occur prior
to the application of chlorine-based bleaching agents as pulping stages, and those tfiat occur
following application of these agents as bleaching stages. With the increased use of non chlorine-
based delignification agents, however, these distinctions are becoming less and less meaningful.
For optimum pollution prevention potential, many experts would recommend viewing pulping and
bleaching as integrated processes.
4.1 EXTENDED DELIGNIFICATION
What it is
Modification of the pulping equipment to achieve a more uniform reaction of cMps with the pulping
chemicals. Results in greater delignification, leading to reduced requirements for chlorine-based bleaching
chemicals and their associated environmental impacts.
Mow it works
In conventional kraft pulping, the digester is filled with chips and given a one-time charge of cooking
chemicals. The alkali concentration in the reactor is initially high, but then falls as the cook progresses
and the cooking chemicals are consumed. Normal reaction times are between one and three hours.
Longer cooks will further reduce pulp lignin content but wiE also begin to degrade the cellulose, as the
reactions become less selective towards lignin.
By applying principles developed by the Swedish Forest Products Research Institute (STFI), it has become
possible to extend pulp cooking times without impacting pulp quality or yield. These principles are
embodied in technology offered by the major equipment suppliers. The Modified Continuous Cook
(MCC®) and Extended Modified Continuous Cook (BMCC®) processes are available from Kamyr for
continuous pulping operations.1 In the MCC® process liquor is introduced at several different points to
maintain a constant alkali concentration throughout the cook (see Figure 4-1). In EMCC®, about 20 to
25 percent of the white liquor is added to the wash liquor in the bottom zone of the digester for counter-
current cooking (see Figure 4-2). EMCC® can be implemented without MCC® and in fact is the normal
way of converting a conventional digester to extended cooking.
1 Both Kamyr AB (Karlstad, Sweden) and Kamyr, Inc. (Glens Falls, New York) can supply the
technology in North America.
Page 4-1
-------�
Single Vessel Hydraulic Digester
Top Separalor
Oultel
o
&
».
1
5-
5
1
Figure 4-1, Equipment diagram for MCC extended cooking, showing multiple liquor addition points.
Source: Kamyr, Inc.
-------�
Single Vessel Hydraulic Digester
Single Vessel Hydraulic Digester, EMCC Adaptation
Top Sepa
WWTEUOUOR
Outlet Qevic
Figure 4-2. Equipment diagram for EMCC extended cooking, showing multiple liquor addition points and liquor addition to wash zone.
&
s,
o
I
SOUK»: Kamyr, Me,
-------�
Pollution Prevention in Pulp & Paper
For batch pulping, me cook can be extended using the Rapid Displacement Heating (RDH) process or one
of its variations. RDH was originally developed by the Beloit Corp. (Beloit, Wisconsin). Adaptations
of the RDH principles are available in the SuperBatch™ technology of Sunds Deflbrator (Sundsvall,
Sweden; Noreross, Georgia) and the Enerbateh® process of Voest-Alpine (Linz, Austria).
The chemical delivery demands of an RDH-type batch system require additional equipment and a
sophisticated process control system. This is especially true where the mill may run as many as 20 batch
digesters at a time, sharing common process equipment (accumulator tanks, pumps, piping)). Production
scheduling can be thrown off if there are disruptions due to equipment malfunction or operator error.
Much of the work done since the discovery of the RDH principles has involved refinement of the "tank
farm" configuration and improvement to the distributed control system that oversees the process.
Installations
Presently, world capacity for extended cooking is near 11 million tons per year (tpy), representing 20
percent of bleached kraft capacity (see Table 4-1). Worldwide, 31 new MCC*/EMCC® systems and 15
retrofits have been installed or are currently underway. Twenty-five of these projects are in the United
States, Including 16 new installations and 9 retrofits. Combined U.S. MCC* and EMCC® capacity
(installed and underway) is 35,255 tpd, representing about 25 percent of U.S. bleached chemical pulp
capacity. The average capacity of these installations is over 1,100 tpd. AH new Kamyr digesters sold
since 1985 have been equipped with (or prepared for) MCC* operation, hence retrofitting newer
continuous digesters is technically quite straightforward.
Installations of extended batch cooking are also shown in Table 4-1. As of this writing, Beloit's RDH
system had been installed at four U.S. mills plus one each in Canada, Finland, Spain and Taiwan. All
four U.S. installations were new installs as opposed to retrofits. The Sunds SuperBatch™ digester system
is currently operating at the Jefferson Smurfit mill in Jacksonville, Florida, at three Scandinavian mills,
and at one South African mill.
Note that some mills may retrofit their existing pulping equipment without the input of the vendor
companies discussed above. While technically not MCC®, EMCC®, or RDH, the equipment and principles
applied are essentially Ihe same.
Economics
Capital costs for extended deligniflcation equipment have been quoted at $15 to $16 million for a new,
1,200 air dried short tons (ADST) per day MCC® digester, with the installed cost estimated at $40 to $45
million. Retrofits will range in cost from under $1 million for simple wash zone upgrades on digesters
installed after 1980 to $15 to $30 million for a more complicated two-vessel conversion.
Costs for new RDH systems have been quoted at around $1.5 million for each new batch digester plus
$5 million for the accumulator tank farm, with a turnkey system running approximately three times that
amount or around $35 million for a 5-digester system. Costs for converting an existing pulping system
to RDH would likely range around $0.5 million per digester. The retrofit potential for existing batch
systems in the United States is somewhat limited, however, by Ihe age of the digesters. Most U.S. batch
digesters are of 1940-1970 vintage and hence many would not be suited for the complex modifications
required for application of RDH. Space requirements for the RDH tank farm may .also limit their
applicability at some mills.
Page 4-4
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Pollution Prevention in Pulp & Paper
TABLE 4-1
Installations of Extended Ddignification Systems Worldwide
Company
Location
Fiber
Furnish
Capacity
(tons/day)
Start-
Up
New Kamyr MCC®/EMCC* Continuous Digesters
North American Mills
Federal Paperboard
Domtar
Longview Fibre
Howe Sound
Weyerhaeuser
Daishowa Canada
Weldwood of Canada
Federal Paperboard
Champion
International
Union Camp
Stone Savannah River
Alabama Pine Pulp
Gulf States Paper
Temple-Inland
Union Camp
Alberta-Pacific
CelgarPulp
Temple-Inland
Weyerhaeuser
Weyerhaeuser
Weyerhaeuser
Willamette
Augusta, GA
Windsor, Que.
Longview, WA
Port Mellon, B.C.
Columbus, MS
Peace River, Alta,
Hintdn, Alta,
Augusta, GA
Courtland, AL
Eastover, SC
Port Wentworth, GA
Clairborne, AL
Demopolis, AL
Silsbee, TX
Savannah, GA
Boyle, Alta,
Castlegar, B.C.
Silsbee, TX
Longview, WA
Plymouth, NC
Plymouth, NC
Johnsonburg, PA
HW/SW
HW
sw
sw
sw
HW/SW
SW
HW
SW
HW
HW/SW
SW
HW/SW
HW
SW
HW/SW
SW
HW
HW/SW
HW/SW
HW/SW
HW
770
1145
1060
1450
1575
1360
1460
1520
1180
1250
865
1620
865
1085
2450
2020
1605
1250
1455
700
1100
780
1988
1988
1988
1990
1990
1990
1990
1991
1991
1991
1991
1991
1992
1992
1992
1993
1993
1994
1994
1994
1994
1994
Page 4-5
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Pollution Prevention in Pulp & Paper
TABLE 4-1 (conk)
Installations of Extended Deligniflcation Systems Worldwide
Company
Location
Fiber
Furnish
Capacity
(tons/day)
Start-
Up
MCC®/EMCC® Retrofits of Kamyr Continuous Digesters
North American Mills
Consolidated Papers
International Paper
International Paper
Champion Intl
Champion Intl
E.B.Eddy
Georgia Pacific
Georgia Pacific
Northwood
Union Camp
James River
Wisconsin Rapids.WI
Georgetown, SC
Mobile, AL
Courtland, AL
Quinnesec, MI
Espanola, Ont,
Ashdown, AR
New Augusta, MS
Prince George, B.C.
Savannah. GA
Camus, WA
SW
SW
HW/SW
HW
HW
SW
SW
HW/SW
SW
SW
HW
500
1300
1200
900
1000
525
900
1800
1100
2450
580
1987
1990
1990
1990
1990
1991
1991
1991
1991
1992
1993
New Kamyr M CC*/EMCC* Continuous Digesters
European, Asian, South American Mills
Metsa-Botnia
Korsnas
Kemi Oy
Iggesund Paperboard
Oji SeisM
Nagoya Pulp
Oji Seishi
Celulosa Arauco
CeMosa Pacifico
AanekosM, Finland
Gavle, Sweden
Kemi, Finland
Iggesund, Sweden
Kasugai, Japan
Kanishi, Japan
Yonago, Japan
Arauco, Chile
Mininco, Chile
HW/SW
HW/SW
HW/SW
SW
SW
•HW
HW
SW
SW
1210
1160
800
690
800
800
1200
1210
1220
1985
1988
1988
1988
1989
1990
1991
1991
1991
Page 4-6
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Pollution Prevention in Pulp & Paper
TABLE 44 (cent)
Installations of Extended Delignification Systems Worldwide
Company
Location
Fiber
Furnish
Capacity
(tons/day)
Start-
Up
MCC®/EMCC® Retrofits of Kamyr Continuous Digesters
European, Asian, South American Mills
Enso Gutzeit
NCR
Store
Iggesund Paperboard
Varkaus, Finland
VaUvik, Sweden
Skutskar, Sweden
Iggesimd, Sweden
HW
sw
HW
HW
590
515
420
800
1983
1990
1990
1990
Beloit RDH Batch Extended Cook Systems
North American Mills
Packaging Corp
S.D. Warren (Scott)
Bowater
Fletcher Challenge
Willamette
Valdosta, GA
Westbrook,ME
Calhoim, TN
Crofton,B,C.
BemettsvlUe, SC
HW/SW
HW/SW
HW/SW
SW
HW/SW
1,000
450
1200
775
900
1984
1989
1990
1990
1990
Beloit RDH Batch Extended Cook Systems
Rest of World
Joutseno Pulp
Nymolla
Cellulosas de Naviron
Chong-Hwa
Joaiseno, Finland
Nymolla, Sweden
Durango, Spain
Hnalien, Taiwan
HW/SW
SW
SW
HW
950
860
350
400
1986
1987
1989
1992
Sunds SuperBatch Batch Extended Cook Systems
Worldwide
Jefferson Sraurflt
ASSI
Mondi Paper
Sodra
Enocell
Jacksonville, FL
Karlsborg, Sweden
Richard's Bay, S. Africa
Varo, Sweden
Uimaharju, Finland
SW
SW
HW/SW
SW
HW/SW
690
875
1500
900
1800
1990
1984
1984
1988
1993
Source: MacLeod (1992).
Page 4-7
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Pollution Prevention in Pulp & Paper
Pollution prevention
Extended deh'gnification can reduce the kappa number of biownstock softwood pulp from a range of 30
to 32 for conventional pulping to a range of 12 to 18 (although target ranges ate currently around 20 to
25). Hardwood kappas can be reduced from around 20 to a range of 8 to 10, with current targets
generally around 12 to 15. The impact of brownstock kappa number reductions on bleaching chemical
demands and formation of many chlorinated organics is now well understood. AOX and polychlorinated
phenols will be reduced in approximate proportion to reductions in the brownstock kappa number.
Declines in conventional pollutants such as BODS, COD, and color characteristics of MCC® pulps are also
well documented (Hermberger et aL, 1988).
Compatibility
When used in combination with oxygen delignification, extended delignification has produced softwood
pulps in the range of kappa number 6 to 10. These pulps are extremely bleachable and could be brought
to full brightness using elemental chlorine-free (ECF) or totally chlorine-free (TCP) sequences.2 Such
sequences are associated with extremely low levels of AOX and CDD/CDF, and will allow closure of
much of the mill's effluent cycle.
Extended delignification increases the amount of lignin and organic solids removed during the cooking
process, and it is beneficial for the mill to burn these in the recovery boiler. Many boilers currently
operate at or near capacity, thus it is often a challenge to find ways to accommodate the increase in solids
load. A range of options are available, however, for increasing solids handling by 5 to 10 percent, and
retrofits and rebuilds can boost capacity by significantly more at less than the $50 to $100 million cost
of a new recovery boiler. Many mills already practice some of these techniques:
Additional evaporator - Additional evaporation stages will increase the concentration of the black
liquor, resulting in improved combustion (reduced gas flow) as well as lower sulfur emissions.
Although this is a common upgrade option, the higher consistency solids are more difficult to
handle and will necessitate improved pumping and firing equipment;
Transport black liquor solids orfsite for disposal - Where other kraft mills with excess recovery
boiler capacity are within 500 miles of the mill, it may be feasible to ship additional solids off site
for firing. This has become common practice in some areas of North America and Europe;
Reduce boiler load per ton of solids - Although boiler load is discussed in terms of pounds of
solids burned, in practice the capacity ultimately depends on the heat content of the black liquor
solids;
2 ECF pulps are produced using 100 percent cMorine dioxide substitution for chlorine; no elemental
chlorine or hypocMorite are used. In TCP sequences, chlorine dioxide is also eliminated. Note that no
bleached kraft mills in the U.S. are currently producing high brightness TCP pulps on a sustained basis.
Louisiana-Pacific Corp. has agreed to eliminate chlorine-based bleaching at its Samoa, California kraft
mill by 1995 (UNA, 1992), although as indicated in a company statement some brightness may be
sacrificed: "Our expectation is that in the interest of a cleaner environment, consumers will accept paper
products that are not quite as bright as they are accustomed to using."
Page 4-8
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Pollution Prevention in Pulp & Paper
(1) In at least one Swedish mill, black liquor oxidation has been used to reduce heat value
of liquor solids sufficiently to accommodate an 8 to 10 percent increase in capacity;
(2) Mills can separate soap from the liquor solids for incineration or sale offsite. Soap
removal can reduce the heat value of the liquor solids by 4 to 8 percent, thereby enabling
further capacity increases;
Increase black liquor storage capacity - Some mills may lack sufficient black liquor storage
capacity, resulting in insufficient supply to keep the boiler operating steadily at capacity (essential
for efficient operation). By constructing additional supply capacity the mill may be able to obtain
a higher liquor solids throughput from the existing boiler;
Black liquor gasification - A relatively recent technology, this proprietary process involves
gasification of strong black liquor in a closed vessel. This produces a smelt similar to that from
a conventional recovery furnace. A single Chemrec® unit is capable of processing the excess
solids generated from oxygen delignification of 3,000 tpd of pulp;3
Anthraquinonc addition in pulping - The use of an anthraquinone catalyst in the digester can
increase the yield from kraft pulping by up to 2.5 percent (see Section 4.4) and decrease the
production of black liquor solids by up to 6 to 10 percent;
Reduce boiler water feed temperature and/or temperature of combustion air - If steaming
rate is the limiting factor on boiler capacity, these actions can reduce the steaming rate by several
percent;
Enrich combustion air with oxygen - For mills limited by gas flow, it may be possible to boost
boiler load capacity by introducing oxygen into the feed air;
Add incremental boiler capacity - Clement (1992) has presented case studies that illustrate a
variety of options for increasing boiler capacity incrementally. In the four U.S. projects cited,
capacity increases ranged from 10 to 63 percent. The costs have ranged from $3 to $63 million;
Boiler rebuild/replacement - Recovery boilers are among the most complex and expensive pieces
of equipment at the pulp mill. The costs of constructing a new boiler could range from $50
to 100 million. While this may seem exceedingly costly, for an older mill a modem boiler will
bring substantial additional benefits in the form of greater efficiency, easier maintenance, and
reduced air pollution;
Production penalty - Mills may choose to decrease production to accommodate the additional
solids per ton of pulp that results from oxygen or extended delignification. This operational
penalty, however, is generally considered excessive.
In addition, it is always possible for the mill to discharge the effluent containing any additional (non-
chlorinated) solids that cannot be accommodated in the recovery boiler. These will be treated in the
existing wastewater treatment system.
3 The Chemrec® process is offered by the Swedish company Gotavarken (U.S. subsidiary located in
Charlotte, North Carolina).
Page 4-9
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Pollution Prevention in Pulp & Paper
The kraft liquor recovery system produces air emissions (from the recovery furnace) and solid wastes such
as dregs (from the dregs washer) and grits (from the,.lime slaker). The modern recovery furnace is
equipped with sophisticated Mr emissions control equipment such as electrostatic precipitation (ESP).
Precipitates (primarily sodium sulfate and sodium carbonate) are returned to the liquor makeup system,
hence the only material losses are the dregs and grits. These are usually landfflled. A higher degree of
deligniflcation would probably result in a minor (i.e., less than 5 percent) increase in the quantity of these
materials going to landfill.
Extended delignifieation will cause an increase in steam demand (die to the longer cooking period),
though more energy will be recovered from the additional lignin solids. The greatest energy impacts may
be observed indirectly though, through reductions in bleaching chemical demands. Most bleaching agents
are manufactured by applying energy to raw inorganic minerals (e.g., chloride, for the manufacture of
sodium chlorate, caustic, and chlorine). McCubbin (1992) has modeled the onsite and offsite energy
impacts of a variety of pollution prevention measures. Conversion of a model 1,000 tpd CDEDED mill
to extended deligniflcation would result in no net increase in onsite power requirements but would reduce
of&ite power requirements (through decreased chemical use) by 3.4 MW (or around 800 KWh/ton).
4.2 OXYGEN DELIGNIFICATION
What it is
Installation of an oxygen reaction tower between the pulping and bleaching stages. Oxygen (a powerful
bleaching agent) is mixed with the pulp and allowed to react. Lignin content in the pulp is further
reduced prior to the bleaching stages, leading to decreased bleaching chemical demands and associated
environmental impacts.
How it works
The brownstock pulp from the digester is first washed and then mixed with oxygen as it enters the reactor
(see Figure 4-3), In high consistency systems, a press is required to remove excess water from the pulp
prior to reaction. In the reactor, the pulp undergoes oxidative delignifieation. The pulp is then washed
again to remove dissolved lignin solids before proceeding to the bleaching line. Oxygen systems are
available from all of the major pulp equipment vendors,
Installations
Until recently, oxygen delignifieation had been more widely adopted outside of North America. In recent
years the adoption rate within the U.S. and Canadian industries has increased. Presently, there are close
to 150 mills worldwide that operate oxygen delignifieation systems, representing 26 million tons of annual
production. Oxygen is currently installed or planned for 27 U.S. mills (see Table 4-2). Of these, 16 will
have come online since 1989 only. U.S. capacity is currently around 8.1 million tons per year.
Page 4-10
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Pollution Prevention in Pulp & Paper
Post Oxygen
Washer
Figure 4-3. Process flow for high-consistency (HC) oxygen delignification.
Source: Miller, 1992,
Page 4-11
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Pollution Prevention in Pulp & Paper
TABLE 4-2
U.S. Installations of Oxygen Delignification Systems
Company Name
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
27
Chesapeake
Weyerhaeuser
Union Camp
Union Camp
Consolidated Paper
Champion International
Champion International
Flambeau Paper
Bowater Corp,
Louisiana-Pacific
Willamette Industries
Champion International
Wausau Paper
Westvaco
Weyerhaeuser
Alabama Pine
Champion International
Confidential client
Simpson Paper
Union Camp
Weyerhaeuser
Weyerhaeuser
Champion International
Champion International
Champion International
Potiatch Corp.
Union Camp
Location of Mil
W. Point, VA
Oglethorpe, GA
Franklin, VA
Eastover, SC
Wisconsin Rapids, WI
Pensacola, PL
Pensacola, PL
Park Falls, WI
Calhoun, TN
Samoa, CA
Bemettsville, SC
Quinnesec, MI
Brokaw, WI
Covington, VA
Columbus, MS
Clairbome, AL
Courfland, AL
Southern U.S.
Eureka, CA
Eastover, SC
Cosmopolis, WA
New Bern, NC
Canton, NC
Canton, NC
Courfland, AL
Lewiston, ID
Franklin, VA
Production
Capacity
(tpd)
550
1,000
800
650
500
800
600
200
1,300
750
840
1,150
290
915
1,400
1,415
1,150
l;385
850
1,100
540
1,080
660
700
1,245
1,130
900
Consist-
ency [a]
HC
HC
HC
HC
MC
MC
MC
MC
MC
MC
MC
MC '
: MC
MC
MC
MC
MC
MC
MC
HC
MC
MC
MC
MC
MC
HC
HC
Year of
Startup
1972
1980
1981
1984
1985
1986
1987
1987
1988
1988
1988
1989
1989
1990
1990
1991
1991
1991
1991
1991
1991
1991
1992
1992
1992
1992
1992
Total capacity 23,900
[a] HC s= High consistency, MC = Medium consistency
Source: Johnson (1992).
Page 4-12
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Pollution Prevention in Pulp & Paper
Economics
The capital costs of the oxygen reaction tower and related equipment (pumps, washers) have been
estimated at between $8 and $16 million (see Table 4-3). At the low end of this range, the savings in
chemical costs, plus savings on current or future effluent treatment requirements, may favor the switch
to oxygen. Installation of an oxygen delignification stage may also help mills avoid the costs of installing
a new chlorine dioxide generating system or replacing an aging C-stage in their bleaching line. At other
mills considerably greater investment may be required, particularly to upgrade pulp washing equipment.
Successful implementation of oxygen delignification requires effective pulp washing both in front of and
following the oxygen stage. For mills that require a considerable upgrade in pulp washing equipment, the
cost of conversion may be closer to $15 million.
Most mills today using oxygen for bleaching will generate it onsite using non-cryogenic systems provided
by equipment vendors. Typically, the mill enters into a 10- to 20-year "over the fence" supply contract
with the vendor. The mill supplies the land for construction of the plant, while the vendor installs the
equipment and in some cases operates the plant as well. The technologies for onsite generation are much
smaller in scale and produce slightly lower purity oxygen compared to cryogenic methods, although this
does not appear to affect pulp properties or mill operations to any significant degree. Advances in
pressure swing adsorption (PSA) and vacuum swing adsorption (VSA) technologies have enhanced the
attractiveness of onsite generation.
In one comparison, capital costs for a PSA oxygen system ranged from $220,000 to $525,000 and
produced oxygen at a cost of $50 to $75 per ton. This compares to prices of $100 per ton for liquid
oxygen (Bansal, 1987). Onsite oxygen plants are available from numerous industrial gas vendors such
as Liquid Air, Air Products, Airco, and Union Carbide.
Pollution prevention
Since effluent from the oxygen stage can be recycled to the raill's recovery system, oxygen delignification
will reduce discharges of pollutants such as BOD5) color, and organochlorines. Table 4-4 shows BOD5
declining by approximately 32 percent, GOD by 43 percent, and TOC1 by 50 percent following installation
of an oxygen stage. Oxygen and extended delignification can also reduce the overall wastewater flows
from the mill by up to 25 percent each, putting it on the track towards zero effluent pulping and chlorine-
free bleaching.
Compatibility
Oxygen delignification is compatible with most conventional bleaching sequences. In addition, since
oxygen delignification has the potential to lower the pre-bleach stage kappa number by as much as 50
percent, a variety of innovative bleaching methods may also be applied. In atypical application, the mill
follows the oxygen stage with a mixture of chlorine and chlorine dioxide, followed by a caustic extraction
stage, another C1O2 bleaching and extraction stage, and a final bleaching stage, i.e. OCpEDED. A
significant benefit of oxygen delignification is that it allows the mill to increase the substitution rate of
chlorine dioxide for chlorine in the CD stage without requiring additional chlorine dioxide generating
capacity. A typical mill-currently operating at 30 percent C102 substitution, for example, could operate
at 70 percent by increasing its dioxide generating capacity, or by adding an oxygen delignification stage
and using existing dioxide capacity at 70 percent. Drawing from a database of actual installations,
Page 4-13
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Pollution Prevention in Pulp & Paper
TABLE 4-3
Capital Cost Estimates for Oxygen Delignification Systems
Information
Source
Literature
Supplier
Consultant
EPA (1990)
Idner (1988)
Description
Short sequence
OD system
OD
OD
MC
Hardwood MC
Softwood HC
Louisiana-Pacific,
Samoa, CA, MC
Simpson Paper,
Fairhaven, CA, MC
Weyerhaeuser
Cosmopolis, WA, MC
Softwood HC, Sweden
Softwood, MC
Sweden
Hardwood, HC
Sweden
Hardwood, MC
Sweden
Size
500 Ipd
500 tpd
1000 Ipd
1000 tpd
n»a.
n.a.
680 tpd
600 tpd
400 Ipd
n.a.
n.a.
n.a.
n.a.
Capital Cost (Smillions)
$8.8
$9-11
$14-16
$13-16
$13,5
$19.5
$8.0
$11.5
$9,5
$11-14,5
$6.5-$8.1
$11-14.5
$6.5-$8.1
MC = medium consistency oxygen
HC = high consistency oxygen
Sources: As indicated in table.
Page 4-14
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Pollution Prevention in Pulp & Paper
TABLE 4-4
Pollutant Impacts of Oxygen Delignification
Versos Conventional Bleaching
Parameter
Kappa no.
BOD7, kg/mt
COD, kg/mt
TOC1, kg/mt
Reduction in acute
toxicity to fish, % of
reference
Softwood (Pine)
Conven
-tional
32
14
80
5 to 5,5
'
HC
18
10.5
50
3 to 3.5
50 to 60
MC
15
95
45
2.5 to 3
60 to 70
Hardwood (Birch)
Conven
-tional
20
14.5
50
2 to 2.5
..
HC
14
11,5
40
1.5 to 2
n.a.
MC
12
10
35
1.5
n.a.
n,a. = not available.
HC = high consistency oxygen
MG = medium consistency oxygen
Source: Idner (1988).
Page 4-15
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Pollution Prevention in Pulp & Paper
Brunner and Pulliam (1992) have recently presented data for a model 1,000 tpd mill that indicated the
latter option results in both lower capital and operating costs.
Other options include "short sequence" bleaching, in which oxygen delignification is followed by two
rather than three bleaching stages (i.e., OCoED or ODEOPD). While short sequence bleaching has the
benefits of lower capital costs and reduced effluent flow, its feasibility for an individual mill will depend
on the pulp quality requirements, including the target brightness level With fewer bleaching stages there
is less opportunity for "fine tuning" the pulp characteristics and probably more variability in pulp quality.
Integrated mills are more likely to consider short-sequence bleaching than market pulp producers.
Finally, when combined with extended delignification, mills may be able to produce oxygen delignified
pulps with kappa numbers below 8 to 10 and without loss of strength or yield. These pulps are extremely
bleachable and may be bleached to 80+ brightness using small amounts of chlorine dioxide (ECF
bleaching), to 70+ percent ISO using one or more peroxide-based stages (e.g., the Lignox process), or to
85+ with ozone and peroxide (OZEP).
As with extended cooking, the addition of an oxygen stage increases the amount of recovered black liquor
solids available for heat recovery. The recovery of 80 percent of the oxygen stage solids will generally
increase the solids going to the boiler by 50 to 55 kg per metric ton (approximately 3 percent) for
hardwoods and by 30 to 35 kg per metric ton (approximately 2 percent) for softwoods. Additional post-
oxygen washing stages can increase this further still. At older mills where pre-chlorination washing is
currently inefficient, the increase could be as much as 10 percent Section 4.1 discusses a range of options
a mill might take to accommodate demands for additional boiler capacity created by oxygen bleaching.
43 OZONE DELIGNIFICATION
What it is
Installation of an ozone reactor between the pulping and bleaching stages, and normally following an
oxygen stage. Ozone (an extremely powerful bleaching agent) is mixed with the pulp which undergoes
a rapid exothermic reaction, Ligrtin content in the pulp is greatly reduced, Since mis occurs prior to any
chlorine-based bleaching stages, dramatic decreases in bleaching chemical demands and associated
environmental impacts can result.
•How it works
Ozone deligniflcation is performed using techniques and equipment similar to that used in oxygen
delignifleation (see Figure 4-4). Peak ozone delignification efficiency has been found to occur at low pH,
thus pulp is normally pretreated with sulftaic acid prior to ozonation. As with oxygen, both medium and
high consistency systems are available. The acidified pulp is fluffed and deposited in me ozone reactor.
Ozone gas generated onsite is delivered to the pulp in an oxygen carrier gas. During reaction, the ozone
is consumed and the carrier gas is recovered and either returned to the ozone generator or used elsewhere
in. the mill.
Page 4-16
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Pollution Prevention in Pulp & Paper
Press
Pulp at 4%
Consistency
Flutter
Discharger
Dilution
Diluted Stock
Out
Figure 4-4. Equipment for Mgji-consistency (HC) ozone delignificatian.
Source: Miller, 1992.
Page 4-17
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Pollution Prevention in Pulp & Paper
Until recently, the use of ozone in pulp bleaching was limited because of the detrimental effects it can
have on pulp quality and strength properties. The successful "taming" of ozone has been greatly
anticipated, however, since it opens the door to elimination of chlorine compounds in bleaching and raises
the possibility of complete closure of the mill's bleach plant. As a result of a considerable research effort,
the past year has seen the startup of the first two full-scale mills (1,000 tpd or more) operating ozone
bleaching lines. Ozone bleaching equipment is now being offered by the following suppliers:
Ozone Generating Equipment Qnsite/Over-the-Ftence gupply
Ozonia Liquid Air
Emery-Trailgaz Air Products
Capital Controls Praxair (formerly Linde)
Sumitumo MG Industries
Ozone generation requires large amounts of power, about 8 kWh per kilogram of ozone.4 The ozone is
most commonly generated from oxygen using the corona discharge method. This technology consists of
a series of tubes through which the feed oxygen or air flows. As high voltage is applied across the
discharge gap, free electrons in the corona collide with the diatomic oxygen and cause disassociation of
the O2 molecules, which recombine to form ozone. Ozone is unstable with a half life of only 15 minutes
and will decompose to regular oxygen, thus ozone must be generated onsite and fed immediately to the
pulp reactor.
Installations
Table 4-5 shows the chronology of ozone pilot plant and full-scale installations worldwide. Early work
was done at the Scott Paper mill in Muskegon, Michigan and (hen at Longview Fiber in Washington state.
PAPRICAN was also involved in early research work at their Pointe Claire, Quebec headquarters. In
1989, Union Camp (Wayne, New Jersey) installed a pilot plant at its mill in Eastover, SC, This $6
million experimental project has provided promising results over a four-year period. Based on their pilot
experiences, the company just recently (September 1992) completed the startup of a full-scale ozone
bleaching line at its 1,000 tpd mill in Franklin, Virginia -- the first in the world to operate at that scale.
The mill uses oxygen, ozone, and chlorine dioxide to produce elemental chlorine-free (ECF) pulp from
southern pine. All of the pulp will be used for onsite production of bleached uncoated free sheet and
coated and uncoated bleached board. Target brightness is 83 to 85 GE, and the bleaching sequence is
OZE0D.
Other commercial-scale ozone projects are now in the startup or planning stages:
• The MOnsteras mill in Sweden started up a 1,000 tpd medium consistency ozone bleach
line at approximately the same time as Union Camp's startup. The mill is reported to be
using 30 kilos of peroxide per ton of pulp to produce totally chlorine-free market pulp
(TCF) at 88 to 89 ISO brightness for sale in Germany;
« The Lenzing mill in Austria has installed medium consistency ozone in an EOPZP
configuration at its 100 tpd dissolving pulp mill. The mill is reportedly converting a
separate 300 qsd line at this time;
4 Note that chlorine dioxide generation requires approximately the same amount of energy as ozone,
but that ozone is twice as powerful a bleaching agent.
Page 4-18
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Pollution Prevention in Pulp & Paper
TABLE 4-5
Ozone Pilot and Full-Scale Hants Worldwide
Year
1971
1973
1975
1976
1982
1982
1988
1989
1990
1990
1991
1991
1991
1991
1991
1992
1992
1992
Location
PAPRICAN
Scott Paper
PAPWCAN
CTP
Myrens Verksted
Weyerhaueser
PWA
Union Camp
Wagner-Biro AO
Kraftanlagen
Heidelberg
Lenzing AQ
OZF
E.B. Eddy Forest
Products
PAPRICAN
CTP
Lenzing AO*
Union Camp*
Sodra*
Points Claire, Quebec
Musckegon, MI
Points Claire, Quebec
Grenoble, France
Hofmen-Hellefos, Norway
Longview, WA
Stockstadt, Germany
Eastavei, SC
Graz, Austria
Beienfurt, Germany
Lenzing, Austria
Gratkorn, Austria
Espanola, Ontario
Pointe Claire, Quebec
Grenoble, France
Lenzing, Austria
Franklin, VA
Monsteras, Sweden
Capacity
(tpd)
10
15
10
0.5
5
20
3
25
1
5
100
15
5
5
3
400
•1000
1000
Consist-
ency
HC
HC
HC
HC
HC
LC
HC
HC
LC
HC
MC
LC/HC
LOMC/
HC
MC
MC/HC
MC
HC
MC
Bleaching sequences
Z, (PZ)
z
2
Z
Z
OZD, OZDED
Z
OZEDED
OZP
OZEP
(EOP)ZP
any sequence
0(Z)...
OZEP, OZED
O(pZE)P
(EOP)ZP
OZBoD
OZBoP (potential)
OZEP
Pulp type
Mechanical
Hardwood kralt
Sulfite, kraft
Mechanical
Mechanical, snlfite
Softwood kraft
Sulfite
Kraft
Suffite, kraft,
nonwood fiber
Mg bisulfite
Hardwood,
dissolving
Kraft, sulfite
Softwood kraft,
hardwood kraft
All types
All types
Hardwood,
dissolving
Kraft, integrated
Market kraft,
HW/SW (HW only
"so far)
... Represents any subsequent sequences
* Commercial installation.
LC = low consistency ozone
MC = medium consistency ozone
HC = high consistency ozone
Source: Liebergott et al. (1992),
Page 4-19
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Pollution Prevention in Pulp & Paper
• MoDo has purchased an ozone system from Kainyr for installation at their mill at Husum,
Sweden;
• SCA Wifsta-Ostrand in Sweden has entered into an agreement to produce pulp at their
Timra kraft mill using ozone technology licensed from Union Camp;
• The E.B. Eddy mill in Espanola, Ontario is considering installation of a full-scale ozone
plant following successful operation of their pilot plant.
Union Camp has formed a worldwide marketing alliance with Sunds Defibrator of Sweden to license its
ozone bleaching technology in the pulp and paper industry under the name C-Free™. The technology is
based on use of oxygen delignification, gas phase ozone, and a small amount of chlorine dioxide, which
enables the licensee to produce ECF pulp at full market brightness.
Economics
Capital costs for the ozone delignification equipment will depend on type of system selected (i.e., high
or medium consistency); Mills using ozone as a "bulk delignification" stage, that is, as the primary
delignifying agent, may choose high consistency due to the decreased ozone consumption per ton of pulp.
Others using ozone as a "polishing stage" for pulp brightening may favor medium consistency.
In comparison with chlorination stage bleaching, ozone requires additional process equipment (pulp press,
high shear mixers, acid handling system) but benefits from the ability to use cheaper construction materials
(corrosion problems are less severe compared to chlorine bleaching). Depending on how close the mill
comes to closing its effluent cycle and whether it maintains one or more D stages, there should be reduced
costs for effluent treatment and bleach plant scrubbing systems. The final cost for the Franklin mill
installation has been recently cited as $113 million for a full 1,000 tpd bleach plant.
Bleaching costs, including ozone generation, are lower than for conventional sequences. Union Camp
reports that bleaching costs at their Franklin mill are approximately 68 and 43 percent lower man the costs
of a modern mill's DEDED sequence running at 100 percent chlorine dioxide substitution (see Table 4-6).
Union Camp's decision to retain a chlorine dioxide stage was based on the expectation that elimination
of elemental chlorine would be sufficient to guarantee satisfactory effluent levels. The use of ozone in
the bleach line, however, introduces the possibility of eliminating all chlorine-containing compounds to
produce totally cMorine-free (TCP) pulp. Hydrogen peroxide would be used as a replacement for chlorine
dioxide in a TCP sequence. The company estimates that replacing C102 with peroxide would raise
operating costs back to the level of a CEDED sequence if 90 brightness were required (peroxide costs
would be around $30 to 40 per ton). Lower brightness TCP pulps (low 80s ISO) could be produced at
significantly lower costs (under $10 per ton premium) if there was greater market acceptance.
Since either oxygen delignification or extended cooking (or both) are considered prerequisites for
successful ozone bleaching, the more widespread adoption of these technologies will undoubtedly increase
interest in ozone. Also, ozone's cost vis-a-vis conventional bleaching sequences has improved as it is now
more likely to replace more expensive chlorine dioxide rather than less expensive chlorine.
Page 4-20
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Pollution Prevention in Pulp & Paper
TABLE 4-6
Bleaching Chemical Costs of Ozone Versus Conventional Sequences
at Union Camp's Franklin, Virginia Mill
Sequence
C-E-D-E-D
O-Z-E-D
Relative Costs
Pine
100
48
Hardwood
100
83
ID-E-D-B-D
O-D-E-D
O-Z-E-D
100
56
32
100
73
57
Note: Bleaching chemical costs of ozone-based sequences are shown relative to those of
conventional sequences (costs equal to 100 for the conventional processes).
Assumptions for costing purposes are shown below.
Source; Nutt et at (1992),
ASSUMPTIONS
Chlorine $153.00 per ton
Chlorine Dioxide $0,32 per Ib
Oxygen $53,00 per ton
Magnesium sulfate $485.00 per ton
Caustic co-purchased with chlorine on ECU basis $215.00 per ton
Caustic purchased independent of chlorine $340,00 per ton
Includes byproduct saltcake credit
Used for CEDED requirements and used for Vi of
O(DC)ED requirements
Used for OZED requirements and used for Vi of
O(DC)BD requirements
Cost of preparing oxidized white liquor
Sulfuric acid
Chelant
Ozone
$29,00 per ton as
NaOH
$68.00 per ton
$0.51 per ib
$0.29 per Ib
Based on power costs of $36/MwH and
Camp's design of a recirculatmg ozone
system
Union
generation
Page 4-21
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Pollution Prevention in Pulp & Paper
Pollution prevention
Due to its powerful bleaching effect, ozone has the potential to replace most if not all of the chlorine-
based bleaching agents used in conventional pulp bleaching. At Union Camp, the bleaching sequence has
been simplified to OZED, eliminating all elemental chlorine and retaining just one stage of chlorine
dioxide bleaching. Emissions from the process are extremely low because of the ability to recycle all of
the O, Z, and E stage effluents (see Table 4-7). Total organic halides (TOX) are below 0.1 kg per adt
in effluent, chloroform is a very low 0.0015 kg per adt, BOD is below 2, COD is below 6, and color is
below 1.5 (traditional color levels are around 100 to 300 kg per ton). The mill has been unable to detect
dioxins using the most sensitive testing methods available, even after boosting chlorine dioxide
consumption in the final stage
Among the numerous bleaching sequences being investigated that make use of ozone are: OZEP, OZED,
OZPY, OZEPY, ZOsyPY, and OZEjjPY. (Note: Om refers to an oxygen stage using a wash of ozone
stage effluent and Y is sodium hydrosulfite.) The absence of elemental chlorine in these sequences and
the elimination of all chlorine-based compounds in some indicates that effluents from future mills using
ozone will be extremely low in pollutants of current concern.
Compatibility
One concern raised by some in the industry is that ozone-bleached pulps tend to be of lower strength and
hence lower quality than those produced by conventional bleaching processes. Most of these concerns
center around observed decreases in the viscosity of pulps bleached using ozone. Viscosity has
traditionally been used as an indicator of pulp strength, and ozone-bleached pulps have in fact been found
to have lower viscosities than conventionally-bleached pulps of similar kappa number. However,
numerous researchers have found that the viscosity-strength relationship is different for non-conventionally
bleached pulps, so that despite the lower viscosities ozone bleaching does not impair pulp strength
properties. . • •
It should be noted that ozone is a toxic gas that must be handled properly. Ozone generators are equipped
with sensors that will shut off power to the unit if any leaks are detected. Ozone production stops as soon
as the power is cut. Under pressure, ozone may also present explosion hazards. For this reason, high
consistency systems that operate at or near atmospheric pressures may be considered safer than medium
consistency systems that operate under pressure.
One distinct safety advantage of ozone over chlorine is that the ozone is generated onsite. Chlorine is
generally shipped to the mill in 100-ton tanker cars; this gas must then be transferred and stored onsite.
Since ozone is produced on demand there is no onsite storage, hence only the small quantities contained
in the pipeline (several kilograms) would pose a danger.
Page 4-22
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Pollution Prevention in Pulp £ Paper
TABLE 4-7
Emissions from Ozone Bleach Line at Union Camp's
Franklin, VA Mill w
Parameter
TOX, kg/ADT Pulp
Effluent
Chloroform, kg/ADT
BOD5_ kg/ADT
COD, kg/ADT
Color, kg/ADT
Effluent Volume m3/ADT
gal/ADT
Pine
0.04
0.075
0.0015
2,0
6.0
1.5
7.5
1,800
Hardwood
0.03
0.06
0.0015
1.0
2.0
0.5
7.5
1,800
w Running an OZED bleaching sequence to produce 83 brightness pulp.
Source: Nutt et al. (1992).
Page 4-23
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Pollution Prevention in Pulp & Paper
4.4 ANTHRAQUINONE CATALYSIS
What it is
Small amounts of anthraquinone (AQ) added during pulping will act as a catalyst to speed up the cooking
process and increase pulp yield. Alternatively, the technique can be used to reduce the amount of lignin
solids generated per ton of pulp, thereby facilitating adoption of extended cooking or oxygen
delignification.
How it works
The AQ is added to pulp during cooking using an application rate of around 0.05 to 0,1 percent on
cooking liquor. The AQ catalyzes or accelerates the fragmentation of lignin, rendering it more vulnerable
to attack and dissolution by the cooking chemicals.
Installations
AQ pulping is used in an estimated 60 percent of Japanese mills to improve yield from what are relatively
expensive wood sources, and in at least two mills in Canada. The trade journal Paper Age has reported
that over 100 mills worldwide use anmraquinone. There is reported to be increasing interest in AQ as
a means of achieving extended delignification and overcoming boiler capacity bottlenecks.
Economics
By increasing yield or reducing chemical requirements, anthraquinohe catalysis offers a potential means
to offset the tendency of oxygen delignification or extended delignification to overload the kraft recovery
system. It has been estimated that AQ could compensate for an increase in chemical recovery load of
up to 7 or 8 percent. An AQ charge of 0,04 percent on wood in a 1,000 adt per day mill would have the
following effects: (1) raise yield by 0.75 percent (or an additional 7.5 tons per day); (2) increase net costs
by $5,262 per day or $5.15 per adt; and (3) reduce boiler load 4.6 percent. In some mills, a 4 to 5 percent
reduction in boiler load will be sufficient to enable the mill to accommodate the additional solids load that
results from oxygen delignification. The additional cost of AQ would, of course, offset the cost savings
that would otherwise result from using oxygen.
Pollution prevention
Anthraquinone addition has the potential to alternatively decrease bleaching chemical requirements or
facilitate adoption of oxygen delignification. In either role, anthraquinone will have a positive (i.e.,
beneficial) impact on the formation and release of chlorinated organics. By producing brownstock pulp
with lower lignin content, the mill can decrease overall bleaching chemical requirements. And by
improving the feasibility of oxygen delignification, the mill can recycle additional effluent as well as cut
back on bleaching chemical usage. As with other delignification modifications mat lower the pre-
ddorination kappa number, chlorinated organics formation should decrease in approximate proportion to
the drop in lignin content.
Page 4-24
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Pollution Prevention in Pulp & Paper
Compatibility
Most of the reacted AQ is removed with the spent liquor and presents no difficulties in the recovery
system. AQ is not detectable in pulps subject to further chemical bleaching.
Anthraquinone is produced from coal tar generated in the coking process at steel mills. The chemical is
used in several industries, including textiles where it serves as an intermediary in dyestuff manufacture.
No negative environmental effects are known.
45 BLACK LIQUOR SPILL CONTROL AND PREVENTION
What it is
Accidental losses of black liquor may occasionally occur due to equipment failure, design flaws, or human
error. Losses can result from overflows or leaks from process equipment (spills), or as a consequence of
deliberate operator action (dumps) taken to avoid much more serious consequences. Equipment
modifications can result in fewer spills or mitigate spill impacts, while spill prevention programs can
potentially have even greater impacts.
How it works
Where no spill recovery system is in place, losses of black liquor will flow through the sewer to the
wastewater treatment system. Depending on the volume of the spill, the Mgh level of BOD and COD in
the black liquor can shock the microbial action of the system, throwing it off balance and degrading the
quality of treated effluent. Production interruptions may be necessary to allow time for the treatment
system to return to equilibrium.
Effective loss control is achieved through good design, engineering, and operator training. Design changes
that can be implemented include: 1) physical isolation of individual pieces of equipment so that spills can
be collected and recovered, 2) modifications to the general floor drainage system so that spills are
collected and returned to the recovery system, 3) provision of additional backup storage capacity, 4)
sensors and other systems that provide immediate warning of potential or actual spill conditions, and 5)
replacement of open-stage washing and/or screening equipment with closed equipment.
An effective spill control system design is shown in Figure 4-5. The system would include conductivity
and pH probes in the process sewer to detect and identify the spill. Once detected and identified, the spill
can be diverted to either a spill lagoon (in the case of weak spills that would not overload the treatment
plant) or to a spill tank, where the spill would be held until it could be reintroduced into the recovery
system.
Operator training and awareness is equally important to prevention. Control of spills requires an
appreciation of the overall process, knowledge about locations where spills are likely to occur, and an
understanding that spill control and environmental protection is part of every employee's job.
Page 4-25
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Pollution Prevention in Pulp & Paper
Detection and
Concentrated
Spill
Spill
Tank
Weak
Spill
Normal Conditions
Weak Black
Liquor Storage
Spill
Lagoon
As Effluent: Treatment
Facility Loadings Allow
Effluent Treatment
Figure 4-5. Spill control system flow design.
Source: E
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Pollution Prevention in Pulp & Paper
Installations
Improved spill control is recognized as an essential element in the overall environmental control of a
modern pulp and paper mill. Newer mills are likely to have advanced spill warning and control systems
designed into the plant from the start, and to use newer equipment design that is less prone to spillage.
In an older mill, the retrofitting of floor drains and other spill collection systems can be quite difficult and
very expensive, but some degree of improvement over the practices of the 1960s is generally possible.
Instrumentation to warn of spills and facilitate rapid implementation of corrective measures can normally
be retrofitted relatively easily.
Economics
Costs for improving spill control are quite site-specific, as they depend more on the physical layout of the
plant than on the particular process in use. Capital costs are more likely to be in the range of hundreds
of thousands rattier than millions of dollars, while operating costs are low and will be partially or totally
offset by recovered chemical and/or heat value, provided the spill is routed to the recovery cycle.
Pollution prevention
Raw black liquor contains high levels of BOD, COD, as well as some persistent non-chlorinated organics,
As increased recycling of mill effluents is achieved through use of extended delignification and oxygen,
spills will account for an increasing percentage of total mill effluent, and efforts to minimize or control
spills will become more important.
Compatibility
When spills are not recovered the heat and chemicals value of the black liquor solids is lost. A high loss
rate due to spills could result in a significant economic penalty in terms of lost heat and chemicals.
4.6 ENZYME TREATMENT OF PULP
What it is
Brownstock pulp is pretreated with cultured enzymes that catalyze the delignification reaction. This
reduces subsequent bleaching chemical demands and the associated environmental impacts.
How it works
Research in the field of biotechnology has isolated specific, naturally-occurring microorganisms that
produce enzymes capable of weakening the lignin bonds in pulp fibers, thereby providing a boost to
delignification. The enzymes of most interest in pulp bleaching are the xylanases, which are secreted by
wood-inhabiting microbes. Xylanases catalyze the hydrolysis of xylan, the main bonding agent between
Page 4-27
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Pollution Prevention in Pulp & Paper
lignin and cellulose. This action is believed to improve the accessibility of bleaching chemicals to the
pulp and enhance the extractability of the solubilized lignin,
Xylanase application in the mill has proven to be relatively simple. Conditions favorable for xylan
reaction with pulp include; pH between 4 and 6, temperatures of 40 °C to 55 °C, reaction times of between
30 and 180 minutes, and pulp consistency between 2.5 and 12 percent. These conditions can be easily
obtained by mixing sulftuic acid and xylanases with pulp coming off the brownstock washer as it enters
the high density storage chest, in effect using the brownstock storage as a reaction vessel.
Installations
Xylanases suitable for use in pulp bleaching are available from several biotechnology and chemical
concerns around the world, including: Genencor International, logen, Novo Nordisk, Sandoz, 1CI Canada,
and Voest-Alpine. Xylanase application rates are expressed in terms of International Units (TO) of
xylanase activity, as applied per ton of pulp. The commercial enzymes are prepared to deliver a specific
dose of Ill's per kilogram to enable application on about a 1 kg per ton of pulp basis.
The exact number of mills running enzyme trials or using enzymes for production quantities is not known
but it is believed that interest is high at this time. Given that the modifications necessary to accommodate
enzyme treatment are quite minor, observers believe there to be many mills carrying out their own trials.
According to a recent report, 10 mills were using enzymes in full scale commercial application and 85
mills were running trials (Juracek and Paice, 1992). Six of the 10 mills running full time were in Europe
and the other four were in Canada.
Economics
The equipment necessary to apply enzymes to pulp is quite modest' Costs for an enzyme delivery system
and pH adjustment are likely in the range of $10,000 to $100,000. The enzyme cost per ton of pulp is
variable and depends on the type, activity level, and recommended application rate for the enzymes. Costs
in the range of $5 to $10 per ton of pulp have been indicated by supplier firms. These costs will be
partially or completely offset by savings in chemical costs.
Pollution prevention
In mill trials, reductions in active chlorine requirements of between 15 and 50 percent are being reported.
Figure 4-6 shows the lower AOX levels associated with xylan-treated pulps versus control pulps in a 20
percent chlorine dioxide substitution bleaching sequence. Some improvement in brightness ceilings have
also been observed, as shown in Figure 4-7. The reduction hi demand for downstream bleaching
chemicals can be used by mills in a variety of situations, including boosting of brightness levels, higher
substitution of chlorine dioxide, or to facilitate production of totally chlorine-free pulp.
Compatibility
Xylanases appear to have no discernible impact on pulp quality or yield. Enzyme trials to date have been
found there to be no impacts on pulp quality, strength or other attributes.
Page 4-28
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Pollution Prevention in Pulp & Paper
% ISO brightness-91.0
Xylanase-pretreated
Figure 4-6, Impact of xylanase treatment on AOX.
Figure 4-7. Impact of xylanase treatment on brightness.
Source*. Senior and Hamilton, 1992.
Page 4-29
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Pollution Prevention in Pulp & Paper
So far, the potential for recycling enzymes has apparently not been investigated, Enzymes are washed
from the pulp and eventually are destroyed in the mill's normal recovery cycle. The development of a
method for recycling enzymes would greatly enhance their attractiveness. Likewise, developments that
would permit enzyme application under closer to normal brownstock pH and temperature conditions would
be welcome.
4.7 IMPROVED BROWNSTOCK WASHING
What it is
Upgrading of the pulp washing systems used to remove lignin solids dissolved during the pulping and
bleaching stages. Good pulp washing will reduce downstream bleaching chemical demands and is
essential for oxygen delignification and ozone.
How it works
Conventional pulp washers create a vacuum inside the drum to hold the fiber mat in place while it is
sprayed with wash water to displace dissolved solids. Normally, a series of three or four washers are
configured in series and operated in eountercurrent fashion.
Current state-of-the-art washing systems replace the vacuum pressure units with pressure, diffusion, or belt
washers, or with pulp presses. These systems are all capable of more effective solids removal from the
pulp.
The efficiency of brownstock washing is often measured in terms of the "sodium carryover" and is
indirectly measured as the amount of NajSC^ (saltcake) lost. Sodium losses that in the 1970s were
commonly in the range of 50 kg per ton have been reduced to 7 kg per ton in new, up-to-date pressure
washing systems.
Installations
The importance of efficient brownstock washing is now well-recognized throughout the North American
pulp and paper industry. The amount of upgrading taken place is difficult to estimate, however, since
improvements can he made through several means, including better utilization of existing equipment,
onsite refurbishment of old equipment, or replacement of equipment through new orders placed with
vendors. One industry observer contacted vendors and verified orders for 38 brownstoek washing systems
between January 1988 and mid-1991 (Pulliam, 1991). Others confirm through discussion with vendors
and paper companies that washing practices have been considerably upgraded in recent years.
Economics
Costs for improved washing could range from negligible in the case of relatively simple optimization of
existing equipment to close to $20 million for a completely upgraded system in a 1,000 tpd mill. A recent
Page 4-30
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Pollution Prevention in Pulp & Paper
case study evaluated modern washer systems from three established vendors and found that capital costs
for all three ranged from $10.2 to $12.3 million for a hypothetical mill (Ricketts, 1992).5 It should be
noted that these costs include costs of constructing an appropriately-sized building to house the equipment.
Depending on the circumstances, it may be possible to utilize existing space.
Major operational requirements for each system are shown in Table 4-8 and net incremental requirements
compared to the existing 25-year old system are converted to dollar values in Table 4-9. Each of the
newer systems will require less electric power and/or steam. The Chemi-Washer system was shown to
result in operating savings of $4,67 per ton, while the Compaction Baffle Filtration system saved $2.32
per ton and the Drum Displacer saved $2.13 per ton. Additional cost savings will result from reduced
bleaching chemicals requirements. These costs were not shown in the analysis because the hypothetical
mill produces unbleached linerboard.
Pollution prevention
Lignin solids travelling with the pulp will compete with pulp fibers for reaction in the bleaching stages,
leading to higher chemical consumption and increased formation of chlorinated organics. Improved pulp
washing will reduce the amount of organic lignin solids carried through to the bleaching stages and reduce
the formation of chlorinated organic compounds such as dioxin and furan. Improvements in conventional
pollutants such as BOD, COD, resin acids, and color can also be expected. Improved washing also
removes highly colored material and some of the persistent, non- biodegradable black liquor fraction which
would otherwise be discarded.
Compatibility
As with other processes that remove additional solids from the pulp, upgraded pulp washing tends to
increase the quantity of solids recovered from the condensed pulping effluent Recovery boilers must be
able to accommodate this increase in load to obtain maximum environmental and economic benefits.
5 The systems evaluated were: Black Clawson's Chemi-Washer, IMPCO's Compaction Baffle Filter,
and the Kamyr/Ahlstrom Drum Displacement Washer. Diffusion washers, which may be the best option
for a retrofit, were not considered in their analysis.
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Pollution Prevention in Pulp & Paper
TABLE 4-8
Major Operating Cost Items for Existing Washing Line
Versus Three Modern Alternatives - Hypothetical Mill Retrofit
Operating Cost Item
Connected horsepower, hp
Net steam savings, mlb/hr
Defoamer usage, Ib/odt
No, of pieces rotating equipment
(motor driven)
Washer facewire replacement
Existing
System
870
0
3.0
9
1 peryr
Chemi-
Washer
820
39.3
20
15
2 per yr
CB
Filters
910
12.6
1.0
13
none
Drum
Displacer
270
3.0
0.5
10
none
TABLE 4-9
Annual Incremental Operating Costs Saved for
Three Modern Alternative Washing Systems - Hypothetical Mill Retrofit
($000)
Incremental Cost Item
Power at $0.0525/kWhr
Steam at $3.50/1,000 Ib
Defoamer at $0.45/lb
Maintenance - labor and materials for
facewire change
Total annual savings
Savings per odt ($)
Chemi-
Washer,
$12
$1,555
$118
($60)
$1,225
$4.67
CB
Filters
($12)
$370
$236
$15
$609
$2.32
Drum
Displacer
$158
$88
$297
$15
$558
$2.13
Source: Ricketts (1992).
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Pollution Prevention in Pulp & Paper
SECTION FOUR REFERENCES
Bansal, 1987, Ravinder K. Bansal, "On-Site Pressure Swing Adsorption Systems for the Pulp and Paper
Industry," in Proceedings, 1987 TAPPI Oxygen Delignification Conference, p. 151.
BNA, 1992. Bureau of National Affairs. "Louisiana Pacific to Quit Bleaching Wood Pulp as Part of
EPA Settlement," California Environment Daily, October 2, 1992.
Brenner and Pulliam, 1992. Lee Brenner and Terry Pulliam. "A Comprehensive Impact Analysis of
Future Environmentally Driven Pulping and Bleaching Technologies," in Proceedings, 1992
TAPPI Pulping Conference, Boston, MA, November 1992.
Clement, 1992. John L. Clement. "Recovery Boiler Capability to Accommodate Alternative Kraft Mill
Processes," in Proceedings, International Symposium on Pollution Prevention in the Manufacture
of Pulp and Paper, August 18-20, 1992, Washington, DC. U.S. Environmental Protection
Agency, Office of Pollution Prevention and Toxics. EPA-744R-93-G02. February 1993.
Edde, 1984. Howard Edde. Environmental Control for Pulp and Paper Mills. Noyes Publications, Park
Ridge NJ.
Heimburger et al., 1988. Stanley A, Heimburger, Daniel S. Blevins, Joseph H. Bostwick, G. Paul
Donnini, "Kraft Mill Bleach Plant Effluents: Recent Developments Aimed at Decreasing Their
Environmental Impact, Part I," TAPPI Journal, October 1988, p, 51.
Idner, 1988. Kristina Idner. "Oxygen Bleaching of Kraft Pulp: High Consistency vs. Medium
Consistency," TAPPIJournal, February, 1988, p.47.
Johnson, 1992. Anthony Johnson. "Worldwide Survey of Oxygen Bleach Plants," in Proceedings.,
Nonchlorine Bleaching Conference, Hilton Head, SC March 1992. Available from Miller-Freeman
Publications, San Francisco.
Jurasek and Paiee, 1992. "Saving Bleaching Chemicals and Minimizing Pollution with Xylanase," in
Proceedings, International Symposium on Pollution Prevention in the Manufacture of Pulp and
Paper, August 18-20, 1992, Washington, DC. U.S. Environmental Protection Agency, Office of
Pollution Prevention and Toxics. EPA-744R-93-002. February 1993.
Liebergott et al., 1992. N. Liebergoott, B. van Lierop, A, Skothos. "The Use of Ozone in Bleaching
Pulps," in Proceedings, 1992 TAPPI Environmental Conference, Richmond VA, April 1992. Page
1105.
Macleod, 1992. Martin Macleod. "Extended Cooking in Kraft Mills: Science, Technology and
Installations Worldwide," in Proceedings, Non-Chlorine Bleaching Conference, Hilton Head, SC,
March 2-5, 1992. Available from Miller-Freman Publications, San Francisco.
Page 4-33
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Pollution Prevention in Pulp & Paper
SECTION FOUR REFERENCES
(cont.)
McCubbin, 1992. Neil McCubbin. "Costs and Benefits of Various Pollution Prevention Technologies
in the Kraft Pulp Industry," in Proceedings, International Symposium on Pollution Prevention
in the Manufacture of Pulp and Paper, August 18-20, 1992, Washington, DC. U.S.
Environmental Protection Agency, Office of Pollution Prevention and Toxics, BPA-744R-93-002.
February 1993.
Miller, 1992. Bill Miller. "Tutorial: Process Technology, Machinery, Advantages & Disadvantages,"
in Proceedings, Nonchlorine Bleaching Conference, Hilton Head SC, March 1992. Available from
Miller-Freeman Publications, San Francisco.
NuttetaL, 1992. Wells Nutt. "Development of an Ozone Bleaching Process," Proceedings, 1992 TAPPf
Pulping Conference, Boston, MA November 1992.
RJcketts, 1992, Drew Ricketts. "Three BSW Systems Studied to Find Best Fit for Mill Upgrade Project,"
Pulp and Paper, September 1991, p. 94.
Senior and Hamilton, 1992. "Biobleaching with Xylanases Brings Biotechnology to Reality," Pulp and
Paper, September 1992, p. 111.
U.S. EPA, 1990. Summary of Technologies for the Control and Reduction of Chlorinated Organicsjrom
the Bleached Chemical Pulping Subcategories of the Pulp and Paper Industry, U.S. Environmental
Protection Agency, Office of Water Regulations and Standards, Office of Water Enforcement and
Permits. April 27, 1990.
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Pollution Prevention in Pulp & Paper
SECTION FIVE
POLLUTION PREVENTION OPPORTUNITIES IN BLEACHING OPERATIONS
This section examines the major pollution prevention technologies that can be implemented in the
bleaching areas of the mill. The "bleaching areas" are defined according to the traditional
distinction as those stages that include and follow the first chlorination stage in a conventional
kraft mill. As discussed previously, however, with the advent of numerous pre-chlorination stages
and the replacement of chlorine-based chemicals, these distinctions are becoming blurred.
5.1 HIGH CHLORINE DIOXIDE SUBSTITUTION
What it is
High substitution is generally defined as the replacement of 70 percent or more of the elemental chlorine
(Clj) used in the first bleaching stage with equivalent amounts of chlorine dioxide (ClOa).1 At substitution
rates above 70 percent, chlorinated organics formation is very low.
How it works
Chlorine reactions with lignin fall into three categories: substitution, addition, and oxidation. The first
two reactions result in the formation of chlorinated organics. Oxidative reactions, meanwhile, generally
result in fragmentation of the lignin. Chlorine dioxide is more of an oxidative bleaching agent than
elemental chlorine. As a result, chlorine dioxide substitution increases the proportion of oxidative
reactions and reduces the formation of chlorinated organic compounds.
Because chlorine dioxide is unstable and cannot be shipped, it is generated onsite at the mill. The
principal feed material for chlorine dioxide is sodium chlorate (NaClO3), produced using electrolysis
technology similar to that used in chlor-alkali production. Onsite generators produce gaseous chlorine
dioxide by reducing sodium chlorate in the presence of a reducing agent. Table 5-1 summarizes most of
the various chlorine dioxide generating processes operated at North American pulp mills. A major
distinction between systems is the amount and type of byproducts produced, which can include C12,
* H2SO4> and NaCl.
Installations
Chlorine dioxide substitution was adopted rapidly as a proven method for reducing dioxin in bleaching
effluent Figure 5-1 below shows the trend in U.S. chlorate consumption between 1955 and 1987. Over
90 percent of U.S. demand for chlorate (the feedstock for chlorine dioxide production) is accounted for
1 Chlorine dioxide is a more powerful bleaching agent and replaces chlorine at a rate of 1:2.63 weight
basis (i.e., 1 kg C1O2 has the equivalent bleaching power of 2.63 kg CLj). In substituting chlorine dioxide
for chlorine, total bleaching chemical demand (in kg) decreases.
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Pollution Prevention in Pulp & Paper
TABLE 5-1
Summary of Chlorine Dioxide Generation Processes
Process
Mathieson
Solvay
R2
R3/SVP
R6/Lurgi/Chemeties/Vulcan
R8/SVP-MeOH/SVP-Lite
Reaction Equation
2NaClO, + SO2 + -HjSO4 ->
2C1O2 4 2NaHSO4
2NaClO3 + CH3OH + HjSO4 ->
2C1O2 + 2HjO + HCHO + NajSO4
NaClOj + NaCl + BjSO4 -*
C1O3 + Q.5C^ + NajSO4 + HjO
NaClOj + NaCl + H^SO, -»
ClOj + OJClj + NajSO, + HjO
l)NaCl + 3Hfl -> NaC103 + 3Hj
2)C12 + H2 -> 2HC1
3)NaClO,"+ 2HC1 ->
C1O2 + O.SClj NaCl + BO
SNaCIO, + 2CH3OH 4 fift,SG4 ->
9C102 + 3N%H(S04)2 + O.SC02 +
1.5HCOOH 4- 7HP
Redocing Agent
SOj
CHjOH
NaCl
NaCl
HC1
CH,OH
Byproducts
spent acid solution
spent acid solution
spent acid and
chlorine
saltcake and chlorine
none
acid saltcake
Source: Stockburger (1992).
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Pollution Prevention in Pulp & Paper
Figure 5-1
North American Consumption of Sodium Chlorate for Chemical Pulp Bleaching
1955 1960
Note: units arc thousand short tons.
1965
1970 1975 1980 1985 1990 1995
Sources: SRI (1989 and 1993); API (1992).
Page 5-3
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Pollution Prevention in Pulp & Paper
by the pulp and paper industry. By 1987, annual consumption had risen to 499,000 tons. Recent
estimates by the American Paper Institute pegged the 1989 level of consumption at 540,000 tons per year,
and projected growth to 900,000 tons per year by 1994 (API, 1992).
A recent report indicated that there are approximately 166 chlorine dioxide generators in North America,
representing installed capacity of 3,194 short tons/day (Britt, 1992; cited in Stockburger, 1992). Table
5-2 summarizes the number and type of generators installed. The modern methanol- based generating
systems (RS/SW-MeOH/SVP-Lite) account for 52 percent of the generators and 76 percent of installed
capacity.
According to market researchers Law, Sigurdson & Associates, most bleached kraft mills are currently
using their chlorine dioxide generators to practice 45 to 50 percent substitution. This percentage is likely
to increase to 60 to 65 percent in the future, depending upon the stringency of future environmental
regulations and the direction taken by the industry to meet them (Shapiro, 1992). Further increases win
require more generating capacity at most mills.
Economics
While most mills currently have chlorine dioxide generating capacity onsite, increasing production to
enable 700 percent plus substitution rates may be quite expensive. Estimates of capital costs for C1O2
generating systems range from $2.8 million for equipment only to $10 to $20 million for installed systems
with upgraded ancillary equipment
Two very recent studies have examined the economics of increased substitution and are worth noting:
» An analysis presented at the U.S. EPA's Symposium on Pollution Prevention in the Manufacture
of Pulp and Paper (McCubbin, 1992) compared the costs and environmental affects of alternative
upgrades to an existing 1,000 tpd model mill (see Table 5-3). One of the options considered was
to increase chlorine dioxide substitution from 11 percent to 50 and 100 percent. At 50 percent
substitution the mill would require an incremental capital investment of $5 million and increased
annual operating expenses of $1,9 million. This upgrade was assumed to be achieved by
expanding the capacity of the existing chlorine dioxide generator (approximately doubling
capacity). At this point the generator would be at its maximum capacity; further expansions
would require a new generator. An upgrade to 100 percent substitution would require a capital
investment of $15.9 million (for a new generator, among other things) and an increase in annual
operating costs of $7.1 million.
• A similar study by Brunner & Pulliam (1992) compared alternative bleaching technologies for a
greenfield mill. Their 1000 tpd model mill was assumed to be practicing 30 percent substitution
under the baseline scenario. Table 5-4 displays the incremental costs and environmental
improvements that would result by modifying the mill design to use 70 percent chlorine dioxide
substitution. No decline in pulp yield would result at 70 percent substitution (Le,, wood chip costs
would not rise). The capital costs for the mill would be less than 1 percent higher than for the
baseline mill (an incremental $0.5 million for a $284 million mill). Shifting from 30 to 70 percent
substitution would increase bleaching chemical costs by 23 percent Total operating costs,
however, would only increase by 4 percent. The total cost for this hypothetical greenfield mill,
including both capital and operating expenses, would presumably increase by 2.6 percent with the
higher substitution rate.
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Pollution Prevention in Pulp & Paper
TABLE 5-2
North American Chlorine Dioxide Generators
Process
Mathieson
Solvay
R2
R3/R3H/SVP
R6/Lurgi/Chemetics
R8/SVP-MeOH/SVP-Lite
TOTAL
Number
27
.17
13
14
9
86
166
Installed
Capacity (short t/d)
190
127
92
198
144
2443
3194
Percent of
N. American
Capacity
6%
4%-
3%
6%
5%
76%
100%
Source: Britt (1992); cited in Stockburger (1992),
Page 5-5
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Pollution Prevention in Pulp & Paper
TABLE 5-3
Cost and Environmental Comparison of Chlorine Dioxide Substitution
Parameter
Incremental Capital Cost
($ Million)
Incremental O&M Costs
($ Million)
AOX in Bleach Plant Effluent
(kg/ton)
Dioxin/Furan Detect?
BOD Reduction (kg/day)
Incremental
Power
Requirements
On-Site
(MW)
Off-Site
(MW)
Chlorine Dioxide Substitution Level
Baseline
Model Mill
11% C1O2
Substitution
$0.0
$0.0
5.3
Yes
0
Maximum
Substitution
w/E0p and
existing
C1O2
Capacity
$2.8
($0.5)
3.4
Perhaps
0
0
(2.6)
50% C1O2
Substitution
$5.0
$1.9
1.9
Marginal
0
0
(2.7)
100% C1O2
Substitution
$15.9
$7.1
2.1
No
0
0
5.3
100% C1O2
Substitution
(W/EOP)
$13.6
$3.2
15
No
0
0
1.7
Note: Baseline mill is a 1,000 tpd softwood kraft pulp mill. Bleach sequence is
Source; McCubbin (1992).
Page 5-6
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Pollution Prevention in Pulp & Paper
An alternate route to increased substitution is the addition of extended delignification and/or oxygen
deligniflcation upstream of the bleach plant. By reducing total bleaching chemical demands by as much
as 50 to 70 percent, these technologies permit existing chlorine dioxide capacity to be used at higher rates
of substitution. The enhanced bleachability of these low-kappa pulps will permit the mill to cut back
elemental chlorine usage substantially or even facilitate its complete elimination.
Pollution prevention
The amount of chlorinated organies formed during bleaching is proportional to the quantity of atomic
chlorine consumed. Both elemental chlorine and chlorine dioxide contain atomic chlorine, of which
roughly 10 percent will end up as AOX. The substitution of chlorine dioxide for elemental chlorine is
effective at reducing the formation of AOX for several reasons. First, chlorine dioxide contains only one-
half the atomic chlorine as elemental chlorine. Secondly, less chlorine dioxide is needed, since it contains
2.63 times the oxidative power as elemental chlorine. Overall, chlorine dioxide bleaching results in only
one-fifth the amount of chlorinated organics as traditional chlorine bleaching.
Brunner and Pulliam indicated that shifting from 30 percent to 70 percent substitution would reduce
chlorinated discharges and color, but would have little impact on BOD (see Table 5-4). Their study
suggests, however, that at substitution rates above 70 percent, improvements in BOD could result.
McCubbin's (1992) comparison of upgrading a model mill from an 11 percent substitution rate suggests
similar improvements in bleach plant effluent (see Table 5-3).
Chlorine dioxide use is also related to the formation of chloroform, a volatile organic and a toxic air
pollutant. A study for the National Council for Air and Stream Improvement, the environmental arm of
the U.S. pulp and paper industry, found that total chloroform emissions from the bleach plant vents and
the acid and alkaline sewers Ml from below 0.35 kg per ton at 15 percent substitution to below 0.01 kg
per ton at 100 percent, though adding C102 before chlorine increased the amounts by 1.6 to 4,9 times
(Crawford et al., 1991). Thus, high chlorine dioxide substitution can be very effective in reducing
emissions of chloroform.
Chlorine dioxide is generated by a variety of commercial processes, some of which generate byproduct
chemicals. The Mathieson process, for example, uses sulfur dioxide (SO^ as a reducing agent and
generates chlorine gas as a byproduct. Sulfur dioxide is generated either onsite by burning sulfur, or is
shipped in. The R3 and Hooker SVP processes use sodium chloride and also produce byproduct chlorine
gas. Byproduct hypochlorite is produced in some chlorine dioxide generators. At one time hypochlorite
was used in the bleaching process, but it has since been largely abandoned because of its close link to
chloroform formation.
At higher substitution rates, the generation of byproducts such as sodium sulfate and sulfuric acid will
exceed the mill's capacity to incorporate them in the chemical recovery cycle. It is likely that excess
byproducts would be discharged to the sewers where it would be subject to whatever treatment
technologies are in place.
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Pollution Prevention in Pulp & Paper
TABLE 5-4
Cost and Environmental Comparison of Chlorine Dioxide Substitution
Greenfield Mill
Parameter
Incremental Capital Cost
($ Million)
Incremental O&M Costs
($ Million)
Total Incremental Cost ($ Million)
Pulp Yield
AOX in Bleach Plant Effluent
(kg/metric ton)
BOD in Bleach Plant Effluent
(Ibs/bleached ton of pulp)
Effluent Color
(Ibs/bleached ton of pulp)
Bleaching Scenario
Baseline Model Mill
30% C1O2 Substitution
$283.88
$180.53
$285.53
92.1%
4.1
37
298
70% C1O2 Substitution
$284.39
$187.77
$292.96
92.1%
2.8
37
176
Note: Baseline mill is a greenfield 1000 tpd softwood kraft pulp mill. Baseline bleach sequence is
Source: Brunner and Pulliam (1992).
Page 5-8
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Pollution Prevention in Pulp & Paper
Compatability
Kraft pulp mills have traditionally been able to use of most of the C1O2 byproducts for bleaching or as
makeup chemicals in the recovery cycle. With increased substitution rates, however, the generation of
byproducts frequently exceeds the mills' makeup requirements. Technologies that limit byproduct
generation, therefore, have gained importance. A newer generating technology (R8/SVP-Lite™) virtually
eliminates the generation of byproduct chlorine gas by using methanol as a reduction agent. This process
was developed in the late 1980s and is now used in many mills.
Equipment specifications for C1O2 generators are stringent due to the extremely corrosive and unstable
nature of the product. Storage and handling of C1O2 solution must be performed with care due to the
explosion potential. In particular, contamination of feed equipment with oxidizable materials such as
rubber, grease, iron, etc. must be avoided.
The corrosiveness of chlorine dioxide will affect the mill's ability to recover chemicals and recycle process
water. Many pulp mills are now striving to close the process water loop in the bleaching plant. A closed
water system can lower costs by increasing the recovery of makeup chemicals, reducing costs for obtaining
and pumping raw water, and limiting wastewater treatment requirements. The use of chlorine dioxide can
promote chloride corrosion in mill equipment (although to a lesser degree than elemental chlorine) thus
making closed systems more difficult to achieve. In order to increase water recycling and chemical
recovery, the waste streams containing chlorinated compounds should be isolated and excluded from the
rest of the closed system.
5.2 SPLIT ADDITION OF CHLORINE/IMPROVED pH CONTROL
What it is
Splitting the charge of elemental chlorine in the first C-stage and improved pH control have been found
to be effective in reducing formation of chlorinated organics.
How it works
By splitting the chlorine addition into several charges, introduced at multiple points throughout the
reaction tower, it is believed that oxidation reactions between lignin and chlorine will be favored over
substitution reactions. While substitution reactions are associated with the formation of chlorinated
organics, oxidation reactions are not
The technique of split chlorine addition follows from research by the Westvaco Corp. into ways to reduce
the formation of chlorinated organics (ffise and ffintz, 1989), The research has focused on close control
of the chlorine concentration in the chlorination stage as a means for reducing formation of chlorinated
organics. This is in contrast to other approaches that may emphasize reducing the total amount of chlorine
used.
The control of pH in the chlorination stage has also been used as a means for affecting the type of pulp
reactions that occur. At higher pH, more of the chlorine is converted to hypochlorous acid (HOC!), a
Page 5-9
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Pollution Prevention in Pulp & Paper
more powerful oxidizing agent. In the absence of other modifications, higher pH would also reduce pulp
yield. For this reason, pH control is combined with split chlorine addition to reportedly reduce chlorinated.
organics formation without loss of yield.
Installations
Westvaco has implemented split chlorine addition at its bleached kraft mills at Luke, Maryland, Covington,
Virginia, and Wiekliffe, Kentucky. These are the only mills known to have adopted this technique.
Economics
Separate costs for conversion of the chlorination stage to implement split chlorine addition and improved
pH control have not been reported. The necessary equipment for splitting the chlorine charge and for
monitoring pH are likely to be quite modest,
Pollution prevention
Westvaco's studies indicate that split chlorine addition using three smaller chlorine charges reduced the
formation of 2,3,7,8-TCDD and 2,3,7,8-TCDF by 70 and 50 percent, respectively. By incorporating
advanced pH control, these discharges reportedly fell by 90 percent. Mill trials have shown that non-
detect levels of TCDD and TCDF of 6 ppt can be obtained.
Compatability
While splitting the addition of chlorine and closer pH control has been shown to reduce dioxin formation,
many mills are seeking to increase the recycle of their effluent as well. This requires reductions in overall
use of chlorine-based bleaching agents, since effluents from chlorine compound bleaching stages cannot
be recycled and must be discharged.
5.3 OXIDATIVE EXTRACTION
Whatitis
Addition of gaseous oxygen to the first caustic extraction stage. The oxygen aids in the removal of
dissolved lignin and provides additional bleaching power. This reduces overall requirements for chlorine-
based bleaching agents.
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Pollution Prevention in Pulp & Paper
How it works
In a conventional bleaching sequence, chlorination is followed by an alkaline extraction stage (using
NaOH), which completes the solubilization of chlorinated and oxidized lignin molecules and facilitates
their removal. Lab and mill trials have found that the addition of gaseous oxygen to the extraction stage
can enhance the removal of lignin and provide additional bleaching power, thereby reducing the
requirements for chlorine and chlorine dioxide. Chlorine dioxide savings of approximately 2 kg per ton
of pulp in subsequent D-stages are normal. Deligniflcation following first-stage chlorination and
extraction has been found to increase by approximately 25 percent.
Oxygen is normally added to the extraction stage via a high-intensity mixer or sparger at the discharge
of the medium consistency pump. Between 4 and 6 kg of oxygen per ton of pulp are typically applied.
Oxidative extraction has also been used to help mills cut back on hypochlorite, a more expensive chemical
and the one that is most associated with chloroform emissions.
Installations
Since its introduction in the late 1970s, oxygen extraction has been widely adopted in North America and
elsewhere. Although recent data for the U.S. industry are not available, in 1987 it was estimated that 80
percent of Canadian mills were practicing oxidative extraction. The percentage in the U.S. is similarly
quite high.
Economics
Equipment requirements for oxidative extraction will depend on the current configuration of the extraction
stage. According to vendor information, an upflow extraction tower (or upflow pre-retention tube in front
of a downflow extraction tower) is necessary to ensure the hydrostatic pressure needed to keep oxygen
in suspension. Additional costs will be incurred for the oxygen mixing equipment, and washer upgrades
following extraction may be desirable.
One source has reported estimated costs for a 1983 installation at a 450 tpd mill of $0,5 million (Ducey,
1984). At another mill, conversion to a pressurized E0-stage required installation of a pressurized pre-
retention tube, a medium consistency pump, and an oxygen sparger. Total costs of that project, including
engineering and installation, were under $2 million dollars (IHastings et ai, 1992),
Pollution prevention
The formation of chlorinated organic compounds is primarily associated with the use of elemental chlorine
in the first bleaching stage. Since the E, stage follows the application of elemental chlorine, the benefits
from oxidative extraction will accrue as the mill is able to reduce chlorine usage in the first stage, or
increase its level of chlorine dioxide substitution. In most cases mills can realize a savings in active
chlorine of about 2 kg per kg of oxygen charged in the E0-stage. With the addition of a pressurized pre-
retention tube, savings of approximately 11 kg of active chlorine per ton pulp have been obtained and
reductions in AOX of approximately 0.5 kg per ton were observed (Hastings et al., 1992).
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Pollution Prevention in Pulp & Paper
Oxygen extraction has proven effective in reducing loadings of other pollutants. In particular, E0 has been
widely adopted as a means for reducing hypochlorite consumption and, consequently, generation of
chloroform.
5.4 PEROXIDE EXTRACTION
What it is
Addition of hydrogen peroxide (K2Oy) to the Et extraction stage (denoted then as an Ep stage). Similar
to oxidative extraction, the addition of peroxide has been found to promote additional removal of Mgnin
solids during extraction. It is very common to combine both peroxide and oxygen in the extraction stage,
i.e., EOP.
How it works
Peroxide is produced offsite and shipped to the mill via tanker as a 70 percent solution in water.
Configuration for an Eop stage is shown in Figure 5-2. The peroxide is generally added at the inlet of the
oxygen mixer when oxygen is used, and at the inlet of the stock pump when there is no oxygen. Since
it decomposes to water and oxygen gas, peroxide is essentially environmentally benign.
Although more commonly used for brightening mechanical pulps, peroxide can also be used as a full
bleach stage in low-chlorine and chlorine-free bleaching sequences. Peroxide would be an essential part
of any totally chlorine-free (TCP), full brightness sequence using ozone, e.g., OZEP. To protect the pulp,
a prior chelation stage is crucial to ensure removal of metal ions that accumulate as chlorine is removed
from the sequence. The only kraft mill currently producing "full" brightness TCP pulp is at Monsteras,
Sweden. The pulp produced is 88 percent ISO hardwood
Installations
It has recently been estimated that 60 U.S. and Canadian mills use approximately 28,000 tpy of peroxide
for enhanced extraction (Strunk, 1990). At an average application rate of 0.25 percent by weight on pulp,
this suggests that 11 million tons of pulp are bleached using peroxide. In the past, the high cost of
peroxide has been cited as a barrier to further adoption. In recent years peroxide prices have dropped
considerably (see below).
Economics
Capital costs for storage tanks, mix tank, and piping will be in the neighborhood of $100,000.
Application of peroxide at rates of 2 to 20 Ibs per ton will add $0.75 to $7.00 per ton at current peroxide
prices. When peroxide was first introduced to the pulp and paper industry, the limited number of suppliers
provided significant technical support and accordingly high prices for (heir product. Now that peroxide
capacity has expanded and the use of peroxide has become more prevalent in the industry producers has
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Pollution Prevention in Pulp & Paper
From
Proceeding
Stoga
From
First Stag*
NaOH
Conventional alkaline extraction stage
Vacuum
Washers
Hot
Water
Vacuum
Washer
To
Next Stage
AJkalrw
Sewer
MC Pump MC Mxer
Oxygen/peroxide-reinforced alkaline extraction stage
Figure 5-2. Modification of extraction stage for peroxide/oxygen reinforcement.
Source: Hastings et al., 1992.
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Pollution Prevention in Pulp & Paper
become far more cost competitive. Prices for peroxide has recently dropped from rougMy $2.00 per kg
three or fora years ago to $0.75 per kg today.
Pollution prevention
The use of hydrogen peroxide in the caustic extraction stage has been shown to increase delignification
and decrease the kappa number of pulp following chlorination and extraction. By assuming some of the
delignification load, peroxide-enhanced extraction will enable mills to reduce bleaching chemical
consumption either upstream or downstream of the extraction stage without impacting pulp brightness or
other properties. Reductions in bleaching chemical use, particularly in the first chlorination stage, are
associated directly with reduced levels of chlorinated organics,
Webster (1990) has described a strategy to achieve significant environmental and economic benefit from
the use of peroxide, without increasing C1O2 requirements. Using a C^DED mill as an example, the
first step is to add H2O2 to the last extraction stage. This permits reductions in chlorine dioxide use in
the final D-stage to be made without sacrificing pulp brightness. Then, peroxide is added to the first E-
stage, enabling the mill to cut the chlorine charge to maintain the same cMormation-extraetion kappa
number. Finally, the chlorine dioxide saved in the final D-stage can be shifted forward to raise the
chlorine dioxide substitution in the CD-stage to a higher level. This will accomplish the goal of lowering
elemental chlorine without the need for expensive increases in chlorine dioxide capacity and without
sacrificing pulp quality.
Recent mill trials using peroxide at various locations in the bleaching sequence showed that, depending
on the current bleaching sequence, the use of peroxide in the extraction stage enabled each mill to cut
back on chlorine or chlorine dioxide to effect reductions in kraft process pollutants (Webster, 1990). The
most significant reductions - over 80 percent.for all five mills — were for dioxin. AOX declined by close
to 30 percent, while chloroform was reduced at two of the mills by approximately 50 percent.
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Pollution Prevention in Pulp & Paper
SECTION FIVE REFERENCES
API, 1992. American Paper Institute, Report on the Use of Pulping and Bleaching Chemicals in the U.S.
Pulp and Paper Industry, June 26, 1992. New York,
Brunner and Pulliam, 1992. Brunner, Lee, and Pulliam, Tory L., "A Comprehensive Impact Analysis of
Future Environmentally Driven Pulping and Bleaching Technologies," Proceedings, 1992 TAPPI
Pulping Conference, Boston MA, November.
Britt, 1992. Britt, M.P., personal communication, Vulcan Chemicals, Birmingham, AL, March 24, Cited
in Stockburger, 1992,
Crawford et al., 1991. Robert J. Crawford, Victor J, Daflons, Ashok K. Jain, and Steven W. Jett,
"Chloroform Generation at Bleach Plants With High Chlorine Dioxide Substitution and/or Oxygen
Delignification," Proceedings, 1991 TAPPI Environmental Conference, p. 305.
Hise and Hintz, 1989. Ronnie G. Hise and Harold L. Hintz. "Effect of Brownstock Washing on
Formation of Chlorinated Dioxins and Furans During Bleaching," Proceedings, 1989 TAPPI
Pulping Conference.
Hastings et al,, 1992. "Current State of the Art of E/Q, E/P, and E/OP Technologies," in Proceedings,
Non-Chlorine Bleaching Conference, Hilton Head, SC, March 2-5,1992. Available from Miller
Freeman Publications, San Francisco.
McCubbin, 1992. McCubbin, Neil, "The Costs and Benefits of Various Pollution Prevention Technologies
in the Bleached Kraft Pulp Industry," Proceedings, International Symposium on Pollution
Prevention in the Manufacture of Pulp and Paper, August 18-20, 1992, Washington, DC. U.S.
Environmental Protection Agency, Office of Pollution Prevention and Toxics. EPA-744R-93-002.
February 1993.
Shapiro, 1992. Shapiro, Lynn, "A Quality Quest," Chemical Marketing Reporter, Special Report: Paper
Chemicals '92, September 28, p.SR 3-8.
SRI, 1989, Stanford Research International. "Sodium Chlorate," CEH Product Review, March 1989.
SRI, 1993, Stanford Research International, "Sodium Chlorate," CEH Product Review (online update),
May, 1993.
Stockburger, 1992. Stockburger, Paul, "What You Need To Know Before Buying Your Next Chlorine
Dioxide Plant," Proceedings 1992 TAPPI Engineering Conference, Boston,MA, September 14-17.
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