{{#Wiki_filter:Indiana Michigan Power Company One Summit Square , P.O.Box 60 Fort Wayne, IN 46801 219 425 2111 CERTIFIED MAIL 4 P 378 90l 729 IItIDIAItIA NICHIGAN POWER Mr.J.B.Beauboeuf-Waste Management Division Michigan Department of Natural Resources John Hannah Building P.0.Box 30241 Lansing, MI 48909 March ll, 1994  

==Dear Mr.Beauboeuf:==

RE: Donald C.Cook Nuclear.Plant Groundwater Discharge Permit Application Enclosed please find a groundwater discharge permit application for the Cook Nuclear Plant located in Bridgman, Michigan, Berrien County.As requested by Mr.Scott Ross during our meeting on November 10, 1993, also enclosed is a study which compares the quality of the effluent from the Turbine Room Sump (TRS)discharge to that of the absorption pond discharge to groundwater.

Included with the permit application is a description of the changes scheduled to be made to further reduce the concentrations of impurities discharged into the absorption pond.Please note, also as requested by Mr.Scott Ross, that this application addresses only the Cook Nuclear Plant's discharges to the groundwater.

An application for renewal of the NPDES surface water discharge permit MI0005827 will be submitted by April 1, 1994.The attached study indicates the absorption pond provides excellent mixing, with a mixing/dilution factor of approximately 20:1.Furthermore, the actual.water entering the ground meets all of the proposed groundwater effluent limits with the exception of aluminum.The aluminum discharge is the result of the use of aluminum sulfate (alum)as a flocculent in the makeup water plant.The replacement of alum is currently being pursued, as described in Attachment 4.Additional changes planned for the Cook Nuclear Plant will result in further reduction of the concentrations of impurities to the absorption pond.Attachments 1 and 2 describe the makeup plant neutralization system and sequencing batch reactors respectively, which will result in improved effluent water quality.

March 11, 1994 Mr.J.B.Beauboeuf Page 2 Attachment 3 is a description of the present zebra mussel-control strategy as it affects the groundwater discharge as well as some of the options being evaluated for future improvements.

Attachment 5 is a description of'hemical corrosion control additives which will be used in various plant systems.These additives will be chosen on their reduced environmental toxicity as well as corrosion control performance.

Finally, we offer to the agency the following proposals for establishing compliance with the proposed groundwater effluent standards:

*We propose to continue compliance monitoring

.at the turbine room sump discharge.

The absorption pond study has.demonstrated that the water entering the aquifer meets the proposed.groundwater effluent limits for boron, sulfates, sodium, and total dissolved solids.Therefore, we propose a monthly composite sample made up of 24 hour daily composite samples be utilized for compliance monitoring.

*We request that aluminum be regulated by total pounds released as proposed by Mr.Ross in our November meeting, rather than by concentration in the absorption pond.The proposed poundage limit is a maximum 125 pounds alum per day.Should you have any questions on the attached material please contact John Carlson, Cook Nuclear Plant Environmental Supervisor, at (616)465-5901 ext.1153 or me at (219)425-2118.

We would be happy to meet with you at your convenience to discuss the application if you believe that would be helpful.Very truly yours, Donald L.Baker Environmental Affairs Director DLB/sdb/046, 042 Enclosure March 11, 1994 Mr.J.B.Beauboeuf Page 3 bc: W.A.S.D.E.D.To N.D'Onofrio/M.

A.Bailey/J.L.Hughey A.Blind J.Brewer M.Fitzgerald/J.

P.Carlson E.Fitzpatrick W.Kemp/K.D.Mack E.Webb/J.P.Novotny Attachment 1 Makeup Demineralizer Regeneration Waste Neutralization System The Cook Plant is installing a system to collect and treat makeup demineralizer regeneration wastes to meet proposed pH permit limits.The current practice is to isolate the Turbine Room Sump (TRS), accumulate the wastes within the TRS, neutralize the waste with sulfuric acid or sodium hydroxide, then discharge the neutralized contents of the TRS to the Absorption Pond.Because the regeneration wastes are not the only source of water being collected in the TRS, a high water level within the TRS may require the discharge of the sump contents prior to the wastes being completely neutralized.

The new system will allow collection and neutralization of the regeneration wastes apart from the TRS.The holding tank for the waste will also be the point of treatment with the capability to add and mix sulfuric acid or sodium hydroxide with the waste prior to metering the neutral mixture to the TRS.The total cost of the Makeup Demineralization Waste System is$3,600,000.00.

The system is targeted for completion by January of 1995, with system startup to occur thereafter.

Attachment 2 Sequencing Batch Reactors The Cook Plant is currently requesting quotations to install a pair of pre-engineered sequencing batch reactors (SBR)to meet the proposed groundwater effluent limits.The new system will operate at a design flow of 50,000 GPD with a maximum flow of 60,000 GPD.The South Extended Aeration Package Plant will be utilized as a retention tank to ensure efficient SBR operation.

Effluent from the new system will continue to be discharged into one of the two seepage lagoons.The new system will be installed and operational by December of 1995.

Attachment 3 Zebra Mussel Control Strategy Zebra mussels are a menace to any industrial or municipal process drawing water from Lake Michigan.Our current control plan is to chlorinate and perform periodic shock chemical treatments utilizing a proprietary chemical formulation.

The Plant has also changed the source water for the fire protection system to a potable supply from Lake Township.This method of control was developed for short term relief from the effects of zebra mussel infestation.

Based on over three years experience in dealing with the mussels at Cook Plant and other Great Lakes facilities, a new strategy is being proposed to our corporate management for approval to protect all operations frog infestation.

The new strategy incorporates intermittent oxidizing biocide treatments of the circulating water system beginning at the intake structures in Lake Michigan, continuous oxidizing biocide treatment of the essential service water and non-essential service water systems, addition of sodium bisulfite to reduce any residual oxidizing biocide prior to discharge to the lake, and, if necessary, shock treatments utilizing proprietary chemical formulations.

The goal of the program is to (1)eradicate existing populations and control further settlement of zebra mussels within the plant systems utilizing lake water, (2)treat the residual oxidant being discharged to non-detectable levels, and (3)reduce or eliminate the number of remedial shock treatments necessary to kill settled colonies of zebra mussels.The resultant zebra mussel control changes will ultimately affect discharges to the Turbine Room Sump from plant systems that are supplied by miscellaneous sealing and cooling water and systems that use non-essential service water that discharge directly to the TRS.

Attachment 4 Alum Replacement Program A Chemistry Task Force has been evaluating chemical flocculent replacements for alum (aluminum sulfate).Our corporate management is currently reviewing various flocculents, taking both groundwater effluent standards and reverse osmosis system performance into consideration.

The replacements currently being reviewed are mainly polymeric flocculent which will enhance the removal of suspended solids in the pre-filters and meet manufacturer recommendations for the water entering the reverse osmosis system.The recommendations from the task force, once approved, will require additional time to test and implement.

The environmental benefit of this review is the reduced amount of aluminum which will be discharged to the groundwater through the Turbine Room Sump discharge.

The scheduled target implementation date to use a new flocculent is fovrth quarter of 1994.  

Attachment 5 Chemistry Corrosion Control Additives The Plant is evaluating substitutes for the current corrosion control additives in the steam generators, plant heating boiler, feedwater and condensate systems, and closed heating/cooling systems.These substitutes will include carbohydrazide, and other available products from chemical companies such as Betz or Nalco.The environmental benefits of these additives include utilization of more benign corrosion control products or products requiring lower effective concentrations.

Use of these products will necessitate discharge to the Turbine Room Sump pathway in concentrations to be determined upon effective optimization.

Consequently, higher concentrations or iron and other system products can initially be expected.

Comparative Study of Turbine Room Sump Discharges and Absorption Pond Water Chemistry Cook Nuclear Plant Groundwater Application February 7, 1994 INTRODUCTION A study was conducted to characterize the water quality in the Cook Nuclear Plant Absorption Pond complex prior to discharge into the groundwater.

This was at the request of Mr.Scott Ross (Michigan DNR)during our November 1993 meeting in Lansing, MI.The intent of the study was to determine the mixing and dilution effects of the Absorption Pond on discharges from the plant's Turbine Room Sump (TRS).This report presents the results of the study, data analysis, and groundwater implications.

Wastewater generated in the plant either drains to the TRS or is pumped to the TRS from localized sumps.The primary sources of wastewater include Makeup Plant demineralizer regenerations, filter backwashes, floor drains, chemistry lab wastes, various equipment and system drains, and non-contact cooling water.Water is collected in the TRS,'eutralized as necessary, and is periodically discharged to an onsite Absorption Pond complex.The ponds are located approximately 825 feet southeast of the plant (Figure 1).The Absorption Pond complex consists of the original Absorption Pond and an Overflow Pond connected by a 392 foot ditch.The ponds have received an average TRS discharge flow of 301,000 gallons per day during the last six months of plant operation.

Both ponds maintain relatively stable water levels with the Absorption Pond overflowing continuously to the downstream Overflow Pond.The pond water entering the ground eventually flows to Lake Michigan based on a 1991 hydrogeology study.MATERIALS AND METHODS'he Absorption Pond study consisted of three stages: 1)a preliminary conductivity survey and pond volume determination, 2)an 18-day comparison of TRS and Absorption Pond water chemistry, and 3)data analysis and report generation.

The preliminary conductivity survey was conducted to determine the uniformity of water chemistry within the Absorption Pond and to obtain pond depth readings.The subsequent 18-day study included two Makeup Plant demineralizer regenerations and was conducted with both plant units operating between 70 and 100<power.The second regeneration was"forced" to compress the study time and provide a more conservative evaluation of the effects of regenerations.

The amount of acid and caustic used in the regenerations was maintained at normal levels.Page 1 of 20

Preliminar Surve A sampling grid was established on the Absorption Pond and Overflow Pond on 40 foot intervals using permanent reference points.At each point, a conductivity measurement was taken at a depth of approximately 1.5 feet using a Hach Model 44600 conductivity meter.Pond depths were also taken at each point using an Impulse Model 4400 depth finder.Additional depth readings were taken around the periphery of the ponds to better develop depth contour maps.The areas of the two ponds were determined using a November 1993 aerial photograph scaled to 1 inch=660 feet and an electronic planimeter.

Ten repetitive measurements were taken on each pond.Average areas were then calculated for the ponds.The volumes of the two ponds and the interconnecting stream were calculated using the depth contour maps and area data.The areas between the depth contour lines were multiplied by the average depth and added to obtain the total pond volumes.18-Da Stud The study was designed to obtain daily composite samples from the TRS and Absorption Pond complex during a period encompassing two demineralizer regenerations.

Samples were collected once per day from the Absorption Pond.The NPDES autocompositor was used to obtain daily TRS composites for the study.Cook Nuclear Plant personnel analyzed the samples for pH and conductivity.

Halliburton NUS Environmental Laboratory analyzed the samples for sulfate, chloride, sodium, total dissolved solids, total aluminum, dissolved aluminum, total boron and dissolved boron.Four sample locations were selected to make up the daily composite for the Absorption Pond complex.Two central points were located at 10 foot depths in the Absorption Pond and two central points at two foot depths were located in the Overflow Pond (Figure 2).Tygon tubing was secured at each sample location and run to the pond shores for sampling.Battery operated peristaltic pumps were used to purge and draw the samples.Equal quantities from each point were combined to make up the Absorption Pond composite.

A TRS and Absorption Pond study period composite was also analyzed for the above parameters which consisted of equal quantities from the 18 daily composites.

The composites were used as checks on the daily analytical data.An additional set of independent grab samples was collected over a 28 hour period during and after the second demineralizer regeneration to provide more detailed data on the event.Grab samples were collected every four hours from the TRS and composite samples (four points)were collected every six hours from the Absorption Pond.The samples were analyzed for conductivity to provide a relative indication of the short-term effects of demineralizer regenerations.

Page 2 of 20 Data Anal sis and Re ort The data from the study was compared statistically using Systat software.The following comparisons and calculations were performed to evaluate the data and test the validity of the study:-The TRS and Absorption Pond data were compared with proposed groundwater discharge limits to determine if the limits would be met during demineralizer regenerations.-The TRS and Absorption Pond data were compared graphically to ensure the patterns matched mass balance calculations.-Mass balances for selected chemistry parameters were performed including calculated versus actual Absorption Pond value comparisons.-The study data were compared with the NPDES discharge monitoring data from past months to ensure the study was representative of plant operations.

Statistical significance is expressed with a percent confidence level and method, when appropriate.

RESULTS Preliminar Surve and Pond Volumes Initial conductivity measurements indicated the ponds were mixing uniformly.

Conductivities ranged from 310-328 uS in the Absorption Pond and from 340-347 uS in the Overflow Ponds.It was concluded that the TRS discharge plume was mixing very quickly and that the selection of sample points could be based on representing equal areas of the Absorption Pond complex.The four sample points shown in Figure 2 were selected on this basis.Depth readings were obtained at 60 locations in the Absorption Pond and at 15 locations in the Overflow Pond.Depth contour maps were developed from this data for the two ponds (Figures 3 and 4).The maximum measured depth of the Absorption Pond was 19.0 feet and 4.7 feet for the Overflow Pond.Pond surface areas and volumes are shown in Table 1.The total water surface area is 2.21 acres with a combined volume of approximately six million gallons.This provides a daily TRS dilution factor of almost 20:1 based on a 301,000 gpd average flow rate.Page 3 of 20

18 Da Stud The TRS water chemistry remains relatively constant (normal TDS range of 130-170 mg/1)except following Makeup Plant (MUP)demineralizer regenerations.

The sulfuric acid and sodium hydroxide used to regenerate the demineralizers sharply increase the sulfate, sodium, conductivity, and TDS levels for approximately 12 hours.The regenerations are conducted on an as needed basis and averaged once per 12 days during the last six months.The trend is toward more infrequent regenerations as operation of the reverse osmosis (RO)unit is refined.Analysis results for the 18 day sampling period for the TRS and Absorption Pond are listed in Table 2.The analysis results for the TRS and Absorption Pond are compared graphically in Figures 5 through 14.Even following demineralizer regenerations, the studied chemistry parameters remained well below the proposed groundwater limits in the Absorption Pond with the exception of dissolved aluminum.The sharp increases in conductivity, sulfate, sodium, boron, and TDS are directly correlated with MUP demineralizer regenerations.

The two boron peaks are thought to be due to the release of boron from the cation beds during the regenerations.

A Lake Michigan boron level of 83 ug/l was reported in our 1990 NPDES Permit apllication.

The amount of boron removed from processing approximately 4-5 million gallons of Lake Michigan water between regenerations would account for the peaks.The dissolved aluminum exceeded or equaled proposed ground water discharge limits in the Absorption Pond on each day;dissolved aluminum values ranged from 50-140 ug/l compared to a limit of 50 ug/l.Aluminum levels in the TRS are elevated due to the use of alum (aluminum sulfate)at an average rate of 300 pounds per week.Higher rates are used during turbid lake conditions.

There was excellent correlation between the TRS and Absorption Pond results for all parameters studied.Table 3 lists the multiple correlation coefficients (R~), F-Ratios for the linear regression tests, and significance level (p).In most cases, the probability of the TRS and Absorption Pond chemistry parameters not being related is less than O.l<.The correlation between the TRS and Absorption Pond could be improved slightly by comparing Absorption Pond data one day later than the TRS data ("lagging one day").This probably reflects the sampling time difference:

1000 hours for the Absorption Pond and 2200 hours for the TRS.This indicates the Absorption Pond data are reliable in assessing the true effects of the TRS on Absorption Pond water chemistry.

Mass balances were also conducted following the regeneration events to further define the validity of the study.The calculated concentrations for the Absorption Pond following regeneration are reasonably close to the actual concentrations obtained from analysis.The results are presented in Table 4.A more intensive short-term study of the effects of regenerations on TRS and Absorption Pond water chemistry was conducted on January 4-5, 1994.The conductivity results are included in Table 5 and shown graphically in Figure 15.The results indicate that the TRS returns to normal water chemistry approximately 12 hours after the start of a regeneration.

The data also indicates that the Absorption Pond mixes very quickly, thereby buffering TRS chemistry spikes.Xn addition to meeting the proposed limits for the TRS discharges, installation of the reverse osmosis (RO)unit has resulted in a marked reduction in levels of groundwater contaminants.

Figure 16 illustrates the water quality effects of operating the RO unit to reduce demineralizer regenerations on the TRS and groundwater Well f11, the closest well to the Absorption Pond.As the plant becomes more efficient at operating the Makeup Plant and other improvements are made, we expect this trend to continue.CONCL'USZONS The quality of the Absorption Pond water entering the aquifer was within the proposed groundwater limits for all of the parameters studied except for dissolved aluminum.The aluminum levels were still very low and will be reduced below the 50 ug/1 limit once plans to replace alum as a flocculant are completed.

Therefore, the TRS compositor sample can continue to be used for discharge monitoring with assurance that the groundwater limits will be met.Mixing and dilution of TRS discharges with Absorption Pond complex water provided a buffering effect resulting in stable pond water quality even during demineralizer regeneration periods.Other than aluminum, the average concentrations of the chemical parameters studied were equal to or less than 60 percent of the proposed concentration limits.This indicates that.there is'substantial margin against exceedances should plant operating conditions deviate from the normal conditions included in this study.From the trends in groundwater well data over the last year, it is also apparent that the Cook Nuclear Plant has made great strides in improving groundwater discharge quality.We expect this trend to continue with further refinements of our Makeup Plant and installation of the neutralization tank and new sewage treatment facility.Page 5 of 20

Table l-Pond Volumes and Absorption Areas Area Volume Location Absorption Pond Overflow Pond Connecting Stream Total Sq.Feet 62,291 30,056 3,920 96,267 Acres 1.43 0.69 0.09 2.21 Cu.Feet 704,606 85,396 3,920 793,922 Gallons 5,270,453 638,762 29,321 5,938,536 page 6 of 20

Table 2-TRS and Absorption Pond Analytical Results (mg/l)Day'ulfate Sodium Chloride TDS Total-Al Dissol-Al Total-B Dissol-B Cond(uS)pH TRS AP TRS AP TRS AP TRS AP TRS AP TRS AP TRS AP TRS AP TRS AP TRS AP 53 N N 10 N 150 N 0.50 N 0.10 N 0.04 N 0.05 N 261 N 7.22 N 53 88 6.2 22 10 11 150 200 0.80 0.40 0.07 0.09 0.04 0.06 0.06 0.06 263 363 7.19 7.2 52 96 4.8 48 91 4.7 55 90 8.5 9 11 23 10 10 23 10 10 150 210 150 220 0.58 0.67 160 220 0.89 0.20 0.24 0.25 0.09 0:05 0.06 0.19 0.07 0.05 0.14 0.14 0.05 0.06 0.06 0.06 0.06 0.07 0.05 0.06 0.05 0.06 267 275 265 365 7.25 7.2 372 7.16 7.2 362 7 26 7 0 10 12 13 14 85 100 16 49 94 5 5 55 97 8.3 60 92 5.9 480 94 190 47 110 51 110 6.3 53 110 52 110 5.6 51 100 5.9 24 10 11 22 10 11 22 11 11 23 10 11 23 11 10 25 11 10 28 11 11 28 10 30 10 10 31 10 10 170 210 0.90 130 210 1.60 140 200 1.20 140 200 0.75 740 190 1.10 130 220 0.91 140 190 0.97 130 210 0.98 130 210 1.60 140 190 1.50 0.22 0.26 0.25 0.32 0.31 0.23 0.36 0.33 0.35 0.50 0.09 0.15 0.06 0.11<.05 0.06 0.16 0.10 0.05 0.15 0.06 0.06 0.09 0.08 0.12 0.12 0.08 0.06 0.30 0.07 0.05 0.30 0.10 0.05 0.20 0.10 0.06 0.30 0.07 0.05 0.06 0.06 0.06 0.06 0.06 0.06 0.06 0.06 0.06 0.06 0.06 0.06 281 0.05 0.06 276 0.05 0.06 275 0.03 0.06 287 0.11 0.06 1135 0.04 0.06 306 0.06 0.04 300 0.05 0.06 269 0.05 0.05 303 0.05 0.06 251 379 7.08 7.0 381 6.99 7.1 376 7 06 7 1 365 7.60 7.2 369 7.67 7.1 415 7.44 7.2 406 7.42 7.1 406 7.72 7.4 420 7.49 7.6 425 7.60 7.6 15 47 110 5.5 16 680 110 260 17 18 65 130 14 N 120 N Avg.113 103 31 Comp 350 110 150 9 10 38 N 10 26 10 10 29 11 10 28 10 10 27 10 10 150 190 1.80 960 220 0.16 160 260 0.61 N 240 N 223 211 0.97 600 220 0.66 0.50 0.27 0.38 0.28 0.31 0.29 0.17 0.09 0.05 0.50 0.07 0.09 0.16 0.20 0.16 N 0.07 N 0.17 0.09 0.06 0.30 0.08 0.1 0.06 0.06 0.06 0.07 0.06 0.06 0.05 0.05 303 0.09 0.06 1700 0.15 0.06 284 N 0.06 N 0.06 0.06 406 0.11 0.06 989 410 7.30 7.0 395 7.18 7.6 450 7 19 7 0 399 7.16 6.8 342 7'0 7.1 399 7.16 6.8 Page 7 of 20 0

Table 2-Continued The first TRS sample was collected at approximately 2200 on December 19,1993 (Day 0).The Day 0 data was included in the Table 3 linear regression model when TRS data was shifted down (lagged)one day.A TRS sample was not collected on the evening of the final day of the study, January 6, 1994.Demineralizer regenerations were conducted on Day 9 (December 28)and Day 16 (January 4).2.Study composite samples consisted of combining equal quantities of the daily composites from the TRS and AP.The much higher than expected analytical results for the TRS composite are believed to have been caused by the inadvertent addition of a grab sample during the 28-hour regeneration study.Page 8 of 20 t'  

~~~~r~~~~~~~~~~~~~~~I I 0~~I I I I I I I~I I I I I I III~I I~I~~~~~I I I~~I I I I I'I~~I~~~~--~~I~~~~~~~>~~I~I I'~e~0 0 I~~e'I I I I I I I~I I~~I I I I I I~~I I I~I~I~I~~I~~-~~I I~I+I~i~I I I I I I I I I III I I I I~~0~~~~I~0~~~~~~~~0~~~I I I o--o 0~~~~~~0~~~~~~0 0~~~I'.~~0~  

0~.-~0=~~~-~e~~~~~~~e~e" R5 RR.%5 I I~I I I I I I~~~~~e I e~I~~~i~~i RRI I I~I~~~I I~~e~1~~~e~~~e~~e~e~e~~e e~e~e I~e~e e~e I~l~e~~e~~~~e e e a'r e~.I~e~~~4 r er 4~e-I~e l~e~~~~l e e~.~~e e e~~~0 e

Table 5-Regeneration Effects on Conductivity (uS)over a 28-Hour Period Time 800 1000 1200 1600 2000 2200 2400 400 800 1000 1200 263 NA 6,820 2,380 367 NA 195 200 256 NA 245 Abs.Pond 395 NA 470 NA 447 NA 436 NA 445 NA 1.Makeup Plant demineralizer regeneration discharge from the TRS began at approximately 1140 hours on Ol/04/93.Page 11 of 20

~>g<>B 1-Cook Nuclear Plant, Absorption Pond Complex and WLL~~CRS L 40t W Plant/)Cj-'L'~Ll a w~v 0 O L P (L I Sverflo POND I-~.'~~".Page 12 o f 20 Figu1e 2-Absorption Pond and Overflow Pond Sample Locations Absorption Pond Connecting Stream (392 feet)Overflow Culvert p/y/I lg X=Sample Location P=Pump Location Overflow X Pond P Page 13 of 20 Figure 3-Absorption Pond Depth Contours/go)PE tj>'r ro Figure 4-Overflow Pond Depth Contours 41 Page 14 of 20 Figure 5-conductivity 2000 1500 1000 O 0 0 500 0 I I I o i 2 o i s e r e o io>>ia is i4 is ie ir ie DAY----AP TRS Figure 6-pH 1.0 0.9~A pH 8.5 0.8 0.7~pH 6.5 0 i 2 s 4 s e r e o io ii 12 13 i4 is ie ir ie DAY----LOGAP LOGTRS LOGMAX LOGMIN Page 15 of 20 Figure 7-Sul f ate 700 600 500 O)4pp~300 CO 200 100 0 1 2 0 4 5 8 1 8 9 10 1'1 12 15 14 15 18 ll 18 OAY----AP TRS LIMIT Figure 8-sodium 300 200 0~~00 0 1 2 0 4 5 8 7 8 8 10 11 12 18 14 ld 18 17 18 DAY----AP-TRS LIMIT Page 16 of 20 Figure 9-Chloride 300 200 l 0 Z 0 100 0 1 2 Q 4 5 0 1 8 9 10 11 12 18)4 15 1S ll 18 DAY----AP TRS LIMIT Figure 10-Total Dissolved Solids 1000 800 600 2 03 P 400 200 0 1 2 0~5 5 7 6 0 10 11 12 18 14 15 15 11 18 DAY----AP TRS LIMIT Page,17 of 20 Figure 11-Total Aluminum 2.0 1.5 2 i.0 0.5 0.0 0 1 2 5 4 5 5 I 8 9 10 1 1 12 13 14 1$15 ll 18----AP-TRS DAY Figure 12-Dissolved Aluminum 0.6~04 E 0 g 0.2 O 0.0///~ef I I A/N I----AP-TRS LIMIT 0 1 2 5 4 5 5 I 8 9 10 11 12'5 14 15 15 17 18 DAY Page 18 of 20

]i Figure 13-Total Boron 0.20 0.15 E C o 010 O K 0 0.05 i I'i I I I'i I I'\I I I I I I I I I I I I 0.00 0 i 2 0~s e r s o io ii i2 ie w is ie ir is----TRS AP DAY Figure 14-Dissolved Boron 0.15 0.10 C Q 0 CCl~oQQ5 O\I I I I I I I I 0 I il I I I I I I I I~~~I I I I I I I 0.00 I I I 0 i 2 0 4 s d I 8 0 10 ll 12 ls la is ie il 18----TRS AP LIMIT DAY Page 19 of 20 Figure 15-Effects of Demineralizer Regenerations on TRS and Absorption Pond Conductivity Over a 28-Hour Period 7000 6000 5000>, 4000 O 3000 O 0 2000 1000 I(I I I I I I I I I I I I I\I\I I I I I I I I 0 4 8 12 16 20 24 28 HOURS AP Figure 16-Decreases in 1993 Chemistry Parameters for Groundwater Well N11 and the TRS Due to RO Unit Installation and Reduced Regenerations 1500 1000 500 1 2 3 4 5 7 10 11 12 MONTH"---"" WELLSO4-------WELLNA---TRSS04-TRSTDS Page 20 of 20

.~SEE INSTRUCTIONS

'w NREVERSE SIDE r"': SECTION I re a rll EPA I.D.NuMSER M I D 0'9 86 4 7 62 1 NUMBER-~M I 0 0 0 5 8 2 7 APPLICATION FOR DIS HARGE ERMIT I ICOIFIQTICN EXI~IICI NEIf IICREASEO USE REISSUAtCE 5 t'0 0 EI'--lTEM A.PARENTCOIPANY~CEPTI'ADER"-

I ND I N M IC HI GAN 0 WE R CO M PA B.DIV./RmU N/A PHYSICAL LOCATION ADDRESS F e SlREEf IAISER oe'G, I STREET NVE COOK LAC C PLANf OR FACILITY n" O'P K'P L A N T'T M,",,E"L'"C T R IC G E'E STAIOARD IIEXISTRIAL CLASSIFICATION (REFER TO TARE I I I)L44911I~ANO INFORMATION

'e CllY NA%RI GMAN Ml Ie ZIP CODE 4 6'e TQIISNIP L K E%RIEN COe H4%CO RISER~Le Nt%OF AUIHXI IZED CONTACT PERSON 0NAL D L BAK ER Ne TIllE ENV AFFAIRS IR 2 1 9 4.2 5~21 1 Oe AIXRESS (IF DIFFEREHf FRII ABOVE)1 10 E WA YNE ST EET Pe CITY NAIEo n F 0 T WAYNE Oe STAlE Re ZIP CXE 4 680 2 Se lYPE OF TREATIEHT FACILITY (REFER TO TABLE II)~1L~1~2~3A~4G Te PRXRAII RNI EFFECTIVE RES IDLNLS IIANG9%&#xc3;f DATE SLDNITTED 0 YES'HS'N.A, DATE IIPLIIEHIED Ue BACK~ICIER SOLRCE z Ve FOUllfION IIN:ICEHT PREVEHTION PLAN 11/18/92 DATE SIEHITTED 906 Xe lYPE CF DISCHARGE~~Q Ye RI VIXI NAVE A CERTIFIED OPERATCII?

El~Cl 0+D.H.Fete arald e,e,g~atr 9~ro~49 9 2 ITEM 2 A>>tiVE R Bo NA%MEN GE MAILING ADDRESS OF APPLICANT Ce STREET AB&#xc3;E%CR POST OFFICE BOX 1 1 0 E W Do CllY NVE F ORT W YNE S REET Ee STATE~IN Fe ZIP aXE 4 6802 REOUIRIO SIGNATISIE I~the ooollcsnt,<<ertltv under Densltv ot Isv thst I hove oersonsl ly exercised ond soo tsnl lier vlth the Intorsestlon subeoltted In this ooDIIcstlon ond~I I ottsctveeents ond tn4t, bssed on ov Inoulry ot those Indlvlduols lerooedlotely resoonslble for obtslnln9 the Intoetootlon, I believe th4t the Inter etio Is true, occur4te 4nd cc slots.I e overs th4t there sre 5lonlflcsnt oenoltl~5 ror subnlttln9 tolse Infection, Includln9 the DO$5lbl I lty ot fine snd Ieaorlsoevoent, SIGNATURE OF APPLICANT ch~.R.C.Men e~/<9(9'4>>.,President SIGNATURE OF LOCAL GOVERNIIIITAL REPRESENTATIVE (SEE NOTE ON REVERSE SIDE)TITL 15

(~"'.v>>~\>a 2'm~'I>j, INSTRUCI'IONS FOR CCMPLETING SECTION I l II i'r'(>(r"I"~'Th<5 farm requlreS Infcrmat(cn abOut the faClllty addreSS>,di5Charge IOCat(On, Plant COntrOIS, tyPe Of dl5PO5al faCIIltY and name.'"" address, and signature of the applicant"'and

k Enter Env(rorvrrental Protection Agency.l Oc Number-')f available.

"'-,"-*''"-"ENTER THE PERMIT N<MBER IN, THE BOX AT" THE TOP OF THIS FORM.THE PERMIT IAIMBER CAN BE FOUNO ON THE FRONT PAGE, OF YOUR EXPIRING',<<c, pERMIT., lf this is,a nev or not previously permitted facility, then leave blank and a number will be asslqned.,>y Z C>, r In the box"Application For Olscharga Permit Isy check one of the five categories (modification, existing unperm(tted>

ne<<>Increased use, or relssuance)

<<hich your permit application falls Into (see page l4 for definitions).

rr ITEM I PHYSICAL LOCATION AOORESS ANO IUFORMATION r'A.-C.Enter the naming Information In accordance with the following:

Z e w-For Industrial facilities, provide The parent ocmpany name (A.), the division new (8.), and the plant name (c.).r r-For federal and state facilities p'rovlde the department.

new (A.), the division,or.,the bureau.name (8.).and the facility new (C.).il-For corrrwrclal facilities provide the owner'5 name, doing-business as<d.b.a.)(A.)and the facility new<C~)~f!""'O.Enter type of facility.Exeaoles'of this arec foundry;high school;autarratlc car wash;dry cleaners;self-serve laundromat.

~~.>E.Refer to Table III (page 5)for the list of Standard Industrial Classification Code<SIC).Enter the code number that best describes the major product or service produced.F.-l.Ehter the PhySICal IOCatlan Of the faCI llty.OO NOT uae POSt Off(Ca bOX nrmrber..e't,Z)t J.-K.Lo-Ro U.Vo Enter the township and county In which this feel llty Is located.The county code number can be tound In Table I (page>5)~Enter the new, title, address and telephone nrmrber of the facility's authorized contact person.This Derson should be thoroughly ferrl liar vith the facts reported on these forms In the.event that contact regarding the permit appl Ication must be made.Refer to Table II (page 5)for the list of Treatment Facility Types, enter up to five methods used by the facility to treat the wastewater.

F 4'>Mr''Indicate whether this facility has a"Residuals Management Plan".It so, enter'date plan wa5 submitted and the date tile Plan was or Is to be lmplewnted.

Such a plan may be needed as deemed appropriate by.the proper Olvlslon 5taff Indicate vhether the waste treatment facilities have a back-up source of paver or whether emergency procedures have been developed In case of a power outage to the waste treatment facility.If the waste treatment feel llty Is not dependent on a source of pover, check the"NA" box.UJ Indicate whether this foci lity has submitted a pollution Incident prevention plan as required under the Michigan water Resources Corrmlsslon Part 5 Rules for the"Spl I lage of Ol I and Polluting Materials".

J'f facility has sanitary vastevater (voter used for dawstlc purposes;~,g.~toilets,, slnk5~shover5).enter the nurrrber of people using this facility.X.Check the type of discharge(s) fran this facility.Indicate whether your waste treatment or control facilities are under the supervision of a certified operator.If yes>please provide the Oerson'S new, SOClal security nrmrber, and certificate number plus the ccneany'S feel llty nrmrber.ITEM 2 MAILING AOORESS FOR ALL CORRESPONOENCE A.provide the new of the aDDIIcant.

For tha purposes of th)5 apol (cation the applicant Is defined as the Derson signing below In accordance with the directions provided on page ld.Correspondence regarding this application and future permit matters vl I I be sent to the applicant.

B.provide the new of the facility, company.or organization which the applicant In"A." above uses for receipt of mall c.~, provide the applicant's address to be used for future correspondence.

SIGNATURE OF LOCAL GOVERQCENTAL REPRESENTATIVE NOTE: If sanitary savage Is to be discharged from housing developments, apartment bul ldlngs, shopping centers.or other corrrwrclal developments, Into 5 systerr other than an approved municipal sanitary vesta collection system, this application 5hall be co-signed by an authorized municipal official or township officer.It Is the rule of the Carmlssicn that applications Involving the dl5po5al of sevaoe of human origin from any entity other than local government should Include the local government as a co-5lgner of the statement, and that el I proceedlng5 and hearings against said entity<<III Include the local unit of government a5 a party by appropriate notice, and all permits 155ued as 5 re5ult of 5uch hear lngs and proceedings vll I be tIled jointly against the said unit and entity<water Resources ccnmlsslon part 5 Rules R 525.IO)8<5) and the Michigan Water Resources Ccnmlsslon Act 245 P.A.of l929 as amended Section 6<b)).This co-signature requlr<<rent Is only aDDllcable to sanitary sewage discharges and Is not for any nonsanltary waste streams from this facility.

SEE INSTRUCTIONS ON REVERSE SIDE A.IXXIICIPAL 3 Be QRFACE MATER INTAKE SECTION I PERMIT~MI ppp5827 NUMBER LAKE TOWNSH~I P LAEMI C IGA te e SOURCE OF WATER SUPPLY Ce PRIYAlE NEIL De OlMER OUANnTY (we.)auveITY (NAx.)N A 2 6 5161 60 0 0~N A ITEM FACILITY WATER USAGE oIjwrm (we.)A>>PROCESS MATER INCLIDI%CONTACT aXX.Im MATER)ouANTITY (Be H3NCONTACT COOLI%MATER OOANTITY (we.)C e SANITARY MATER aewr TY.)De OTIER 6 3 4 40 0 0~DAY 6 4 2 1 1 2 0 0 0 SAIIDNs/DAY 6 0 00 0~DAY F IR E P RO TEC TI ON WTE R 3 6 00 00 0~DAY ITEM 5 aewrm HYDRAZINE 0 0 3020 12 6 5 0 0~TAEAR CRITICAL MATERIALS&PRIORITY POLLUTANTS USED STORED PRODUCED CLWTITY t4VK OF SIBSTANCE PARA%TER IAPSER ONNTITY CHLORINE SODIUM C 0 7 7 82 50 5 357500 KYLENE 0 1 3 3 02~07 2 50 0 REFER TO TABLES IV&V TOLUENE 0 01088 3 1 POUNDS 2 GALLONS 3 CUBIC YARDS 4 TONS CL'l IA I OOANTITY LITHIUM (Lithium H droxide form)CLASS02 HYDROQUINONE L>>It>>PARAIETER IAPSER asorllY MERCURY 0 0 12 3 319 CLASS 02 1 u/YeR OIMIfllY*L~J/YeR x Total quantity unknown, contained in thermometers, barometers and mercoid switches located throughout the plant.

INSTRUCTIONS FOR COMPLETING SECTION I ITEMS 3, 4, AND 5 This form requires Information about the water supply to the feel llty, the feel lltyrs water usage, and crltlcal materials and prlorlty pollutants used, stored, or produced at this feel llty.ENTER THE PERMIT ICMBER IN THE BOX AT THE TOP OF THIS FORM.THE PERMIT NUMBER CAN BE FOUND ON THE FRONT PAGE OF YOUR EXPIRING PERMIT.If this Is a new or not previously permitted feel llty, then leave blank and a number'ill be assigned.ITEM 3 SCURCE OF MATER SUPPLY List all water supplies used.The volrmre may be estimated froyr water supply meter readings or from bl lllng statements from a~ster supply utl llty.If water Is not metered, estimate trcm prmrp capacity.Mhere a name Is required, enter name of water supply;e.g., Mud l.ake, Huron River, or the City of Millpond.ITEM 4 FACILITY MATER USAGE List amounts of water to be used for various purpo5e5 asr Process Mater-see Glossary tor deflnltlon lpage 48).Noncontact Cooling Mater-see Glossary for detlnltlon (page 48).Sanitary Mater-Mater used for dcmestlc purposes;e.g..toilets, sinks, showers.If water Is first used for'na purpose and the srme~ster Is subsequently u5ed for one or Inore other purposes~Indicate the volrmwr per day ot the Inst designated use betore treatment and/or discharge.

For example, If water Is Inltlally used a5 noncontact cooling water end then as process water, the quantity ot~ster given should be Indicated as process~ster.The total of Item 4 should equal the total of Item 3.Any difference In these totals should be explained In an attached sheet of this appllcatlon.

ITEM 5 CRITICAL MATERIALS ANO PRIORITY POLLUTANTS USED, STORED PRCOUCED List all chemical substances which are In Mlchlgan's Crltlcal Materials Register Table IV lpage 6)and/or U.S.EPA's Prlorlty yet lW t Litt teble y (bee yt tb t e e e tly M.t~.rKd d by tbl~teblllty.

SEE INSTRUCTIONS ON REVERSE SIDE SECTION I PERMIT~MI 0005827 NUMBER ITEM 3 Ae Nltl CIPAL SOURCE OF WATER SUPPLY PRIVAlE MElL ouAttflTY (we.)ouANTITY (we.)aulnNs/DAv auUINs/DAv tTEM 4 FACILITY WATER USAGE As oautfITY (we.)PROCESS HATER INCLLD It6 CONfACT CCOLIm HATER)OOANTITY (r MINCONTACT CXILI t6 HATER txtANTITY (we.)SANITARY HATER OTIER (we.)aulnNsJ DAY~DAV GAllnNS/DAY aulnNs/DAv ITFM 5 I OOOITITY MERCURIC NITRATE C L S+W/YEAR CRITICAL MATERIALS PRIORITY POLLUTANTS USED STORED PRODUCED K QJN I x NA%OF SISSTANCE PARA%TER tltSER OOANfllv NttK OF QSSTANCE MERCURIC SULFATE CL SSQ 21 CHROMIC ACID C LASS 01 5 L~J/YEAR REFER TO TABLES IVaV NAIE OF QBSTANCE PARAtETER MJSER Oautf ITY CHLOROFORM 6 3 XJ/YEAR 1 POUNDS 2 GALLONS 3 CUBIC YARDS 4 TONS CL Ql IA I X NAIE OF QEISTAM:E PARAtETER MPEIER oSutf llY C LASS01 7 WITS LXI/YEAR PARA%TER MJSER oUutfllY NAtK OF QSSTAtCE PARAIETER MHKR ouANTITY S OS 0 13 32 214 T/m L~J/YEAR" Contained in insulation.throughout plant;believed not to be present in the discharge.

17 INSTRUCTIONS FOR COMPLETING SECTION I ITEMS 3, 4, AND 5 This form requires Information about the~ater supply to the feel llty, the feel Ilty's water usage, and crit teat materials and prlorlty pollutants used, stored, or produced at thIs faclllty.I ENTER THE PERMIT ISMBER IN THE BOX AT THE TOP OF THIS FORM.THE PERMIT NIPRIER CAN BE FCVNO ON THE FRONT PAGE OF YOUR EXPIRING pERHIT.If this Is a new or not previously pen((ltted feel llty, then leave blank and a number will be assigned.ITEM 3 SOURCE OF WATER SUPPLY l.lst all water supplies used.The volu((e may be estimated frcm water supply meter readings or frcm bllllng statements from a water supply utlllty.If~afar Is not metered, estimate from pm((p capacity.where a naee Is required, enter name of~ater supply;e.g., Mud Lake, Huron River, or the City of Millpond.ITEM 4 FACI LITY WATER USAGE List amounts of water to be used for various purposes as: Process Water-see Glossary for deflnltlon lpage 48).Noncontact Cooling'Water-see Glossary for deflnltlon Ipage 48).Sanitary Water-Water used for domestic purposes;e.g., toilets, sinks.showers.If~ater Is first used for one purpose and the sane water Is subsequently*

used for one or more other purposes, Indicate the vol(m>>per day of the last designated use before treatment and/or discharge, For example, If water Is Inltlally used as noncontact cooling water and then as" process water, the qua'ntlty of water given should be Indicated as process water.The total of Item 4 Should equal the total of Item 3.Any difference In these totals should be explained In an attached sheet of this appllcatlon.

ITEM 5 CRITICAL MATERIALS AND PRIORITY POLLUTANTS USED STORED PRCDUCED List all chemical substances which are ln Mlchlgan's Crltlcal Materials Register Table Iy (page 6)and/or U.S.EpA's Prlorlty Po((ut t (((t T ((V ((((((7)((t (nt(y~.(~.(~d ((y (((~((('((((y.

SEE INSTRUCTIONS ON REVERSE SIDE SECTION I PERMIT~Mj pp p5827 NUMBER~EM 3 SOURCE OF WATER SUPPLY A e e'VI I C I PAI.Be SLRFACE'iJATER IteTAXE C~PRIVATE WELL D.OTnER ee IXI>>eIT TY u V l~%OF'ee'TER'eIAV

~MITITY"'AX,)".JAIITI Tv e uM.)P>>FV I I i I I I GALLOte DAY'eALLCe DAY cAt'te'oAv ITEiVI"UAIITITY uAX.)A~PROCESS WATER (IIJCLtXIIIJS COIITACT COOL!tlS WATER)>>LeAeIT I Ve B.IIOIICNITACT CCCL I M WATER QUAeYT I TY (FAX.)~I I I I I i te'DAv EA'";JS/DAY CALLNIS/OAT FAG IL IT Y WATER USAGE C, SAIII TARY WATER O.OTHER".UAIITI TY I FAX.)SP<4 I>>eIT I TY'uAX.)BALI>>>>JS/DAY)TEM 5 CRITICAL MATERIALS&P RID R IT Y LLUTANTS'JSED STORED I RODUCED REFER TO TABLES IV&V I POUNDS 2 GALLONS 3 CUBIC YARDS 4 TONS IeI i I Iel Cet I lIAeZ OF SUBST>>IJCE QUAtlTI TY HAtlE OF SUBSTAIJCE PARAMETER tll'BER OUAIIT I TY tA%OF SUBSTANCE PARAIETER tILI SER OUAI'll I TY tIAuE OF SLSSTAIJCE eeETER tllSER CU"IT I TY t~OF SL9STA'XE PARAuiPTER te?TSER t&#xc3;%OF SUBSTAXCE NICKEL NITRATE C L IA S.S 0 2 2 ANTIMONY POTASS UM C LASSO 1 0 I I I I~~/YEAR IAI ITS~/vEAR uttl TS~!YEAR WITS LJ/vEAR LII IO IiI Ie PARAt E TER tlltSER OUUIT I TY:~uE OF SLSST&#xc3;ICE PARAMETER Ill~I I I WITS~/YEAR WITS LJ/VEAR 17 I'ISTRUCTIONS FCR CCI~ZLET I NG SECTICII I ITEMS 3, 4,<<ND 5 ,his!cr.requires infomarlon about!ne water suoplv to the facility, the facility's water<<sage, and critical n'aterlals and prlcrltv pollutants used, stored>cr produced at th,is foci I ltv.El)TER ME ogc>>IT'dJ'cB Q I)I TFE BOX AT TFE CP OF HIS FCFM.'PERMIT HU'VER CAN BE FOU)d)C".wE cFONT c"'&#x17d;OF YOUR EXPIQING'IS IS 0 ew Cr not Prevlc'sly per<<I ec~pl li v en leave o ianx an 1urper<<'I oe assi ITEM 3""U-rc-NA Q SU""Iv:s!all.<<ater supplies used.The voluee b'av be esrlnared fron water supoly tater reaclncs c"'rcn bill(rg s-are,enrs

'.rc~a ware!s piv~I I lry.>5 water Is ror re!epee~es!I are'n purp capacity.<<here a na e is recui 0c, enter na e o.water supplv: e~~i"ud Lake, riuron River, or the City of Ml llpcnd.I TE>>"ACILITv.CATER'JSAGE:.ourts of<<arer rc oe used for various purposes as: Process eater-see Glossary for ceflnltlon (page<<8).'icnccntac!

Cooling)rater-see Glossary'cr deflnltlcn (page c8).Sanirarv Rater-'Aater used for dcresrlc ourooses: e.c., rollers.sinks.snowers.<<arer is f irsr used fcr one ourpose anc the sme<<arer ls suosequenrly usec'cr cne or"cre other purposes, lrclca!e he vclure cer cav C.-he last cesicnarec use before treatrenr and/or cischarce.

ccr Rxancie..'atet

~s ln(tlal lv used as rcncontact tpci'"c*s!er snc"sn ss prccess'<<a<<er,;he quanri 7 of.<<a!er"ivan s<<pule be inclcatec as:recess<<ater.'e-tai cf lre<<:-'hould ecual the tora)cf Itw 3.Anv c(fference in these!ctals should=.exolainec Ir an attached sheet of r<<ls cool ication.ITc~a 5 Pl ICAL>>ATERIALS ANO PRIORITY POLLUTANTS USED.S CRED.PPCOLCED List all chenical substances

'<<nlch are in Michigan's Critical>>aterlals Register Table IV (page 5)and/or"..EPA's Priority Fol I>>tant List Table V (page 7)that are currenrlv used, stored, or produced by this foci II tv.

SEE INSTRUCTIONS ON REVERSE SIDE SECTION I BER~~MI 0005827 rEM 6 As PROVIDE A BRIEF DESCRIPTION AND LINE DIAGRAH SHXIIID THE HATER FUXI THROXIH YQB FACILITY FR%INTAKE TO DISCHARGEs SHGH ALL OPERATIONS CONTRIBUTING MASTEMATERs INCLUDING PROCESS AtQ PRODUCTION AREAS>SANITARY FLOMSs COOL!%MATERI AND STtA%QTER RIPOFFs YOU HAY GIKXX SIHIIAR OPERATIONS INID A SIIKsLE INITs llew MATER BAlANCE SHXXJj SHXI AVERAGE FLOHS~QKH AU.SIGNIFICANT USES CF MATER TO PROOUCTSs ATQSPHREs AND DISCHARGEs YOU SHXLD USE ACTUAL HEASLR9%NTS HIeIEVER AVAIIABLFJ OTKRHISE USE YOLB BEST ESTIIQTEs DESCRIPTION (See attached Descriptions)

DIAG RANI 19 INSTRUCTIONS FOR COMPLETING SECTION I ITEM 6)This form requires Infomation about the~ater flow through your facility from Intake to discharge.

ENTER THE PERMIT NUMBER IN THE BOX AT THE TOP OF THIS FORM.THE PERMIT NWBER CAN BE FOUNO ON THE FRONT PAGE OF YOUR EXISTING PERMIT.If this Is a new or not previously permitted facility, then leave blank and a number will be assigned.ITEM 6 DESCRIPTION ANO LINE DIAGRAM OF FACILITY'5 PROCESSES ANO TREATMENT SCHEME A.Briefly describe the route taken by~ater In your facility from the Intake to the discharge and also provide a line drawing.Example Description and Oia ram Narrative:

The rinse water frcm the various plating operations Is collected ln one of the two 35,000 gallon tanks.calcium chloride and alen are added to assist'n fluoride removal and aid In coagulation.

The water Is adJusted to a pH of about 5.5 using dilute sulfuric acid.The pH Is then raised to a pH of about IO.3<<lth lime to precipitate the metals as hydroxide.

Polymer Is added to f locculate the metal hydroxides.

The waste stream flows through a clarifier, the metal hydroxide settles to the bottcm as"sludge".The treated water flows frcm the clarifier to a manhole~here It ccnmlngles with contact cooling~ater fran the strip line.This ccnmlngled

~ater Is discharged to the Buck River.The sludge frcm the clarifier goes to a vacuole filter where It Is dewatered.

The sludge Is later taken to a landfill.Calcium Chloride Alum Sul furic Acid Lime Polymer Plating Wastewater 70.000 Gallon Tank Acidification Neutral izatio Flocculat1on Batch Bumps Dump Tank Sludge Thickener Clarifier Hon-contact Cooling Hater Calcium Chloride Alma Sul furic Acid Lime Landfill VacuNa Filter Gondola Sludge Iiater Hanhol e Buck R1ve John Ooe, Inc., Oeertown, manufactures sleeve bearings for autoeotive and truck engines.Production Is divided Into 3 phases.Metal powder ls produced In the first phase.This is acconpanied by melting copper>tin and lead Into Ingots in an electric furnace and applying a Jet of water to quench end solidify the melting metal Into powder form.The second phase consists of adhering the fine metal powder to a coll of steel by passing the tio slowly through furnaces, Water used to cool the strip constitutes the contact cooling water.Bearings are then formed and machined from the coated steel.In the third phase, most bearings receive a nickel strike and lead, tin copper electroplate.

The remaining bearings are aluminum or babbitt and receive a tin or lead plate.Rinse water before and after the various plating operations constitutes the process water.Huni ci pal Mater Supp'ly Sanitary Facility 30,000 gpd Huni ci pa 1 Treatment Std fsafa ter Str1pe Line 295.000 gpd Powder Hfg.4 000 gpd Cooling Hater 250,000 gpd Plating Process 40,000 gpd Maste Treatment Plant 45,000 gpd uck R1ve 20 Additional Information Section I Item 6, Subpart A Cook Nuclear Plant Groundwater Permit Application Outfall OOD-Descri tion of Utili Waste Waters Utility waste water from within the plant is discharged into an on-site absorption pond.The ultimate disposition of these waste waters is to the ground which vents to Lake Michigan.The waste waters include: WASTEWATER FLOW DIAGRAM 41 Wastes from the makeup water treatment system.The main contributors to the waste stream are: the makeup plant demineralizer regeneration wastes (avg.40,000 gallons per regeneration), degasifier pump seal water (108,000 gpd), carbon filter backwash water (avg.45,000 gpd)and pre-filter backwash water (avg.72,000 gpd).The retention tank periodically discharges a very small volume of solid material removed by settling.Alum (aluminum sulfate)is added to the pre-filter influent as a flocculent.

These pre-filters are backwashed to the TRS to remove the suspended matter captured on the filter media.The Alum contained in the backwash is discharged to the TRS in the form of insoluble aluminum hydroxide.

Carbon filters are also periodically backwashed to the TRS.These filters primarily remove organics, chlorine and small amounts of iron.Sulfuric acid and sodium hydroxide used by the makeup demineralizers to regenerate the resin are rinsed to the TRS and generally neutralize each other in the sump, forming sodium sulfate prior to discharge.

Non-essential service water is used to supply vacuum degasifier pumps which utilize approximately 75 gpm total via two pumps to remove dissolved gases (primarily carbon dioxide and oxygen)from the vacuum degasifier and exhaust them to the atmosphere.

A new component of the makeup plant, a reverse osmosis (RO)system, has been installed to remove the bulk of the dissolved solids from the lake water prior to demineralization.

Normal reject water flow is to Lake Michigan.The RO system must maintain very clean membranes to assure efficient operation and purity of water.Several methods are used to maintain this level of cleanliness from scale and biofouling.

Using hydrochloric acid or sulfuric acid, the feed water pH is lowered to reduce the scaling tendencies of the water.Approximately once per month a flush is performed using approximately 0.5%hydrochloric acid and caustic to dissolve any scale that deposits on the membranes (avg.5000 gallons per month).A chemical cleaning is performed when the periodic acid washes no longer are effective.

19a Additional Information Section I Item 6, Subpart A Cook Nuclear Plant Groundwater Permit Application WASTEWATER FLOW DIAGRAM 41 (cont.)The chemical cleaning involves several steps and may contain citric acid, hydrochloric acid, phosphoric acid, sodium hydroxide and a neutral pH detergent (avg.10,000 gallons per event).Also, to remove dead biological matter from the membranes, a soak using sodium bisulfite may be performed as necessary, approximately once per year (avg.5000 gallons per event).WASTEWATER FLOW DIAGRAM 42 During periods when not in operation, the heating boiler is stored full of treated boiler water containing at most 400 ppm hydrazine (for oxygen scavenging) and 50 ppm ammonia or 50 ppm ethanolamine (ETA)(for corrosion protection).

Prior to use, this"wet lay-up" water is drained to the TRS for discharge into the Absorption Pond.The volume drained is approximately 1600 gallons and may occur 30 times per year.During a unit outage, the condensers are checked for leaks by filling the steam'ide with condensate containing approximately, 1000 grams of fluorescein disodium salt or Rhodamine B.These dyes are fluorescent under black light which aids in the detection of joint and tube leaks during visual inspection.

The volume of water drained from the condensers ranges from 160,000 up to 1,000,000 gallons and may occur one time per year.In addition, the cooling water side of the condensers are drained to the TRS for general maintenance periodically (8 condenser halves per unit, approximately 25,000 gallons of lake water per half).The component cooling water system (CCW)is periodically drained to allow for equipment inspection, maintenance or repair.This system uses demineralized water from the makeup plant as its source of makeup water along with a maximum of 1200 ppm nitrite (from Calgon LCS 60)and 100 ppm glutaraldehyde as treatment chemicals.

The infrequent drainings may occur and release approximately 60,000 gallons of treated water to the TRS per year.The diesel generator cooling jacket water system(DJW) also employs the same chemical control for corrosion as in the component cooling water system with a maximum of 2000 ppm nitrites from Calgon LCS 60.19b  

Additional Information Section I Item 6, Subpart A Cook Nuclear Plant Groundwater Permit Application WASTEWATER FLOW DlAGRAM g2 (cont.)This system is drained to'the floor drains to the TRS when maintenance is performed on the jacket water system.The system volume is approximately 1000 gallons.Any minor system leaks would also be directed to the floor drain during normal operations.

The essential service water systems (ESW)and non-essential service water systems (NESW)are also periodically drained to allow for equipment inspection, maintenance, or repair.These drains may discharge approximately 72,000 gallons of Lake Michigan water used for non-contact cooling into the TRS.This water is either chlorinated intermittently at a residual concentration of 0.2 mg/1 TRC or continuously at 0.036 ppm total residual chlorine.During some special treatment periods, this water may contain zebra mussel ,biocides, used as a molluscicide for zebra mussel control.Periodically, components of the ESW or NESW systems may be chemically cleaned to remove iron deposits using vendor supplied cleaning solution such as EDTA (ethylenediaminetetraacetic acid)or ascorbic acid, acetic acid and ammonia.These wastes could either be drained to the TRS or Lake Michigan.The steam generators (S/G)are drained for inspection and maintenance during scheduled unit outages (approximately every 18 months)and during an event where steam generator failure is detected that requires a unit shutdown.The steam generators.utilize 150 ppb hydrazine, 20 ppm ammonia, and 2.5 ppm ETA to control the water and steam chemistry to be non-aggressive to cycle components.

Unit 1 steam generator also utilizes 10 ppm boron to control corrosion.

A steam generator volume released during the draining is approximately 32,000 gallons each.During wet lay-up the S/Gs are stored full of water with up to 400 ppm of hydrazine and 50 ppm ammonia or ETA are added for corrosion control.This water is normally drained to surface water via NPDES outfalls OOA or OOB, but may be drained to the TRS in some instances.

The miscellaneous drain tanks can be aligned to discharge to the TRS.As much as 350,000 gallons per day may be directed to the TRS to control the"chemistry limitations on the secondary water systems.Water chemistry is primarily the same as steam generators.

Around the plant miscellaneous sumps collect approximately 45,000 gpd of water from various equipment drains, leaks, pump seals, steam jet air ejector drains, etc.19c  

~9 Additional Information Section I Item 6, Subpart A Cook Nuclear Plant Groundwater Permit Application WASTEWATER FLOW DIAGRAM 42 (cont.)The frequency of discharge and types of chemicals used in this equipment have been described elsewhere in this description.

Miscellaneous floor drains are located throughout the plant to provide a safe working environment by routing spilled or leaked water to the TRS.The major chemical influx into these drains are from the detergents and waxes used to maintain the floors.Also routed to the TRS through the floor drains are the chemical feed tank drains, fire protection water, drinking water, cooling water, and drains from bioboxes used to monitor the zebra mussel control measures and other chemical control monitors.The chemical feed tanks which may be drained contain hydrazine, ammonia, boron, ETA, sodium hypochlorite.

The bioboxes will discharge chlorine and, during zebra mussel treatments, zebra mussel biocides.Non-radiological chemical lab sink and floor drains are routed to the TRS for disposal.The drains carry water and the wastes generated while performing analyses and preparing laboratory standards including those on the attached list.Also discharged will be glassware and normal laboratory cleaning wastes.The average volume directed to the TRS is estimated to be 500-1000 gpd.Secondary (steam generator or condensate) sample water from continuous analyzers are routed to drains which discharge to the TRS.The analyzers are on the cycles which may contain as much as 10 ppm boron, 150 ppb hydrazine, 20 ppm ammonia, and 2.5 ppm ethanolamine.

The analyzers measure corrosion transport at a average flow of 8500 gallons per day.Miscellaneous sealing and cooling water supplies cooling and sealing water to the TRS pumps, condensate booster pumps, circulating water pumps, vacuum priming pumps, drain seal reservoir tanks and drain sample coolers.The average flow per day is approximately 150,000 gallons.Non-essential service water supplies approximately 53,000 gpd of non-contact cooling water to various sample coolers throughout the plant's turbine building including the Conductivity Room and the Steam Jet Air Ejector sample points.Chemical spills that enter the TRS may be neutralized within the sump to prevent a discharge to the environment.

The potential for spills to the TRS exists for the following chemicals with the proposed neutralizers listed: 19d  

Additional Information Section I Item 6, Subpart A Cook Nuclear Plant Groundwater Permit Application WASTEWATER FLOW DIAGRAM g2 (cont.)Chemical Sulfuric acid Sodium hydroxide Sodium hypochlorite Hydrazine Neutralizer Sodium hydroxide Sulfuric acid Sodium thiosulfate NESW (lake water), Hydrogen peroxide Outfall OOE-Sanitar Waste Dischar es WASTEWATER FLOW DIAGRAM 43 Sanitary wastes are presently segregated and routed to two extended aeration package treatment plants.The existing equipment is designed to treat 50,000 GPD and the effluent from the sewage treatment plants discharge into one of the two seepage lagoons.The lagoons discharge into the groundwater with the ultimate disposition being Lake Michigan.The sludge removed from the sedimentation tank basins is taken to a local POTW for disposal or dewatered and stored as low level radioactive waste, as appropriate.

Plant sanitary waste consists of shower and restroom facilities, janitor washbasins located throughout the plant non-radiological property.Kitchen wastes are generated from the plant cafeteria, the Energy Information Center and Training buildings.

The chemistry training laboratory discharges to the sewage treatment plants via a limestone bed neutralization tank.The chemistry lab is used to train technicians on analyses performed in the plant.The discharge from the lab carries water and wastes generated while performing analyses and preparing laboratory standards including those on the attached list.A small photo lab in the training building uses (on a emergency basis)small quantities of hydroquinone to develop black and white pictures for plant use.The training building HVAC system also drains to the limestone bed.A radiography lab in the plant also discharges small quantities of processing chemicals for non-destructive testing in the plant.None of the products in the radiography lab contain critical materials or priority pollutants.

All portable toilet wastes on the plant site are collected and discharged to the package plants.A biodegradable deodorant is used in the portable toilets.Sludge effluent waste may also be recycled through the plants to decrease the amount of sludge for processing when possible.19e  

Additional Information Section I Item 6, Subpart A Cook Nuclear Plant Groundwater Permit Application WASTEWATER FLOW DIAGRAM 43 (cont.)Miscellaneous rinsing of waste receptacles and possible miscellaneous cleaning operations waste utilizing various detergents may be rinsed to the sewage treatment plants.Miscellanous Outfall WASTEWATER FLOW DIAGRAM 44 The main plant transformers on each unit are located within concrete berms.The berms are for spill containment should a catastrophic failure of a transformer occur.To protect against operational and safety concerns which stem from ponded water, these areas gravity drain to oil/water separators specific for each unit.Each separator is a below ground concrete basin designed to retain oil and release water to a series of drywells.Also discharging into the separators are the emergency diesel generator pit sumps.These sumps collect limited water and fuel oil (less than 500 gallons per year)from the emergency diesel generator room.Periodically, the oil/water separators are pumped clean to remove the accumulated oil for proper off-site disposal.The Security Diesel Generator Day tank has an overflow line that connects to the Unit One transformer deck catchbasin.

Discharge to the catchbasin would only occur if the day tank were overfilled.

Procedures and level indicators are used to prevent overfilling.

CHEMICAL LAB ANALYSIS Additional Information Section I Item 6, Subpart A Cook Nuclear Plant Groundwater Permit Application PLANT CHEMISTRY LAB (to Outfall OOD)Chloride Fluoride Hardness Hydrazine Silica Oil 6 Grease pH Free Mineral Acidity Total Phosphorus Chemical Oxygen Demand Sulfate Nitrites Total Residual Chlorine ASTM D-512-81 (1986)ASTM D-1179-80 (1986)Standard Methods 413 B (1985)ASTM D-1126-80 EPA-600-4-79-020 Method 130.2 (1979)ASTM D-1385 (1983)ASTM D Power Water Analysis Manual CH-41 EPA-600-4-79-020 Method 413.1 (1979)ASTM D-1293-84 Standard Methods 423 (1985)ASTM D-1067-82 Method B EPA-600-4-79-020 Method 365.3 (1979)EPA-600-4-79-020 Method 410.2 (1979)ASTM D-516-82 Method A (1985)EPA-600-4-79-020 Method 375.3 (1979)Standard Methods 426 A (1980)Determination of Corrosion Inhibition by Calgon Corporation ASTM D-1253 (1986)Standard Methods (1980)TRAINING BUILDING LAB'to Outfall OOE)Boron Chloride Fluoride Haxdness Hydrazine Silica Oil&Grease pH Total Phosphorus Atomic Absorption Metals Ion Chromatography Westinghouse Chemical Analysis Procedure for PWR WCAD 7333 Rev.1 (1973)ASTM D-512-81 (1986)ASTM D-1179-80 (1986)Standard Methods 413 B (1985)~ASTM D-1126-80 EPA-600-4-79-020 Method 130.2 (1979)ASTM D-1385 (1983)ASTM Power Water Analysis Manual CH-41 EPA-600-4-79-020 Method 413.1 (1979)ASTM D-1293-84 Standard Methods 423 (1985)EPA-600-4-79-020 Method 365.3 (1979)Standard Methods 302B, 303A (1985)EPA-600-4-79-020 Method 215.1, 220.1, 242.1, 249.1, 273.1 (1979)Dionex System Operators Manual WASTEWATER FLOW DIAGRAM Pl MAKEUP PLANT'dditional Information Section I Item 6.Subpart A Cook Nuclear Plant Groundwater Permit Application Lake Township (Potable Water)Non-essential Service Water (NESW)Alum Addition Pre-filter Backwash 2x Day Aug.ee e Sodium Hypochlorite (IfNeeded)

Retention Tank Blow Down I x Day Or As Needed Reject Water to Lake Michigan 001-002 Sulfuric Acid or llydrochloric Acid Addition Reverse Osmosis Carbon Filter Backwash 2 x Day Avg Or As Needed Acid/Caustic Rinse Chem Cleaning Biofouling Cleaning NESW water for seals Cation Resin Beds Regeneration Waste Degasifier NESW ca ater Neutralization Tat)k (Installed by 1-95)Mixed Beds Anion Resin Beds Caustic egene ration tvaste cid/Caustic Regeneration Waste Makeup Plant Water to Plant Services Turbine Room Sump Flow to OOD

'E OUTFALL'ooi OUTFALL~002 WASTEWATER FLOW DIAGRAM P2 OUTFALL 003 Additional Information Section I Item 6, Subpart A Cook nuclear Plant Groundwater Permit Application Unit 2 Misc.Cooling Unit 2 Discharge Intake Forebay Unit 1 Discharge Unit 1 Misc.Cooling Dye Checks Heat Exchangers Sample Coolers Units IP.2 SJAEs Drains Cleaning Waste Bioboxes Unit-2 Condenser Unit-2 ESW Unit-2 Steam Generator I I NESW i Makeup Plant Flow Diagram tt l Unit-1 Condenser Unit-1 Steam Generator Unit-1 ESW Dye Checks Drains Cleaning Wastes Bioboxes In-linc Monitors Misc.Drains Layup Drains U-2 CCW DJW Makeup Plant Regeneration Wastes (An.i)Plant Heating Boiler U-1 CCW DJW In-line Monitors Misc.Drains Layup Drains Chem Feed Tank Drains Barrel Rinse Neutralization Tank Installed By 1-95 Misc.Plant Sumps Non-rad Lab Drains Misc.Floor Drains Turbine Room Sump pH Meter Sodium Hydroxide Sulfuric Acid Misc.Processed Waste e.g.Glycol Auto Compositor How Meter Absorption Pond GROUNDWATER e

WASTE WATER FLOW DIAGRAM 83 SEWAGE TREATMENT PLANT Additional Information Section I Item 6, Subpart A Cook Nuclear Plant Groundwater Permit Application Fire Protection (Frusbing and sassing wares is dirccscd so ssorsnwascr and/or groundwarcr).

Lake Township Potable Water Supply Plant Site Sanitary Waste&Kitchen Waste Radiograph Processing Laboratory Waste Photo Lab Training Building Chemistry Lab Waste Training Building HVAC System Wastes Portable Toilet Wastes East Extended Aeration Plant Limestone Bed Neutralization Tank EIIlucnt North Outfall OOE SeepageTank South Outfall OOE SeepageTank Miscellaneous Rinsing Operations l I South Extended Aeration Plant Sludge Effluent gf Procegged)

WASTE WATER FLOW DIAGRAM-4 DRY WELLS Additional Information Section I Item 6, Subpart A Cook Nuclear Plant Groundwater Permit Application Security Diesel Generator Day Tank Overfiow Unit 1 Main Transformer Deck Drains (Stormwater)

Unit 1 Emergency Generator Pit Sump Unit 2 Main Transformer Deck Drains (Stormwater)

Unit 2 Emergency Generator Pit Sump Unit 1 Catchbasin Oil/Water Separator Unit 2 Catchbasin Oil/Water Separator Unit 1 Dwells Unit 2 Dwells GROUNDWATER SEE INSTRUCTIONS QN REVERSE SIDE SECT1ON I NUMBER-~MI 00058 27EM 7 Ao PROVIDE A ttAP OF THE TREATMENT FACILITY UXATIOtb SCNlt6 Tl%LOCATION OF~DISCNARSE POINT(S)AIO OTIER INRR%TICN RGXKSTED ON REVERSE SIDE OF PAGEa LOCATION AIAP (See Attached Map)21 INSTRUCTIONS FOR COMPLETlt4 SECTION I ITEM 7 This form requires a location map of the treatment facility showing discharge point(s).ENTER THE PER4HT NUMBER IN THE BOX AT THE TOP OF THIS FOIa(.THE PERMIT Ias(BER CAN BE FOUNO ON THE FRONT PAGE OF YOUR EXPIRING PERMIT.If thlS IS a new Or nOt PreVIOualy Permitted faCIIlty, then leaVe blank and a number<<III be aSSlgned.ITEM 7 LOCATION MAP A.Provide a detailed location man of the treatment facility, showing the location of the discharge point(s)for all surface water and groundwater discharges, and all known supply and drinking water wells of adjacent properties to the facility.For both surface and groundwater discharge applicants, Indicate the location and Identlf Icatlon number of any groundwater monitoring wells relative to the facility which are currently being used by the applicant to monitor the groundwater.

Also>Include the receiving stream, lake, or storm sewer and the streets and roads In the area.22 SEE INSTRUCTIONS ON REVERSE SIDE SECTION I NUMBER W MZ 0005827.EM 8 CONCEN TRATED ANIMAL FEEDING OPERATION Ae IQ VCU TE A COtCEIIIRATEO ANI FEEDIMI FJCILI (IF tO CONTItAK TO IIIII Q)Se MJSBI OF ACRES USED FOI COtFI%I%HT FEKDIMI?Ce IF 11%RE IS OPEN COIFI%1%NTe HAS A RtMFF DIVERSION AtO CONIROL SYSIEN MEN CONSTR'?(IF Mls CONTI'O ITEN 9)Ds WAT IS TI%IESIGN BASIS KR TIE CWiRK SYSTIH?C%CK NK OF 1%RUJRIMI AtO EHIER MJSER OF II&KB OF RAIN?lD me, 2II MXR SIOFII Q 25 YEA+2II MXR SIORII P OT%R (SPECIFY)~e~IICI%S IMIES~s~INC%S Ee WAT IS TIE MJ%ER OF AQKS OF CONmISUTIMI ERAIQGE?F>WAT IS TIE DESIGN SAFEIY FACBXI IOR THIS CONIROL SYSTEI(?~~~esses LJ~LJ Ae LIST lYPE OF ANINLs N/A~LJ L JITEIVI 9 TYPE NUMBER OF ANIMALS IN OPEN AND HOUSED.INE MENT Ill 4 I III 4Iel I 4IO I Bs GIVE'D%MJSBI OF 1HIS lYPE OF ANINIL IN OPEN COKIMJ%NTe Ce GIVE ll%MJSER OF THIS lYPE OF ANIIVIL IH MXISED IXtlFI%%NTe As LIST lYPE OF AHINALe Bs GIVE TI%MISER OF THIS lYPE OF ANItsAL IK OPEN%IF ll&%HT e Cs GIVE TIE MJSER OF THIS lYPE OF ANINL IH MXNED Ae LIST TYPE OF ANINLe Be GIVE TI%MJSER OF THIS TYPE OF ANINAL IN OPEN COIF IMJ%HTe Cs GIVE TI%MJSBI OF lHIS lYPE OF AHULL IN MNSED CCtF II8%HTe As LIST lYPE OF AHIHALs Be GIVE 11%MJSER OF THIS TYI%OF ANIHAL IN OPEN COtF1%%HTe Ce GIVE TIE MJSER OF'THIS lYPE OF ANIMAL IN MXSED Ae LIST lYPE OF ANINALe Bs GIVE 1HE MJ%%R OF lHIS lYPE OF ANINAL IN IXsEH CO%1%I%HTs Ce GIVE 11%MJmBI CF THIS lYPE OF ANINL IN INUSED COtF As LIST TYPE OF ANINLe Be GIVE 1%MJ%ER OF 1HIS TYPE OF ANINAL IH OPEN COIF I MJ%NTe Ce GIVE 11%MJSER OF'THIS 1YPE OF ANINAL IH MNSED CCH'Il&%NTs Ae LIST lYPE OF ANINALe Be GIVE TIE MJSBI OF THIS TYPE OF ANINAL IH QKH Ce GIVE THE MJSER OF THIS 1YPE OF ANINAL IN INUSED CCIF I%t%NT e Ae LIST lYPE OF ANINLs Bs GIVE TI%MJSER OF THIS lYPE OF ANIISL IN 0%N GXFIIBJ%HTe Ce GIVE 11%MJSKR OF THIS lYPE OF AHINAL IN MXISED COM-1%%HI'e 23 INSTRUCTIONS FOR COMPLETING SECTION I ITEMS 8 ANO'P.This form requires information about the design, size, and type and numbers of animals In a concentrated animal feedlot.ENTER THE PERMIT NHBER IN THE BOX AT THE TOP OF THIS FORM.THE PERMIT NI&#xc3;BER CAN BE FO(P4)ON THE FRONT PAGE OF YOUR EXPIRING PERMIT.If this Is s new or not previously permitted feel llty, then leave blank and n number vll I be assigned.I GENERAL INFORMATION Not all animal feeding operations are required to obtain NpoEs permits.Exclusions are based on sIte and occurrence of discharge.

In particular, for animal feeding operations, the size cutoffs depend on whether or not pollutants sra discharged through n manmade device or by direct contact<<Ith the facility or animals.A facility for laying hens or brollers Is not required to have a permit unless It hns n liquid manure handling system or continuous overflow watering.Also, facilities which discharge only In the case of n 25 year, 24 hour storm event are not required to have a permit.ITEM 9-8 Give only the ares used for the animal confinement or feeding facility.Oo not Include.sny area used for growing or operating feed.~0 I ITEM 9-C V E Check"Yas" lf sny system for collection of runoff hss been constructed.

Supply the Information under 0, E, and F to the best of your knowledge.

ITEM IO-B ANO C'i to, g I'!Give the maximum nunber of each type of animal In open confinement or housed uri'er roof (either partially or total ly)which are held nt your facility for s total of 45 days or more In any l2 month period.I Use the following categories for type of animals: Slaughter Cattle-Feeder Cattle-Mature Dairy Cattle (milked or dry)-Swine (each weighing over 55 pounds)-Horses-Sheep-Lambs-Turkeys-Laying Hens I-Broi lars(Ducks I A permit ls not required unless the facility has s I lquld manure handling system or continuous overflow watering.ANIMAL FEEDING OPERATION means a lot or facility (other than an aquatic animal production facility)where tha following conditions are met: (A)Animals (other thnn aquatic animals)have been, are, or will be stabled or confined nnd fed or maintained for a total of 45 days or more In any I2 month period)and (8)Crops, vegetation, forage growth, or post-harvest residues ara not sustained in the normal growing season over anY portion of the lot or facility.Two or more animal feeding opertlons under cameo ownership nre n single animal feedIng operation lf they adjoin each other or If they use a ccnmon area or system for the disposal of wastes.ANIMAL UNIT means a unit of measurement for any animal feeding operation calculated by adding the following nunbersf The number of slaughter and feeder cattle multiplied by 1.0;plus the number of mature dairy cattle multiplied by 1.4;plus the number of swine veighlng over 25 kllogrnms (approximately 55 pounds)multiplied by 0.4;plus the number of sheep multiplied by O.l;plus the number of horses multiplied by 2.0.CONCENTRATED ANIMAL FEEDING OPERATION means an animal feeding operation which meets the criteria set forth In either (A)or (8)below or<<hlch the Director designates as such on s case-by-case basis.A.More than the nunbers of animals specified In sny of the following categories sre confined (REGARDLESS OF WHETHER A SURFACE WATER DISCHARGE EXISTS): t.I.I,OOO slaughter or feeder cattle.2.700 mature dairy cattle (whether ml lked or dry cows).3.2,500 swine each weighing over 25 kllogrnms (approximately 55 pounds).4.500 horses.5.I0,000 Sheep Or lambe.6~55,000 turkeys.7.I00,000 laying hens or boilers (lf the facility has s continuous overflow watering).

B.30,000 laying hans or brollers (If the facility has s liquid manure handling system).9.5,000 ducks.10.I,000 animal units.B.More than the following nunbers and types of animals are confined (WITH SURFACE WATER DISCHARGE AS DESCRIBED BELOw': I.300 slaughter or feeder cattle.24 2~200 mature dairy cattle (whether milked or dry cows).3.750 swine each weighing over 25 kllcgroas (approximately 55 pounds).4.I50 horses.5.3,000 Sheep Or lambS.6.I6,500 turkeys.30,000 laying hens or brollers (if the facility has continuous overflow watering).

8.9,000 laying hens or brollers (lf the facility has a I)quid manure handling system)~9.I,500 ducks.IO.300 animal units."Either one of the following conditions are'mat: pollutants are discharged Into waters of the United States throuch a mamsade ditch, flushing systea or other similar mannada device (wmaenade" means constructed by man and used for the purpose of transporting wastes);or pollutants are discharged directly into waters of the United States<<hlch originate outside of and pass over, across, or through the facility or otherwise ccme Into direct contact<<Ith the animals confined In the operation.

provided, however, that no animal feeding operation Is a concentrated animal feeding operation as defined above lf such animal feeding operatlcn discharges only In the event of a 25 year, 24 hour storm event.N0TE: The permittee shall continue<<Ith Section,ll and address Items I, 2, 4, and 5 on pages 3).33, and 35.

SEE INSTRUCTIONS ON REVERSE SIDE SECTION I PERMIT~gg p p p 5827 EM 10 AO VATIC ANIMAL PRODUTION FACILITY tTEM't1 SPECIES OF AQUATIC ANIMALS PRODUCED AT THIS FACILITY As DO YOU OPERATE AN AXIATIC ANIHAL PRODUCTION FACILITY?(IF tfts CCNfltAE TO ITBI 12)Bs INDICATE TIE TOTAL tAtSER OF PON5s RACKHAYS AMI SINILAR STR&#xc3;llRES AT YOlR FACILITYs Cs IN)ICATK IN ltIICH CALENDAR tONIH tVtXItttI FEED1%OCQRIs D.MKR Tta TOTAL IANBER OF PlXtKIS OF POCO FKD IXRIm THIS As IS THIS SPECIE A HARN CR tXXD HATER SPECIE?g/p Bs GIVE THE t4VE OF THIS SPECIEs Cs MER TIE TOTAL HARVESTABLE HEIQIT OF THIS SPECIE PRODUCED BY THIS FACILITY PER YEAR IN RXMSs Ds MER TIE HAXItttI HEIGHT PRESENT FOR THIS SPECIE ttIICH HEXAD REPRESENT YMI 8&#xc3;NL OPERATIONs As IS THIS SPECK A 1ARH OR COLD I%TER SPECIE B>>GIVE TIE WE OF THIS SPECIEs Cs EN1KR TIE TOTAL H4RVESTABLE HEIGHT OF THIS SPECIE PRmXD BY THIS FACILITY PER YEAR IN RXtOS>>De MKR TIE HAXItltI ttEIQIT PRESE%RR THIS SPECIE ttIICH HXAD REPRESENT YOUI tOAHAL OPERATIONs A, 15 THIS SPECIE A HARII CR GXD HATER SPECIE?g B~GIVE TIE NA%OF THIS SPECIEs Vn Cs MKR THE TOTAL NRVESTABLE NEIQIT OF THIS SPECIE F Ds ENIER THE tVUUtttt HEIGHT PRESENT FOR THIS SPECIE ISICH ICXU)REPRESENT VOIR NXHAL CPERATI ONs As IS THIS SPECIE A HARII OR CXD HATKR SPECIE?Bs GIVE TIE NttE OF THIS SPECIEs Cs ENIKR TIE TOTAL HARVESTABIE HEIGNf OF THIS SPECIE PtmXH)BY THIS FACILITY PER YEIR IN POQOSe Ds ENIKR TIE HAXI tM HEIGHT PRKSBIf FCR THIS SPECIE ttIICH lORD RERIESENT YON tCNNL OPERAT ION s As IS THIS SPKIE A HARtl CR COLD HATER SPECIE?Bs GIVE TIE N4%OF'THIS SPECIEs Ce MKR THE TOTAL NRVESTABLE HEIGHT OF THIS SPECIE PRQOUCED BY THIS FACILITY PER YEAR IN Pres Ds EHIKR TIE HAXIt%M IEIGHT PRESENT FCR THIS SPECIE tSIOI lORD REPRESENT YQR tC&#xc3;NAL OPERATIQls Ae IS THIS SPECIE A HAttI OR OXD HATER SPECIE?Bs GIVE TIE HttK OF THIS SPECIEs Cs ENfKR T%TOTAL tVUIVESTABLE HEIGHT OF THIS SPECIE PRCQXED BY TH S FAC TY Y N Ds ENTER TIE HLYItttt NEIGHf PRESENf FCR THIS SPECIE tttICH MXAD REPRESENT YNR tCRPAL OPKRATIONe INSTRUCTIONS FOR CCMPLETING SECTION I ITEMS 10 ANO I I This form requires infq{mation about the design, size, and type and numbers of animals In an aquatic an&#x17d;al production feel ll y.ENTER THE PERMIT NIA{BER IN THE BQX AT THE TOP OF THIS FORM THE PERMIT NIPBER CAN BE FOUND ON THE FRONT PAGE OF YOUR EXoIRING PFRMIT.If thlS IS a new Or nOt preVIOuSly pe{mitted faClllty, then leaVe blank and a nunber Will be aSSigned.GENERAL INFORMATION Not ail fish farmsare required to obtain NPOES permits.Exclusions are based on size and occurrence of discharge.

For aquatic animal production facilities, the size cutoff5 are based on whether the species are wa{m~ater or cold water, on the production weight per year In harVeStabie POundS, and On the Zmqunt Of feeding In paundS Of fOOd IfOr COld~ater 5Pecie5).AISO~faCI litleS which discharge less than 30 days per year, or only durlno periods of excess runoff I for warm~ater fish)are not required to have a permit.coNcENTRATEQ AQUATlc ANIMAL pRQQUOTIQN FAQII,ITY means a hatcnery, tish fern, or other facility which contains, grows or holds aquatic animals In either Of the following cateaorles, or which the Director desianates as such on a ca5e-by-case ba515~A.Cold water fish species or other cold~ater aquatic animals Including, but not limited to, the Salmonidae family ot fish Ie.g..trout and salmon)In ponds, raceways or other similar structures

~bleb discharge at least 30 days per Year but doe5 not Include: I..Facilities which produce less than 9,090 harvest~eight kllograms Iapproxlmateiy 20,000 pounds)ot aquatic animals per year.2., Facilities which feed less than 2,272 kllograms (approximately 5,0QQ pounds)ot food during the calendar month ot maximum feeding.B.Harm~ater fish species or other warm water aquatic animals Including, but not limited to, the Amelurldae, Cet{achldae, and Cyprlnldae families ot fish (e.g., respectlveiy, catfish, sunfish, and minnows)In ponds, raceways, or other similar StruCtureS whlCh diSCharge at leaat 30 daya per year, but dOeS nat InClude: I.Closed ponds which discharge only during periods ot excess runoff.2.Facilities which produce less than 45,454 harvest weight kllog{ams{approximately 100,000 pounds)of aquatic animals per yea{', ITEN 10 B Give the total nunber of discrete ponds or raceways In your facility..

Under"other" give a descriptive name of any structure which 15 not a pond or a raceway but which results In discharge to waters of the United States.ITEN 10-D The value gIven for maximum monthly pounds of food should be representative of your normal operation.

ITEN 11 8 The name of fish species should be proper, c{mtnon, or scientific names.ITEN Il C AND D The values given tor total~eight produced by your facility per year and the maximum~eight present at any one time should be representative of your normal operation.

NOTE: The permittee shall continue with Section II and address Items I, 2, 4, and 5 on pages 31, 33, and 35.28 SECTION t MI 0005827 i TEM 12 LIST NAHE AND HAILING ADDRESS OF ALL PROPERTY$4ERS ALIACENT TO TIE TREATMENT FACII.ITY AND OR DISC%ROE/DISPOSAL AREAs See attached list.MAILING LIST OF ADJACENT PROPERTY OWNERS 29 SO MI0005827 Section I, Item 12 ADJACENT PROPERTY OWNERS EAST Interstate I-94 (Michigan Dept.of State Highways)SOUTH Lake Township c/o Gerald Wasko Township Supervisor 1410 Shawnee Road Bridgman, MI 49106 WEST Lake Michigan (State of Michigan and United States of America)NORTH Rosemary Beach 11-11-6800 0038-00-5 Tengerstrom, Eric H.;3415 S.59th;Cicero, IL 60650 0037-02-5 Tengerstrom, Eric H.;3415 Cicero, IL 60650 S.59th;0037-01-7 Merkel's Floor Covering, Inc.;8314 Scottdale Rd.;Berrien Springs, MI 49103 0037-00-9 Kraiss, Wilbur&Marilou;5004 S.Long Ave.;Chicago, IL 60638 I 0036-00-2 Temmel, Edward P.&Kathleen;9617 E.Shore Dr.;Oak Lawn, IL 60453 0033-00-3 Gilpin, Clark&Nancy;1005 E.60th St.;Chicago, IL 60637 0032-01-'5 Wittebort, Robert J., Jr.&Nancy H.;3180 N.Lakeshore Dr.;Chicago, IL 60657 0030-02-1 Meier, Paul&Louise G.;1357 Madison Park;Chicago, IL 60615 0028-01-8 Balka, Ronald A.&Janet M.;3334 Louise Dr.;Lansing, IL 60438 Section I, Item 12 ADJACENT PROPERTY OWNERS Page 2 11-110006 0002-03 0004-00 0004-04 0004-01 0004-02 11-11-0007 0013-00 0013-01 Michigan Dept.of Natural Resources; P.O.Box 30028;Lansing, MI 48909 Franklin Real Estate Co.;P.O.Box 2000;St.Joseph, MI 49085 Temmel, Edward P.;9617 E.Shore Dr.;Oak Lawn, IL 60453 Caparo, William E.6 Oyler, Kathryn E.;122 S.Ellsworth Pl.;South Bend, IN 46635 Rosemary Beach Corp.;c/o Secretary; 3415 S.59th St.;Cicero, IL 60650 Lake Charter Twp.;Shawnee Rd.;Bridgman, MI 49106 Lake Charter Twp.;Shawnee Rd.;Bridgman, MI 49106 0006-01 Indiana Michigan Power Company 0001-01 0004-01 11-11-0005 0029 0036-01 0027-00 0036-00 0036-02 11-11-0005-0002 01-6 11-11-0008 0041-00 0009-00 Lake Charter Twp.;Shawnee Rd.;Bridgman, MI 49106 Lake Charter Twp.;Shawnee Rd.;Bridgman, MI 49106 Technisand, Inc.;11833 Ravenna Rd.;Chardon, OH 44024 Ruff, Timothy W.;P.O.Box 504 Bridgman, MI 49106 Technisand, Inc.;11833 Ravenna Rd.;Chardon, OH 44024 Emery, Martin;Hopkins, Elwood J.&Mable N.;7499 Thornton Dr.;Stevensville, MI 49127 Indiana Michigan Power Company Bank of America Texas P.O.Box 650380 Dallas, TX 75265 Michigan Dept.of Transportation; Lansing, MI 48900 Franklin Real Estate Co.;P.O.Box 2000;St.Joseph, MI 49085

 

NARSULEX,'xQ (~iQ Ii MATERlAL SAFETY DATA SHEET Sulfuric Acid 1.PRODUCT AND COMPANY IDENTIFICATION

.Product Name: Sulfuric Acid Formui: H,SO, Molec War Weight: 98.08 Chemical Name: Sulfuric Acid ghemlcai Family: Inorganic Acid~Su 7664-93-9~Synonyms:

Sulphuric Acid, Oil of Vitriol, Battery Acid product Use: Used tn manufacture of fertilizers, explosives, other acids, metal pickling and petroleum processing.

MARSULEX inc.111 Gordon Baker Road Suite 300 orth York, ONT M2H 3R1 (416)496-9655 MARSULEX Inc.40 Richards Avenue P.O.Box 5453 Nofwalk, CT 06856-5453 (203)8544300 EMERGENCY TELEPHONE NUMBER (800)263-9502 Prepared by MARSULEX Technical Section (416)496-4164.2.COMPOSITION/INFORMATION ON INGREDIENTS

-Sulfuric Acid N n-Water I nt%by Wt.70-100%OM%CAS Number 7664-93-9 7732-186 3.HA2'ARD INFORMATION EMERGENCY OVERVIEW:/Oangerl Extremely corrosive.

Causes severe burns.Reacts violently with water.Highly reactive and capable of igniting combustible materials on contact.Not flammable, but reacts with most metals to form explosive hydrogen gas./Sulfuric Ackl h a colorless to amber, dear to slightly cloudy, oily liquid.National Rre Protection Assochtlon (NFPA)Rating Hazardous Materials Identification System (HMIS)Rating RRE f 0 4 Extreme/Severe

'3 High/Serous

~2 Moderate 1=Slight 0=Minimum W Water Reactive ectNe Date: Februay, 1993.Supefaedea:

Februasy, 1990 MARSULEX MSOS 4010E Page 1 of 9 MATERIAL SAFETY DATA'SHEET, Sulfuric Acid 3.HAZARD INFORMATtON (continued)

POTENTIAL HEALTH EFFECTS: Exposure Llmlts: Sulfuric Acid ACGIH (TLV)1 mg/m'TWA)3 mg/m'STEL)

OSHA (PEL)1 mg/8 (TWA)In contact with the skin: Concentrated solution may cause pain and severe burns to the skin and brownish or yellow stains.Prolonged and repeated exposure to dilute solutions may cause irritation, redness, paIn and drying and cracking of the skin.ln contact with the eyes: Immediate paIn, severe burns and corneal damage which may result in blindness.

C Inhaled: Mists and vapors may cause Irritation of the eyes, nose and respiratory tract.May cause Increased'ulmonary resistance, transient cough and bronchoconstrlctlon.

Severe overexposure may result In lung collapse and pulmonary edema which can be fatal.Ingested: Severe burning and pain In the mouth, throat and abdomen.Vomiting, diarrhea and perforation of the esophagus and stomach lining may occur.Long Term Exposure: , Repeated exposure may produce erosion and discoloration of teeth.~l'lthough no direct link has been established between exposure to sulfuric acid, Itself, and cancer In man, the World Health Organization (WHO)International Agency for Research on Cancer (IARC)have concluded that occupational exposure to strong Inorganic acid mists containing sulfuric acid is carcinogenic to man, causing cancer of the larynx (the voice box)and, to a lesser extent, the lung.Exposure to any mist or aerosol during the use of this product should be avokied and, in any case, keep exposures below the occupational exposure limit for sulfuric acid.1 Corrosive effects on the skin and eyes may be delayed, and damage may occur without the sensation or onset of pain.Repeated overexposure may lead to contact dermatitis, may cause bronchitis with cough, phlegm, shortness of breath and emphysema, can cause chronic runny nose, tearing of the eyes, nosebleeds and stomach upsets.Strict adherence to first aid measures following any exposure Is essential.

Existing Medical Conditions Possibly Aggravated By Exposure: Skin Irritation may be aggravated in Individuals with existing skin lesions.Breathing of vapors or sprays.(mists)may aggravate acute or chronic asthma and chronic pulmonary disease such as emphysema and bronchitis.

Carcinogenicity Data: Although there are reports linking exposure to sulfuric acid to cancer, this product Is not classified by NTP (National Toxicology Program), not regulated as carcinogenic by OSHA (Occupational Safety and Health Administration), and has not been evaluated by IARC (International Agency for Research on Cancer)or ACGIH (American Conference of Governmental Industrial Hyglenlsts).(See also, Long Term Exposure).

Effective Date: February, 1993 Supersedes:

February, 1990 MARSULEX MSDS k010E Page 2of 9 NATU LEX, MATERIAL SAFETY DATA SHEET Sulfuric Acid 4.FlRST AID MEASURES Prompt removal of this material from contact with the body is of utmost importance.

&TART FIRST AID AT ONCE.Precaution:

Persons attending the victim should avoid direct contact with heavily contaminated clothing and vomitus.Wear impervious gloves while decontaminating skin and hair.In contact with the skin: Flush skin with running water for a minimum of 20 minutes.Start flushing while removing g contaminated clothing.If irritation persists, repeat flushing.Obtain medical attention IMMEDIATELY.

Do not transport victim unless the recommended flushing period is completed or flushing can be continued during , transport.

a, While the patient Is being transported to a medical facility, apply compresses of Iced water.If medical treatment must be delayed, Immerse the affected area in iced water.If immersion is not practical, compresses of Iced water can be applied.Avoid freezing tissues.Discard heavily contaminated clothing and shoes ln a manner which limits further exposure.Otherwise, wash clothing separately before reuse.ln contact with the eyes: Immediately flush eyes with running water for a minimum of 20 minutes.Hold eyelids open during flushing.If Irritation persists, repeat flushing.Obtain medical attention IMMEDIATELY.

Do not transport~~victim until the recommended flushing period Is completed unless flushing can be continued during transport.

Inhaled: Move victim to fresh air.Give artmclal respiration ONLY If breathIng has stopped.Give Cardiopulmonary flesuscltatlon (CPR)If there ls no breathing AND no pulse.Obtain rnedlcal attention IMMEDIATELY.

Ingested: If victim ls alert and not convulsing, rinse mouth and give N to 1 glass of water to dilute materhl.If spontaneous vomiting occurs, have victim lean forward with head down to avoid breathing ln of vomitus, rinse f mouth and administer more water.IMMEDIATELY contact local poison control center.Vomiting may need to be Induced but should be directed by a physician or a poison control center.IMMEDIATELY transport victim to an emergency facility.Note to Physician:

All treatments should be based on observed signs and symptoms of distress in the patient.Medical conditions that may be aggravated by exposure indude asthma, bronchitis, emphysema and other lung diseases and chronic nose, sinus or throat conditions.

Severity of the bum is generally determined by the concentration of the solution and the duration of exposure.In the event of skin or eye contact, lmmedhte and thorough flushing is essential.

Continued washing of the effected area with cold or iced water will be helpful in removing the last traces of sulfuric acid.Cream or ointments should not be applied before or during the washing phase of the treatment.

5.FIRE FtGHTING MEASURES F sh Point (method): Not applicable, product Is non-flammable utolgnltlon Temperature:

Not combustible Rammabllity Limits In air(%): UEL Not applicable LEL Not applicable Effective Date: February, 1993 Superaed ea: February, 1990 MARSULEX MSDS fffetOE Page 3 of 9 MATERIAL SAFEIY DATA SHEET Sulfuric Acid 5.FIRE FIGHTING MEASURES (continued)

Fire Extinguishing Media: For small fires use dry chemical or carbon dioxide.For large Ares, flood fire area with water from a distance.Expect violent reaction with water.Do not get solid stream of water on spilled material.Special Fire Fighting Procedures:

Wear a NIOSH/MSHA approved selfwontalned breathing apparatus If vapors or mists are present and full protective clothing.For fighting fires In close proximity to spill or vapors, use acid-resistant personal protective equipment.

Evacuate residents who are downwind of Are.Prevent unauthorized entry to Are area, Dike area to contain runoff and prevent contamination of water sources.Neutralize runoff with lime, soda ash or other suitable neutralizing agents (see Deactivating Chemicals, Section 6).Cool containers that are exposed to flame with streams of water until fire is out.Other Fire or Explosion Hazards: Not flammable but highly reactive.Capable of igniting finely divkled combustible materhls on contact.Reacts violently with water and organic materials with evolution of heat.Extremely hazardous.~in contact with many materials, particularly carbides, chlorates, fulmlnates, nltrates and picrates.Sulfuric acid reacts with most metals, especially when dilute to give flammable, potentially explosive hydrogen gas.Hydrogen gas can accumulate to explosive concentrations inside confined spaces.Follow approprhte NFPA codes.6.ACCIDENTAL RELEASE MEASURES Steps to be taken In the event of a spill or leak: Remove all ignition sources.Ventilate area.Use appropriate Personal Protection Equipment.

Prevent liquid from entering sewers or watetways.

Dike with inert material (sand, earth, etc.).Stop or reduce leak if safe to do so.Collect Into containers for reclamation or disposal only if container~r (s suitable to withstand the material.Conskler lnsitu neutralization and disposal.Ensure adequate decontamination of tools and equipment following dean up.Comply with Federal, Provincial/State and local regulations on reporting releases.=: " Deactivating Chemicals:

Ume, limestone, sodium carbonate (soda ash), sodium bicarbonate, dilute sodium'hydroxide, dilute aqua ammonia.Waste Disposal Methods: Dispose of waste material at an approved waste treatment/disposal facility, In accordance with applicable regulations.

Do not dispose of waste with normal garbage or to sewer systems.Note-Clean-up material may be a RCRA Hazardous Waste on disposal..-'Spills are subject to CERCLA reporting requirements:

RQ=1000 lbs.7.HANDLING AND STORAGE Precautions:

Wear appropriate Personal Protection Equipment.

Do not breath sprays or mists.Do not Ingest.Do not get In eyes, on skin or on clothing.Keep ignition sources away from sulfuric acid storage, handling and transportation equipment.

Handling Procedures and Equipment:

Carbon steel or stainless steel materials are suitable for use for acid concentrations equal to or greater than 93%.However, the effect of lower concentrations on the materhls of construction can be very complex.Contact product supplier for specific recommendatlons when handling sulfuric acid at strengths less than 77%.Effective Oate: February, 1993 Supersedes:

February, 1990 MARSULEX MSDS 4010E Page 4 of 9 NAILciULKK...

MATERIAL SAFETY DATA SHEET Sulfuric Acid 7.HANDLING AND STORAGE (continued)

Storage Temperature:

Store above freezing point (Section 9).Elevated temperatures will Increase the corrosion/rate of most metals.Storage Requirements:

Store packaged acid in a dry, well, ventilated location away from combustibles, oxkllzers, bases, or metallic powders.Storage tanks should be protected from water ingress, be well ventilated, and'aintained structurally in a safe and reliable condition.

Other Precautions:

Sulfuric acid will attack some forms of plastics and coatings.Always add acid to water-not g water to acid.If kept In upper floors of building, floors should be ackl proof with drains to a recovery tank.8.EXPOSURE CONTROLS/PERSONAL PROTECTION

-'Recommendatlons listed in this section Indicate the type of equipment which will provkle protection against over exposure to this product Conditions of use, adequacy of engineering or other control measures, and actual exposures will dictate the need for specific protective devices at your workplace.

~<Engineering Controls: Local exhaust ventilation required.spiratory Protection:

A NIOSH/MSHA approved air-purifying respirator equipped with acid gas/fume, dust, mist cartridges for concentrations up to 10 mg/nf'.An air-supplied respirator if concentrations are higher or unknown.S)tin Protection:

impervious (l.e., neoprene, PVC)gloves, coveralls, boots and/or other acid resistant protective

Eye Protection:

Tight-fitting chemical goggles and face shield./Other Personal Protective Equipment:

Where there is a danger of spilling or splashing, acid resistant aprons or suits should be worn.Trouser legs should be worn outside (not tucked in)rubber boots.Safety showers and~eyewash fountains should be Installed in storage and handling areas.9.PHYSICAL AND CHEMICAL PROPERTIES h Physical State: Llqukf Appearance and Odor.Sulfuric acid Is a clear to amber, heavy, oily liquid which may have a sharp penetrating odor..Odor Threshold:

No data Boiling Point: 77.67%:193'C(380'F);

93.19%: 276'C (529'F);98%: 330'C (626'F)Melting/Freezing Point: 77.67%:-11.2'C (+11.6'F);

93.19%:-29.5'C (-21.1'F);

98%:-1.1'C (30'F)Vapor Pressure at 40'C (102'F): 77.67%: 1.2 mmHg;93.19%: 0.0016 mmHg;98%:.0.002 mmHg Specific Gravity at 16'C (60'F): 77.67%: 1.7059;93.19%: 1.8354;98%: 1.8437 Vapor Density: (Air=1): 3.4 sulfuric acid component Bulk Density: Not applicable (see specific gravity)ffecthre Date: February, 1993 Supersede@

February, 1990 MARSULEX MSDS 401 OE Page 5 of 9 MATERIAL SAFETY DATA SHEET Sulfuric Acid 9.PHYSICAL AND CHEMICAL PROPERTIES (continued)

Evaporation Rate: Not applicable

Miscible In all proportions In water.Also soluble in alcohol.pH: 0.3 (1N solution at 25'C/78'F) 10.STABILITY AND REACTIVITY Stability:

.~Under Normal Conditions:

Stable, but reacts violently with water and organic materials with evolution of heat.Under Fire Conditions:

Decomposes to form sulfur oxides(SQ).

Conditions to Avoid: Temperatures which may have a negative effect on the materials of construction used ln equipment.

Materials to Avoid: Contact with organic materials (such as chlorates, carbldes, fulmlnates and plcrates)may cause , fire and expiosions.

Contact with metals may produce flammable hydrogen gas.When diluting, add acid to water.Do NOT add water to the acid.n Hazardous Decomposltlon or Combustion Products: Toxic gases and vapors (e.g.sulfur dioxide, sulfuric acid;vapors/mists and sulfur trloxkfe)may be released when sulfuric acid decomposes.

WIII not occur 11.TOXICOLOGICAL INFORMATION Toxicological Data:.Lox, (oral, rat)2140 mg/kg L+(inhalatlon, rat)=510 mg/nt'or 2 hrs Skin effects (rabbit): Severe irritation Eye effects (rabbit): Severe irritation Carcinogenicity Data: Although there are reports linking exposure to sulfuric acid to cancer, this product Is not.classied by NTP (National Toxicology Program), not regulated as carcinogenic by OSHA (Occupational Safety and Health Administration), and has not been evaluated by IARC (Intematlonal Agency for Research on Cancer)or ACGIH (American Conference of Governmental Industrial Hyglenlsts).

See Section 3.Hazard Information, regarding Potential Health Effects (Long Term Exposure)for further discussion.

Reproductive Effects: No information Is available and no adverse reproductive effects are anticipated.

Mutagenicity Data: No'information is available and no adverse mutagenic effects are anticipated.

, Teratogeniclty Data: No Information is available and no adverse teratogenIc effects are anticipated.

None known/Effective Oats: February, 1993 Supersedes:

February, 1990 MARSULEX MSDS 4010E Page 6 ef 9 NIAII5ULKX,'ATERIAL SAFETY DATA SHEET Sulfuric Acid 12.ECOLOGICAL INFORMATION Ecotoxlc Effects: Harmful to aquatic life ln very low concentrations.

Ijtiay be dangerous if it enters water Intake;Fish toxicity critical concentration 10 mg/L;7.34 mg/L/48 hrs-Lymneae Palustrls-0-100%mortality, 13.DISPOSAL CONSIDERATIONS

~Responsibility for proper waste disposal ls with the owner of the waste.Work with the appropriate regulatory bodies to ensure compliance with regulations.

~Consider the collection of residual sulfuric acid Into containers for reclamation or disposal only if the container Is suitable to withstand the material.~Conskler lnsitu neutralization and disposal.Clean-up materhl may be a RCRA Hazardous Waste on disposal.~Provincial/State or local regulations or restrictions are complex and may differ from Federal regulations.

~The information applies to the material as manufactured; processing, neutralizing, use or contamination may make the Information inappropriate, Inaccurate or Incomplete.

14.TRANSPORT INFORMATION U.S.(Under DOT)//Shipping Name: RQ Sulfuric acid Hazard Chss or Division: 8 Product Identification No.(PIN): UN1830 Packing Group: II Canada (Under TC)Shipping Name: Sulphuric acid Chsslficatlon(s):

Class 8 (9.2)Product Identification No.(PIN): UN1830 Packing Group: II 16.REGULATORY INFORMATION.A.SARA Title III HAZARD CATEGORIES AND LISTS Pr H t rl Acute (Immedhte)

Health: Chronic (Delayed)Health: Rre: Reactivity:

t Sudden Release of Pressure: Yes Yes No Yes No~U Extremely Hazardous Substance (40 CFR 355, SARA Title III Section 302)CERCLA Hazardous Substance (40 CFR 302.4)Toxic Chemical (40 CFR 372.65, SARA Title III Section 313)Yes Yes Yes Effective Date: February, f993 Supersedes:

February, 1990 MARSULEX MSDS 4010E Page 7 of 9 MATERIAL SAFETY DATA"SHEET Sulfuric Acid 15.REGULATORY INFORMATION (continued)

Reportable Quantity (RQ)under U.S.EPA CERCLA: RQ=1000 Ib TSCA Inventory Status: Reported/Included

/'~~aNaoa.Workplace Hazardous Materials Information System (WHMIS)WHMIS Classification(s):

Class E-Corrosive Qass D1A-Very Toxic WHMIS Health Effects Index: Acute Lethality-very toxic-Immedhte Corrosive to animal skin WHMIS ingredient Disclosure List: Confirmed A;Meets crlterh for disclosure at 1%or greater.Reportable Quantity (RQ)under Transport Canada-, TDG: RQ=5 Iltres (or Kg)If It represents a danger to health, life, property or the environment.

16.OTHER INFORMATION Additional Information and References 1.Enviro-TIPS Manual,'Sulphuric Acid and Oleum", Environment Canada, February 1984.2.Weast, R.C.(Ed.),"CRC Handbook of Chemistry and Physics', 60th Edition (1980)3.Sax, N.l.,'Dangerous Properties of Industrial Materials', 7th Edition (1989)I 4.ACGIH, Threshold Umit Values for Chemical Substances and Physical Agents and Biological Exposure Indices, 1991-92 5.Sittig, Marshall,"Handbook of Toxic arid Hazardous Chemicals and Carclnogens", 2nd Edition, 1985 Revision Indicators:

g a ln the left margIn Indicates a revision or addition of Information since the previous Issue.Effectiv Date: February, 1998 supersedes:

February, 1990 MARSULEX MSDS 441 0E Page 8 of 9 NARSULKX, MATERIAL SAFETY DATA SHEET Sulfuric Acid 16.OTHER INFORMATION (continued)

Legend: CAS 8 CERClA CFR DOT EPA MSHA NIOSH PEL pvc RCRA SARA STEL TCTDG TLV TSCA'DNA UEL-Chemical Abstracts Service Registry Number-Comprehensive Environmental Response, Compensation, and Uabillty Act-Code of Federal Regulations

-Department of Transportation

-Environmental Protection Agency-The concentration of material in air expected to kill 50%of a group of test animals-Lethal Dose expected to kill 50%of a group of test animals-Lower Explosive Limit-Mine Safety and Health Administration

-National institute for Occupational Safety and Health-Permissible Exposure Limit-Polyvinyl chloride-Resource Conservation and Recovery Act-Superfund Amendments and Reauthorlzatlon Act of the U.S.EPA-Short Term Exposure Umlt-Transport Canada-Transportation of Dangerous Goods Act/Regulations

-Threshold Limit Value-Toxic Substances Control Act-Time-Weighted Average-Upper Explosive Limit The information contained herein has been prepared by MARSULEX Inc.and is offered only as a guide to the handling of this specific materhl and has been prepared In good faith by technically knowledgeable personnel.

It Is not Intended to be all-Inclusive and the manner and conditions of use and handling may Involve other and additional conslderatlons.

No warranty of any kind!s given or Implied and MARSULEX Inc.will not be liable for any.damages, losses, inJurles or consequential damages which may result from the use or reliance of any Information contained herein.EffecUve Date: February, 1993 Supersedes:

February, 1990 MARSULEX MSDS 4010E Page 9 of 9

INSTRUCTIONS FOR CCMPLETI IIG SECTION I I ITEMS I AND 2 ThiS farm requires information on the facility's discharge additives.

location, discharge schedule, volume f low rate and water treatment FNTER THE PERMIT NUMBER IN THE BOX AT THE TOP OF THIS FORM.THE PERMIT NUMBER CAN BE FOUND ON THE FRONT PAGE OF YOUR EXPIRING pEIa(IT.If this Is a new or not previously permitted facility, then leave blank and a number will be assigned.Enter the outfall number In space provided tor each page of sectIon I I.Far each Individual discharge point o separate set of Section Il forms must be filled out.ITEM I DISCHARGE LOCATION SCHEDULE AND FLOW RATES A.Enter the location of discharge, this should Include quarter-quarter section, quarter section, section, to n, and range.8.List nome of receiving water (If surface voter discharge).

C.Indicate whether foci)Ity discharges on a seasonal basis.D.If yes, list discharge periods.Provide the land application rates used or expected to be used In terms of inches per hour, hours pec day.and Inches p<<w<<".F.Indicate the type of wastewater to be discharged fram this outfall.Refer to the wastewater type code given In the left margin More than one code may be applicable.

G.Provide the average number of hours per day In~hich the facility discharges treated wastewater and the total number of days per year in whiah the d(SCharge OCCurS.H.Provide current (from the last l2 months)or expected flow rates os requested.

Refer to unit code divan In the lett margin far the appropriate flow units.)sly-million gallons per year;MGD-million gallons per day;GPD-gallons pec doy.I.Provide the maximum discharge flow rate which you want to have authorized within the permit.NOTE: For NPOES permits on)Y.the use of such a flow rate will not place on actual limit restriction on the flaw but will be the flaw rote used to develop ettluent limits.Also, when the Monthly Operating Reports are reviewed by Compliance staff It will help thee to determine If any new or Increased uses might have occurred at the facility.J.Provide the design flow tor this specific outtall discharge (e.g.batch treatment system flaw, packaged treatment system flaw.or sane other finite treatment system flaw).ITEM 2 WATER TREATMENT ADO IT IVES A.Indicate~bather discharge Is treated with conditioners, Inhibitors, or mlcrobloclde.

If not, continue to Item 3.B.Give name, function, and chemical composition of additives used.C.Give nome and address of the monutacturer(s) ot the additives used.D.Indicate expected minimis, overage and maxlcmxs discharge concentrations of the additive(s) tor this discharge.

Indicate whether you treat the discharge to remove the additive(s) before discharge of wastewater.

F.Indicate the removal efficiency of each additive from the wastewater ond the discharge frequency of each additive to the surface water or groundwater.

G.hOTE: It Is the responsibility ot the applicant to supply the product Information as requested In this Item 4.Information requested but not supplied may result In the application being returned to the applicant for ccmpletlon.

32 SEE INSTRUCTIONS ON REVERSE SIDE SECTlON II PERMIT~~"Cl 4005827 lTEM OJIFNI.IlfKR As LOCATION OF DISCNRGE~~<s'5E e.$ErKfl I~05, 1M~><<, pA%E L11 5~B.IVY RECEIVING HATER (IE.GROLIEWATER OR IPVE OF SIRFACE BSOPTIONOND DISCHARGE LOCATION Cs DO YW DISCHARGE SEASWILLY.(IF IOs CCNTIIAE TO E)D.IF YESe LIST DISCNRGE PERIODS N/A IOe/DAY Q~QX~IOe/DAY FLOW RATE WASTEWATER Ee (AND APPLICATION RATE N/A INs IR>>~~LJ IRs DAY INs/NKe~~u~~'u KJ Nc(1 CONTACT COOUNG 2 NON CONTI(CT COOLING 3 PROCESS 4 SANITARY 5 STORMWATER Fe lYPE OF HASIEHATER DISCNRGE G s D ISOQRGE SOHlIE (YEARLY AVERAGE)Hs DISCHARGE FLOI RATE All time daily maximum times 365.TOTAL YEARLY DAILY HINIMPI DAILY NXIILPI 4 9 W ITj C0DE 0'2J 2.6~2 L3 L~J u W LJ LJ HG(RS/DAY 1 MGY 2 MGD 3 QPD ITEM Je HAXlKPI DESIGN DISCHARGE FLOI RATEe As DO YW USE HATER TREAllEHT ACOITIVES lO TREAT YOLR DI~(IF Ie.CCNTDAE TO IITH 3)Bs, Nt%FWCTIONe AID OEHICAL COSOSITICN OF TAESE AID IT IVES e DESIGN SULFURIC ACID SODIUM HYDROX 5-2 u~H Neutralization*