Industrial Process Fugitive Emissions Inventory For The Region V Great Lakes Shoreline


 EPA-905/2-80-007
Do not WEED. This document
should be retained in the EPA
Region 5 Library Collection.
         REPORTi
                    INDUSTRIAL PROCESS FUGITIVE EMISSIONS
                         INVENTORY  FOR THE REGION V
                            GREAT LAKES SHORELINE
                                              Solutions for
                                                 energy,
                                               environment
                                              & technology
                                        PACIFIC ENVIRONMENTAL
                                             SERVICES,  INC.

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                           TABLE OF  CONTENTS


Section                                                           Page

  1.0  INTRODUCTION	   1-1

       1.1  Background	   1-1
       1.2  Definition of Fugitive Emissions  	   1-1
       1.3  Approach	   1-2

  2.0  CONCLUSIONS AND RECOMMENDATIONS  	   2-1

       2.1  Conclusions	   2-1
       2.2  Recommendations	   2-2

  3.0  METHODOLOGY	   3-1

       3.1  Identification of Industrial Fugitive Emissions . .   3-1
       3.2  Quantification of Fugitive Particulate
            Emission Rate	   3-4
       3.3  Estimation of Fugitive Emissions Impact
            to the Great Lakes	   3-9

  4.0  INVENTORY RESULTS AND DISCUSSION 	   4-1

       4.1  Lake Erie	   4-12
       4.2  Lake Huron	   4-14
       4.3  Lake Superior	   4-16
       4.4  Lake Michigan	   4-18

  5.0  FUGITIVE EMISSIONS AND WATER QUALITY INTERACTION ....   5-1

       5.1  Coking Process	   5-1
       5.2  Coal Storage	   5-2
       5.3  Grain Handling	   5-2
       5.4  Ferrous Metallurgical 	   5-3
       5.5  Non-Ferrous Metallurgical 	   5-3
       5.6  Mineral Operation 	   5-4
       5.7  Other Operations  	   5-6

  6.0  RECOMMENDATIONS FOR FURTHER STUDY  	   6-1

       6.1  Verification of Fugitive Emissions  	   6-1
       6.2  Determine Environmental Impacts from Fugitive
            Particulates in Great Lakes Water Quality 	   6-1
       6.3  Development and Refinement of Fugitive
            Emission Factors  	   6-2

  7.0  BIBLIOGRAPHY

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                     TABLE OF CONTENTS (concluded)
APPENDIX A  State of Illinois Fugitive Emission Source
            Inventory	    A-l
APPENDIX B  State of Indiana Fugitive Emission Source
            Inventory	    B-l
APPENDIX C  State of Michigan Fugitive Emission Source
            Inventory	    C-l
APPENDIX D  State of Minnesota Fugitive Emission Source
            Inventory	    D-l
APPENDIX E  State of Ohio Fugitive Emission Source
            Inventory	    E-l
APPENDIX F  State of Wisconsin Fugitive Emission Source
            Inventory	    F-l
APPENDIX 6  Lake Impact from the State of Illinois	    G-l
APPENDIX H  Lake Impact from the State of Indiana	    H-l
APPENDIX I  Lake Impact from the State of Michigan	    1-1
APPENDIX J  Lake Impact from the State of Minnesota  	    J-l
APPENDIX K  Lake Impact from the State of Ohio	    K-l
APPENDIX L  Lake Impact from the State of Wisconsin  	    L-l
APPENDIX M  State of Illinois Source List  	    M-l
APPENDIX N  State of Indiana Source List 	    N-l
APPENDIX 0  State of Michigan Source List  	    0-1
APPENDIX P  State of Minnesota Source List 	    P-l
APPENDIX Q  State of Ohio Source List	    Q-l
APPENDIX R  State of Wisconsin Source List 	    R-l

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                             LIST OF FIGURES

Number                                                            Page
3-1   Project Methodology 	   3-2
3-2   Counties Bordering the Great Lakes  	   3-3
4-1   Non-Attainment Area Designation Map for the
      State of Illinois	   4-2
4-2   Non-Attainment Area Designation Map for the
      State of Indiana	   4-3
4-3   Non-Attainment Area Designation Map for the
      State of Michigan	   4-4
4-4   Non-Attainment Area Designation Map for the
      State of Minnesota	   4-5
4-5   Non-Attainment Area Designation Map for the
      State of Ohio	   4-6
4-6   Non-Attainment Area Designation Map for the
      State of Wisconsin	   4-7
4-7   Percentage of Fugitive Impact by Process
      on Lake Erie	   4-13
4-8   Percentage of Fugitive Impact by Process
      on Lake Huron	   4-15
4-9   Percentage of Fugitive Impact by Process
      on Lake Superior	   4-17
4-10  Percentage of Fugitive Impact by Process
      on Lake Michigan	   4-19

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                             LIST OF TABLES
Number                                                             Page
 3-1  Fugitive Emission Factors 	   3-5
 3-2  Calculation Sheet to Determine the Seasonal  Fugitive
      Emission Impact to the Lakes	3-10
 3-3  Local Climatological Data Summaries (LCD)  for
      Green Bay, Wisconsin	3-12
 3-4  Weather Stations and Their Adjacent Counties  	   3-13
 4-1  Potential Industrial Fugitive Impacts Incorporating
      Prevailing Wind Effects 	   4-8
 4-2  Potential Lake Impact from Industrial Fugitive Emissions
      Incorporating Prevailing Wind Direction 	   4-11
 5-1  Concentrations of Trace Elements in the Offshore Waters
      of the Great Lakes	5-5
                                   iv

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LIST OF COMMONLY USED ABBREVIATIONS USED THROUGHOUT THE TEXT
  AP-42     Compilation of Air Pollution Emission Factors
  BOF       Basic Oxygen Furnace
  EAF       Electric Arc Furnace
  EIF       Electric Induction Furnace
  IJC       International Joint Commission
  IPFPE     Industrial Process Fugitive Particulate Emissions
  LCD       Local Climatological Data
  OHF       Open Hearth Furnace
  PCB       Polychlorinated Biphenols
  SIC       Standard Industrial Classification
  TSP       Total Suspended Partial!ates

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                            1.0  INTRODUCTION

1.1  BACKGROUND
    Prior to 1969, the atmosphere had not been considered as  an  impor-
tant pathway for the loading of material to the Great Lakes Basin.
During the period of 1969 through 1975, several preliminary studies
were completed which indicated that significant amounts of material
were being deposited on the lakes' surfaces by the various atmospheric
mechanisms.  The International Joint Commission (IJC), a bilateral
board with representatives from the United States and Canada, had
reported that substantial quantities of nutrients and toxic materials
were being deposited in the Great Lakes Basin from the atmosphere,
both in rainfall and in dry fallout.  These deposits may fall directly
into the lakes, or may enter indirectly from land runoff following
precipitation in the Basin area.  The atmospheric contributions  of
phosphorus directly to the Great Lakes in 1978 were estimated to be:
Lake Superior, 59 percent; Lake Michigan, 27 percent; Lake Huron, 40
percent; and Lake Erie, 4 percent, of the total phosphorus loading for
each lake.
    Of even greater significance were the atmospheric inputs  of  poten-
tially toxic materials.  PCBs  and lead were two examples of materials
that were contributed to the Great Lakes in a significant amount by
                       n
atmospheric deposition.   Substantial quantities of air pollutants
entering the Great Lakes water can be attributed to fugitive  emissions
from industrial activity.

1.2  DEFINITION OF FUGITIVE EMISSIONS
    The term "fugitive emission", as used in this report, includes
parti cul ate emissions from industry-related operations that escape to
the atmosphere without passing through a primary exhaust system  such
    Environmental Quality, Council on Environmental Quality,
    December, 1979.
  2 Ibid.
                                   1-1

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                                    3
as a stack, flue, or control system.   This includes emissions from
manufacturing operations; loading, unloading, and transporting of
materials; storage piles; and other industrial processes where parti -
culates escape to the atmosphere.  As distinguished from fugitive
emissions, "fugitive dust" includes natural dust, agricultural, and
other non-industry activities (e.g., unpaved roads, commercial con-
struction sites, etc.).  Because fugitive emissions are not emitted
from a definable point, they cannot be easily measured by conventional
techniques.  Therefore, their emissions and subsequent impacts on  air
and water quality are extremely difficult to estimate.

1.3  APPROACH
    Pacific Environmental Services, Inc. (PES) was contracted by the
U.S. Environmental Protection Agency (U.S. EPA) Region V to provide
technical expertise and assistance to conduct a fugitive emission
inventory of industrial sources within the Region V states which
potentially impact the water quality of the Great Lakes Basin.
    PES established the following four tasks in the performance of
this project:
    1.   Identification of Industrial Fugitive Emissions
    2.   Quantification and Characterization of the Fugitive Particu-
         1 ates
    3.   Identification of the Causal Relationship Between the Cate-
         gorized Emissions and Water Quality
    4.   Development of a Methodology to Obtain and Quantify Unavail-
         able Emission Inventory Data
    All of the data in this report are based on the 1978 emissions
inventory from each state in EPA Region V, which were the only up-to-
date and complete emission inventories available at the time of pro-
ject initiation.
    Venditti, F.R., O.A. Armstrong, and Mr. Durham.  Symposium on the
    Utilization of Particulate Technology - Volume 4 "^Fugitive Dusts
    and Sampling Analysis, and Characterization of Aerosols.  EPA-
    600/7-79-044d.February, 1979.
                                   1-2

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                  2.0  CONCLUSIONS AND RECOMMENDATIONS

2.1  CONCLUSIONS
    This report was the result of a limited-scope preliminary study of
particulate fugitive emissions from major industrial sources located
within the six states of EPA Region V.  For the purposes of this re-
port, a major source is defined as a source which has a potential to
emit 100 tons/yr of particulate matter.  Also, most emission rates
quoted are within a wide range, since fugitive emission factors are
currently presented in this manner.  This study revealed that approxi-
mately 229,000 to 531,000 tons of fugitive particulates were deposited
into the Great Lakes during 1978 by major industrial sources located
in the Region V states.  These estimates represent approximately 95 to
220 percent of the total controlled particulate emissions (about
240,000 tons) from point sources located at the same industrial sites.
The largest fugitive emission source bordering the lakes is the iron
and steel industry.  Large industrial cities such as Chicago, Gary,
Cleveland, Toledo, Detroit, and Milwaukee were found to have the
largest concentration of major fugitive emission sources.
    Once these fugitive emissions reach the lake, they could con-
ceivably increase the total solids in the water causing purification
problems for public and industrial water supplies.  Some of the parti-
culates are soluble in water, and secondary reactions are likely to
occur.  Another EPA sponsored study showed that 60 percent of the total
lead (Pb) input, 30 percent of the zinc (Zn) input, and 20 percent of
the iron (Fe) input to the southern basin of Lake Michigan is attri-
                                               4
buted to dry deposition of atmospheric aerosol.   It was also found
that major inputs of sulfate and nitrate are by dry loading.  Phos-
phorus input by dry loading is about equal to precipitation inputs.
    An Experimental Study of Lake Loading by Aerosol Transport and
     "y D<
    JulyrT9797
rig by Aerosol  Transpo
 Micniqan Basin.  EPA-
Dry Deposition in the Southern Lake Michigan Basin.

                                2-1

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Since the chemical compositions of the majority  of  the  fugitive  parti-
culates are unknown at this stage (in the  absence of  further  study),
it is difficult to estimate the total effects  of fugitive  emission
deposition on the water quality.
    Some processes do emit toxic material  to the atmosphere as fugi-
tive emissions, but their quantity and character are  unknown.  Many of
the primary and secondary reactions between the  water and  these  toxic
materials are also unknown.  The methodology used in  conducting  this
study was the most efficient and accurate  way  to develop a major fugi-
tive emission inventory realizing the funding  and time  constraints
associated with this effort.

2.2  RECOMMENDATIONS
    As stated previously, this study comprised a necessary first step
of developing an industrial fugitive emission  inventory; further
demonstration and verification of the water quality impact from  fugi-
tive emissions should continue to be pursued.  In addition, further
study is needed in the following areas:
    o  extension of this study to include  Region II and Region III
       states and portions of Canada which border the Great Lakes;
    o  verification of fugitive emissions;
    o  determination of the environmental  impact from fugitive emis-
       sions by process type;
    o  quantification of area source impacts on  water quality;
    o  determination of chemical composition of  fugitive emissions;
    o  extension of this study to include  non-traditional  Fugitive
       Emission Sources.
Recommendations for further studies are described in  Section 6.0.
                                   2-2

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                            3.0  METHODOLOGY

    An industrial process fugitive emission inventory was developed to
determine the potential fugitive particulate emissions from major
stationary sources within a five-mile radius of the Great Lakes shore-
line.  This inventory was based on fugitive particulate emissions
associated with actual annual throughput of each of the affected
facilities.  A detailed description of this methodology is provided
below.  The flowchart of this methodology is also shown in Figure 3-1.

3.1  IDENTIFICATION OF INDUSTRIAL FUGITIVE EMISSIONS SOURCES
    The first task was to obtain 1978 emission inventories from each
of the six states in the U.S. Environmental Protection Agency (U.S.
EPA) Region V.  The following state agencies were contacted:  Illinois
Environmental Protection Agency; Indiana Board of Health, Air Pollu-
tion Division; Michigan Department of Natural Resources; Minnesota
Pollution Control Agency; Ohio Environmental Protection Agency; and
Wisconsin Department of Natural Resources.  The inventories were
screened to include only those counties that border the Great Lakes
(Figure 3-2), and were further screened to include only townships
within five miles from the Great Lakes.  With the aid of county maps,
industrial point sources within five miles from the Great Lakes shore-
line were identified.  The five mile distance used for this inventory
was prescribed by U.S. EPA project personnel.  After the identification
of the point source locations was completed, potential point sources
were categorized by the nature of their size, and type of industrial
process.  Potential "major" sources with 100 tons per year or greater
uncontrolled particulate emissions were chosen.  Each permitted indus-
trial process within the major source was classified as to whether or
not fugitive particulate emissions may originate from it.  The chosen
point sources were then described by the following eight criteria:
                                   3-1

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            INVENTORY COUNTIES BORDERING THE
               GREAT LAKES IN EPA REGION V
                  COUNTY MAP - UTM MAP
                            J
       ASSEMBLE 1978 MAJOR POINT SOURCES EMISSION
         INVENTORIES (by county) FOR EACH STATE
                            1
               SCREEN SOURCES FOR LOCATION
       (approximately 5 miles or less  from shore)
                            r
               SCREEN SOURCES FOR PROCESS
   (particulate, potential, fugitive emission source)
TABULATE THE SOURCES INFORMATION FROM EMISSION INVENTORY
                   (Appendices 1-6)
           ASSEMBLE FUGITIVE EMISSION FACTORS
         CALCULATE POTENTIAL FUGITIVE EMISSIONS
   CATEGORIZE FUGITIVE EMISSIONS BY PROCESS AND COUNTY
              GATHER WEATHER DATA FROM NCC
                            1
             COMPUTE SEASONAL LAKE IMPACT BY
                 COUNTY AND BY PROCESSES
                   (Appendices 7 - 12)
                           T
        COMPILE LAKE IMPACT BY PROCESS AND STATE
                        (Table 1)
                            1
       IDENTIFY THE EFFECTS OF FUGITIVE EMISSIONS
                TO THE LAKE WATER QUALITY
             Figure 3-1.   PROJECT METHODOLOGY
                           3-2

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    (1)  Source I.D. - same number as state air pollution permit file;
    (2)  SIC Code - Standard Industrial Classification Code;
    (3)  Annual Process - 1978 annual throughput for that source;
    (4)  Controlled Point Source Emissions - actual emissions from
         that source;
    (5)  Potential Fugitive Emissions - estimated fugitive emissions
         from that source;
    (6)  Particle Size - average size of the fugitive particulate;
    (7)  Operation Schedule - seasonal operation frequency (percent); and
    (8)  Process Description - short process description
    Except for Items (5) and (6), all information was available
directly from the emission inventory computer printouts supplied by
each state.  Appendices A through F list the fugitive source inven-
tories by state.

3.2  QUANTIFICATION OF THE FUGITIVE PARTICULATE EMISSION RATE
    The potential fugitive emission rate was calculated using emission
factors for industrial process fugitive particulate emission sources
available in "Compilation of Air Pollutant Emission Factors," Publica-
tion Number AP-42; "Technical Guidance for Control of Industrial Pro-
cess Fugitive Particulate Emissions," March, 1977 - EPA-450/3-77-010;
and "Particulate Emission Factors Applicable to the Iron and Steel
Industry," September, 1979 - EPA-450/4-79-028.  Whenever possible,
emission factors from AP-42 were used.  Table 3-1 lists the fugitive
emission factors which were used in this report.  The majority of the
emission factors have reliability ratings of "D" (below average-
supportable by limited test data and engineering judgment), and "E"
(poor-supportable by best engineering judgment).  Factors with an "E"
rating are at best within an order of magnitude and therefore, actual
emission rates from a given facility could differ significantly.
Because fugitive emissions are not emitted from a definable point,
they cannot be easily measured, and are therefore difficult to
estimate.
    The estimated annual fugitive emission rate for a source with
control equipment and/or a stack was calculated by multiplying the
fugitive emission factor for that particular source by the source
                                  3-4

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                      Table 3-1.   FUGITIVE EMISSION FACTORS
                                 Uncontrolled Fugitive
                                    Emission Factor            Emission Factor
  Source                         	(Ib/ton)	        Reliability Rating

(Technical
Coal Unloading
Coal Storage
Coal Conveying & Transfer
Coal Charging
Coking (door leaking)
Quenching
Coke Handling

(Technical
COKE MANUFACTURING
Guidance for Control of IPFPE)*
0.4
0.33
0.04-0.96
1.0-10.0
0.4-0.9
1.2
0.023-0.13
IRON PRODUCTION
Guidance for Control of IPFPE)


E
D
E
C
C
C
E


Shipping or Railroad Car Unloading:
Iron Ore
Limestone
Iron Ore Storage
Iron Ore Handling & Transfer
Limestone Handling & Transfer
0.02-0.03
0.2
0.33
2.0
0.2
Blast Furnace Flue Dust Handling 0.3
Sinter Handling
Slag Handling

(Technical
Molten Pig Iron Transfer
Basic Oxygen Furnace
Open Hearth Furnace
Electric Arc Furnace
Ingot Casting
Molten Steel Reladling
Scarfing
1.27-3.65
2.02-2.1
STEEL PRODUCTION
Guidance for Control of IPFPE)
0.056-0.25
1.15-1.2
0.1-0.39
0.236-3.25
0.028-0.12
0.028-0.12
0.011
E
E
D
D
D
E
E
C


D
D
D
C
E
E
C
PRIMARY COPPER SMELTING

Roasting
Reverberatory Smelting Furnace
Converter
Fire Refining Furnace
(AP-42)
23.00
8.5
10.50
1.90

__
—
--
—
industrial Process Fugitive Particulate Emissions
                                       3-5

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                Table 3-1.  FUGITIVE EMISSION FACTORS (Continued)


                                 Uncontrolled Fugitive
                                    Emission Factor            Emission Factor
  Source                         	(Ib/ton)	        Reliability Rating


                          SECONDARY ALUMINUM PRODUCTION
                    (Technical Guidance for Control of IPFPE)

Sweating Furnace                       0.72                            E
Smelting Furnace (Reverberatory)       0.94                            E
Smelting Furnace (Crucible)            0.09                            E
Smelting Furnace (Induction)           0.09                            E


                             SECONDARY LEAD SMELTING
                    (Technical Guidance for Control of IPFPE)

Sweating Furnace                       1.6-3.5                         E
Reverberatory Furnace                  2.8-15.7                        E
Blast or Cupola Furnace               12.0                             E
Casting                                0.44                            C


                             SECONDARY ZINC SMELTING
                    (Technical Guidance for Control of IPFPE)

Reverberatory Furnace                  Negligible-1.3                  E
Kettle Sweat Furnace                   0.56                            E
Rotary Sweat Furnace                   0.56-1.26                       E
Muffle Sweat Furnace                   0.54-1.6                        E
Electric Resistance Sweat Furnace      0.5                             E
Crucible Melting Furnace               0.005                           E
Kettle Melting Furnace                 0.005                           E
Reverberatory Furnace                  0.005                           E
Electric Induction Melting Furnace     0.005                           E


                                    FOUNDRIES
                    (Technical Guidance for Control of IPFPE)

Raw Material Receiving & Storage       0.74                            E
Cupola Furnace Operation               0.1-2                           E
Crucible Furnace Operation             0.1-0.6                         E
Electric Arc Furnace                   5.0-10 (metal charged)          E
                                       1.05-3.48 (steel charged)
Open Hearth Furnace                    0.1-0.9                         E
Electric Induction Furnace             2.0 (metal  charged)             E
                                       1.5 (iron charged)               E

                                       3-6

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                Table 3-1.  FUGITIVE EMISSION FACTORS (Continued)


                                 Uncontrolled Fugitive
                                    Emission Factor            Emission Factor
  Source                         	(Ib/ton)	        Reliability Rating


                              FOUNDRIES (Continued)

Pot Furnace                            0.4                             E
Reverberatory Furnace                  8.3-8.7                         E
Pouring Molten Metal Into Molds        0.1-4.13 (gray iron foundry)    E
                                       2.52 (copper)                   E
                                       0.93 (lead)                     E
Casting Operation                      1.37-13.61                      E
Core Making                            0.71-6.08                       E
Sand Handling                          1.37                            E


                      MATERIAL  EXTRACTION  AND  BENEFICATION
                    (Technical Guidance for Control of IPFPE)

Unloading, Transfer, Crushing          2.17-4.06                       E


                             TERMINAL GRAIN ELEVATOR
                    (Technical Guidance for Control of IPFPE)

Grain Handling                         1.84-26.7                       E
(transfer, conveying, screening,
cleaning, drying, shipping)


                              CEMENT MANUFACTURING
                    (Technical Guidance for Control of IPFPE)

Cement Manufacturing                  10.6-18.3                        E


                                LIME MANUFACTURING
                    (Technical Guidance for Control of IPFPE)

Lime Manufacturing                     3.14-3.186                      E


                                CONCRETE BATCHING
                                     (AP-42)

Transfer of Sand & Aggregate to        0.04
  Elevated Bins

                                       3-7

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                Table 3-1.  FUGITIVE EMISSION FACTORS (Concluded)


                                 Uncontrolled Fugitive
                                    Emission Factor            Emission Factor
  Source                         	(Ib/ton)	        Reliability Rating


                          CONCRETE BATCHING (Continued)

Cement Unloading to Elevated           0.24
  Storage Silos
Weight Hopper Loading of Cement,       0.02
  Sand Aggregate
Mixer Loading of Cement,               0.04
  Sand Aggregate
Loading of Transit Mix Truck           0.02
Loading of Dry Batch Truck             0.04


                                ASPHALT CONCRETE
                    (Technical Guidance for Control of IPFPE)

Concrete Manufacturing                 8.656                           E


                              WOODWORKING  OPERATION
                                     (AP-42)

Wood Waste Storage Bin Vent            1.0
Wood Waste Storage Bin Loadout         2.0
Sawing and Sawdust Pile                1.35                            E
                                       3-8

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annual throughput, and converted to tons per year.   For  instance,  the
potential fugitive emission rate for a primary copper  smelter  having
an annual production rate of 1,000 ton/year is:

    /43.9 Ibs of particu1 atew1.000 ton/year. _ ??  t     nartirulatP/vpar
    (  ton of end product}  (2!oOO Ibs/ton }   Z2  tons  Peculate/year

*Fugitive emission factor AP-42, page 7.3-7.

     A source with no control  equipment and stack was  considered  as a
fugitive emission source and the fugitive emission rate was  recorded
as the "uncontrolled emission  rate" found on the process  emission
inventory printout.

3.3  ESTIMATION OF FUGITIVE EMISSION IMPACTS TO THE  LAKES
    Table 3-2 was used to determine the seasonal fugitive emissions
impact to the lakes.  This table contained the following  information:
    o  state
    o  county
    o  process description
    o  SIC Code
    o  total potential fugitive emission rate within the  county
    o  total potential lake impact from the county
    o  particle size
    o  seasonal fugitive emission rate
    o  wind frequency impact on lake
    o  the seasonal lake impact
This table was completed as follows:
    A total estimated fugitive emission rate per process, regardless
    of source, within the county was calculated by adding each fugi-
    tive emission rate estimated for that process (i.e.,  potential
    fugitive emissions for each coal storage process within  Cook
    County, Illinois and within five miles of the Lake Michigan shore-
    line).  A total potential fugitive emission rate describing this

                                   3-9

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STATE OF:
                       COUNTY:
SIC:
PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
                       POTENTIAL LAKE
                       IMPACT (tons/yr):
PARTICLE SIZE:
                        DEC/FEB
                     MAR/MAY
JUNE/AUG
SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)









SIC:
PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
                       POTENTIAL LAKE
                       IMPACT (tons/yr):
PARTICLE SIZE:
                        DEC/FEB
                     MAR/MAY
JUNE/AUG
SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)









   Table  3-2.  CALCULATION SHEET TO DETERMINE THE SEASONAL  FUGITIVE  EMISSIONS
                              IMPACT TO THE LAKES

                                      3-10

-------
    process category was calculated by adding each coal  storage  emis-
    sion rate within a particular county.  Seasonal fugitive emission
    rates for each process were then computed by multiplying each
    process's potential fugitive emissions with its respective seasonal
    operation schedule, which was obtained from state emission inven-
    tories.  Only the State of Michigan Emission Inventory did not
    provide this kind of information.  In order to complete this
    study, PES assumed an equal operation schedule year  round, i.e.,
    25/25/25/25 for all of Michigan's industrial sources.
    Since the pollution dispersion directions were determined by the
prevailing wind direction for each area in this study, local climato-
logical data (LCD) obtained from the National Climatic Center, Ashe-
ville, North Carolina, were used to determine the prevailing wind
directions at all locations surrounding the Region V Great Lakes.  A
sample LCD is given in Table 3-3 for Green Bay, Wisconsin.  A list of
the stations in which climatological data was obtained is given  in
Table 3-4.  The prevailing winds for each location was used to deter-
mine the seasonal impact on the Great Lakes for fugitive emission
sources.  This was accomplished by determining the prevailing winds at
each station for each month and comparing them to each source location
to determine whether the source would impact on the lake under study.
The percent frequency of winds blowing towards each lake (wind posi-
tive) was then determined on a seasonal basis from this monthly  infor-
mation (December through February, March through May, June through
August, and September through November).  The seasonal impacts were
calculated by multiplying the seasonal fugitive emissions from each
source by the seasonal wind positive data.  The results of lake  impacts
for each state and county are listed in Appendices G through L.  The
reliability of these results are also discussed in Section 4.0.
    An attempt was made to characterize the fugitive emissions with
respect to particle size.  Typical particle size ranges for the emis-
sions correspond to those used in "Technical Guidance for Control of
Industrial Process Fugitive Particulate Emissions," Publication No.
EPA - 450/3-77-010.
                                  3-11

-------

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3-12

-------
                 Table 3-4.  WEATHER STATIONS (BY COUNTY)
STATE:  Illinois
    Weather Station:  Midway Airport (Chicago, Illinois)
    County:  Cook, Lake

STATE:  Indiana
    Weather Station:  Midway Airport (Chicago, Illinois)
    County:  Lake, Porter

STATE:  Michigan
    Weather Station:  Phelps Collins Field (Alpena, Michigan)
    County:  Presque Isle
    Weather Station:  City Airport (Detroit, Michigan)
    County:  Macomb, Monroe, Wayne
    Weather Station:  Bishop Airport (Flint, Michigan)
    County:  Arenac, Bay, Huron
    Weather Station:  U.S. Post Office (Marquette, Michigan)
    County:  Alger, Delta, Marquette, School craft
    Weather Station:  Muskegan County Airport (Muskegon, Michigan)
    County:  Berrien, Mason, Muskegon, Ottawa
    Weather Station:  Suburban Office (Sault Ste. Marie, Michigan)
    County:  Chippewa,  Mackinac
    Weather Station:  International Airport (Duluth, Minnesota)
    County:  Ontonagon
    Weather Station:  Austin Straurel Field (Green Bay, Wisconsin)
    County:  Monominee
                                3-13

-------
                        Table 3-4 (Concluded)
STATE:  Minnesota
    Weather Station:  International Airport (Duluth, Minnesota)
    County:  Lake, St. Louis

STATE:  Ohio
    Weather Station:  Toledo Express Airport (Toledo, Ohio)
    County:  Lucas, Ottawa
    Weather Station:  Cleveland Hopkins Int'l Airport (Cleveland, Ohio)
    County:  Ashtabula,  Cuyahoga, Erie, Lorain, Lake

STATE:  Wisconsin
    Weather Station:  Austin Straurel Field (Green Bay, Wisconsin)
    County:  Door, Kewaunee, Marinette, Manitowoc
    Weather Station:  General Mitchell Field (Milwaukee, Wisconsin)
    County:  Kenosha, Milwaukee, Racine, Sheboygan, Ozaukee
    Weather Station:  International Airport (Duluth, Minnesota)
    County:  Douglas
                                3-14

-------
                  4.0  INVENTORY RESULTS AND DISCUSSION

    This section summarizes the results of  the fugitive emissions
study on a lake-by-lake basis.  It also interprets the relationships
between the associated state (or states) and the major fugitive emis-
sion processes.  Within U.S. EPA Region V jurisdiction, approximately
48 percent of the counties  (29 out of a total of 60) surrounding the
Great Lakes are designated  as "partial county non-attainment  areas"
with respect to TSP  (see Figures 4-1 through 4-6).  Table 4-1 shows
the summary of yearly fugitive emission impacts on each lake.  Since
most current fugitive emission factors for  industrial  sources have
ranges associated with them, the study results presented in Table 4-1
reflect these ranges.  These ranges provide only an estimate  of poten-
tial emissions, since proper control of fugitive emission points could
significantly reduce any or all of the resultant emission rates.  As
stated in Section 3.3, this fugitive emission impact summary  incorpor-
ates both potential fugitive emissions generated by each source, and
the prevailing wind direction in the vicinity of the facility.  In
some states, potential fugitive emissions impact their bordering lakes
greatly due to the prevailing wind directions (see Table 4-2).  This
study used seasonal wind averages for local climatological data sum-
maries to, project emission  impacts to Great Lakes water quality.  In a
               1 2
previous study, '  four standard weather stations were involved in
San Antonio, Texas.  The average distance separating the stations was
12 miles, the direction data were given to  16 compass points, and the
wind speed to 1 mph.  These data indicated  that 90 percent of the time
wind direction between stations would differ by no more than  three
compass points and 90 percent of the time wind speed would differ by

1 U.S. Weather Bureau, 1953:  A Meteorological Survey of the Oak
  Ridge Area:   Final Report Covering the Period 1948-1952.  USAEC
  Report ORO-99, Weather Bureau, Oak Ridge, Tennessee.
2 U.S. Atomic Energy Commission, 1968, Meteorology and Atomic Energy
  Office of Information Services.
                                  4-1

-------
I
I
I
I
I
I
I
I
I
I
I
I
I
 *
I
                                                               TSP.
                                                                            Lake  Michigan
* denotes counties
  that border lake
I

I

I

I

I
      UNSHADED COUNTIES  Am ertw »iLhrnrmu or untiastifwd

        SHADED COUNTIES  Am trafy nonaga«ii»e«u

              TRiANGU:  Denotes a partial county niaiUiMninan
                       are* MirrwwMra in ttwcoumy
             Figure 4-1.  NON-ATTAINMENT AREA DESIGNATION  MAP FOR STATE OF ILLINOIS

                                                    4-2

-------
I
I
I
I
I
I
I
I
I
I
I
I
1
I
I
I
I
I
I
                          Lake
                        Michigan
Michigan
          Illinois
denotes counties
that  border  lake
                                                                          TSP
                                                    UNSHADED COUNTIES  Am ndxr attainment or undauifed

                                                      SHADED COUNTIES  Am totally nonattrnmrant

                                                            TRIANGLE  Denotw a oafns* county nonctairwnwn
                                                                     ana somawhw, in tfra county
           Figure 4-2.   NON-ATTAINMENT AREA DESIGNATION  MAP FOR  STATE OF  INDIANA

                                                  4-3

-------
I
                                                           UNSHADED COUNTIES  Are **«w attainment « uncte*****
                                                             SHADED COUNTIES  Am totsify rotvnsiranent
                                                                   TRIANGLE  Denotes * paral coomy noo»ttainiD«nl
                                                                            trea somewhera in fri* eoumy
             Wisconsin
V  denotes counties  that
    border lake
I
I
I
Illinois
  Figure 4-3.  NON-ATTAINMENT AREA DESIGNATION  MAP FOR STATE  OF MICHIGAN
                                         4-4

-------
                                                             TSP
                                                              Canada
                                                              * denotes counties  that
                                                                border lake
                                      UNSHADED COUNTIES  Am enner «to«nent or unetessffied

                                        SHADED COUNTIES  Am wtsSy nwwtainment

                                              TRIANGLE  Dsnww • partial county nonara'nment
                                                       area somewfwm in tti» county
Figure 4-4.   NON-ATTAINMENT AREA  DESIGNATION MAP FOR STATE OF  MINNESOTA

                                        4-5

-------
I
                                                                              West  Virginia
I
  * denoted counties that
    border lake
I
I
                                              UNSHADED COUNTIES  Art erw natrrwu  tx»«v nomtarvnant
                                                      TRlANGt£  Denoo« a furatt courrry no
Figure 4-5.
NON-ATTAINMENT AREA  DESIGNATION MAP  FOR STATE OF  OHIO
                       4-6

-------
         Minnesota
                              Lake Superior
                                                        UNSHADED COUNTIES  Ac* erf*r anainrmnt or urtdauified

                                                          SHADED COUNTIES  Am totafy nonttaHmunt
                                                                TRIANGLE 0«not»« • pwtM county
                                                                           aomawham in th* county
                                                                                               Michigan
denotes counties
border lake
           Figure 4-6.  NON-ATTAINMENT AREA  DESIGNATION MAP FOR  STATE OF WISCONSIN

                                                  4-7

-------


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       Table 4-2.  POTENTIAL LAKE IMPACT FROM INDUSTRIAL FUGITIVE EMISSIONS
                      INCORPORATING PREVAILING WIND DIRECTION
  STATE
Illinois

Indiana

Michigan

Minnesota

Ohio

Wisconsin
  POTENTIAL INDUSTRIAL
FUGITIVE EMISSION (TPY)

    50,000-130,000

    86,000-120,000

    64,000-99,000

    38,000-160,000

    26,000-86,000

    25,000-90,000
IMPACTING
  LAKE

  100%

   95%

   59%

   75%

   92%

   24%
 FUGITIVE EMISSION
IMPACTING LAKE (TPY)

  50,000-130,000

  82,000-110,000

  38,000-60,000

  29,000-120,000

  24,000-79,000

  6,000-22,000
                                        4-11
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no more than 9 mph.  Obviously, the shorter the distance from each
individual source to the National Weather Service station, the greater
the likelihood of similar meteorological measurement.  Although this
estimate of average wind directions is far from absolute, it yields an
approximation of the magnitude of industrial emissions impacting the
lake and provides an insight to the areas affecting lake quality the
greatest.

4.1  LAKE ERIE
    The results of this study show that 42,000 to 103,000 tons of
industry generated fugitive particulate emission reached the Lake Erie
shoreline during 1978.  These emissions originated from the states of
Ohio and Michigan, which border Lake Erie.  As with all of the re-
maining lakes, only the impact of United States sources was studied.
Ohio was the dominant state, emitting about 60 percent of the total
fugitive emissions.  Over 70 percent of those fugitive emissions
originated from the following industries:  iron melting, coal storage,
coke production, lime manufacturing, and grain handling.  The contri-
bution percentage from those processes are shown in Figure 4-7.
    In the state of Ohio, eight counties border Lake Erie:  Ashtabula,
Cuyahoga, Erie, Lake, Lorain, Lucas, and Ottawa.  The majority of
industries are concentrated in Cuyahoga and Lucas counties in which
Cleveland and Toledo, two large industrial cities, are located.  Fifty-
four major sources were located in this study area, of which 50 per-
cent were located in Cuyahoga County and 16 percent in Lucas County
(see Appendix E).  These sources were categorized under 13 different
industrial processes, the largest being iron melting in Cuyahoga
County.  However, the fugitive emissions from iron melting had a large
particle size—50 percent were greater than 70 microns; consequently,
the actual fugitive emissions deposited in the lake may be less than
estimated due to the particles increased settling velocity (i.e.,
particles may settle out prior to reaching shoreline).  The estimated
fugitive emissions impact on Lake Erie from the state of Ohio ranged
between 25,000 and 79,000 tons per year.
                                   4-12
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       Figure 4-7.  PERCENTAGE OF FUGITIVE IMPACT BY
                    PROCESS ON LAKE ERIE
                                     Iron and Steel
                                     Manufacturing
                                          34%
Lime Manufacturing 15%
           Coking Process
                16%
Coal Storage
    16%
                               4-13
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    Macomb, Monroe, and Wayne Counties border Lake Erie in the state

of Michigan.  The major industrial area is located in Wayne County,

which includes the city of Detroit.  Most of the iron and steel  indus-

try are located outside of the five mile radius from the shoreline.

The state of Michigan contributes fugitive emissions to Lake Erie and

Lake St. Clair.  For the purposes of this study, they were treated as

one lake since the two lakes are connected by the Detroit River.  A

total of 43 Michigan sources impact Lake Erie (see Appendix C),  90

percent of which are located in Wayne County.  These sources were

categorized under 15 different industrial processes, the largest being

the coking processes located in Wayne County.  The estimated fugitive

emissions impact to Lake Erie from the state of Michigan ranged  from

17,000 to 24,000 tons per year.


4.2  LAKE HURON

    This study determined that there were 9,700 to 12,000 tons of

fugitive emissions impacting Lake Huron during 1978.  Within the

jurisdiction of EPA Region V, only the state of Michigan borders Lake

Huron.  Within Michigan, the following 11 counties border Lake Huron:

Bay, Arenac, Huron, Presque Isle, St. Clair, Sanilca, losco, Alcona,

Alpena, Tuscola, and Sheboygan.  Only the first four counties have

major fugitive emission sources, with Bay County as the major con-

tributor of fugitive emissions to the lake.  The remaining counties

consist of rural areas having few major industrial sources.

    There were a total of 27 sources subject to this study, which were

categorized under ten different industrial processes.  The largest

fugitive emission process was the stone crushing process, which contri-

buted approximately 8,000 tons of fugitive particulates to Lake Huron.

The fugitive emission contribution percentage by process is shown in

Figure 4-8.
                                   4-14
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Figure 4-8.  PERCENTAGE OF FUGITIVE IMPACT BY
             PROCESS ON LAKE HURON
             Stone Crushing 81%
                       4-15
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4.3  LAKE SUPERIOR

    During 1978 there were 31,000 to 130,000 tons of fugitive emis-

sions deposited in Lake Superior.  Within EPA Region V jurisdiction,

the states of Michigan, Wisconsin and Minnesota border Lake Superior.

    Within the state of Michigan, the following eight counties border

Lake Superior:  Chippewa, Luce, Alger, Marquette, Baraga, Keweenaw,

Houghton, Ontonagon, and Gogebic.  All of these counties are consi-

dered rural areas and have a relatively small impact on the lake.

    There were ten Michigan sources subject to this study, which were

categorized into four industrial processes.  Stone crushing was the

largest fugitive emission process.  Industrial process fugitive emis-

sion contribution percentages are shown in Figure 4-9.  The total

Michigan fugitive emission annual impact to Lake Superior ranged

between 2,700 and 4,300 tons.

    Within the state of Minnesota, the three counties bordering Lake

Superior are St. Louis, Lake, and Cook.  The major industrial area is

concentrated in Duluth, located in St. Louis County.  There are a

total of 13 Minnesota industrial fugitive sources impacting Lake

Superior which were categorized under five industrial processes.  The

largest process contributing fugitive emissions was iron ore opera-

tions, which emitted over 20,000 tons per year.  The second largest

was grain handling, emitting over 8,000 tons per year.  The annual

fugitive emissions impact to Lake Superior ranged between 29,000 and

124,000 tons.

    Within the state of Wisconsin, the four counties bordering Lake

Superior are Douglas, Bayfield, Ashland, and Iron.  The major indus-

trial area is concentrated in Douglas County, while the other three

counties are considered rural areas.  Potentially, there were 17,000

to 135,000 tons of fugitive emissions emitted from Douglas County, with

the majority being emitted from grain handling operations.   Since the

local climatological data indicated that the prevailing wind direction

was never in the lake direction, there was no fugitive emissions impact

to Lake Superior from the state of Wisconsin.

                                   4-16
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Figure 4-9.  PERCENTAGE OF FUGITIVE IMPACT BY
             PROCESS ON LAKE SUPERIOR
       Grain Handling 24%
                       4-17
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4.4  LAKE MICHIGAN
    During 1978, there were approximately 146,000 to 288,000 tons of
fugitive emissions generated by major industrial sources and deposited
into Lake Michigan.  Due to its larger U.S. shoreline, the fugitive
emission loading is the greatest of the Great Lakes studied.  Within
EPA Region V jurisdiction, these four states border the lake:  Michi-
gan, Illinois, Indiana, and Wisconsin.
    The state of Indiana was the major contributor of fugitive emis-
sions to Lake Michigan.  Over 55 percent of the total fugitive emis-
sions impacting the lake originated from Indiana.  The state of
Illinois was the second largest fugitive emission contributor to Lake
Michigan.  The ten major industrial processes which contributed to the
fugitive emission impact of Lake Michigan were:  coking processes, coal
storage, grain handling, iron production, steel production, mineral
handling, sintering processes, lime manufacturing, iron foundry, and
cement manufacturing.  The contribution percentage from each process
is shown in Figure 4-10.  One third of all fugitive emissions were
contributed by the coking process located in the Gary, Indiana metro-
politan area.
    Within Illinois, the two counties which border Lake Michigan are
Cook and Lake.  The major industrial areas are concentrated in Cook
County (see Appendix 1), especially the southern section of the city
of Chicago.  A total of 71 Illinois sources were subject to this study,
which were categorized under 20 industrial processes.  The largest
fugitive emission process was coal storage, emitting about 50 percent
of the total fugitive emissions from those sources.  Grain handling
was the second largest process.  The estimated fugitive emissions
impact to Lake Michigan from the state of Illinois ranged between
7,900 and 18,000 tons per year.
    Within the state of Indiana, the two counties which border Lake
Michigan are Lake and Porter.  The Gary, Indiana area (in Lake County)
contains the majority of industrial facilities.  A total of 41 indus-
trial fugitive sources impact Lake Michigan which were categorized

                                   4-18
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         Figure  4-10. PERCENTAGE OF FUGITIVE  IMPACT BY
                      PROCESS ON LAKE MICHIGAN
                                        Coking Process
                                             36%
Grain Handling 10%
      Iron and Steel
      Manufacturing
           17%
                               Coal  Storage
                                   20%
                               4-19
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under 17 industrial processes; the largest being the coking process.

This process emitted 60 percent of the total fugitive emissions from

the facilities.  Fugitive emissions originating from steel production

was the second largest source.  The impact to Lake Michigan from the

state of Indiana ranged between 82,000 and 117,000 tons per year.

    There are 18 Michigan counties bordering Lake Michigan.  Muskegon

contains the majority of industries.  A total of 31 sources were sub-

ject to this study, and were categorized under eight industrial pro-

cesses.  The largest fugitive emission process was mineral handling,

emitting about 57 percent of the total emissions from these sources.

The emissions impact to Lake Michigan ranged between 7,900 and 18,000

tons per year.

    The state of Wisconsin has 12 counties bordering Lake Michigan.

The majority of Wisconsin's industrial area is concentrated near the

city of Milwaukee, located in Milwaukee County.  A total of 68 sources

were subject to this study, and were categorized under 15 industrial

processes.  The largest fugitive emission process was coal storage.

The impact to Lake Michigan from Wisconsin ranged between 6,000 and

22,000 tons per year.
                                 4-20
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            5.0  FUGITIVE EMISSION WATER QUALITY INTERACTION

    All major industrial sources bordering the Great Lakes were
categorized into 20 industrial processes.  Each of these processes
fall under seven general categories described in the following sec-
tions.  The following discussion concentrates on estimates of the
effect that fugitive emissions generated by those industrial processes
have on water quality in the Great Lakes.

5.1  COKING PROCESS
    The coking process is the largest fugitive emission process within
EPA Region V jurisdiction.  Within the process, there are several
fugitive emission sources:  charging of coal, oven door leaks, coke
pushing, and wet coke quenching.  The particles which are emitted from
the charging of coal, oven door leaks, and coke pushing are basically
coal dust, coke dust, and polycyclic organic hydrocarbons.  The water
vapor, which acts as a particulate comes from the quench tower and con-
tains toxic materials such as naphtalene, phenol, and polyacylic aroma-
tic hydrocarbons.  Coal and coke dust increase the total suspended
solids in the water.  Even when the toxic tendency is omitted, this
process contributes about 60,000 tons of sediment particles to the
Great Lakes.  Sediment loading is considered to have a special role  as
a pollutant in the Great Lakes where particles settle at rates deter-
mined by particle size and density.  Settling in the near-shore zone
is intermittent.  Physical processes associated with turbulent mixing
by the wave action results in resuspension and onward transportation
of the sediment.  In a calm condition, resettling occurs, but again,
it is of intermittent nature until such particles move to depths where
they are able to settle undisturbed.  This produces deep water concen-
trations of fine particles and associated contaminants, as observed  in
Lake Superior, Lake Michigan, Lake Huron, and the eastern basin of Lake
Erie.  It has been suggested that excessive sedimentation near fish
spawning grounds could be detrimental to fish viability.  High sediment
levels in the lake may pose aesthetic problems for recreational uses
and may also present problems for drinking water treatment plants.
                                  5-1
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5.2  COAL STORAGE

    The second largest potential fugitive emission source  is  coal

storage.  Fugitive emissions originate from coal unloading, coal

storage piles, and coal transferring processes.  The majority of these

processes are associated with the power plants which border the lakes.

The fugitive emissions emitted from coal storage processes have the

same chemical characteristics as coal being processed.

    Fixed carbon is the major component of the fugitive coal  dust.

Currently, sulfur and other associated compounds bound to the coal are

not considered to be major water quality concerns.  This coal dust

increases the suspended solid in the water and can present problems

for the drinking water treatment plants.


5.3  GRAIN HANDLING

    Grain handling is the third largest, emission source.  Fugitive

emissions originated from the following operations:  grain unloading,

loading, transferring, cleaning, and drying processes.  The word

"grain" includes corn, wheat, rye, oats, barley, flaxseed, malt, and

soybeans.  Some of these grains have large particle sizes, and there-

fore, the actual fugitive emission deposit to the lakes are likely

less than estimated.  The fine grain particles, however, that do

deposit in the lake increase suspended solids in the water.  The major

composition of grain is of a proteinaceous or nitrogenous nature. As

soon as proteins leave the life cycle, they fcegifl to decorspose by

various mechanisms until ultimately, their nitrogen content is re-

turned to the soil or to the water as nitrates.  Nitrates are the

principle nitrogenous material available in soil for the growth of

plants and is especially helpful in the growth of algae.  However,

nitrogen is not a limiting nutrient in the Great Lakes, except in some

near-shore and embayment areas with restricted circulation.
                                   5-2
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5.4  FERROUS METALLURGICAL
    Ferrous metallurgical operations are another large fugitive  emis-
sions contributor in EPA Region V jurisdiction.  These operations
include iron and steel production, ferrous foundry, and sintering.
The compositions of these emissions are iron oxide, tin, arsenic,
nickel, chromium, silicon oxide, aluminum oxide, calcium oxide,  ferric
fluoride, cadmium, lead, zinc, and manganese.  The major composition
of the fugitive particulate emissions is iron oxide, a comparatively
harmless particle to the human body.  Part of the fugitive emissions
also contain some toxic materials, i.e., lead, zinc, arsenic, cadmium
and its compounds, and ferric fluoride.  Lead and cadmium are on the
EPA's priority list of toxic substances.  Presently, lead is not an
environmental contaminent of concern in the Great Lakes, relative to
current concentrations in fish.  It has the potential for becoming a
problem through chemical and biological methylation if current loadings
of lead to the lakes are not reduced.  A further detailed study  is
required to determine the actual concentrations of fugitive toxic
substances originating from ferrous metallurgical processes.

5.5  NONFERROUS METALLURGICAL
    The International Joint Commission (IJC) ranked the following
toxic materials based on their real or anticipated potential as  an
environmental hazard:
    (1)  Mercury, lead
    (2)  Arsenic, cadmium, selenium
    (3)  Copper, zinc, chromium, vanadium
These hazardous materials are associated with the nonferric metallur-
gical industry which includes primary and secondary copper, lead, zinc,
aluminum, smelting, and foundry operations.  The particles coming from
these operations contain the following compounds:  lead oxide, iron
pyrite, limestone, sulfide, sulfate of lead, tin, copper, fluoride,
                                   5-3
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cadmium, cadmium fluoride, and zinc oxide.  Many of these substances

are also classified as toxic material, i.e., arsenic, cadmium, lead,

copper, fluoride, and zinc.  Table 5-1 shows the concentration of

these elements in the offshore water of the Great Lakes.   Only the

mercury concentration in Lake Erie and cadmium concentration in Lake

Michigan exceed the current IJC objectives.  However, it should be

noted that the objectives are based on total elemental content, rather

than on particular chemical forms of the element.


5.6  MINERAL OPERATIONS

    Stone crushing is the largest fugitive emission process impacting

Lake Huron.  Emissions originate from drilling, crushing, trans-

ferring, and regrinding processes.  Although a large portion of these

emissions consist of heavy particles that settle within the plant, the

remaining suspended particles still have impact on the lakes as sus-

pended solids.  These processes are also associated with the emission

of asbestos fibers (a listed toxic material).  This particular

pollutant must be monitored closely in areas where traditional waste

discharges (wastewater) have been known to occur, as in the case of

some Minnesota mining operations and their associated affect on Lake

Superior water quality.

    Although limestone crushing and refining have a large impact on

total suspended solids loading in the Great Lakes, the basic nature of

these minerals may help maintain acceptable pH levels in the face of

increased acid fallout from local acid rains.  However, this benefit

may not outweigh the total disbenefit of increased total suspended

solids.


    Environmental Management Strategy for the Great Lakes System.
    International Reference Group on Great Lakes Pollution from Land
    Use Activities,  Winsor, Ontario, July, 1978.
                                   5-4
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5.7  OTHER OPERATIONS

    Other fugitive emission sources are lime manufacturing, cement

manufacturing, asphalt batching, and gypsum manufacturing.  The parti-

culate fugitive emissions associated with those processes are calcium

oxide, sand, lime, silica, iron, aggregate, and calcium sulfate.  The

ion of calcium and iron most likely will increase the hardness of the

water.  Also, those particulates will increase the suspended solid and

sediment loading in the Great Lakes.
                                  5-6
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                 6.0  RECOMMENDATIONS FOR FURTHER STUDY


6.1  VERIFICATION OF FUGUTIVE EMISSIONS

    The fugitive emission factors used in this study primarily repre-

sent model sources for each individual process.  For any specific

source, the actual fugitive emissions can vary substantially from  the

present study results.  Also, the actual fugitive emissions can  vary

from source to source depending on the age of the equipment, the

control level, etc.  However, the actual fugitive emission rates can

be verified by the field inspection and/or source monitoring of  a

cross-section of industries.

    Basically, this field inspection and/or source monitoring would

generate a quantitative, and to some extent, refine the qualitative,

picture of the estimated fugitive emissions.

    When conducting ambient monitoring, it is recommended that the

duration of sampling be of sufficient length to obtain statistically

significant data, which in this case will represent accurate fugitive
emission rates.


6.2  DETERMINE ENVIRONMENTAL IMPACTS FROM FUGITIVE PARTICULATES  IN
     GREAT LAKES WATER QUALITY

    Since the composition of the fugitive particulates emitted from

each process is uncertain, it is impractical to estimate the overall

environmental effects of fugitive particulates on the lake water

quality without conducting further composition analysis.  In addition

to a fugitive particulate composition analysis, the water quality

impact can also be determined by the water quality analysis.  This

water quality impact analysis would be performed in the laboratory on

a daily basis by comparing two water samples — one blank and one

contaminated by fugitive emissions.  This analysis would provide an

understanding of the short and long range effects of each of the

fugitive sources.
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6.3  DEVELOPMENT AND REFINEMENT OF FUGITIVE EMISSION FACTORS

    At the present time, fugitive emission factors  are far from  being

well defined and/or complete.  Further studies are  recommended to

include the development of fugitive emission factors for  processes

affecting Great Lakes water quality, which are, not  presently  available;

and the refinement of fugitive emission factors which have, at present,

a reliability rating of "E" (poor-supportable by best engineering

judgment).


6.4  EXTENSION OF STUDY AREA TO CANADA AND U.S. EPA REGIONS II AND  III

    This study cataloged fugitive emissions from Region V sources

impacting the Great Lakes.  Impacts from Canadian and other U.S.

sources may comprise an equal or greater share of the water quality

impact.  A complete fugitive emission inventory of  all sources bor-

dering the Great Lakes would give a complete picture of the potential

water quality impact of these fugitive sources.


6.5  EXTENSION OF STUDY TO INCLUDE NON-TRADITIONAL  FUGITIVE
     EMISSION SODRTE?

    Recent studies have shown that non-traditional  fugitive emission

sources have a large impact on local air quality.   The results of this

study include fugitive emissions from major industrial processes.

Emissions such as road dust (industrial, residential, and rural) and

various construction activities were not included in the  inventory

results.  Fugitive emissions generated from agricultural  activities

which can produce large quantitites of particulate  were also  not

included.  The vast majority of land surrounding the Great Lakes con-

sists of the non-traditional fugitive sources described above.  The

total fugitive emission impact on the Great Lakes can only be deter-

mined when these non-traditional sources are included in  the  inventory

results.
                                   6-2
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                                       7.0  BIBLIOGRAPHY
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*                                         Reference
•         Masser, Charles.   U.S.  EPA.   Conversation with PES personnel.   May, 1980.

•                                    Books and Pamphlets
           Danielson, J.A.   Air Pollution Engineering Manual.  2nd ed.  May,  1973.
•         Environmental  Qua!ity.   Council  on Environmental  Quality.   December,
™              1979.
           Sawyer, C.N., and P.L. McCarty.  Chemistry for Sanitary Engineers.
                McGraw-Hill, 1978.
I
•         Stern,  A.C.   Air Pollution - Engineering Control  of Air Pollution.
                3rd ed.   Academic Press, 1977.

           Waldbott, G.L.  Health Effects of Environmental  Pollutants.   L.V.  Moshy
                Company, 1973.
                                           Articles

           Analysis of Fugitive Dust Emissions in the Detroit Metropolitan Air
                Quality Maintenance Area.
                Lansing, MI.   July, 1978.
•              Quality Maintenance Area.  Michigan Department of Natural Resources,

I

I

I

I
           Chalekod, P.K.,  T.R.  Blackwood, and S.R.  Archer.   Source Assessment
                Crushed Limestone; State of Art.   EPA-600/2-78-004e.April,  1978.

           Compilation of Air Pollutant Emission  Factors.  AP-42.   3rd ed.  U.S. EPA.
                July, 1979.

           Cooper, D.W. et  al.,  J.S.  Sullivan, M.  Quinn,  R.C.  Antonelli,  and  M.
                Schneider.   Setting Priorities for Control of Fugitive Particulate
                Emissions from Open Sources.  EPA-600/7-79-186.   August,  1979.

           Cowherd, C. Jr.,  R. Bonn,  and T.  Cuscino  Jr.   Iron and Steel Plant Open
                Source Fugitive  Emission Evaluation.  EPA-600/2-79-103.   May, 1979.

           Cuscino, T.A. Jr.   Particulate Emission Factors Applicable to  the  Iron
                and Steel  Industry^EPA-450/4-79-028.September, 1979.
I
                                            7-1
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I
                            Articles (con't)

Duluth Metropolitan Area Bulk Storage Facility Inventory and Fugitive
     Emission Summary.  Minnesota Pollution Control Agency.  April, 1978.

Environmental Management Strategy for the Great Lakes System.  Interna-
     tionat Reference Group on Great Lakes Pollution from Land Use Activ-
     ities.  Windsor, Ontario.   July, 1978.

Great Lakes Science Advisory Board Annual Report.  International Joint
     Commission.  July, 1979.

Great Lakes Water Quality.  International Joint Commission.  Windsor,
     Ontario.  July, 1979.

Kolnsberg, H.J.  Development of Measurement Techniques for Fugitive
     Emissions from Process and Effluent Streams.  EPA-600/7-70-116.
     May, 1979.

Laube, A.H., and B.A. Drummond.  Coke Quench Tower Emission Testing
     Program.  EPA-600/2-79-082.  April, 1979.

McCutchen, G.  Overview of Fugitive Emissions.  Second Symposium on
     Fugitive Emissions:  Measurement and Control.  EPA-600/7-77-148.
     December, 1977.

Sievering, H. et al., M. Dave1 , D.A. Dolske, R.L. Hughes, and P. McCoy.
     An Experimental Study of Lake Loading by Aerosol Transport and Dry
     Deposition in the Southern Lake Michigan Basin.EPA-905/4-79-016.
»pos
Jly,
     July, 1979.

Technical Guidance for Control of Industrial Process Fugitive Particulate
     Emissions.  EPA-450/3-77-010.  March, 1977.

Technical Analysis of the Adequacy of the State Implementation Plan for
     the Attainment and Maintenance of Suspended Particulate Ambient Air
     Quality .Standards in the Chicago Air Quality Maintenance Area.  IEPA,
     Division of Air Pollution Control.  August, 1979.

Venditti, F.P., J.A. Armstrong, and M. Durham.  Symposium on the Transfer
     and Utilization of Particulate Control Technology — Volume 4 _- Fugi-
     tive Dusts and Sampling, Analysis, and Characterization of Aerosols.
     EPA-600/7-79-044d.  February, 1979.
                                                                  *
Wallace, D., and C. Cowherd Jr.  Fugitive Emissions from Iron Foundries.
     EPA-600/7-79-195.  August, 1979.

Zoller, J., T. Bertke, and T. Janszen.  Assessment of Fugitive Particulate
     Emission Factors for Industrual Processes.  EPA-450/3-78-107.  Sep-
     tember, 1978.


                                   7-2
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                                           APPENDIX A
|                    STATE OF ILLINOIS FUGITIVE EMISSION SOURCE INVENTORY
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                                                                /
I
*                                        APPENDIX G
•                           LAKE  IMPACT  FROM THE STATE OF  ILLINOIS
I
I
I
I
I
I
I
I
I
I
-------
STATE OF:
Illinois
COUNTY:    Cook
SIC: 2400 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 62
PARTICLE SIZE: 1% less than 30 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 10
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 10
Wood Working
POTENTIAL LAKE
IMPACT (tons/yr): 62

MAR/MAY JUNE/AUG
13 24
100 100
13 24


SEPT/NOV
15
100
15

SIC: 4911 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 1932
PARTICLE SIZE: 50% less than 10 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 483
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 483
Coal Storage
POTENTIAL LAKE
IMPACT (tons/yr): 1932

MAR/MAY JUNE/AUG
483 483
100 100
483 483


SEPT/NOV
483
100
483
                                      6-1
-------
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
I
1
I
1
STATE OF: Illinois
SIC: 4221 PROCESS DESCRIPTION
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 7849-71556
PARTICLE SIZE: 10% less than 20 u
DEC/FEE
SEASONAL FUGITIVE
EMISSIONS 1174-13455
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 1174-13455

SIC: 3341 PROCESS DESCRIPTION
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 189
PARTICLE SIZE: 100% less than 1 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 47
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 47

COUNTY: Cook
: Grain Handling
POTENTIAL LAKE
IMPACT (tons/yr): 7849-71556

MAR/MAY JUNE/AUG SEPT/NOV
1444-12276 2089-16949 3142-28876
100 100 100
1444-12276 2089-16949 3142-28876

: Copper Smelting
POTENTIAL LAKE
IMPACT (tons/yr): 189

MAR/MAY JUNE/AUG SEPT/NOV
48 46 48
100 100 100
48 46 48
6-2
-------
STATE OF:
Illinois
COUNTY:    Cook
SIC: 3321 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 10
PARTICLE SIZE: 100% less than 20 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 2
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 2
Iron Cupola
POTENTIAL LAKE
IMPACT (tons/yr): 10

MAR/MAY JUNE/AUG
3 2
100 100
3 2


SEPT/NOV
3
100
3

SIC: 2951 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 450
PARTICLE SIZE: 60% less than 4 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 21
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 21
Asphalt Batching
POTENTIAL LAKE
IMPACT (tons/yr): 450

MAR/MAY JUNE/AUG
73 197
100 100
73 197


SEPT/NOV
159
100
159
                                      6-3
-------
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Illinois COUNTY: Cook
SIC: 3462 PROCESS DESCRIPTION: Steel Melting - EAF
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 314 - 342 IMPACT (tons/yr): 314 -
PARTICLE SIZE: 80% less than 5 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 78-85 79-86 79-86
WIND FREQUENCY
(% impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 78-85 79-86 79-86

SIC: 3270 PROCESS DESCRIPTION: Concrete Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 72 IMPACT (tons/yr): 72
PARTICLE SIZE: 20% less than 5 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 11 17 21
WIND FREQUENCY
(X impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 11 17 21
6-4


342
SEPT/NOV
78-85
100
78-85



SEPT/NOV
23
100
23

-------
STATE OF:     Illinois                  COUNTY:      Cook
SIC:   3270      PROCESS DESCRIPTION:     Cement Manufacturing
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    129	 IMPACT (tons/yr):    129
PARTICLE SIZE: 50%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
less than 20 u
DEC/FEB
14
100
14

MAR/MAY JUNE/AUG SEPT/NOV
30 46 39
100 100 100
30 46 39

SIC: 33 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
PARTICLE SIZE: 50%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
282-478
less than 15 u
DEC/FEB
70-119
100
70-119
Iron Finishing - Shot Blast
POTENTIAL LAKE
IMPACT (tons/yr): 282-478

MAR/MAY JUNE/AUG SEPT/NOV
71-120 71-120 70-119
100 100 100
71-120 71-120 70-119
                                     6-5
-------
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Illinois
SIC: 3340 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/.yr): 5
PARTICLE SIZE: 100% less than 1 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 1
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 1

SIC: 2816 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 6
PARTICLE SIZE: 100% less than 16 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 1
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 1

COUNTY: Cook
Al Smelting - Reverboratory fur.
POTENTIAL LAKE
IMPACT (tons/yr): 5

MAR/MAY JUNE/AUG SEPT/NOV
2 1 1
100 100 100
2 1 1

PbO Milling
POTENTIAL LAKE
IMPACT (tons/yr): 6

MAR/MAY JUNE/AUG SEPT/NOV
2 2 1
100 100 100
2 2 1
6-6
-------
STATE OF:    Illinois
COUNTY:
Cook
SIC: 3340 PROCESS DESCRIPTION: Zinc Smelting
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
PARTICLE SIZE: 100%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
POTENTIAL LAKE
18-46 IMPACT (tons/yr): 18-46
less than 1 u
DEC/FEB MAR/MAY JUNE/AUG
4-11 5-12 5-12
100 100 100
4-11 5-12 5-12

SEPT/NOV
4-11
100
4-11

SIC: 3274 PROCESS DESCRIPTION: Lime Handling
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
PARTICLE SIZE: 90%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
POTENTIAL LAKE
894 IMPACT (tons/yr): 894
less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
223 224 224
100 100 100
223 224 224

SEPT/NOV
223
100
223
                                     G-7
-------
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Illinois
SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 2201-5127
PARTICLE SIZE: 50% less than 70 u
DEC/FEE
SEASONAL FUGITIVE
EMISSIONS 550-1282
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 550-1282

SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 2478
PARTICLE SIZE: 50% less than 180 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 619
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 619

COUNTY: Cook
Iron Melting - Blast Furnace
POTENTIAL LAKE
IMPACT (tons/yr): 2201-5127

MAR/MAY JUNE/AUG SEPT/NOV
550-1282 550-1282 550-1282
100 100 100
550-1282 550-1282 550-1282

Iron Ore Handling
POTENTIAL LAKE
IMPACT (tons/yr): 2478

MAR/MAY JUNE/AUG SEPT/NOV
620 620 619
100 100 100
620 620 619
G-8
-------
STATE OF:    Illinois
COUNTY:
Cook
SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 2219-3390
Sintering
POTENTIAL LAKE
IMPACT (tons/yr): 2219-3390
PARTICLE SIZE: 10% less than 15 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 555-847
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 555-847
MAR/MAY JUNE/AUG SEPT/NOV
555-848 555-848 555-847
100 100 100
555-848 555-848 555-847

SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 21
Slag Handling
POTENTIAL LAKE
IMPACT (tons/yr): 21
PARTICLE SIZE: 50% less than 17 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 5
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 5
MAR/MAY OUNE/AUG SEPT/NOV
555
100 100 100
555
                                      6-9
-------
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Illinois
SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 2467
PARTICLE SIZE: 9Q% less than 10 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 617
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 617

SIC: 3399 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 181-222
PARTICLE SIZE: 50% less than 15 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 45-55
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 45-55
(
COUNTY: Cook
Cookinq Process
POTENTIAL LAKE
IMPACT (tons/yr): 2467

MAR/MAY JUNE/AUG SEPT/NOV
617 617 617
100 100 100
617 617 617

Core Oven
POTENTIAL LAKE
IMPACT (tons/yr): 181-222

MAR/MAY JUNE/AUG SEPT/NOV
45-56 45-56 45-55
100 100 100
45-56 45-56 45-55
3-10
-------
STATE OF:    Illinois
                       COUNTY:     Cook
SIC:   3312
PROCESS DESCRIPTION:     Steel Melting - BOF
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
        258
POTENTIAL LAKE
IMPACT (tons/yr):
258
PARTICLE SIZE: 90% less than 5 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 64 65 65
WIND FREQUENCY
(% impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 64 65 65
SEPT/NOV
64
100
64

SIC: 3312 PROCESS DESCRIPTION: Unpaved Road
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 1070 IMPACT (tons/yr): 1070
PARTICLE SIZE:
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 267 268 268
WIND FREQUENCY
(% impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 267 268 268
SEPT/NOV
267
100
267
                                     6-11
-------
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Illinois COUNTY: Cook
SIC: 3312 PROCESS DESCRIPTION: Iron Casting
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 886 - 5659 IMPACT (tons/yr): 886 -
PARTICLE SIZE: 1009$ less than 15 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 221-1415 222-1415 222-1415
WIND FREQUENCY
(% impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 221-1415 222-1415 222-1415

SIC: 2499 PROCESS DESCRIPTION: Aggregate Handling
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 1728 IMPACT (tons/yr): 1728
PARTICLE SIZE:
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 432 432 432
WIND FREQUENCY
(% impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 432 432 432
G-12


5659
SEPT/NOV
221-1415
100
221-1415



SEPT/NOV
432
100
432

-------
STATE OF:   Illinois                    COUNTY:      Lake
SIC:   11        PROCESS DESCRIPTION:    Coal Storage
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   23698-31379      IMPACT (tons/yr):   23698-31379
PARTICLE SIZE:  50% less than 10 u
	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	5924-7845     5925-7845	5925-7845      5924-7845

WIND FREQUENCY
  (% impact on lake)      100	100	100	100

SEASONAL IMPACT
  (tons)	5924-7845     5925-7845	5925-7845      5924-7845
SIC:   3341      PROCESS DESCRIPTION:   Iron Melting - Reverberatory Furnace


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):     25	 IMPACT  (tons/yr):     25	
PARTICLE SIZE:   100%  less than 1 u
	DEC/FEB       MAR/MAY	JUNE/AUG        SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	6	6	6	6

WIND FREQUENCY
   (% impact  on  lake)       100	100	100	100

SEASONAL IMPACT
   (tons)	6	6	6	6
                                     6-13
-------
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Illinois COUNTY: Lake
SIC: 3341 PROCESS DESCRIPTION: Iron Cupola
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 11 IMPACT (tons/yr): 11
PARTICLE SIZE: 100% less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 23 2
WIND FREQUENCY
(% impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 23 2

SIC: 2951,3273 PROCESS DESCRIPTION: Unpaved Road
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 70 IMPACT (tons/yr): 70
PARTICLE SIZE: —
DEC/FEB MAR/MAY OUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 8 8 24
WIND FREQUENCY
(% impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 8 8 24
G-14



SEPT/NOV
4
100
4



SEPT/NOV
22
100
22

-------
STATE OF:    Illinois                   COUNTY:     Lake
SIC: 3275 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 32
PARTICLE SIZE: 100% less than 100 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 7
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 7
Rock Handling
POTENTIAL LAKE
IMPACT (tons/yr): 32

MAR/MAY JUNE/AUG
8 9
100 100
8 9


SEPT/NOV
8
100
8

SIC: 2951 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 425
PARTICLE SIZE: 60% less than 4 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 20
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 20
Asphalt Batching
POTENTIAL LAKE
IMPACT (tons/yr): 425

MAR/MAY JUNE/AUG
40 211
100 100
40 211


SEPT/NOV
154
100
154
                                      6-15
-------
1
1
1
1
1
1
1
I
1
1
1
i
1
1
1
1
1
1
1
STATE OF: Illinois COUNTY: Lake
SIC: 3275 PROCESS DESCRIPTION: Gypsum Manufacturing
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 65 IMPACT (tons/yr): 65
PARTICLE SIZE: 95% less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 13 16 20
WIND FREQUENCY
(% impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 13 16 20

SIC: 3241 PROCESS DESCRIPTION: Cement Manufacturing
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): . 152 IMPACT (tons/yr): 152
PARTICLE SIZE: 58% less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 15 46 46
WIND FREQUENCY
(% impact on lake) 100 100 100
SEASONAL IMPACT
(tons) 15 46 46
6-16



SEPT/NOV
16
100
16



SEPT/NOV
45
100
45

-------
STATE OF:
Illinois
COUNTY:
Lake
SIC:   3273
  PROCESS DESCRIPTION:     Concrete Batching
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
          44
POTENTIAL LAKE
IMPACT (tons/yr)
        44
PARTICLE SIZE:    20% less than 5 u
                        DEC/FEB
                       MAR/MAY
             OUNE/AUG
              SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS
                                          16
                                13
WIND FREQUENCY
  (% impact on lake)

SEASONAL IMPACT
  (tons)	
           100
100
  100
                                          16
100
                                13
                                     G-17
-------
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                                          APPENDIX H
I                           LAKE IMPACT FROM THE STATE OF INDIANA
I
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-------
STATE OF:     Indiana                   COUNTY:      Lake
SIC:   2046      PROCESS DESCRIPTION:     Grain Handling
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   5819-19406       IMPACT (tons/yr):    5819-19406	•


PARTICLE SIZE:    10% less than 20 u                                            _
PARTICLE SIZE:    50% less than 15 u
                                                                                I
	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	1455-4852     1455-4852	1455-4852      1455-4852   •

WIND FREQUENCY
  (% impact on lake)      100	100	100	100      -

SEASONAL IMPACT                                                                 ™
  (tons)	1455-4852     1455-4852	1455-4852      1455-4852
SIC:   3325      PROCESS DESCRIPTION:      Foundry Sand Handling
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    218-323	 IMPACT (tons/yr):    218-323
	DEC/FEB       MAR/MAY	JUNE/AUG       SEPT/NOV    •

SEASONAL FUGITIVE
EMISSIONS	54-81	56-81	55-81	54-81     m

WIND FREQUENCY
   (% impact on lake)      100	100	100	100

SEASONAL IMPACT                                                                 •
   (tons)	54-81	56-81	55-81	54-81


                                 H-l
-------
1
1

1



1
1
1

1

1





1

1


1

1






1


STATE OF: Indiana

SIC: 3325 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 641-6733

PARTICLE SIZE: 50% less than 15 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 160-1683

WIND FREQUENCY
(% impact on lake) 100

SEASONAL IMPACT
(tons) 160-1683


SIC: 3325 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 325

PARTICLE SIZE: 80% less than 5 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 81

WIND FREQUENCY
(% impact on lake) 100

SEASONAL IMPACT
(tons) 81

H-2


COUNTY: Lake

Foundry Cleaning

POTENTIAL LAKE
IMPACT (tons/yr): 641-6733



MAR/MAY JUNE/AUG SEPT/NOV


160-1683 160-1683 160-1683


100 100 100


160-1683 160-1683 160-1683


Steel Meltinq - Electric

POTENTIAL LAKE
IMPACT (tons/yr): 325



MAR/MAY JUNE/AUG SEPT/NOV


81 81 81


100 100 100


81 81 81


-------
STATE OF:       Indiana	  COUNTY: 	Lake	


                                                                                I

SIC:   2951      PROCESS DESCRIPTION:      Asphalt Batching	


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    220	 IMPACT (tons/yr):     220	 •


PARTICLE SIZE:    60% less than 4 u                                             _



	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV    I

SEASONAL FUGITIVE
EMISSIONS	3	56	93	68      •

WIND FREQUENCY
  (% impact on lake)      100	100	100	100      •

SEASONAL IMPACT
  (tons)	3	56	93	68
SIC:   3341      PROCESS DESCRIPTION:       Lead Smelting
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):      341-952       IMPACT  (tons/yr):       341-952


PARTICLE SIZE:    100%  less  than 16  u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV   •

SEASONAL  FUGITIVE
EMISSIONS	85-238	85-238	85-238	85-238    •

WIND  FREQUENCY
   (%  impact  on  lake)       100	100	100	100       -

SEASONAL  IMPACT                                                                •
   (tons)	85-238	85-238	85-238	85-238



                                 H-3                                            •
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1
1
1



1
1
1

1

1





1

1


1

1






1
STATE OF: Indiana COUNTY: Lake

SIC: 3312 PROCESS DESCRIPTION: Coking Process

POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 46619 IMPACT (tons/yr): 46619

PARTICLE SIZE: 90% less than 10 u

DEC/FEE MAR/MAY JUNE/AU6 .

SEASONAL FUGITIVE
EMISSIONS 11655 11655 11655

WIND FREQUENCY
(% impact on lake) 100 100 100

SEASONAL IMPACT
(tons) 11655 11655 11655


SIC: 3312 PROCESS DESCRIPTION: Steel Melting - OHF

POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 160 IMPACT (tons/yr): 160

PARTICLE SIZE: 75% less than 5 u

DEC/FEB MAR/MAY JUNE/AUG

SEASONAL FUGITIVE
EMISSIONS 40 40 40

WIND FREQUENCY
(% impact on lake) 100 100 100

SEASONAL IMPACT
(tons) 40 40 40

H-4








SEPT/NOV


11655


100


11655









SEPT/NOV


40


100


40


-------
STATE OF:
Indiana
COUNTY:
Lake
SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 5427
PARTICLE SIZE: 90% less than 5 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 1357
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 1357
Steel Melting - BOF
POTENTIAL LAKE
IMPACT (tons/yr):

MAR/MAY JUNE/AUG
1357 1357
100 100
1357 1357

5427
SEPT/NOV
1357
100
1357

SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 6161
PARTICLE SIZE: 50% less than 70 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 1540
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 1540
Iron Melting - Blast
POTENTIAL LAKE
IMPACT (tons/yr):

MAR/MAY JUNE/AUG
1540 1540
100 100
1540 1540
Furnace
6161
SEPT/NOV
1540
100
1540
                                 H-5
-------
1
1

1



1
1
1

1

1







1


1

1

1







STATE OF: Indiana

SIC: 4911 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 1569-3365

PARTICLE SIZE: 50% less than 10 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 392-841

WIND FREQUENCY
(% impact on lake) 100

SEASONAL IMPACT
(tons) 392-841


SIC: 3312 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 50

PARTICLE SIZE: 100% less than 2 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 12

WIND FREQUENCY
(% impact on lake) 100

SEASONAL IMPACT
(tons) 12

H-6



COUNTY: Lake

Coal Storage

POTENTIAL LAKE
IMPACT (tons/yr): 1569-3365



MAR/MAY JUNE/AUG SEPT/NOV


392-841 392-841 392-841


100 100 100


392-841 392-841 392-841


Steel Scarfing

POTENTIAL LAKE
IMPACT (tons/yr): 50



MAR/MAY JUNE/AUG SEPT/NOV


13 12 13


100 100 100


13 12 13



-------
STATE OF:    Indiana                    COUNTY:       Lake
SIC:   3312      PROCESS DESCRIPTION:      Sintering
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    3120-8969       IMPACT (tons/yr):    3120-8969	.


PARTICLE SIZE:    10% less than 5 u



	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV    •

SEASONAL FUGITIVE
EMISSIONS	780-2242	780-2242	780-2242	780-2242    •

WIND FREQUENCY
  (% impact on lake)     100	100	100	100       _

SEASONAL IMPACT                                                                 •
  (tons)	780-2242	780-2242	780-2242	780-2242
SIC:    3275     PROCESS DESCRIPTION:     Gypsum Product
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):       189	 IMPACT  (tons/yr):      189
PARTICLE SIZE:    95% less than 20 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	47	47	47	47

WIND FREQUENCY
   (% impact on  lake)      100	100	100	100

SEASONAL IMPACT
   (tons)	47	.  47	47	47
                                 H-7
-------
1
1
1



1
1
1

1

1



1



1


1

1






1
STATE OF: Indiana

SIC: 3241 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 3456-5966

PARTICLE SIZE: 58% less than 20 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 864-1491

WIND FREQUENCY
(% impact on lake) 100

SEASONAL IMPACT
(tons) 864-1491



SIC: 3341 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 45

PARTICLE SIZE: 100% less than 1 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 11

WIND FREQUENCY
(% impact on lake) 100

SEASONAL IMPACT
(tons) 11

H-8
COUNTY: Lake

Cement Manufacturing

POTENTIAL LAKE
IMPACT (tons/yr): 3456-5966



MAR/MAY JUNE/AUG SEPT/NOV


864-1492 864-1492 864-1491


100 100 100


864-1492 864-1492 864-1491



Copper Smelting

POTENTIAL LAKE
IMPACT (tons/yr): 45



MAR/MAY JUNE/AUG SEPT/NOV


11 11 11


100 100 100


11 11 11
-

-------
STATE OF:    Indiana	  COUNTY:     Lake	

                                                                                I
SIC:   3341      PROCESS DESCRIPTION:     Zinc Smelting	


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):       9	 IMPACT (tons/yr):     9	•


PARTICLE SIZE:    100% less than 1 u                                            .
	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	2	2	2	2

WIND FREQUENCY
  (% impact on lake)     100	100	100	100

SEASONAL IMPACT
  (tons)                   2	2	2	2
SIC:   3274      PROCESS DESCRIPTION:     Lime Calcining
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    954	 IMPACT  (tons/yr):       954
PARTICLE SIZE:    95%  less than 20 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL  FUGITIVE
EMISSIONS	238	239	239	238

WIND  FREQUENCY
   (%  impact  on  lake)      100	100	100	100

SEASONAL  IMPACT
   (tons)	238	239	239	238
                                 H-9
I
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1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Indiana
SIC: 3341 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 207
PARTICLE SIZE: 100% less than 2 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 52
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 52

SIC: 3273 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 453
PARTICLE SIZE: 20% less than 5 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 92
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 92
H-10
COUNTY: Lake
Aluminum Smelting Furnace
POTENTIAL LAKE
IMPACT (tons/yr): 207

MAR/MAY JUNE/AUG SEPT/NOV
52 52 52
100 100 100
52 52 52

Concrete Batching
POTENTIAL LAKE
IMPACT (tons/yr): 453

MAR/MAY JUNE/AUG SEPT/NOV
112 147 102
100 100 100
112 147 102

-------
STATE OF:     Indiana                   COUNTY:     Lake
SIC:   1499      PROCESS DESCRIPTION:    Mineral Handling
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    383	 IMPACT (tons/yr):     383
PARTICLE SIZE:   100% less than 100 u
	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV    1

SEASONAL FUGITIVE
EMISSIONS	81	111	111	80      •

WIND FREQUENCY
  (% impact on lake)      100	100	100	100      •

SEASONAL IMPACT
  (tons)	81	111	111	80      •
                                 H-ll
-------
STATE OF:     Indiana                   COUNTY:     Porter
SIC:   3312      PROCESS DESCRIPTION:      Iron Melting - Blast Furnace
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):      1502	 IMPACT (tons/yr):     872
PARTICLE SIZE:    50% less than 70 u
	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	375	376	376	375

WIND FREQUENCY
  (% impact on lake)	0	66	100	66

SEASONAL IMPACT
  (tons)	0	248	376	248
SIC:   3312      PROCESS DESCRIPTION:     Steel Melting - BOF
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):     1976	 IMPACT (tons/yr):     1146
PARTICLE SIZE:     90% less than 5 u
	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	494	494	494	494

WIND FREQUENCY
  (% impact on lake)	0	66	100	66

SEASONAL IMPACT
  (tons)	0	326             494            326
                                H-12
-------
STATE OF:      Indiana                  COUNTY:    Porter
SIC:    3312     PROCESS DESCRIPTION:   Steel Scarfing
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):      11	 IMPACT (tons/yr):
PARTICLE SIZE:    100% less than 2 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	3	3	3	3

WIND FREQUENCY
  (% impact on lake)	0	66	100	66

SEASONAL IMPACT
SIC:   3312      PROCESS DESCRIPTION:       Coking Process
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):     4100	 IMPACT  (tons/yr):      2378
PARTICLE SIZE:    90%  less  than 10 u
                        DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV
 SEASONAL FUGITIVE
 EMISSIONS	1025	1025	1025	1025

 WIND  FREQUENCY
   (%  impact  on  lake)	0	66	100	66_

 SEASONAL IMPACT
   (tons!	Q	677	1025	677
                                H-13
-------
1
1

1



1
1
1



1

1
1



1
1
1

1

1



1


STATE OF: Indiana

SIC: 3312 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 1294-3719

PARTICLE SIZE: 10% less than 5 u

DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 323-930

WIND FREQUENCY
(% impact on lake) 0

SEASONAL IMPACT
(tons) 0



SIC: 4911 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 411-872

PARTICLE SIZE: 50% less than 10 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 103-218

WIND FREQUENCY
(% impact on lake) 0

SEASONAL IMPACT
(tons) 0




COUNTY: Porter

Sintering

POTENTIAL LAKE
IMPACT (tons/yr): 752-2158



MAR/MAY JUNE/AUG SEPT/NOV

324-930 324-930 323-930


66 100 66


214-614 324-930 214-614



Coal Storage

POTENTIAL LAKE
IMPACT (tons/yr): 239-506



MAR/MAY JUNE/AUG SEPT/NOV


103-218 103-218 103-218


66 100 66


68-144 103-218 68-144


H-14
-------
STATE OF:    Indiana                    COUNTY:       Porter
SIC: 5153 PROCESS DESCRIPTION: Grain Handling
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 59 IMPACT (tons/yr): 35
PARTICLE SIZE: 10% less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 15 15 15
WIND FREQUENCY
(% impact on lake) 0 66 100
SEASONAL IMPACT
(tons) 0 10 15
SEPT/NOV
15
66
10

SIC: 2951 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 31 IMPACT (tons/yr): 22
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 22 9
WIND FREQUENCY
(% impact on lake) 0 66 100
SEASONAL IMPACT
(tons) 01 9
SEPT/NOV
18
66
12
                                H-15
-------
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                                          APPENDIX I
                            LAKE  IMPACT FROM THE STATE OF MICHIGAN
-------
STATE OF:     Michigan	  COUNTY:     Presque  Isle
SIC:   1422      PROCESS DESCRIPTION:     Stone Crushing
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   11888	 IMPACT (tons/yr):    7877
PARTICLE SIZE:   100% less than 100 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	2972	2972	2972	2972

WIND FREQUENCY
  (% impact on lake)	66	33	66	100

SEASONAL IMPACT
  (tons)	1962	981	1962	2972
SIC:    1422     PROCESS DESCRIPTION:      Coal Storage
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):      3-6	 IMPACT  (tons/yr):     2-4
PARTICLE SIZE:    50%  less than 10 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV    -

SEASONAL FUGITIVE                                                                •
EMISSIONS	0.75-1	1^2	1^2	0.75-1

WIND  FREQUENCY                                                                   I
   (%  impact  on  lake)	66	33	66	100	

SEASONAL IMPACT                                                                 I
   (tons)	0.5-1	0.3-0.6	0.7-1.2	0.75-1
                                 1-1
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1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Michigan COUNTY: Macomb
SIC: 3273 PROCESS DESCRIPTION: Concrete Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 122 IMPACT (tons/yr): 72
PARTICLE SIZE: 20% less than 5 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 30 31 31
WIND FREQUENCY
(% impact on lake) 100 33 33
SEASONAL IMPACT
(tons) 30 10 10

SIC: 2951 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 18 IMPACT (tons/yr): 11
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 45 5
WIND FREQUENCY
(% impact on lake) 100 33 33
SEASONAL IMPACT
(tons) 42 2
1-2



SEPT/NOV
30
66
22



SEPT/NOV
4
66
3

-------
STATE OF:     Michigan	  COUNTY:     Macomb
SIC:    3362     PROCESS DESCRIPTION:    El Furnace
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):      2	 IMPACT (tons/yr): 	1
PARTICLE SIZE:    100% less than 1 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	0.5	0.5	0.5	0.5

WIND FREQUENCY
  (% impact on lake)	100	33	33	66

SEASONAL IMPACT
  (tons)	       0.5	0.2	0.2	0.3
SIC:   3321      PROCESS DESCRIPTION:    Foundry Mailer/Shake Out
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    69-675	 IMPACT  (tons/yr):    40-392
PARTICLE SIZE:    50% less than 15 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV     •

SEASONAL FUGITIVE                                                                ™
EMISSIONS	17-169	17-169	17-169	17-169

WIND  FREQUENCY                                                                   •
   (%  impact on  lake)       100	33	33	66

SEASONAL IMPACT                                                                 I
   (tons)	17-169	6-56	6-56	11-111
                                 1-3
-------
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STATE OF:   Michigan
                       COUNTY:
             Macomb
SIC:   3321
PROCESS DESCRIPTION:     Cupola
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):    30-343
                       POTENTIAL LAKE
                       IMPACT (tons/yr):    18-199
PARTICLE SIZE:    100% less than 20 u
                        DEC/FEB
                     MAR/MAY
SEASONAL FUGITIVE
EMISSIONS
         7-86
8-86
WIND FREQUENCY
  (% impact on lake)
         100
 33
SEASONAL IMPACT
  (tons)	
         7-86
3-28
                                 1-4
             JUNE/AUG
8-86
 33
3-28
             SEPT/NOV
7-86
 66
5-57
-------
STATE OF:  Michigan	  COUNTY:    Huron
SIC:   4911      PROCESS DESCRIPTION:    Coal Storage
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   123-249	 IMPACT (tons/yr):     123-249
PARTICLE SIZE:    50% less than 10 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV     |

SEASONAL FUGITIVE
EMISSIONS	31-62	31-62	31-62	31-62      -

WIND FREQUENCY                                                                   *
  (% impact on lake)      100	100	100	100

SEASONAL IMPACT                                                                  I
  (tons)	31-62	31-62	31-62	31-62

                                                                                 I
SIC:     1422     PROCESS DESCRIPTION:      Sand Crushing
POTENTIAL FUGITIVE                       POTENTIAL LAKE
EMISSIONS (tons/yr):     688-1288        IMPACT  (tons/yr):    688-1288
PARTICLE SIZE:    100%  less  than  100  u
	DEC/FEB        MAR/MAY	JUNE/AUG        SEPT/NOV    .

SEASONAL FUGITIVE
EMISSIONS	172-322	172-322	172-322	172-322

WIND  FREQUENCY                                                                   •
   (%  impact  on  lake)       100	100	100	100

SEASONAL IMPACT                                                                 I
   (tons)	172-322	172-322	172-322	172-322
                                 1-5
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STATE OF: Michigan COUNTY: Arenac

SIC: 1422 PROCESS DESCRIPTION: Stone Crushing

POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 22-41 IMPACT (tons/yr): 22-37

PARTICLE SIZE: 100% less than 100 u

DEC/FEB MAR/MAY JUNE/AUG

SEASONAL FUGITIVE
EMISSIONS 6-10 6-10 6-10

WIND FREQUENCY
(56 impact on lake) 100 100 66

SEASONAL IMPACT
(tons) 6-10 6-10 4-7


SIC: 3274 PROCESS DESCRIPTION: Lime Milling

POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 39 IMPACT (tons/yr): 36

PARTICLE SIZE: 95% less than 20 u

DEC/FEB MAR/MAY JUNE/AUG

SEASONAL FUGITIVE
EMISSIONS 10 10 10

WIND FREQUENCY
(% impact on lake) 100 100 66

SEASONAL IMPACT
(tons) 10 10 7

1-6











SEPT/NOV


6-10


100


6-10









SEPT/NOV


9


100


9


-------
STATE OF:     Michigan
COUNTY:     Bay
SIC: 2950 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 17 IMPACT (tons/yr): 16
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 44 4
WIND FREQUENCY
(% impact on lake) 100 100 66
SEASONAL IMPACT
(tons) 44 3
SEPT/NOV
5
100
5

SIC: 3272 PROCESS DESCRIPTION: Concrete Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 5 IMPACT (tons/yr): 4
PARTICLE SIZE: 20% less than 25 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 11 2
WIND FREQUENCY
(% impact on lake) 100 100 66
SEASONAL IMPACT
(tons) 1 1 1
SEPT/NOV
1
100
1
                                 1-7
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STATE OF: Michigan
SIC: 3321 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 20-194
PARTICLE SIZE: 50% less than 15 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 5-49
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) ' 5-49

SIC: 4221 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 47-639
PARTICLE SIZE: 100% less than 20 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 12-160
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 12-160
1-8
COUNTY: Bay
Shakeout and Finishing
POTENTIAL LAKE
IMPACT (tons/yr): 18-179

MAR/MAY JUNE/AUG SEPT/NOV
5-49 5-49 5-49
100 66 100
5-49 3-32 5-49

Grain Drying
POTENTIAL LAKE
IMPACT (tons/yr): 44-586

MAR/MAY JUNE/AUG SEPT/NOV
12-160 12-160 12-160
100 100 100
12-160 8-106 12-160

-------
STATE OF:    Michigan	  COUNTY:     Bay
SIC:   4911      PROCESS DESCRIPTION:    Coal Storage
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    501-1014	 IMPACT (tons/yr):    458-930
PARTICLE SIZE:   50% less than 10 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV    •

SEASONAL FUGITIVE
EMISSIONS	125-254	125-254	125-254	125-254    -

WIND FREQUENCY                                                                  *
  (% impact on lake)      100	100	66	100

SEASONAL IMPACT                                                                 •
  (tons)	125-254	125-254	83-168	125-254

                                                                                I
SIC:   3321      PROCESS DESCRIPTION:    EAF -  Iron  and  Steel Melting
POTENTIAL  FUGITIVE                       POTENTIAL  LAKE
EMISSIONS  (tons/yr):    16-31	 IMPACT  (tons/yr):       15-29
PARTICLE SIZE:     100%  less  than 1 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL  FUGITIVE
EMISSIONS	4-8	4I8	4^	4-8

WIND  FREQUENCY
   (%  impact  on  lake)      100	100	66	100

SEASONAL  IMPACT
   (tons)	4-8	4-8	3-5	4-8
                                 1-9
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STATE OF: Michigan
SIC: 3714 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 19
PARTICLE SIZE: 100% less than 2 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 5
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 5

SIC: 3241 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 1019-1529
PARTICLE SIZE: 58% less than 20 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 255-382
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 255-382
COUNTY: Bay
Zinc Pot Furnace
POTENTIAL LAKE
IMPACT (tons/yr): 18

MAR/MAY JUNE/AUG SEPT/NOV
545
100 66 100
535

Cement Grinding
POTENTIAL LAKE
IMPACT (tons/yr): 933-1398

MAR/MAY JUNE/AUG SEPT/NOV
255-382 255-382 255-382
100 66 100
255-382 168-252 255-382
1-10
-------
STATE OF:     Michigan	  COUNTY:      Qntonagon
SIC:   2631      PROCESS DESCRIPTION:     Coal Storage
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    48-97	 IMPACT (tons/yr):    12-24
PARTICLE SIZE:    50% less than 10 u
	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV     •

SEASONAL FUGITIVE
EMISSIONS	12-24	12-24	12-24	12-24

WIND FREQUENCY                                                                   *
   (% impact on lake)	0	66	33	0	

SEASONAL IMPACT                                                                  1
   (tons)	0	8-16	4-8	0
SIC:   1021       PROCESS DESCRIPTION:      Copper Smelting
POTENTIAL FUGITIVE                       POTENTIAL LAKE
EMISSIONS (tons/yr):   3931	 IMPACT  (tons/yr):      973
PARTICLE SIZE:    50%  less than 37 u
	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	983	983	983	983

WIND  FREQUENCY
   (%  impact  on  lake)	0	66	33	0

SEASONAL IMPACT
   (tons)	     0	649	324	0
                                 1-11
-------
I



              STATE  OF:      Michigan	  COUNTY:      Marquette


I
              SIC:   4911       PROCESS  DESCRIPTION:      Coal  Storage	

I
              POTENTIAL  FUGITIVE                       POTENTIAL  LAKE
•            EMISSIONS  (tons/yr):    595-1202	 IMPACT  (tons/yr):    347-701


—            PARTICLE SIZE:    50%  less  than  10  u
I
DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV
               SEASONAL  FUGITIVE
•             EMISSIONS	149-301	149-301	149-301	149-301

               WIND  FREQUENCY
_               (%  impact  on  lake)	33	0	100	100

*             SEASONAL  IMPACT
                 (tons)	49-99	0	149-301	149-301



I             =—=———=—



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                                               1-12

I
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STATE OF:     Michigan	  COUNTY:      Chippewa
SIC:    1611     PROCESS DESCRIPTION:    Asphalt Batching
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):     6	 IMPACT (tons/yr): 	4
PARTICLE SIZE:    60% less than 20 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	1	2	2	1

WIND FREQUENCY
  (% impact on lake)	33	100	100	0

SEASONAL IMPACT
  (tons)	0	2	2	0
SIC:   1422      PROCESS DESCRIPTION:    Stone Crushing
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   2387-4466	 IMPACT  (tons/yr):      1391-2603


PARTICLE SIZE:  100%  less than 100 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV     ^

SEASONAL FUGITIVE                                                                "
EMISSIONS	597-1117      597-1117	597-1117	597-1117

WIND  FREQUENCY                                   -                                •
   (%  impact  on  lake)	33	100	100	0	

SEASONAL IMPACT                                                                 |
   (tons)	           197-369       597-1117	597-1117	0
                                 1-13
-------
I

               STATE  OF:      Michigan	  COUNTY:     Alger	
I
               SIC:      2621     PROCESS  DESCRIPTION:     Coal  Storage	
               POTENTIAL  FUGITIVE                       POTENTIAL LAKE
m             EMISSIONS  (tons/yr):     16-32	 IMPACT (tons/yr):      9-19
               PARTICLE  SIZE:    50% less  than  10  u
I
1
DEC/FEB       MAR/MAY	JUNE/AUG       SEPT/NOV
               SEASONAL  FUGITIVE
m             EMISSIONS _ 4-8 _ 4-8 _ 4-8 _ 4-8
               WIND FREQUENCY
.               (% impact  on  lake) _ 33 _ 0 _ 100 _ 100
               SEASONAL  IMPACT
                 (tons) _ 1^3 _ 0 _ 4-8 _ 4-8
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1                                             1-14
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STATE OF:    Michigan
                       COUNTY:     Monroe
SIC:    4911     PROCESS DESCRIPTION:     Coal Storage
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):   2213-4477
                       POTENTIAL LAKE
                       IMPACT (tons/yr):    1836-3716
PARTICLE SIZE:    50% less than 10 u
                        DEC/FEB
                     MAR/MAY
               JUNE/AUG
               SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS
       553-1119
553-1119
553-1119
553-1119
WIND FREQUENCY
  (% impact on lake)
         100
   66
   66
  100
SEASONAL IMPACT
  (tons)	
       553-1119
365-739
365-739
553-1119
SIC:   3273
PROCESS DESCRIPTION:   Concrete Batching
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
                       POTENTIAL LAKE
                       IMPACT (tons/yr)
PARTICLE SIZE:    2Q%  less than 5 u
                        DEC/FEB
                     MAR/MAY
               JUNE/AUG
               SEPT/NOV
 SEASONAL FUGITIVE
 EMISSIONS
WIND FREQUENCY
   (% impact on  lake)
         100
   66
    66
  100
 SEASONAL  IMPACT
   (tons)    	
                        0.6
                   0.6
                                      1-15
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STATE OF: Michigan
SIC: 2082 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 761-1695
PARTICLE SIZE: 10% less than 20 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 190-424
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 190-424

SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 24
PARTICLE SIZE: 100% less than 2 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 6
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 6

COUNTY: Wayne
Grain Handling
POTENTIAL LAKE
IMPACT (tons/yr): 441-984

MAR/MAY JUNE/AUG SEPT/NOV
190-424 190-424 190-424
33 33 66
63-140 63-140 125-280

Steel Scarfing
POTENTIAL LAKE
IMPACT (tons/yr): 14

MAR/MAY JUNE/AUG SEPT/NOV
666
33 33 66
224
1-16
-------
STATE OF:    Michigan	  COUNTY:     Wayne
SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 2259
PARTICLE SIZE: 90% less than 5 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 565
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 565
Steel Production - BOF
POTENTIAL LAKE
IMPACT (tons/yr): 1310

MAR/MAY JUNE/AUG
565 565
33 33
186 186


SEPT/NOV
565
66
373

SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 1126
PARTICLE SIZE: 100% less than 1 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 281
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 281
Steel Melting - EAF
POTENTIAL LAKE
IMPACT (tons/yr): 652

MAR/MAY JUNE/AUG
282 282
33 33
93 93


SEPT/NOV
281
66
185
                                      1-17
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STATE OF: Michigan
SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 6958
PARTICLE SIZE: 90% less than 10 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 1739
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 1739

SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 897-2579
PARTICLE SIZE: 10% less than 5 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 224-645
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 224-645

COUNTY: Wayne
Coking Process
POTENTIAL LAKE
IMPACT (tons/yr): 4035

MAR/MAY JUNE/AUG SEPT/NOV
1740 1740 1739
33 33 66
574 574 1148

Iron Sintering
POTENTIAL LAKE
IMPACT (tons/yr): 520-1497

MAR/MAY JUNE/AUG SEPT/NOV
224-645 224-645 224-645
33 33 66
74-213 74-213 148-426
1-18
-------
STATE OF:     Michigan	  COUNTY:      Wayne
SIC:   3275      PROCESS DESCRIPTION:    Gypsum Manufacturing
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    2031	 IMPACT (tons/yr):     1179
PARTICLE SIZE: 95%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
less than 20 u
DEC/FEB
508
100
508

MAR/MAY JUNE/AUG SEPT/NOV
508 508 508
33 33 66
168 168 335

SIC: 3241 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
PARTICLE SIZE: 58%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
2968
less than 20 u
DEC/FEB
742
100
742
Cement Manufacturing
POTENTIAL LAKE
IMPACT (tons/yr): 1722

MAR/MAY JUNE/AUG SEPT/NOV
742 742 742
33 33 66
245 245 490
                                      1-19
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STATE OF: Michigan COUNTY: Wayne
SIC: 3274 PROCESS DESCRIPTION: Lime Calcining
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 935 - 1263 IMPACT (tons/yr): 542-733
PARTICLE SIZE: 95% less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 234-316 234-316 234-316
WIND FREQUENCY
(% impact on lake) 100 33 33
SEASONAL IMPACT
(tons) 234-316 77-104 77-104

SIC: 2951 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 79 IMPACT (tons/yr): 47
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 20 20 20
WIND FREQUENCY
(% impact on lake) 100 33 33
SEASONAL IMPACT
(tons) 20 7 7
1-20



SEPT/NOV
234-316
66
154-209



SEPT/NOV
20
66
13

-------
STATE OF:   Michigan	  COUNTY:    Wayne
SIC:   3341      PROCESS DESCRIPTION:     Lead Smelting
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):     11	 IMPACT (tons/yr): 	6
PARTICLE SIZE:    100% less than 16 u
	DEC/FEB	MAR/MAY        JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	3	3	3	2

WIND FREQUENCY
  (% impact on lake)     100	33	33	66

SEASONAL IMPACT
  (tons)	3	1	1	1
SIC:   4911      PROCESS DESCRIPTION:     Coal Storage
POTENTIAL FUGITIVE                       POTENTIAL  LAKE
EMISSIONS (tons/yr):     1521-3062        IMPACT  (tons/yr):    881-1776
PARTICLE SIZE:   50%  less  than  10  u
	DEC/FEB        MAR/MAY	JUNE/AUG       SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	380-765	380-766	380-766	380-765

WIND FREQUENCY
   (% impact  on  lake)	100	33	33	66

SEASONAL IMPACT
   (tons)	380-765	125-253	125-253	251-505
                                      1-21
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STATE OF: Michigan
SIC: 3295 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 570
PARTICLE SIZE: 100% less than 100 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 142
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 142

SIC: 3255 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 94
PARTICLE SIZE: 10% less than 100 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 23
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 23

COUNTY: Wayne
Stone Crushing
POTENTIAL LAKE
IMPACT (tons/yr): 330

MAR/MAY JUNE/AUG SEPT/NOV
143 143 142
33 33 66
47 47 94

Casting Refractory Crushing
POTENTIAL LAKE
IMPACT (tons/yr): 54

MAR/MAY JUNE/AUG SEPT/NOV
24 24 23
33 33 66
8 8 15
1-22
-------
STATE OF:    Michigan	  COUNTY:      Wayne
SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 2125-3243
Iron Blast Furnace
POTENTIAL LAKE
IMPACT (tons/yr): 1231-1882
PARTICLE SIZE: SQ% less than 70 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 531-811
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 531-811
MAR/MAY JUNE/AUG SEPT/NOV
531-811 531-811 531-811
33 33 66
175-268 175-268 350-535

SIC: 3321 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 182-1274
Iron Foundry - Cupola
POTENTIAL LAKE
IMPACT (tons/yr): 105-738
PARTICLE SIZE: 100% less than 20 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 45-318
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 45-318
MAR/MAY JUNE/AUG SEPT/NOV
46-319 46-319 45-318
33 33 66
15-105 15-105 30-210
                                      1-23
-------
STATE OF:     Michigan	  COUNTY:     Wayne
SIC:   3312      PROCESS DESCRIPTION:    Iron Ore Handling
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    3192	 IMPACT  (tons/yr):     1851
PARTICLE SIZE:   100% less than 100 u
	DEC/FEB       MAR/MAY	JUNE/AUG        SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	798	798	798	798

WIND FREQUENCY
  (% impact on lake)	100	33	33	66

SEASONAL IMPACT
  (tons)	798	263	263	527
SIC:   3312      PROCESS DESCRIPTION:    Casting Cleaning
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   249-2392	 IMPACT  (tons/yr):    143-1387
PARTICLE SIZE:    50% less than 15 u
	DEC/FEB       MAR/MAY	JUNE/AUG       SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	62-598	62-598	62-598	62-598

WIND FREQUENCY
  (% impact on lake)      100	33	33	66

SEASONAL IMPACT
  (tons)	62-598	20-197	20-197	41-395
                                     1-24
-------
STATE OF:     Michigan	  COUNTY:      Wayne
SIC: 3321 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 116-313
Iron Melting - EAF
POTENTIAL LAKE
IMPACT (tons/yr): 68-181
PARTICLE SIZE: 100% less than 1 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 29-78
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 29-78
MAR/MAY JUNE/AUG SEPT/NOV
29-78 29-78 29-78
33 33 66
10-26 10-26 19-51

SIC: 3362 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 11
Brass Electric Induction Furnace
POTENTIAL LAKE
IMPACT (tons/yr): 5
PARTICLE SIZE: 100% less than 1 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 3
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 3
MAR/MAY JUNE/AUG SEPT/NOV
333
33 33 66
1 1 1
                                      1-25
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*       STATE OF:     Michigan	  COUNTY:     School craft
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         SIC:  1422       PROCESS  DESCRIPTION:       Lime Mill	



         POTENTIAL FUGITIVE                       POTENTIAL LAKE
-       EMISSIONS (tons/yr):    5096	 IMPACT (tons/yr):     2115



         PARTICLE SIZE:    95%  less  than  20  u
__.	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV


SEASONAL FUGITIVE

EMISSIONS                1274          1274              1274           1274
"       WIND FREQUENCY
            (% impact  on  lake)	66	100	0	0_

•       SEASONAL  IMPACT
            (tons)	841	1274	0	0_




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                                               1-26
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STATE OF:
Michigan
  COUNTY:      Ottawa
SIC:   3272
  PROCESS DESCRIPTION:   Concrete Batching
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):   30
                         POTENTIAL LAKE
                         IMPACT (tons/yr):   5
PARTICLE SIZE:   20% less than 5 u
                        DEC/FEB
                       MAR/MAY
               JUNE/AU6
               SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS
                          8
WIND FREQUENCY
  (% impact on lake)
           66
   0
                   0
SEASONAL IMPACT
  (tons)	
                                          0
                                  0
SIC:   4911
  PROCESS DESCRIPTION:
     Coal Storage
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):   663-1340
                         POTENTIAL LAKE
                         IMPACT (tons/yr):    77-221
PARTICLE SIZE:    50* less than 10 u
                        DEC/FEB
                       MAR/MAY
               JUNE/AUG
               SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS
         166-335
166-335
166-335
166-335
WIND FREQUENCY
   (% impact on  lake)	66

SEASONAL  IMPACT
   (tons)  	77-221
                          0
                          0
                  0
                  0
                                      1-27
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STATE OF:    Michigan
              COUNTY:    Ottawa
SIC:    3362     PROCESS DESCRIPTION:    Foundry Shakeout
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):   25-259
              POTENTIAL LAKE
              IMPACT (tons/yr):    4-43
PARTICLE SIZE:    50% less than 15 u
                        DEC/FEB
            MAR/MAY
SEASONAL FUGITIVE
EMISSIONS
6-65
6-65
WIND FREQUENCY
  (% impact on lake)
 66
SEASONAL IMPACT
  (tons)	
4-43
                                     1-28
             JUNE/AUG
6-65
                 0
            SEPT/NOV
6-65
                0
                                0
-------
STATE OF:    Michigan
COUNTY:    Muskegon
SIC: 26 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 731-1476
PARTICLE SIZE: 50% less than 10 u
DEC/FEE
SEASONAL FUGITIVE
EMISSIONS 183-369
WIND FREQUENCY
(% impact on lake) 66
SEASONAL IMPACT
(tons) 121-244
Coal Storage
POTENTIAL LAKE
IMPACT (tons/yr): 121-244

MAR/MAY JUNE/AUG
183-269 183-369
0 0
0 0


SEPT/NOV
183-369
0
0

SIC: 3273 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 11
PARTICLE SIZE: 20% less than 5 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 3
WIND FREQUENCY
(% impact on lake) 66
SEASONAL IMPACT
(tons) 2
Concrete Batching
POTENTIAL LAKE
IMPACT (tons/yr): 2

MAR/MAY JUNE/AUG
3 3
0 0
0 0


SEPT/NOV
3
0
0
                                      1-29
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STATE OF:    Michigan	  COUNTY:    Muskegon
SIC:    3361     PROCESS DESCRIPTION:     Foundry Sand Handling
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    152-1482	 IMPACT (tons/yr):     25-244
PARTICLE SIZE: 50%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
less than 15 u
DEC/FEB MAR/MAY JUNE/AUG
38-370 38-371 38-371
66 0 0
25-244 0 0
SEPT/NOV
38-370
0
0

SIC: 3714 PROCESS DESCRIPTION: Iron Melting - Cupola
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
PARTICLE SIZE: 100%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
\
POTENTIAL LAKE
12-152 IMPACT (tons/yr): 2-25
less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
3-38 3-38 3-38
66 0 0
2-25 0 0

SEPT/NOV
3-38
0
0
1-30
-------
STATE OF:    Michigan
COUNTY:    Muskegon
SIC:    3321     PROCESS DESCRIPTION:    Steel Melting - Electric Furnace
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):     22-40
POTENTIAL LAKE
IMPACT (tons/yr):    3-7
PARTICLE SIZE: 100% less than 1 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 5-10 6-10 6-10
WIND FREQUENCY
(% impact on lake) 66 0 0
SEASONAL IMPACT
(tons) 3-7 0 0
SEPT/NOV
5-10
0
0

SIC: 2951 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 14 IMPACT (tons/yr): 2
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 344
WIND FREQUENCY
(% impact on lake) 66 0 0
SEASONAL IMPACT
(tons) 200
SEPT/NOV
3
0
0
                                      1-31
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STATE OF:
Michigan
COUNTY:    Muskegon
SIC:   3321
  PROCESS DESCRIPTION:
     Coke  Oven
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):    42-356
                         POTENTIAL LAKE
                         IMPACT (tons/yr):
                      7-59
PARTICLE SIZE:    50% less than 10 u
                        DEC/FEB
                       MAR/MAY
SEASONAL FUGITIVE
EMISSIONS
          10-89
11-89
WIND FREQUENCY
  (% impact on lake)
           66
  0
SEASONAL IMPACT
  (tons)	
           7-59
                                     1-32
             JUNE/AUG
11-89
  0
             SEPT/NOV
10-89
                                0
-------
STATE OF:      Michigan	  COUNTY:    Monominee
SIC:    2621     PROCESS DESCRIPTION:    Coal Storage
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    26-52	 IMPACT  (tons/yr):    19-39
PARTICLE SIZE:    50% less than 10 u
	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	6-13	7-13	7-13	6-13

WIND FREQUENCY
   (% impact on lake)      66	33	100	100

SEASONAL IMPACT
   (tons)	4-9	2-4	7-13	6-13
                                      1-33
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STATE OF:     Michigan
                       COUNTY:    Delta
SIC:   4010
PROCESS DESCRIPTION:   Iron Ore Conveying
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):    518
                       POTENTIAL LAKE
                       IMPACT (tons/yr)
                      216
PARTICLE SIZE:   100% less than 100 u
                        DEC/FEB
                     MAR/MAY
SEASONAL FUGITIVE
EMISSIONS
         130
130
WIND FREQUENCY
  (% impact on lake)
          66
100
SEASONAL IMPACT
  (tons)	
          86
130
                                     1-34
             JUNE/AUG
130
  0
            SEPT/NOV
130
                 0
  0
-------
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STATE OF:    Michigan	  COUNTY:   Mason	
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                                      1-35                                            I
SIC: 3297 PROCESS DESCRIPTION: Lime Calcining
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 1025 IMPACT (tons/yr): 169
PARTICLE SIZE: 95% less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 256 256 256
WIND FREQUENCY
(% impact on lake) 66 0 0
SEASONAL IMPACT
(tons) 169 0 0
SEPT/NOV
256
0
0

SIC: 3321 PROCESS DESCRIPTION: Iron Melting Cupola
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 9-98 IMPACT (tons/yr): 1-16
PARTICLE SIZE: 100% less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 2-24 2-25 2-25
WIND FREQUENCY
(% impact on lake) 66 0 0
SEASONAL IMPACT
(tons) 1-16 0 0
SEPT/NOV
2-24
0
0
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1
1
1
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1
1
1
1
1
1
STATE OF: Michigan COUNTY: Mason
SIC: 3321 PROCESS DESCRIPTION: Foundry Sand Handling
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 83-828 IMPACT (tons/yr): 14-137
PARTICLE SIZE: 5Q% less than 15 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 21-207 21-207 21-207
WIND FREQUENCY
(% impact on lake) 66 0 0
SEASONAL IMPACT
(tons) 14-137 0 0

SIC: 2951 PROCESS DESCRIPTION: Asphalt Batchinq
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 20 IMPACT (tons/yr): 3
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 55 5
WIND FREQUENCY
(% impact on lake) 66 0 0
SEASONAL IMPACT
(tons) 30 0
1-36



SEPT/NOV
21-207
0
0



SEPT/NOV
5
0
0

-------
STATE OF:
Michigan
COUNTY:   Mason
SIC:   4452
  PROCESS DESCRIPTION:
   Coal Storage
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):     4-8
                         POTENTIAL LAKE
                         IMPACT (tons/yr): 	1
PARTICLE SIZE:    50% less than 10 u
                        DEC/FEB
                       MAR/MAY
SEASONAL FUGITIVE
EMISSIONS
           1-2
1-2
WIND FREQUENCY
  (% impact on lake)
           66
 0
SEASONAL IMPACT
  (tons)	
                          0
                                      1-37
             JUNE/AUG
1-2
 0
                 0
            SEPT/NOV
1-2
 0
                0
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I



         STATE OF:       Michigan	 COUNTY:      Mackinac	


I
         SIC:    1422     PROCESS  DESCRIPTION:       Stone Crushing	


         POTENTIAL  FUGITIVE                     POTENTIAL LAKE
•       EMISSIONS  (tons/yr):      4294-8034      IMPACT  (tons/yr):    4294-8034


-       PARTICLE SIZE:   100% less  than  100  u
•       	DEC/FEB       MAR/MAY	JUNE/AUG       SEPT/NOV

         SEASONAL FUGITIVE
•       EMISSIONS	1074-2009      1074-2009	1074-2009      1074-2009

         WIND FREQUENCY
_         (% impact on lake)       100	100	100	100

™       SEASONAL IMPACT
           (tons)	1074-2009      1074-2009	1074-2009      1074-2009



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•                                            1-38
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                                                                                     I
STATE OF:    Michigan	  COUNTY:      Delta	
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                                      1-39                                            _
SIC: 1494 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 21 IMPACT (tons/yr): 8
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 55 5
WIND FREQUENCY
(% impact on lake) 66 100 0
SEASONAL IMPACT
(tons) 35 0
SEPT/NOV
5
0
0

SIC: 9349 PROCESS DESCRIPTION: Coal Storage
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 37-74 IMPACT (tons/yr): 15-32
PARTICLE SIZE: 50% less than 10 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 9-19 9-19 9-19
WIND FREQUENCY
(% impact on lake) 66 100 0
SEASONAL IMPACT
(tons) 6-13 9-19 0
SEPT/NOV
9-19
0
0
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1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Michigan
SIC: 3322 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 358-3557
PARTICLE SIZE: 50% less than 15 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 90-889
WIND FREQUENCY
(% impact on lake) 66
SEASONAL IMPACT
(tons) 59-587

SIC: 3321 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 553-5641
PARTICLE SIZE: 50% less than 15 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 138-1410
WIND FREQUENCY
(% impact on lake) 66
SEASONAL IMPACT
(tons) 91-931

COUNTY: Berrien
Foundry Muller
POTENTIAL LAKE
IMPACT (tons/yr): 238-2356

MAR/MAY JUNE/AUG SEPT/NOV
90-889 90-889 90-889
100 66 33
90-889 59-587 30-293

Foundry Shakeout - Cleaning
POTENTIAL LAKE
IMPACT (tons/yr): 366-3737

MAR/MAY JUNE/AUG SEPT/NOV
138-1410 138-1410 138-1410
100 66 33
138-1410 91-931 46-465
1-40
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                                                                                     I


STATE OF:     Michigan _  COUNTY:      Bern" en _

                                                                                     I
SIC:   3322      PROCESS DESCRIPTION:     EAF - Iron _

POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    138-346 _ IMPACT (tons/yr):     93-230 _     |

PARTICLE SIZE:    100% less than 1 u                                                 m


_ DEC/FEB       MAR/MAY _ JUNE/AUG       SEPT/NOV         I


                                                                                     I
WIND FREQUENCY
  (% impact on lake)      66 _ 100 _ 66 _ 33            •

SEASONAL IMPACT
  (tons) _ 23-57 _ 35-87 _ 23-57 _ 12-29          -
SIC:   3322      PROCESS DESCRIPTION:       Cupola
SEASONAL FUGITIVE
EMISSIONS                35-87         35-87           35-87          35-87
POTENTIAL FUGITIVE                      POTENTIAL  LAKE
EMISSIONS (tons/yr):     106-738 _ IMPACT  (tons/yr):      72-490
PARTICLE SIZE:    100% less than 20 u
	DEC/FEB       MAR/MAY	JUNE/AUG        SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	27-185	27-185	27-185	27-185

WIND FREQUENCY
   (% impact  on  lake)	66	100	66	33

SEASONAL IMPACT
   (tons)	18-22	27-185	18-122	9-61

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STATE OF:
Michigan
 COUNTY:    Berrien
SIC:   2951
   PROCESS DESCRIPTION:   Asphalt Batching
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 	20
                          POTENTIAL LAKE
                          IMPACT (tons/yr);
                      13
PARTICLE SIZE:    6055 less than 4 u
                        DEC/FEB
                        MAR/MAY
SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
  (% impact on lake)
            66
100
SEASONAL IMPACT
  (tons)	
                                      1-42
              JUNE/AUG
66
            SEPT/NOV
33
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                                           APPENDIX J
                             LAKE IMPACT FROM THE STATE OF MINNESOTA
-------
STATE OF:
Minnesota
  COUNTY:      St.  Louis
SIC:    4221     PROCESS DESCRIPTION:
                             Grain Handling
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):    9797-129723
                          POTENTIAL LAKE
                          IMPACT (tons/yr):
                         7396-102376
PARTICLE SIZE:    10% less than 20 u
                        DEC/FEB
                        MAR/MAY
               JUNE/AUG
              SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS (Tons)
         863-14616    1959-29545
               3198-41927     3777-50338
WIND FREQUENCY
  (% impact on lake)
           100
  33
   66
   100
SEASONAL IMPACT
  (tons)
         863-14616     646-9750
              2110-27672
              3777-50338
SIC:   3312
   PROCESS DESCRIPTION:
     Coke Oven
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):    1097-1255
                          POTENTIAL LAKE
                          IMPACT  (tons/yr):    845-966
PARTICLE SIZE:    100%  less than 10 u
                        DEC/FEB
                        MAR/MAY
               JUNE/AUG
              SEPT/NOV
 SEASONAL FUGITIVE
 EMISSIONS  (Tons)
           176-200
186-213
373-427
362-414
WIND FREQUENCY
   (% impact  on  lake)	100

SEASONAL  IMPACT
   (tons)	176-200
                            33
                          61-70
                   66
                246-282
                100
              362-414
                                      J-l
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STATE OF: Minnesota
SIC: 2951 PROCESS DESCRIPTION
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 97
PARTICLE SIZE: 60% less than 4 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS (Tons) 0
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 0

SIC: 4911 PROCESS DESCRIPTION
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 269-460
PARTICLE SIZE: 50% less than 10 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS (Tons) 60-110
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 60-110

COUNTY: St. Louis
: Asphalt Batching
POTENTIAL LAKE
IMPACT (tons/yr): 81

MAR/MAY JUNE/AUG SEPT/NOV
0 49 49
33 66 100
0 32 49

: Coal Storage Pile Transport
POTENTIAL LAKE
IMPACT (tons/yr): 204-347

MAR/MAY JUNE/AUG SEPT/NOV
59-107 75-121 75-122
33 66 100
19-35 50-80 75-122
J-2
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STATE OF:   Minnesota                   COUNTY:      St. Louis
SIC:    1011     PROCESS DESCRIPTION:     Iron Ore
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   16818	 IMPACT (tons/yr):      12572
PARTICLE SIZE:   100% less than 100 u
	DEC/FEB       MAR/MAY	JUNE/AUG       SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS  (Ton)	4205	4205	4205	4205

WIND FREQUENCY
  (% impact on lake)	100	33	66	100

SEASONAL IMPACT
  (tons)	4205	1387	2775	4205
                                      J-3
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1
STATE OF: Minnesota COUNTY: Lake
SIC: 1011 PROCESS DESCRIPTION: Iron Ore
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 10,000 IMPACT (tons/yr): 7475
PARTICLE SIZE: 100% less than 100 u
DEC/FEB MAR/MAY JUNE/AU6
SEASONAL FUGITIVE
EMISSIONS (Tons) 2500 2500 2500
WIND FREQUENCY
(% impact on lake) 100 33 66
SEASONAL IMPACT
(tons) 2500 825 1650

SIC: 1011 PROCESS DESCRIPTION: Coal Storage
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 59-126 IMPACT (tons/yr): 46-95
PARTICLE SIZE: 50% less than 10 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS (Tons) 17-35 16-34 10-21
WIND FREQUENCY
(% impact on lake) 100 33 66
SEASONAL IMPACT
(tons) 17-35 5-11 7-14
J-4



SEPT/NOV
2500
100
2500



SEPT/NOV
17-35
100
17-35

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                                          APPENDIX K
|                            LAKE IMPACT FROM THE STATE OF OHIO
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STATE OF:   Ohio _  COUNTY:    Ashtabula _
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SIC:   4911      PROCESS DESCRIPTION:    Coal Storage _ _

POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    512-1047 _ IMPACT (tons/yr):    468-959 _ |
PARTICLE SIZE:    50% less than 10 u
                                                                                •
_ DEC/FEB       MAR/MAY _ JUNE/AU6 _ SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS _ 128-262 _ 128-262 _ 128-262 _ 128-262    •

WIND FREQUENCY
  (% impact on lake) _ 66 _ 100 _ 100 _ 100      •

SEASONAL IMPACT
  (tons) _ 84-173 _ 128-262 _ 128-262 _ 128-262    •
SIC:    3274     PROCESS DESCRIPTION:      Lime Calcining	


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):      151	 IMPACT (tons/yr):       139	•


PARTICLE SIZE:    95%  less  than 20 u                                             •



	DEC/FEB       MAR/MAY	JUNE/AUG        SEPT/NOV     1

SEASONAL FUGITIVE
EMISSIONS	38	38	38	38      •

WIND  FREQUENCY
   (%  impact on  lake)	66	100	100	100

SEASONAL IMPACT
   (tons)	25	38	38	38


                                 K-l
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STATE OF:
Ohio
COUNTY:
Ashtabula
SIC:   3399
PROCESS DESCRIPTION:     Metal Melting
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 	66_
                       POTENTIAL LAKE
                       IMPACT (tons/yr):
                      62
PARTICLE SIZE:    50% less than 70 u
                        DEC/FEB
                     MAR/MAY
SEASONAL FUGITIVE
EMISSIONS
          17
 17
WIND FREQUENCY
  (% impact on lake)
          66
100
SEASONAL IMPACT
  (tons)	
          11
 17
                                K-2
             JUNE/AUG
     17
    100
     17
                SEPT/NOV
 17
100
 17
-------
                                                                                I


STATE OF:       Ohio	  COUNTY:      Cuyahoga	

                                                                                I
SIC:   3312      PROCESS DESCRIPTION:      Steel  Melting	

POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):      473	 IMPACT (tons/yr):     432	 |

PARTICLE SIZE:    90% less than 5 u                                             _


	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV    I


                                                                             -I
SEASONAL FUGITIVE
EMISSIONS	118	118	118	118

WIND FREQUENCY
  (% .impact on lake)	66	100	100	100       •

SEASONAL IMPACT
  (tons)	78	118	118	118




                                                                                I
SIC:   4911      PROCESS DESCRIPTION:     Coal  Storage	


POTENTIAL FUGITIVE                      POTENTIAL  LAKE
EMISSIONS (tons/yr):    453-929	 IMPACT (tons/yr):     414-849	•


PARTICLE SIZE:    50% less than 10 u
                        DEC/FEB       MAR/MAY        JUNE/AUG       SEPT/NOV
                                                                                I
 SEASONAL FUGITIVE
 EMISSIONS	113-232	113-232	113-232	113-232     •

 WIND FREQUENCY
   (% impact on  lake)	66	100	100	100	

 SEASONAL IMPACT                                                                '
   (tons)	75-153	113-232	113-232	113-232




                                 K-3                                             I
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1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Ohio
SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 3764
PARTICLE SIZE: 50% less than 76 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 941
WIND FREQUENCY
(% impact on lake) 66
SEASONAL IMPACT
(tons) 621

SIC: 3341 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 38
PARTICLE SIZE: 100% less than 1 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 10
WIND FREQUENCY
(% impact on lake) 66
SEASONAL IMPACT
(tons) 7
K-4
COUNTY: Cuyahoga
Iron Melting - Blast Furnace
POTENTIAL LAKE
IMPACT (tons/yr): 3444

MAR/MAY JUNE/AUG SEPT/NOV
941 941 941
100 100 100
941 941 941

Brass Smelting
POTENTIAL LAKE
IMPACT (tons/yr): 35

MAR/MAY JUNE/AUG SEPT/NOV
10 9 9
100 100 100
10 9 9

-------
STATE OF:      Ohio	  COUNTY:      Cuyahoga
SIC:    2041     PROCESS DESCRIPTION:     Flour Milling
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):     176-2503       IMPACT (tons/yr):    161-2291
PARTICLE SIZE:    100% less than 10 u
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV     i

SEASONAL FUGITIVE
EMISSIONS	44-626	44-626	44-626	44-626     •

WIND FREQUENCY
  (% impact on lake)      66	100	100	100      •

SEASONAL IMPACT
  (tons)	29-413	44-626	44-626	44-626     -
SIC:   3321      PROCESS DESCRIPTION:     Sand Handling  (Foundry)
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    207-1469	 IMPACT  (tons/yr):     190-1343
PARTICLE SIZE:    50%  less than 15 u
	DEC/FEB       MAR/MAY	JUNE/AUG        SEPT/NOV

SEASONAL FUGITIVE
EMISSIONS	52-367	52-367	52-367	52-367

WIND  FREQUENCY
   (%  impact  on  lake)	66	100	100	100

SEASONAL IMPACT
   (tons)	34-242	52-367	52-367	52-367
                                 K-5
-------
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Ohio COUNTY: Cuyahoga
SIC: 3295 PROCESS DESCRIPTION: Sand Processing
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 47-69 IMPACT (tons/yr): 43-63
PARTICLE SIZE: 100% less than 100 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 12-18 12-18 11-16
WIND FREQUENCY
(% impact on lake) 66 100 100
SEASONAL IMPACT
(tons) 8-12 12-18 11-16

SIC: 2951 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 50 IMPACT (tons/yr): 50
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 0 10 20
WIND FREQUENCY
(% impact on lake) 66 100 100
SEASONAL IMPACT
(tons) 0 10 20
K-6



SEPT/NOV
12-17
100
12-17



SEPT/NOV
20
100
20

-------
STATE OF:
Ohio
COUNTY:   Cuyahoga
SIC:   3323
  PROCESS DESCRIPTION:    Coke Oven
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):    1253
                         POTENTIAL LAKE
                         IMPACT (tons/yr):     1127
PARTICLE SIZE:    90* less than 10 u
                        DEC/FEB
                       MAR/MAY
             JUNE/AUG
             SEPT/NQV
I
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SEASONAL FUGITIVE
EMISSIONS
           313
313
 313
 313
WIND FREQUENCY
  (% impact on lake)
            66
100
 100
 100
SEASONAL IMPACT
  (tons)	
           188
313
 313
SIC:    3341
  PROCESS DESCRIPTION:    Aluminum Chip Drying
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
           8
POTENTIAL LAKE
IMPACT (tons/yr):
PARTICLE SIZE:    100% less than 2 u
                        DEC/FEB
                       MAR/MAY
             OUNE/AUG
 313
             SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
   (% impact on lake)

SEASONAL  IMPACT
   (tons)	
           66
100
100
100
                                 K-7
-------
I



               STATE  OF:       Ohio	  COUNTY:        Cuyahoga	


I

               SIC:     3321      PROCESS  DESCRIPTION:       Gray  Iron  Foundry	


               POTENTIAL  FUGITIVE                       POTENTIAL  LAKE
•             EMISSIONS  (tons/yr):    2189-14101        IMPACT (tons/yr):     2002-12902


•             PARTICLE SIZE:    100%  less  than 20  u



•             	DEC/FEB        MAR/MAY	JUNE/AUG       SEPT/NOV

               SEASONAL FUGITIVE
•             EMISSIONS	547-3525       547-3525	547-3525	547-3525

               WIND FREQUENCY
•               (% impact on  lake)	66	100	100	100

               SEASONAL IMPACT
-               (tons)	361-2327       547-3525	547-3525	547-3525



I             _=____=^=___



I


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™                                            K-8


I
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                                                                                I



STATE OF:    Ohio	  COUNTY:       Erie	


                                                                                I
SIC:    3274     PROCESS DESCRIPTION:      Lime Stone Crushing and Calcining


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   5011	 IMPACT (tons/yr):     4809	|


PARTICLE SIZE:    95% less than 20 u                                            •



	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV    1



                                                                            -I
WIND FREQUENCY
  (% impact on lake)	66	100	100	100      •

SEASONAL IMPACT
  (tons)	391	1300	1677	1441      -




                                                                                I
SIC:   3399      PROCESS DESCRIPTION:     Coal Storage	

                                                                                I
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    13-30	 IMPACT (tons/yr):    11-29	m


PARTICLE SIZE:    50% less than 10 u                                            _
SEASONAL FUGITIVE
EMISSIONS                 593           1300             1677           1441
	DEC/FEB       MAR/MAY	JUNE/AUG	SEPT/NOV


SEASONAL FUGITIVE
EMISSIONS	3^8	3^8	3^8	3-8


WIND FREQUENCY
   (% impact on  lake)	66	100	100	100


SEASONAL IMPACT
   (tons)	2-5	3-8	3-8	3-8
                                 K-9
                                                                               I
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1
1

1



1


1

1

1





1

1


1








1

1


STATE OF: Ohio

SIC: 4911 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 1116-2509

PARTICLE SIZE: 50% less than 10 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 279-627

WIND FREQUENCY
(% impact on lake) 33

SEASONAL IMPACT
(tons) 92-207


SIC: 3274 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 577

PARTICLE SIZE: 95% less than 20 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 144

WIND FREQUENCY
(% impact on lake) 33

SEASONAL IMPACT
(tons) 48

K-10



COUNTY: Lake

Coal Storage

POTENTIAL LAKE
IMPACT (tons/yr): 929-2088



MAR/MAY JUNE/AUG SEPT/NOV


279-627 279-627 279-627


100 100 100


279-627 279-627 279-627


Lime Calcining

POTENTIAL LAKE
IMPACT (tons/yr): 480



MAR/MAY JUNE/AUG SEPT/NOV


144 144 144


100 100 100


144 144 144



-------
STATE OF:        Ohio                   COUNTY:         Lorain
SIC: 4911 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 1729-3537
Coal Storage
POTENTIAL LAKE
IMPACT (tons/yr): 1439-2944
PARTICLE SIZE: 50% less than 10 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 432-884
WIND FREQUENCY
(% impact on lake) 33
SEASONAL IMPACT
(tons) 143-292
MAR/MAY JUNE/AUG SEPT/NOV
432-884 432-884 432-884
100 100 100
432-884 432-884 432-884

SIC: 3312 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 885
Coke Oven
POTENTIAL LAKE
IMPACT (tons/yr): 736
PARTICLE SIZE: 90% less than 10 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 221
WIND FREQUENCY
(% impact on lake) 33
SEASONAL IMPACT
(tons) 73
MAR/MAY JUNE/AUG SEPT/NOV
221 221 221
100 100 100
221 221 221
                                K-ll
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1
1



1


1

1

1





1

1


1

1






1
STATE OF: Ohio

SIC: 3312 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 1524

PARTICLE SIZE: 50% less than 70 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 157

WIND FREQUENCY
(% impact on lake) 33

SEASONAL IMPACT
(tons) 57


SIC: 3312 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 610

PARTICLE SIZE: 9Q% less than 5 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 140

WIND FREQUENCY
(% impact on lake) 33

SEASONAL IMPACT
(tons) 46

K-12
COUNTY: Lorain

Iron Melting - Blast Furnace

POTENTIAL LAKE
IMPACT (tons/yr): 1419



MAR/MAY JUNE/AUG SEPT/NOV


676 390 301


100 100 100


676 390 301


Steel Melting - BOF

POTENTIAL LAKE
IMPACT (tons/yr): 516



MAR/MAY JUNE/AUG SEPT/NOV


171 159 140


100 100 100


171 159 140


-------
                                                                                I



STATE OF:     Ohio	  COUNTY:     Lorain	*


                                                                                I
SIC:    3312     PROCESS DESCRIPTION:    Sintering	

                                                                                I
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   138-398	 IMPACT (tons/yr):    128-365	•


PARTICLE SIZE:    10% less than 5 u                                             _
                        DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV
I
SEASONAL FUGITIVE
EMISSIONS	17-48	37-107	46-131	39-111    •

WIND FREQUENCY
  (% impact on lake)	33	100	100	100      •

SEASONAL IMPACT                                                                 ™
  (tons)	6-16	37-107	46-131	39-111





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                                 K-13                                           •
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1
1



1


1

1

1





1

1


1

1






1
STATE OF: Ohio

SIC: 4911 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 888-1814

PARTICLE SIZE: 50% less than 10 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 222-454

WIND FREQUENCY
(% impact on lake) 100

SEASONAL IMPACT
(tons) 222-454


SIC: 5153 PROCESS DESCRIPTION:

POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 3075-41973

PARTICLE SIZE: 10% less than 20 u

DEC/FEB

SEASONAL FUGITIVE
EMISSIONS 345-4715

WIND FREQUENCY
(% impact on lake) 100

SEASONAL IMPACT
(tons) 345-4715

K-14
COUNTY: Lucas

Coal Storage

POTENTIAL LAKE
IMPACT (tons/yr): 813-1662



MAR/MAY JUNE/AUG SEPT/NOV


222-454 222-454 222-454


66 100 100


147-300 222-454 222-454


Grain Handling

POTENTIAL LAKE
IMPACT (tons/yr): 2821-38522



MAR/MAY JUNE/AUG SEPT/NOV


743-10146 453-5183 1533-20928


66 100 100


490-6696 453-5183 1533-20928


-------
                                                                                I


STATE OF:      Ohio	  COUNTY:     Lucas	 *

                                                                                I
SIC:   3312      PROCESS DESCRIPTION:     Coke Oven	

POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    890	 IMPACT (tons/yr):      813	•

PARTICLE SIZE:    90% less than 10 u                                            _
                        DEC/FEB	MAR/MAY        JUNE/AUG	SEPT/NOV
                                                                                I
SEASONAL FUGITIVE
EMISSIONS	222	222	222	222      •

WIND FREQUENCY
  (% impact on lake)      100	66	100	100      _

SEASONAL IMPACT                                                                 *
  (tons)	222	147	222	222




                                                                                I
SIC:   3312      PROCESS DESCRIPTION:     Iron Melting - Blast Furnace	


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    135	 IMPACT (tons/yr):    124	


PARTICLE SIZE:    50% less than 70 u
                        DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV
                                                                                I
SEASONAL FUGITIVE
EMISSIONS	34	34	34	34      •

WIND FREQUENCY                                                                  *
   (% impact on lake)      100	66	100	100

SEASONAL IMPACT                                                                 »
   (tons)	34	22	34	34



                                 K-15
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1
1

1



1


1

1

1





1

1


1

1






1


STATE OF: Ohio COUNTY: Ottawa

SIC: 3275 PROCESS DESCRIPTION: Coal Storage

POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 10-21 IMPACT (tons/yr): 9-18

PARTICLE SIZE: 50% less than 10 u

DEC/FEB MAR/MAY JUNE/AUG

SEASONAL FUGITIVE
EMISSIONS 3-5 3-5 2-5

WIND FREQUENCY
(% impact on lake) 100 66 100

SEASONAL IMPACT
(tons) 3-5 2-3 2-5


SIC: 1422 PROCESS DESCRIPTION: Limestone Crushing

POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 196 IMPACT (tons/yr): 179

PARTICLE SIZE: 95% less than 20 u

DEC/FEB MAR/MAY JUNE/AUG

SEASONAL FUGITIVE
EMISSIONS 49 49 49

WIND FREQUENCY
(% impact on lake) 100 66 100

SEASONAL IMPACT
(tons) 49 32 49

K-16











SEPT/NOV


2-5


100


2-5









SEPT/NOV


49


100


49


-------
STATE OF:    Ohio
             COUNTY:     Ottawa
SIC:    3275     PROCESS DESCRIPTION:    Gypsum Grinding
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):    315
             POTENTIAL LAKE
             IMPACT (tons/yr):    292
PARTICLE SIZE:    95% less than 20 u
                        DEC/FEB
           MAR/MAY
            JUNE/AUG
SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS
63
69
    95
WIND FREQUENCY
  (% impact on lake)	100

SEASONAL IMPACT
  (tons)	63
              60
              46
               100
   100
                               95
                                                                                I
                                 K-17
-------
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                                          APPENDIX L
I                          LAKE  IMPACT FROM THE STATE OF WISCONSIN
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STATE OF:    Wisconsin
                       COUNTY:     Douglas
SIC:   1099
PROCESS DESCRIPTION:     Ore Storage
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    10672-53169     IMPACT (tons/yr):
PARTICLE SIZE:   100% less than 100 u
                                               0
                        DEC/FEB
                     MAR/MAY
 JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS
      2313-11523    1668-8310
2846-14179
WIND FREQUENCY
  (% impact on lake)
                        0
    0
SEASONAL IMPACT
  (tons)	
                                       0
                                      L-l
SEPT/NOV
2846-14179
                    0
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1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
STATE OF: Wisconsin COUNTY: Douglas
SIC: 3241 PROCESS DESCRIPTION: Cement Grinding, Loading
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 828-865 IMPACT (tons/yr): 0
PARTICLE SIZE: 582 less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 83-87 248-260 248-260
WIND FREQUENCY
(% impact on lake) 0 0 0
SEASONAL IMPACT
(tons) 000

SIC: 2951 PROCESS DESCRIPTION: Asphalt Plant
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS {tons/yr): 20 IMPACT (tons/yr): 0
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 46 6
WIND FREQUENCY
(% impact on lake) 0 0 0
SEASONAL IMPACT
(tons) 00 0
L-2



SEPT/NOV
248-260
0
0



SEPT/NOV
5
0
0

-------
STATE OF:
               Wisconsin
COUNTY:
Douglas
SIC:  2083
                 PROCESS DESCRIPTION:
   Grain Handling
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):   4412-80153
                                        POTENTIAL LAKE
                                        IMPACT (tons/yr): 	0_
PARTICLE SIZE:   10% less than 20 u
                        DEC/FEB
                                      MAR/MAY
             JUNE/AUG
               SEPT/NOV
I
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I
SEASONAL FUGITIVE
EMISSIONS
                        506-9287    1287-23451
             1492-26938    1127-20475
WIND FREQUENCY
  (% impact on lake)
                           0
SEASONAL IMPACT
  (tons)	
                           0
0
    0
0
                 PROCESS DESCRIPTION:    Limestone Manufacturing, Loading
SIC:   3274
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):    676
                                        POTENTIAL LAKE
                                        IMPACT (tons/yr)
PARTICLE SIZE:   905 less than 20 u
                        DEC/FEB
                                      MAR/MAY
             JUNE/AUG
               SEPT/NOV
SEASONAL FUGITIVE
EMISSIONS
                          176
176
   176
149
WIND FREQUENCY
   (% impact on  lake)

SEASONAL  IMPACT
   (tons)	
                            0
                                 0
                                      L-3
-------
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1
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I
STATE OF:
Wisconsin
COUNTY:    Door
SIC:   2951
  PROCESS DESCRIPTION:     Asphalt Batching
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 	31.
                         POTENTIAL LAKE
                         IMPACT (tons/yr)
                        31
PARTICLE SIZE:   60% less than 4 u
                        DEC/FEB
                       MAR/MAY
SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
  (% impact on lake)
           100
100
SEASONAL IMPACT
  (tons)	
             0
                                     L-4
             JUNE/AUG
                                          12
100
                 12
            SEPT/NOV
100
-------
STATE OF:    Wisconsin
                       COUNTY:     Kenosha
SIC:    3351     PROCESS DESCRIPTION:    Brass Melting
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
        1-2
POTENTIAL LAKE
IMPACT (tons/yr):
PARTICLE SIZE:    100% less than 1 u
                        DEC/FEB
                     MAR/MAY
             JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS
                     0.4-0.8
             0.4-0.8
WIND FREQUENCY
  (% impact on lake)
         100
 0
100
SEASONAL IMPACT
  (tons)	
                                    0.4-0.8
SIC:   2951
PROCESS DESCRIPTION:    Asphalt Batching
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):   7
                       POTENTIAL LAKE
                       IMPACT (tons/yr):
PARTICLE SIZE:    60% less than 4 u
                        DEC/FEB
                     MAR/MAY
             JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS
           0
WIND FREQUENCY
   (% impact on  lake)	100

SEASONAL  IMPACT
   (tons)	0
                                       100
                                      L-5
             SEPT/NOV
              0.2-0.4
0
                             0.2-0.4
             SEPT/NOV
                              100
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1
1
1
1
1
1
1
I
1
I
1
1
1
1
1
1
1
1
1
STATE OF: Wisconsin COUNTY: Kewannes
SIC: 2951 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 20 IMPACT (tons/yr): 17
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 0 4 12
WIND FREQUENCY
(% impact on lake) 66 33 100
SEASONAL IMPACT
(tons) 0 1 12

SIC: 2436 PROCESS DESCRIPTION: Wood Working
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 2 IMPACT (tons/yr): 2
PARTICLE SIZE: 50% less than 30 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 0 0.4 1.2
WIND FREQUENCY
(% impact on lake) 66 33 100
SEASONAL IMPACT
(tons) 0 0.1 1.2
L-6



SEPT/NOV
4
100
4



SEPT/NOV
0.4
100
0.4

-------
STATE OF:
Wisconsin
COUNTY:     Manitowoc
SIC: 3241 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
PARTICLE SIZE: 58%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
255-434
less than 20 u
DEC/FEB
0
66
0
Cement Rotary Kiln
POTENTIAL LAKE
IMPACT (tons/yr): 234-399

MAR/MAY JUNE/AUG
31-52 112-191
33 100
10-17 112-191


SEPT/NOV
112-191
100
112-191

SIC: 2951 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr):
PARTICLE SIZE: 60%

SEASONAL FUGITIVE
EMISSIONS
WIND FREQUENCY
(% impact on lake)
SEASONAL IMPACT
(tons)
80
less than 4 u
DEC/FEB
0
66
0
Asphalt Batching
POTENTIAL LAKE
IMPACT { tons/yr): 69

MAR/MAY OUNE/AUG
16 37
33 100
5 37


SEPT/NOV
27
100
27
                                     L-7
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1
1
1
1
1
1
1
1
I
1
I
I
1
1
1
1
1
1
1
STATE OF: Wisconsin COUNTY: Manitowoc
SIC: 4931 PROCESS DESCRIPTION: Coal Storage
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 49-97 IMPACT (tons/yr): 36-72
PARTICLE SIZE: 50% less than 10 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 12-24 12-24 12-24
WIND FREQUENCY
(% impact on lake) 66 33 100
SEASONAL IMPACT
(tons) 8-16 4-8 12-24

SIC: 3274 PROCESS DESCRIPTION: Lime Kiln
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 76-96 IMPACT (tons/yr): 57-72
PARTICLE SIZE: 95% less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 19-24 19-24 19-24
WIND FREQUENCY
(% impact on lake) 66 33 100
SEASONAL IMPACT
(tons) 13-16 6-8 19-24
L-8



SEPT/NOV
12-24
100
12-24



SEPT/NOV
19-24
100
19-24

-------
                                                                                     I


STATE OF:    Wisconsin	  COUNTY:    Manitowoc	

                                                                                     I
SIC:    3361     PROCESS DESCRIPTION:   Aluminum Reverberatory Furnace	
                                                                                     I
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    2	 IMPACT (tons/yr):     2	      •

PARTICLE SIZE:    100% less than 2 u                                                 _
                        DEC/FEE	MAR/MAY	JUNE/AU6       SEPT/NOV
I
SEASONAL FUGITIVE
EMISSIONS _ OJ5 _ 0.5 _ 0.5 _ 0.5           m

WIND FREQUENCY
  (% impact on lake) _ 66 _ 33 _ 100 _ 100           _

SEASONAL IMPACT                                                                      *
  (tons) _ 0.3 _ 0.2 _ 0.5 _ 0.5

                                                                                     I
                                     L-9
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1
1
1
1
1
I
1
I
1
1
1
1
1
I
1
1
1
1
1
STATE OF: Wisconsin COUNTY: Marinette
SIC: 2496 PROCESS DESCRIPTION: Coal Storage
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 2-3 IMPACT (tons/yr): 1-2
PARTICLE SIZE: 50% less than 10 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 0.5-0.8 0.6-0.8 0.5-0.7
WIND FREQUENCY
(% impact on lake) 66 33 100
SEASONAL IMPACT
(tons) 0.3 0.2-0.3 0.5-0.7

SIC: 2951 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 6 IMPACT (tons/yr): 5
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 022
WIND FREQUENCY
(% impact on lake) 66 33 100
SEASONAL IMPACT
(tons) 0 1 2
L-10



SEPT/NOV
0.4
100
0.4



SEPT/NOV
2
100
2

-------
                                                                                     I



STATE OF:    Wisconsin _  COUNTY:     Marinette _


                                                                                     I
SIC:   2496      PROCESS DESCRIPTION:     Coarse Material Handling _


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    27 _ IMPACT (tons/yr):    19 _      m


PARTICLE SIZE:   100% less than 100 u



                        DEC/FEE _ MAR/MAY _ JUNE/AUG       SEPT/NOV         •


                     _ 8 _ 9 _ 5 _ 5            •

WIND FREQUENCY
  (% impact on lake) _ 33 _ 66 _ 100 _ 100            _

SEASONAL IMPACT                                                                      •
  (tons) _ 3 _ 6 _ 5 _ 5

                                                                                     1
SEASONAL FUGITIVE
EMISSIONS

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1
1
1
1
1
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1
1
1
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1
1
1
1
STATE OF: Wisconsin
SIC: 2082 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 779-6913
PARTICLE SIZE: 10% less than 20 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 188-706
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 188-706

SIC: 4911 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 1556-3097
PARTICLE SIZE: 50% less than 10 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 387-769
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 387-769
•
COUNTY: Milwaukee
Grain Handling
POTENTIAL LAKE
IMPACT (tons/yr): 576-4143

MAR/MAY JUNE/AUG SEPT/NOV
210-1888 211-1900 177-1537
0 100 100
0 211-1900 177-1537

Coal Storage
POTENTIAL LAKE
IMPACT (tons/yr): 1171-2330

MAR/MAY JUNE/AUG SEPT/NOV
385-766 398-793 386-768
0 100 100
0 398-793 386-768
L-12
-------
STATE OF:
Wisconsin
COUNTY:
Milwaukee
SIC: 3714 PROCESS DESCRIPTION: Zinc Melting
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 8 IMPACT (tons/yr): 6
PARTICLE SIZE: 100% less than 2 u
DEC/FEB MAR/MAY JUNE/AU6
SEASONAL FUGITIVE
EMISSIONS 22 2
WIND FREQUENCY
(% impact on lake) 100 0 100
SEASONAL IMPACT
(tons) 20 2
SEPT/NOV
2
100
2

SIC: 2951 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 107 IMPACT (tons/yr): 82
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 2 26 50
WIND FREQUENCY
(% impact on lake) 100 0 100
SEASONAL IMPACT
(tons) 2 0 50
SEPT/NOV
30
100
30
                                      L-13
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1
1
1
1
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1
1
1
1
1
1
1
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1
1
1
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1
STATE OF: Wisconsin
SIC: 3519 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 15
PARTICLE SIZE: 100% less than 2 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 4
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 4

SIC: 3321 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 170-2535
PARTICLE SIZE: 100% less than 20 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 46-710
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 46-710

COUNTY: Milwaukee
Aluminum Melting
POTENTIAL LAKE
IMPACT (tons/yr): 12

MAR/MAY JUNE/AUG SEPT/NOV
335
0 100 100
035

Iron Melting - Copula
POTENTIAL LAKE
IMPACT (tons/yr): 128-1941

MAR/MAY JUNE/AUG SEPT/NOV
43-592 33-540 47-691
0 100 100
0 33-540 47-691
L-14
-------
                                                                                     1



STATE OF:   Wisconsin	  COUNTY:     Milwaukee	


                                                                                     I
SIC:   3321      PROCESS DESCRIPTION:    Iron Melting - EAF	


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    133-414	 IMPACT  (tons/yr):     99-310	     m


PARTICLE SIZE:    100% less than 1 u



	DEC/FEB	MAR/MAY	JUNE/AUG       SEPT/NOV         •

SEASONAL FUGITIVE
EMISSIONS	34-104	34-104	32-102	33-104          m

WIND FREQUENCY
   (% impact on lake)     100	0	100	100	     —

SEASONAL IMPACT                                                                      •
   (tons)	34-104	0	32-102	33-104

                                                                                     >•

_=____^^                                 I


SIC:   3325      PROCESS DESCRIPTION:    Steel  Melting -  EAF	


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    409-1146	 IMPACT  (tons/yr):    303-852	     _

                                                                                     A
PARTICLE SIZE:    100% less than 1 u
DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV
                                                                                      I
 SEASONAL FUGITIVE
 EMISSIONS	98-279	107-294	98-279	107-294          -

 WIND  FREQUENCY                                                                        ™
   (%  impact  on  lake)       100	0	100	100

 SEASONAL IMPACT                                                                      1
   (tons)	98-279	0	98-279	107-294

                                                                                      I

                                      L-15                                            •
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1
1
1
1
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1
1
1
1
1
1
I
I
STATE OF: Wisconsin
SIC: 3320 PROCESS DESCRIPTION
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 592-3020
PARTICLE SIZE: 5Q% less than 15 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 113-775
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 113-775

SIC: 3362 PROCESS DESCRIPTION
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 39-175
PARTICLE SIZE: 100% less than 1 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 11-49
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 11-49

COUNTY: Milwaukee
: Sand Preparation
POTENTIAL LAKE
IMPACT (tons/yr): 446-2263

MAR/MAY JUNE/AUG SEPT/NOV
146-758 133-669 160-819
0 100 0
0 133-669 160-819

: Bronze Melting
POTENTIAL LAKE
IMPACT (tons/yr): 28-128

MAR/MAY JUNE/AUG SEPT/NOV
11-47 8-35 9-44
0 100 100
0 8-35 9-44
L-16
-------
                                                                                      I



STATE OF:    Wisconsin	  COUNTY:      Milwaukee	       *


                                                                                      I
SIC:    3241     PROCESS DESCRIPTION:      Cement Manufacturing	

                                                                                      I
POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):      16	 IMPACT (tons/yr):     11	       m


PARTICLE SIZE:     58% less than 20 u



	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NQV          •


                           2	5	6	3	       •

WIND FREQUENCY
  (% impact on lake)     100	0	100	100	       -

SEASONAL IMPACT                                                                       •
  (tons)	2	0	6	3	

                                                                                      H



SIC:   3312      PROCESS DESCRIPTION:    Coke Oven	


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):    520-2040	 IMPACT (tons/yr):   391-1530	       _

                                                                                      I
PARTICLE SIZE:    90%  less than 10 u
SEASONAL FUGITIVE
EMISSIONS
                        DEC/FEB       MAR/MAY         JUNE/AUG        SEPT/NOV
                                                                                     I
SEASONAL FUGITIVE
EMISSIONS	146-571	130-510	120-469	125-490           -

WIND FREQUENCY                                                                        *
   (% impact  on  lake)       100	0	100	100

SEASONAL IMPACT                                                                      I
   (tons)	146-571	0	120-469	125-490

                                                                                      I
                                      L-17
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1
1
1
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1
1
1
I
1
1
1
1
1
I
1
1
1
1
I
STATE OF: Wisconsin
SIC: 3341 PROCESS DESCRIPTION
POTENTIAL FUGITIVE
EMISSIONS (tons/.yr): 15-85
PARTICLE SIZE: 100% less than 16
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 4-21
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 4-21

SIC: 3714 PROCESS DESCRIPTION
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 649-6061
PARTICLE SIZE: S0% less than 20 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 182-1697
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 182-1697

COUNTY: Milwaukee
: Lead Smelting
POTENTIAL LAKE
IMPACT (tons/yr): 12-63
u
MAR/MAY JUNE/AUG SEPT/NOV
4-21 4-21 4-21
0 100 ' 100
0 4-21 4-21

: Core Oven
POTENTIAL LAKE
IMPACT (tons/yr): 507-4727

MAR/MAY JUNE/AUG SEPT/NOV
143-1333 143-1333 182-1697
0 100 100
0 143-1333 182-1697
L-18
-------
                                                                                     I
STATE OF:    Wisconsin                  COUNTY:     Ozaukee	
                                                                                     I
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                                                                                     I
SIC: 4911 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 328-653
Coal Storage
POTENTIAL LAKE
IMPACT (tons/yr): 246-489
PARTICLE SIZE: 50% less than 10 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 82-163
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 82-163
MAR/MAY JUNE/AUG SEPT/NOV
82-163 82-163 82-163
0 100 100
0 82-163 82-163

SIC: 2951 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 10
Asphalt Batching
POTENTIAL LAKE
IMPACT (tons/yr): 7
PARTICLE SIZE: 60% less than 4 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 0
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 0
MAR/MAY JUNE/AUG SEPT/NOV
343
0 100 100
043
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1
1
1
1
I
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1
I
1
1
1
I
1
I
1
1
I
1
1
STATE OF: Wisconsin COUNTY: Racine
SIC: 2951 PROCESS DESCRIPTION: Asphalt Batching
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 37 IMPACT (tons/yr): 28
PARTICLE SIZE: 60% less than 4 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 8 9 11
WIND FREQUENCY
(% impact on lake) 100 0 100
SEASONAL IMPACT
(tons) 8 0 11

SIC: 1422 PROCESS DESCRIPTION: Limestone Crushing
POTENTIAL FUGITIVE POTENTIAL LAKE
EMISSIONS (tons/yr): 800 IMPACT (tons/yr): 624
PARTICLE SIZE: 95% less than 20 u
DEC/FEB MAR/MAY JUNE/AUG
SEASONAL FUGITIVE
EMISSIONS 200 176 208
WIND FREQUENCY
(% impact on lake) 100 0 100
SEASONAL IMPACT
(tons) 200 0 208
L-20



SEPT/NOV
9
100
9



SEPT/NOV
216
100
216

-------
                                                                                      I



STATE OF:    Wisconsin	  COUNTY:     Racine	       •


                                                                                      I
SIC:   3325      PROCESS DESCRIPTION:    Steel Melting - EAF	


POTENTIAL FUGITIVE                      POTENTIAL LAKE
EMISSIONS (tons/yr):   138-749	 IMPACT (tons/yr):   108-584	       -


PARTICLE SIZE:    100% less than 1 u



	DEC/FEB	MAR/MAY	JUNE/AUG	SEPT/NOV          •

SEASONAL FUGITIVE
EMISSIONS	35-187	30-165	36-195	37-202           _

WIND FREQUENCY                                                                        *
  (% impact on lake)     100	0	100	100

SEASONAL IMPACT                                                                       •
  (tons)	35-187	0	36-195	37-202

	       I



SIC:   3325      PROCESS DESCRIPTION:    Core Oven	


POTENTIAL FUGITIVE                      POTENTIAL LAKE                                ™
EMISSIONS (tons/yr):    4-37	 IMPACT (tons/yr):     3-29	


PARTICLE SIZE:    90%  less than 10 u

                                                                                      I
	DEC/FEB       MAR/MAY	JUNE/AUG        SEPT/NOV


SEASONAL FUGITIVE
EMISSIONS	1^9	1^8	1-10	1-10

WIND FREQUENCY
   (% impact  on  lake)       100	0	100	100


SEASONAL IMPACT
   (tons)	1-9	0	1-10	1-10
                                      L-21
I
-------
•
1



"        STATE OF:      Wisconsin _  COUNTY:     Racine


I
          SIC:    3325      PROCESS DESCRIPTION:       Sand  Preparation


          POTENTIAL  FUGITIVE                      POTENTIAL LAKE
.        EMISSIONS  (tons/yr):    671 _ IMPACT (tons/yr):    521


          PARTICLE SIZE:     50% less  than 15 u
          _ DEC/FEB _ MAR/MAY _ JUNE/AUG       SEPT/NOV


          SEASONAL FUGITIVE

          EMISSIONS                 168           148            174            179
          WIND FREQUENCY
            (% impact on lake) _ 100 _ 0 _ 100 _ 100

•        SEASONAL IMPACT
            (tons) _ 168 _ 0 _ 174 _ 179



1        ———=——



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                                               L-22


I
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                                                                                     I
STATE OF:    Wisconsin	  COUNTY:       Sheboygan	      "
                                                                                     I
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                                                                                     I
                                                                                     I
                                                                                     I
                                                                                     1
                                      1-23                                            m
SIC: 9911 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 94-188
Coal Storage
POTENTIAL LAKE
IMPACT (tons/yr): 72-141
PARTICLE SIZE: 50% less than 10 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 24-47
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 24-47
MAR/MAY JUNE/AUG SEPT/NOV
24-47 24-47 24-47
0 100 100
0 24-47 24-47

SIC: 3431 PROCESS DESCRIPTION:
POTENTIAL FUGITIVE
EMISSIONS (tons/yr): 297-1345
Iron Melting - EAF
POTENTIAL LAKE
IMPACT (tons/yr): 222-1008
PARTICLE SIZE: 100% less than 1 u
DEC/FEB
SEASONAL FUGITIVE
EMISSIONS 74-336
WIND FREQUENCY
(% impact on lake) 100
SEASONAL IMPACT
(tons) 74-336
MAR/MAY OUNE/AUG SEPT/NOV
74-336 74-336 74-336
0 100 100
0 74-336 74-336
-------
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1
                                         APPENDIX M
§                              STATE OF ILLINOIS SOURCE LIST
I
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STATE:  ILLINOIS
I.D. NUMBER
COOK COUNTY
031600AAO
031600ABS
031600ABZ
031600AGL
031600AIN
031600AMI
031600AMY
031600AMZ
031600AOX
031600ARH
031600ATP
031600AVZ
031600AWO
031600BBM
031600BJO
031600BNS
031600BNW
031600BOJ
031600BPP
031600BQF
031600BRV
031600CJH
031600CRQ
NAME OF FACILITY

Edward Hines Lumber Co. - Main Yard
Sandberg Mfg. Co.
Vilas Mages Co.
H. Kramer & Co.
Commonwealth Edison - Crawford Station
Conmonwealth Edison - Fisk Station
Central Soya Inc.
Celotex Corp.
R. Lavin & Sons, Inc.
SIPI Metals Corp.
A. Finkel & Sons Co.
Northwestern Malt & Grain Co.
Dixie Portland Flour Mills
Connelly - GPM, Inc.
Monarch Asphalt
General Foods Corp.
American Cyanamid Co.
Petti bone Corp.
Material Service Corp. - Yard #9
Material Service Corp. - Yard #3
Barrett Paving Materials
Penn-Dixie Industries, Inc.
American Steel Container Co.
CITY

Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
                                       M-l
-------
1
1
1
••


I

1

1




I



I

1



1

1



1

1

1
STATE: ILLINOIS
I.D. NUMBER
COOK COUNTY (con1

031600DXA
031600EDK
031600EMV
031600AAW

031600AEC
031600AOL

031600AQW

031600ARY
031600ASE

031600ATR
031600CBQ
031600EBN
031600ADY
031600AED

031600AHI
031600AIE
031600ALZ
031600AMA
031600AMB

031600AMC
031600AMD
031600ANE



NAME OF FACILITY .
t)

Ideal Box Co.
SIPI Metals Weed St. Plant
Playskool , Inc.
General Motors
Electro-Motive Division - Plant 2
Milles Equipment & Supply
Imperial Smelting Corp.

Stauffer Chemical - Industrial Chemical
Division
American Asphalt Paving Co.
American Brick Co.

Fleischmann Malting Co., Inc.
World's Finest Chocolate, Inc.
Gordon Shopiro
Marblehead Lime Co.
Mississippi Lime Co.

Rail-to-Water Corp.
Indiana Grain Co-Op
U.S. Steel - South Works
Interlake - Chicago Blast Furnace Plant
Wisconsin Steel Works

Republic Steel Corp.
Continental Grain Co. - Elevator B
Cargill, Inc. - Commodity Marketing Div.
•
M-2

CITY


Chicago
Chicago
Chicago

Chicago
Chicago
Chicago

Chicago

Chicago
Chicago

Chicago
Chicago
Chicago
Chicago
Chicago

Chicago
Chicago
Chicago
Chicago
Chicago

Chicago
Chicago
Chicago



-------
STATE:  ILLINOIS
I.D. NUMBER
COOK COUNTY
031600AQE
031600AUB
031600AWJ
031600BEU
031600BFB
031600BFD
031600CGT
031600DVV
031600EEV
031600EKT
031288AAB
031288AAD
031288ABN
LAKE COUNTY
091725AAA
091725AAG
097140AAA
097190AAC
097190AAJ
097190AAP
097190ADB
097809AAB
09781 1AAB
NAME OF FACILITY
(con't)
Continental Grain Co. - Elevator C
Interstate Smelting & Refining Co.
Fal staff Brewing Co.
Pillsbury Co.
Interlake, Inc. - Chicago Coke Plant
Valley Mold & Iron
Chicago Paving & Construction
Cametco, Inc.
Heckett Engineering Co.
Aglomet Chicago, Inc.
Monarch Asphalt Co.
Wells Manufacturing Co.
Barrett Paving Material

Abbott Laboratories - Group Operations Div.
North Chicago Refiners & Smelters, Inc.
Skokie Valley Asphalt Co. Inc.
Commonwealth Edison - Waukegan Station
Johns Manville Products Corp.
National Gypsum Co.
National Gypsum Co.
Peter Baker & Son Co.
Meyer Material Co. - North Chicago
CITY

Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Chicago
Skokie
Skokie
Skokie

North Chicago
North Chicago
Park City
Waukegan
Waukegan
Waukegan
Waukegan
Lake Bluff
Lake Bluff
                  Plant #21
                                       M-3
-------
I
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                                         APPENDIX N
1                              STATE OF INDIANA SOURCE LIST
I
I
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I
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STATE:  INDIANA
I.D. NUMBER
LAKE COUNTY
0002
0007
0009
0012
0013
0014
0015
0016
0024
0025
0032
0035
0037
0038
0039
0041
0042
0044
0065
0070
0073
0074
NAME OF FACILITY
(2360-)
American Maize Products Co.
Associated Box Corporation
Blaw Knox Foundry & Mill Machinery
Globe Industries
Hammond Lead Products
Harbison-Walker Refractories Co.
Inland Steel, Indiana Harbor Works,
Part A
Inland Steel, Indiana Harbor Works,
Part B
Kaiser Aluminum & Chemical
N & A Foundry Corp.
Northern Indiana Public Service Co. -
Mitchell
Commonwealth Edison Stateline Generator
United States Gypsum Co.
U.S. Steel - Gary Works, Part 1
U.S. Steel - Gary Works, Part 2
U.S. Steel Lead Refinery, Inc.
Universal Atlas Cement, Buffington Station
Youngstown Sheet & Tube
American Smelting & Refining
Marblehead Lime Co.
Atlas Blacktop Co., Inc.
A. Metz, Inc.
CITY
Hammond
East Chicago
East Chicago
Whiting
Hammond
Hammond
East Chicago
East Chicago
Gary
Griffith
Gary
Hammond
East Chicago
Gary
Gary
East Chicago
Gary
East Chicago
Hammond
Gary
Hammond
*._....
                                      N-l
-------
1
1
1

I
I

1
•V
1
•
1

1



1

1



1

1



1
1
1
STATE
I.D.

LAKE
0077
0084
0093
0098

0100

0140
0142
0143
0144

0147
0150
0162
0163
0165

0166
: INDIANA
NUMBER NAME OF FACILITY

COUNTY (con 't) (2360- )
Western Cold Drawn Steel Co.
U.S. Reduction Co.
Bieker Co.
Glidden-Durkee Division
SCM Corporation
Halstab Division, Hammond Lead Products,
Inc.
Bucko Construction Co., Inc.
Northern Indiana Dock Co.
Wallace Metals, Inc.
National Briquette Corp.

Bihlman Asphalt Co.
Certified Concrete, Inc.
A. Metz, Inc.
General Refractories Co.
H.B. Reed and Co., Inc.

Republic Steel Corp. - Union Drawn Div.
CITY


Gary
East Chicago
Hammond
Hammond

Hammond

Gary
East Chicago
East Chicago
East Chicago

East Chicago
East Chicago
Gary
Gary
Gary

Gary
PORTER COUNTY (3420-)

0001
0002
0007

0016




Bethlehem Steel Corp.
Bailly Generating Station
Porter County Farm Bureau

Walsh & Kelly


N-2

Burns Harbor
Chesterton
Wheel er

~ — —



-------
I
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                                         APPENDIX 0
§                              STATE OF MICHIGAN SOURCE LIST
I
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STATE:  MICHIGAN
I.D. NUMBER
ALGER COUNTY
B1470
ARENAC COUNTY
B4970
M1856
BAY COUNTY
A0224
A0227
A0233
B1485
B1487
B1491
B1493
B2460
B2840
B2844
BERRIEN COUNTY
A0367
B1511
B1512
B2404
B5838
NAME OF FACILITY
Kimberly Clark Munising Mill
Van Deusen Stone Company
Bay County Road Commission
Aetna Portland Cement
Northern Concrete Pipe Inc.
Bay City Foundry
Bay Asphalt Paving Company
American Hoist & Derrick Co.
Bay City Division
Wickes Agriculture
Monitor Sugar Company
Chevrolet Motor Division
Consumers Power Company
D.E. Karn #1 & 2
Consumers Power Company
J.C. Weadock Plant
Man ley Bros, of Indiana Inc.
Auto Specialties Mfg. Co.
Riverside Plant
Auto Specialties Mfg. Co.
St. Joseph Plant
Bendix Corp.
Consumers Asphalt & Concrete Co.
CITY
Munising
Au Gres
Omer
Essexville
Bay City
Bay City
Essexville
Bay City
Bay City
Bay City
Bay City
Essexville
Essexville
Bridgman
Benton
Harbor
St. Joseph
St. Joseph
Benton
Harbor
I
1
I
                                0-1
-------
1
1
1
wi



1






1

1




1

1




1

I



1
1
STATE: MICHIGAN
I.D. NUMBER NAME OF FACILITY
BERRIEN COUNTY

B6223

B6578
CHIPPEWA COUNTY

B1566


B2362

DELTA COUNTY
B1570
B1573

B5239

B5240

HURON COUNTY
B2815

B2873
B4944
MACKINAC COUNTY

B4924
MACOMB COUNTY

A3179

A3352
B1783

(con't)

John G. Yerington Co.
Benton Harbor Plant
Bridgman Casting Center


Soo Gravel & Asphalt Co.


Drummond Dolomite Inc.


Chicago & Northwestern Trans.
Upper Peninsula Power Co.

Payne & Do Ian Inc. (Permit 44-75
Portable)
Payne & Dolan Inc. (Permit 95-75
Delta County)

Detroit Edison Co. - Harbor Beach
Power Plant
Michigan Sugar Company
Wallace Stone Company

Limestone Operations

Ready Mix Concrete Inc.

Ward & Vannuck Asphalt Co.
New Haven Foundry
0-2
CITY


Benton
Harbor
Bridgman


Sault
Sainte
Marie
Drummond
Island

Escanaba
Escanaba

Escanaba

Escanaba


Harbor
Beach
Sebewaing
Bay Port

Cedarville

Warren

Mt. Clemens
New Haven

-------
STATE:  MICHIGAN
I.D. NUMBER
NAME OF FACILITY
CITY
MACOMB COUNTY (con't)
B4124
B5635
B5852
B6264
B6277
B6280
B6287
MARQUETTE COUNTY
B1833
B4261
MASON COUNTY
A3933
A3934
B1846
B1851
B4114
MENOMINEE COUNTY
B1855
MONROE COUNTY
A4097
A4127
B2816
Ace Concrete Products Co.
Wolverine Bronze Co.
E.B. Metzen Co.
Ace Concrete Products Co.
Four Seasons Transit Mix Cement
Construction Co.
Van Horn Bros. - Mt. Clemens Plant
Mini -Mix Co.
Marquette BD of Light & Power
Upper Peninsula Generating Co.
Presque Isle Station
Harbison-Walker Refractories
Division of Dresser Industries
Great Lakes Casting Corp.
Dow Chemical Ludington Plant
Laman Asphalt & Redi-Mix, Inc.
Chesapeake and Ohio Railway Co.
Menomine Paper Company, Inc.
Builders Ready-Mix Concrete
Ford Motor Co. - Monroe
Monroe Power Plant
Roseville
Roseville
New
Baltimore
Mt. Clemens
Roseville
Mt. Clemens
Fraser
Marquette
Marquette
Ludington
Ludington
Ludington
Ludington
Ludington
Menominee
Monroe
Monroe
Monroe
                                 0-3
-------
1
1
1












1

1

1
1

1




1

1





1

1

STATE: MICHIGAN
I.D. NUMBER
MONROE COUNTY (con

B2846


MUSKEGON COUNTY
A4203

A4231


A4238
A4242
A4302

A4315
B1893
B1906
B1907

B1908


B1925
B1929
B2836
ONTONAGON COUNTY
A5754

B1966

OTTAWA COUNTY
A5872
A5879



NAME OF FACILITY
't)

Consumers Power Company
J.R. Whiting Plant


S.D. Warren Co.

Certified Concrete Inc.


Muskegon Aluminum Foundry Co.
Enterprise Brass Works
Sealed Power Corp.

Cannon-Muskegon Corp.
Muskegon Asphalt Paving Co.
CWC Castings - Plant 1
(Sanford Street)
CWC Castings - Plant 3
(2673 Henry St.)
CWC Casting Division - Plant 4
(Broadway St.)

Tech-Cast Inc.
Westran Corp.
Consumers Power Co. - B.C. Cobb Plant

Champion Packaging - Ontonagon Mill
Division
White Pine Copper Division


Holtrop Concrete Products
Grand Haven Brass Foundry
0-4


CITY


Luna Pier



Muskegon

Muskegon
Heights

Muskegon
Muskegon
Muskegon
Heights
Muskegon
Muskegon
Muskegon
Heights
Roosevelt
Park
Muskegon
Heights

Montague
Muskegon
Muskegon

Ontonagon

White Pine


Ferrysburg
Grand Huron

-------
STATE:  MICHIGAN
I.D. NUMBER
NAME OF FACILITY
CITY
OTTAWA COUNTY
B2835
PRESOUE ISLE
B4925
(con't)
Consumer Power Plant
J.H. Campbell Plant
COUNTY
Limestone Operations - Calcite Plant
West Olive
Rogers City
SCHOOLCRAFT COUNTY
B4931
WAYNE COUNTY
A6928
A7809
A7816
A7835
A8631
A8640
A8646
A9036
A9740
B0673
B2081
B2116
B2166
B2169
B2800
B2810
B2811
Inland Lime and Stone Co.
Stroh Brewery Co.
Great Lakes Steel Division
Kahl Iron Foundry Inc.
Industrial Smelting Co.
GM - Cadillac Motor Car Division
Ford Motor Company Steel Division
Ford Dearborn Specialty Foundry
Rickel Malting Company Inc.
.Allied Chemical Corp.
Anaconda American Brass
Revere Copper & Brass
Michigan Division Plant
McLouth Steel Corp.
Chrysler Huber Ave. Foundry
Marblehead Lime Co.
BASF Wyandotte Corp.
Detroit Edison River Rouge Power Plant
Detroit Edison Trenton Chan Power Plant
Gulliver
Detroit
Ecorse
Detroit
Detroit
Detroit
Dearborn
Dearborn
Detroit
Detro i t
Detroit
Detroit
Trenton
Detroit
River Rouge
Wyandotte
River Rouge
Trenton
                                 0-5
-------
1
1
1
V

1

1


1

1



1
1
1
1
1
I
1
1
1
STATE: MICHIGAN
I.D. NUMBER NAME OF FACILITY CITY
WAYNE COUNTY (concluded)
B2812 Detroit Edison Conners Creek Power Plant Detroit
B3009 Detroit Edison Pennsalt Power Plant Wyandotte
B3011 Detroit Edison Willis Heating Plant Detroit
B3195 Asphalt Products Plant 6-A Detroit
B3518 United States Gypsum Co. River Rouge
B3520 Detroit Lime Co. Detroit
B3567 Peerless Cement Co. Detroit
B4009 Base Wyandotte Corp. - South Works Wyandotte
B4237 Asphalt Products Corp. - Plant 1A Detroit
B4243 Levy Slag Plant - No. 6 Detroit

B6087 Darco Corp. River Rouge







0-6

-------
          APPENDIX P



STATE OF MINNESOTA SOURCE LIST
-------
STATE:  MINNESOTA
I.D. NUMBER
NAME OF FACILITY
CITY
ST. LOUIS
0001
0013
0021
0022
0023
0032
0035
0036
0037
0055
0058
0059
COUNTY (3260-)
J.C. Campbell Co.
Minnesota Power & Light Co.
Aurora Station
Cargill, Inc. - Elevator B
Duluth Steam Coop. Association
Duluth Site
International Multi-foods
Reserve Mining Co. - Babbitt Site
U.S. Steel Corp. - Morgan Park Site
Arrowhead Blacktop Co. - Jeffery Road
Munger Site
Arrowhead Blacktop Co. - Plant #3
Cargill, Inc. - Elevator C
Lake Shore Blacktop Co. - Two Harbors Site
U.S. Steel Corp. - Lake Shipping
Two Harbors
Duluth
Duluth
Duluth
Duluth
Silver Bay
Morgan Park
Duluth
Duluth
Duluth
Two Harbors
Duluth
LAKE COUNTY (1840-)
0003
Reserve Mining Co. - Silver Bay Site
Silver Bay
                                       p-1
-------
       APPENDIX Q



STATE OF OHIO SOURCE LIST
-------
STATE:  OHIO
I.D. NUMBER
NAME OF FACILITY
CITY
ASHTABULA COUNTY
0204000211
0204010003
0204010193
CUYAHOGA COUNTY
1318000078
1318000103
1318000229
1318000244
1318000245
1318000372
1318000958
1318001007
1318001169
1318001287
1318001613
1318001622
1318001721
1318002490
1318002662
1318002816
1318003287
Cleveland Electric & Illuminating Co.
Union Carbide Corp. - Metals Division
G & W Natural Resources Group
Titanium
Jones & Laugh! in Steel Corp.
River Smelting & Refining
Cereal Food Processors
Cleveland Electric Illuminating
Steam Heating Plant
Cleveland Electric Illuminating
Lake Shore Plant
Forest City Foundries
Shell Sands, Inc.
Harshaw Chemical Co.
NASA Lewis Research Center
Wabash Alloys, Inc. - A&C Division
Republic Steel Corp.
U.S. Steel Corp. - Lorain Cuyahoga Works
National Metal Abrasive Co.
Division Pumping Station
Standard Slag Co., Republic Plant
Union-Independent Division of UNSCO
Sand Products Corporation
Ashtabula
Ashtabula
Ashtabula
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
Cleveland
                                       Q-l
-------
STATE:  OHIO
I.D. NUMBER
CUYAHOGA COUNTY
1318003295
1318003729
1318004160
1318005539
1318120178
1318120179
1318120180
1318201633
1318201688
1318202137
ERIE COUNTY
0322010062
0322020045
0322020183
LAKE COUNTY
0243000165
0243020456
0243030257
0243160009
0243160174
LORAIN COUNTY
NAME OF FACILITY
(con't)
Smith Facing & Supply Co.
Horvitz Co.
Hupp, Inc.
Valley Mould & Iron Co.
Ford Motor Co. - Cleveland Engine Plant 2
Ford Motor Co. - Cleveland Engine Plant 1
Ford Motor Co. - Cleveland Casting Plant
Addressograph Multigraph
Chase Brass & Copper Co., Inc.
Lincoln Electric Co.
Huron Lime Co.
New Departure - Hyatt
Sandusky Crushed Stone Co.
IRC Fibers Co.
Erie Coke & Chemical Co.
Republic Steel Corp. - Lime Plant
Cleveland Electric Illuminating Co.
East Lake Plant
Ohio Rubber Co.
.
CITY
Cleveland
Cleveland
Cleveland
Cleveland
Brookpark
Brookpark
Brookpark
Euclid
Euclid
Cleveland
Huron
Sandusky
Sandusky
Painesville
Fairport Harbor
Grand River
Willoughby
Willoughby

1947030013
Cleveland Electric Illuminating Co.
Avon Lake Plant
Avon Lake
                                      Q-2
-------
STATE:  OHIO
I.D. NUMBER
LORAIN COUNTY
1947080049
1947080229
LUCAS COUNTY
0448010064
0448010086
0448010203
0448010247
0448010313
0448010495
0448010699
0448020006
OTTAWA COUNTY
0362000078
0362000088
0362010011
NAME OF FACILITY
(con't)
Ohio Edison - Edgewater
U.S. Steel Corp. - Lorain Cuyahoga Works

General Mills Inc.
Toledo Edison Co. - Acme Station
Cargill Inc.
Toledo Mental Health Center
Mid-States Terminal, Inc.
Andersons Grain Division - Toledo Plant
R.G.C.
Toledo Eidson Co. - Bay Shore Station

U.S. Gypsum Co.
Maumee Stone Co. - Rocky Ridge Plant
Celotex Corp.
CITY

Lorain
Lorain

Tol edo
To! edo
Tol edo
Tol edo
Tol edo
Tol edo
Tol edo
Oregon

Gypsum
Benton Township
Port Clinton
                                      Q-3
-------
          APPENDIX R
STATE OF WISCONSIN SOURCE LIST
-------
STATE:  WISCONSIN
I.D. NUMBER
DOOR COUNTY
150001
150007
DOUGLAS COUNTY
160001
160002
160003
160005
160006
160008
160011
160013
160017
160020
160034
160037
KENOSHA COUNTY
300001
300021
KEWAUNEE COUNTY
310001
310002
MANITOWOC COUNTY
360004
NAME OF FACILITY

Door County Highway Dept.
Bissen Blacktop Inc.

Adm Grain Co.
Continental Elevator
CLM Corporation Superior
Farmers Union Grain Terminal
Peavey Co. Globe Elevator
National Gypsum Co. - Cement Division
M & 0 Elevators, Inc.
Peavey Co. Flour Mills
Superior Midwest Energy Terminal
Lakehead Blacktop Co.
Burlington Northern Ore Factory
Haskins Blacktop & Construction

Anaconda Co. - Brass Division
Kenosha Asphalt Paving

Kewaunee County Highway Commission
Algoma Hardwoods Inc.

Medusa Cement Co.
CITY

Sturgeon Bay
Sturgeon Bay

Superior
Superior
Superior
Superior
Superior
Superior
Superior
Superior
Superior
Superior
Superior
Gordon

Kenosha
Kenosha

—
Algoma

Manitowoc
                                       R-l
-------
STATE:  WISCONSIN
I.D. NUMBER
MANITOWOC COUNTY
360005
360006
360007
360011
360035
360047
MARINETTE COUNTY
380006
380008
380018
MILWAUKEE COUNTY
410002
410003
410009
410006
410014
410027
410045
410054
410058
410059
410051
NAME OF FACILITY
(con't)
Manitowoc County Highway Dept.
Manitowoc Public Utilities
Rockwell Lime Co.
Reliance Construction Co. - Plant 181
Schuette Construction Co.
Wisconsin Aluminum Foundry
Rodman Industries
Ansul Company
Biehl Construction Co. -Marinette Plant
Pabst Brewing Co.
Joseph Schlitz Brewing Co.
Wisconsin Electric Power.- E. Wells Station
Briggs & Stratton Corp. - Milwaukee Plant
#2
Ready-Crete, Inc.
A.O. Smith Corp.
Miller Brewing Co. - Milwaukee Plant
Milwaukee County Institutions - Power Plant
Northwest Asphalt Product Inc.
Highway Pavers Inc. - Asphalt Plant
White Construction Co. - Asphalt Plant
CITY
Manitowoc
Manitowoc
Rockwood
Meeme
Kossuth
Manitowoc
Marinette
Marinette
Marinette
Milwaukee
Milwaukee
Milwaukee
Milwaukee
Milwaukee
Milwaukee
Milwaukee
Wauwatosa
Milwaukee
Milwaukee
Milwaukee
                                      R-2
-------
STATE:  WISCONSIN
I.D. NUMBER
MILWAUKEE COUNTY
410060
410076
410077
410078
410081
410091
410096
410100
410103
410105
410106
410110
410126
410128
410133
410134
410136
410137
410138
410140
410142
410143
410144
NAME OF FACILITY
(con't)
Briggs & Straton Corp. - Wauwatosa Plant
Grede Foundries Inc. - Milwaukee Steel Div.
Milwaukee Solvay Coke Co.
Paving Mix and Construction Co., Inc.
Hynite Corporation
Cudahy Paving Co., Inc.
Ladish Company
Rexnord, Inc. - Nordberg Machine Group
Wisconsin Electric Power - Valley Station
City of Milwaukee Asphalt Plant
Mi deity Foundry Co.
Universal Atlas Cement Div. - U.S. Steel
Howmet Turbine Components
Barclay Foundry, Inc.
Kurth Malting Co., Plant 1
Wehr Steel Co.
Sherwin Corp.
Krause Milling Co.
AMPCO Metal Div. - Milwaukee
Milwaukee Malleable and Great Iron Works
Maynard Steel Casting Co.
Froedteri Malt Corp.
Falk Corp. - Plant 1
CITY

Wauwatosa
Milwaukee
Milwaukee
Oak Creek
Oak Creek
Cudahy
Cudahy
Milwaukee
Milwaukee
Milwaukee
Milwaukee
Milwaukee
Milwaukee
Milwaukee
West Milwaukee
West All is
Milwaukee
West Milwaukee
Milwaukee
Milwaukee
Milwaukee
West Milwaukee
Milwaukee
                                       R-3
-------
STATE:  WISCONSIN
I.D. NUMBER
MILWAUKEE COUNTY
410146
410153
410154
410155
410157
410166
410167
410253
410256
OZAUKEE COUNTY
460016
460029
RACINE COUNTY
520016
520027
520032
520888
SHEBOYGAN COUNTY
600004
600007
NAME OF FACILITY
(con't)
Minerals Reclamation Corp.
Motor Castings Co. - Plant 1
Federal Casting Division
Motor Castings Co. - Plant 2
All is Chalmers Corp. - Foundry
Grey Iron Foundry Inc. - West All is
Briggs & Stratton Corp. - West All is Plant
Pelton Casteel Inc. - W. Dewey PI. Plant
Bucyrus - Erie Co. - Main Plant
Wisconsin Electric Power - Port Washington
Station
White Construction Co. - Saukville Plant
Payne & Do! an of Wisconsin
Vulcan Materials Co. - Racine Quarry #383
A.W. Oakes & Son, Inc.
Evans Products Co. - Racine Steel Castings
Kohler Co. - Kohler Plant
City of Sheboygan Incinerator
CITY
West All is
West All is
West All is
Milwaukee
West All is
West All is
West All is
Milwaukee
South Milwaukee
Port Washington
Saukville
Racine
Racine
Racine
Racine
Kohler
Sheboygan
                                       R-4
-------
                                     TECHNICAL REPORT DATA
                              (Please read Instructions on the reverse before completing)
  i. REPORT NO.
     905/2-80-007
                                                             3. RECIPIENT'S ACCESSION NO.
  4. TITLE AND SUBTITLE
     Industrial  Process Fugitive Emission Inventory  for
     the  Region  V Great Lakes  Shoreline
                                                              5. REPORT DATE
                                                 6. PERFORMING ORGANIZATION CODE
  7. AUTHORIS)
     Charles
     Eddy S.
J. Mackus
Lin
                                                             8. PERFORMING ORGANIZATION REPORT NO.
  9. PERFORMING ORGANIZATION NAME AND ADDRESS
                                                              10. PROGRAM ELEMENT NO.
     Pacific Environmental
     465 Fullerton
     Elmhurst, IL  60126
               Services, Inc.
                                                 11. CONTRACT/GRANT NO.
                                                 68-01-4140
                                                 Work Assignment No. 73
  12. SPONSORING AGENCY NAME AND ADDRESS
     U.S.  Environmental  Protection Agency, Region  V
     Division of Stationary Source Enforcement
     230 S.  Dearborn
     Chicago, IL  60604
                                                 13. TYPE OF REPORT AND PERIOD COVERED
                                                 Final
                                                 14. SPONSORING AGENCY CODE

                                                 5EAE
  15. SUPPLEMENTARY NOTES
  16. ABSTRACT
     This report was the  result of a limited-scope  preliminary study  of particulate
     fugitive emissions from major industrial  sources located within  the six states of
     U.S. EPA Region V.   This study revealed that approximately 229,000 to 531,000 tons
     of fugitive particulates were deposited into the Great Lakes during 1978.  Large
     industrial cities  such as Chicago, Gary,  Cleveland, Toledo, Detroit, and Milwaukee
     were found to have the largest concentration of major fugitive emission sources.
     Iron and steel industries were found to be  the largest fugitive  emission sources
     bordering the lakes.
  7.
                                  KEY WORDS AND DOCUMENT ANALYSIS
                   DESCRIPTORS
                                                b.lDENTIFIERS/OPEN ENDED TERMS
                                                              c.  COSATI Field/Group
     Air Pollution  Control
     Industrial Process  Fugitive Emissions
     Great Lakes
     Fallout
     Water Pollution
     Meteorology
                                    Fugitive Emission  Invento
                                    Atmospheric loading
                                    Nutrients
                                    Water Quality  Effect
  3. DISTRIBUTION STATEMENT
     Unlimited
                                   19. SECURITY CLASS (This Report)
                                    Unclassified
21- NO 
-------
                                                        INSTRUCTIONS

   1.   REPORT NUMBER
       Insert the EPA report number as it appears on the cover of the publication.

   2.   LEAVE BLANK

   3.   RECIPIENTS ACCESSION NUMBER
       Reserved for use by each report recipient.

   4.   TITLE  AND SUBTITLE
       Title should indicate clearly and briefly the subject coverage of the report, and be displayed prominently.  Set subtitle, if used, in smaller
       type or otherwise subordinate it to main title. When a report is prepared in more than one volume, repeat the primary title, add volume
       number and include subtitle for the specific title.

   5.   REPORT DATE
       Each report shall carry a date indicating at least month and year.  Indicate the basis on which it was selected (e.g., date of issue, date of
       approval, date of preparation, etc.).

   6.   PERFORMING ORGANIZATION CODE
       Leave blank.
                                 •
   7.   AUTHOR (S)
       Give name(s) in conventional order (John R. Doe, J. Robert Doe, etc.). List author's affiliation if it differs from the performing organi-
       zation.

   8.   PERFORMING ORGANIZATION REPORT NUMBER
       Insert if performing organization wishes to assign this number.

   9.   PERFORMING ORGANIZATION NAME AND ADDRESS
       Give name, street, city, state, and ZIP code.  List no more than two levels of an organizational hirearchy.

   10.  PROGRAM ELEMENT NUMBER
       Use the program element number under which the report was prepared. Subordinate numbers may be included in parentheses.

   11.  CONTRACT/GRANT NUMBER
       Insert contract or grant number under which report was prepared.

   12.  SPONSORING AGENCY NAME AND ADDRESS
       Include ZIP code.

   13.  TYPE OF REPORT AND PERIOD COVERED
       Indicate interim final, etc., and if applicable, dates covered.

   14.  SPONSORING AGENCY CODE
       Leave blank.

   15.  SUPPLEMENTARY NOTES
       Enter information not included elsewhere but useful, such as: Prepared in cooperation with, Translation of. Presented at conference of,
       To be published in, Supersedes, Supplements, etc.

   16.  ABSTRACT
       Include a brief (200 words or less) factual summary of the most significant information contained in the report. If the report contains a
       significant bibliography or literature survey,  mention it here.

   17.  KEY WORDS AND DOCUMENT ANALYSIS
       (a) DESCRIPTORS - Select from the Thesaurus of Engineering and Scientific Terms the proper authorized terms that identify the major
       concept of the research and are sufficiently specific and precise to be used as index entries for cataloging.

       (b) IDENTIFIERS AND OPEN-ENDED TERMS  - Use identifiers for project names, code names, equipment designators, etc.  Use open-
       ended terms written in descriptor form for those subjects for which no descriptor exists.

       (c) COSATI FIELD GROUP - Field and group assignments are to be taken from the 1965 COSATI Subject Category List. Since the ma-
       jority of documents are multidisciplinary in  nature, the Primary Field/Group assignment(s) will be specific discipline, area of human
       endeavor, or type of physical object. The application(s) will be cross-referenced with secondary Field/Group assignments that will follow
       the primary posting(s).                                                                         • -

   18.  DISTRIBUTION STATEMENT
       Denote releasability to the public or limitation for reasons other than security for example "Release Unlimited."  Cite any availability to
       the public, with address and price.

   19.&20. SECURITY CLASSIFICATION
       DO NOT submit classified reports to the National Technical Information  service.

   21.  NUMBER OF PAGES
       Insert the total number of pages, including this one and unnumbered pages, but exclude distribution list, if any.

   22.  PRICE                                 ,    •
       Insert the price set by the National Technical Information Service or the Government Printing Office, if known.
:PA Form 2220-1 (9-73) (Reverse)
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