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• 6575-PN02 Policy and Procedure Manuel T)eo Aeweson Pe.

SNEC Soil Erosion and Sedimentation Control Plan 0 Apennenmey/ Scope  % & be Omos Epocaw Dee Smaon Nucieer Experimereaf Station Sol Ero@n and Sedimentation Plan for mairamining compliance with State Reguladons 6575 11/08/94 This document is within QA plan scope Yes X No Safety Redews Required Yes X No List of Effective Pages faQt fm Egge Revisign fagg Revision fagg Revisaon 1.0 0 2.0 0 3.0 0 4.0 0 5.0 0 6.0 0 l 7.0 0 8.0 0 9.0 0 10.0 0 11 E21 0 c.

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SNEC Soil Erosion and Sedimentation Control Plan 0 TABLE OF CONTENTS P3gg Secti9n 3.0 1.0

SUMMARY

3.0

2.0 INTRODUCTION

4.0 3.0 SITE LOCATION / DESCRIPTION 5.0 4.0 GEOLOGY 5.0 5.0 SOIL DESCRIPTION 6.0 6.0 RUNOFF 7.0 7.0 CONTROL MEASURES DURING DEMOUTION 8.0 8.0 PERMANENT CONTROL MEASURES 9.0 9.0 MAINTENANCE 10.0 10.0 GLOSSARY 11.0

11.0 REFERENCES

12.0 12.0 EXHIBITS 9

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$ SNEC Soll Erosion and Sedimentation Control Plan 0 t

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SUMMARY

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The Saxton Nuclear Experimental Co@ci uvii Facuky (SNEC) is located 0.75 miles north of the Borough of Saxton in IJberty Township, Bedford County, Penneytvarna The ske is approximately 1.1 acres situated )

within a 150 acre plot owned by the Pennsylvania Electric Company. The ske is nearly level and consists of surface f5 (3 to 6 feet in depth) ranging from well graded saty send and gravel to a well graded mixture of  ;

j ash and cinders. The site tcpogi.py wt allow surface runoff to be directed to the Raystown Branch of the i

Juniata River (c.pproximatsiy 0.1 rniles north of the site). Old fleid and forest vegetation covers the land between the site and the river.

i As a guide for erosion control, SNEC wel maintain the following erkeria:

i e Merumize sou disturbance; t

j 9 Minimize alteration of the natural drainage paths;

! 9 Mirumize time of exposure, 1

i e Cover and grade with permeable material; l 9 Where natural ground cover is removed, the site wSI be planted with vegetation that wiu stabitze the

. soi, permk high inMtration rates and not require excessive maintenance; and l 9 Minirnize impervious cover. This win provide groundwater recharge aruf minimize the volume and

intensky of site runoff f

2.0 INTRODUCTION

2.1 Many of the problems naarv4mied wth storm water drainage arise from unwise land-use. Removing I

, vegetation from slopes, cherGs drainage pettoms, wr.c .;..u..g storm water Sows and creating

! higher peak discharge flows accelerate sou erosion through the action of splash impact on bare soR and the increased velocities d storm water runoff. The increased volume of sol entering drainage channels and conduits reduces the water carrying capacky of the drainage system; decreasing efficiency and promoting flooding. Sol erosion not only wastes a valuable resource but often spots j the landscape. Increased amounts of sediment runoff irto waterways is a rnain contributor towards j water pollution.

2.2 Erosion control should begin before changes in land-use are initiated Before earth-moving l

actMties, the soas, the tepcy.$y, and the proposed change in land-use shodd be studied and a l j plan developed to prevent accelerated sol erosion and sedimentation Appropriate erosion control 4 techniques should be implemented. These may indude the retaining of areas of vegetation, scheduling earth-moving activities in phases, and instkuting temporary and permanent erosion and i sedimentation (,ontrol practices. l 2.3 Pennsylvarua's Clean Streams law (PL 1987, No. 394), prohibits the discharge of pollution to the waters of the Commonwealth whether from industrial or domestic sources (Pa DER 1990). The Pennsylvania Department of Erwironmental Resources (Pa DER), under the Clean Streams Law, requires a soi erosion and sedimentation control plan for every earthmoving activity. Addstionally, a perrrut is required for any earthmovmg activtty 25 acres or more. The fogowing erosion and 3.0 mm

Numbw SAXT0" " NUCBR 8***"""*****" ' ' " 6575-PN.02 Policy and Procedure Manuni nos Ammon No.

SNEC Soil Erosion and Sedimentation Control Plan 0 sedimentation control plan for SNEC is of a genenc nature and is applicable to any earthmoving actMty at SNEC.

2.4 Erosion and sedimentation control meneures using State guideline recommendations wel be integrated with the isndeosping scheme and made permanent by estabhshing vegetatim cover after the earthmoving actMty is complete.

3.0 SME LOCATION / DESCRIPTION 3.1 SNEC is located about 100 miles east of Pittsburgh and 90 miles west of Harrisburg in the Anegheny Mountams,0.75 mies north of the Borough of Saxton in Liberty Township, Bedford County, P=.-Aa.t (GPUS 1963). The site is situated in the valley of the Raystown Branch of the Junista River, along the east bank, as shown in Exhibit 1. It is located in the northwestem comer of the Broad Top QuadrarWe of the U.S. Geological Survey Mep. The river vaney lies between Tussey Mountain to the west and Terrace Mountain to the east. The river meenders along its watercourse with an overad flow direction to the northeast. The relief from the twer to the ridge tops exceeds 500 feet (Ground / Water Technology, Inc.1981).

3.2 SNEC was butt adjacent to an existing coal-fired generating station. The Company property cuiiv.': : -;- i . ^ y 150 acres. The nucieer factity is located within an approximate 1.1 acre plot as shown in the aerial photograph of Exhibit 2.. Steam produced by the nuclear reactor was transferred to a 10-megewett turbine generator located at the Sexton Steam Generating Station At present, the cool-fire plant has been demolished and SNEC has been donctivated The Control Auxliary bu8 ding, a concrete pad previously supporting an 80,000 gebon capacity water tank, a waste storage area, a waste treatment piart and approximately 1,150 square feet of connecting pipe tunnel have been demolished. Only the reactor containment vessel remains (See Exhibit 3).

4.0 GEOLOGY 4.1 SNEC lies in the Appalachian highlands in the Ridge and Valley Province The Ridge and Vaney Province cornpnses altemate emema*=ns of narrow ridges and broad or narrow vaBeys trending generally northeast. This is a region of altemating hard and soft sedimentary rocks that have been severely folded by lateral c0E+. :: ' i into a series of anticlines and sinchnes, The ridge is of Tuscarora quartzite and smed amounts of pleistocene gravel and recent alluvium are found along the river. Most of the area is underlain by Devonian Strata. In the vicinity of the site, these strata slope approximately 50' to the west.1.myers of shale and sandstone have been found at depths greater then 12 feet below the surface (GPUS 1983). A geologic cross section of the region is shown in Exhibit 4. This geologic cross eartian is drawn at a northwest - southeast orientation and indicates that SNEC is constructed on the limb of a me}or sincline that dips generally towards the east (Ground / Water Technology, Inc.1981).

5.0 SOIL DESCRIPTION 5.1 Split-spoon samples collected during a hydrogeological Irwestigation (Ground) Water Technology, Inc 1981) and samples from hand <iug pits indicate that the sufficial soH is comprised of two types of construction backful (1) wed graded reddish saty fine to coarse sand with some fine to medium gravel and (2) a well graded mixture of ash and cinders. Both of those 15 materials were placed during station construction. Laboratory mechanical analyses were performed on both the saty sands and the ash. The depth of the il generally ranges from three to six feet, although the fIl may be deeper at locations where building construction excavation took place.

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SNEC Soil Erosion and Sedimentation Control Plan 0 5.2 Underiying the ful materials is a boulder layer. This layer is generally four to six feet thick and separates the ful motorial from the top of the bedrock. The materini making up the boulder matrix is believed to be silty ciey. The sat and clay were found to be loceitted in the boulder layer and did not appear to be present in the fractured bedrock below that Zone (Ground / Water Technology, Inc.

1981). The actual bedrock underlying SNEC is described as grey to olive brown shales, praywackes and sendstones.

5.3 To obtain a reistive indication of the abtity of the various subourface zones to transport water, fleid permeablity tests were conducted in selected bore holes and laboratory machenical snelyses were performed on construction fel material (Ground / Water Technology. Inc.1981). The red suty sand f5 material was well-graded, containing about 45 percent possing a #200 sieve. The well graded 4 4 nature of the fIl suggests a very low permemb51ty, probably ranging between 10 cm/sec to 10 cm/sec. The ash fut r9etorial, however, is believed to have substartiely greater permeablity then the red sery send m. Actuoi pamembesty values for the ash fel are unevenable since the friable particles may have been altered by the mechanical analysas technique 5.4 in general, the censtruedon fgl and boulder layers were less permeable then the bedrock. Tests indicated that the boukler layer acted as a barrier to the flow of groundwater between the construction 151 and the bedrock (Ground / Water Technology, Inc.1981). The permoeb81ty of the bedrock verted with depth. Results indicated rock permenbetty ranging from moderale values (about 1.06 x 104 cm/sec), to negligible values (no Sow recorded in the test secdons). The highest permeabilty was at the MMar layer-bedrock interface This probably was a function of the weathered, fractured nature of the top of the bedrock.

6.0 RUNQFF 6.1 In the general vicinity of the site surface runoff wIl Row down the sides of the ridges into small streams, such as Shoup Run which transects the Company property, and wul be comed to the river.

Also, some surface water wel flow direc6y to the river. The watershed extending upstroom from Saxton is about 756 square mies. ,

6.2 The SNEC site currently contanns an overland drainage system which directs runoff to the rtver.

Methods of sediment control are described in Section 7.0.  ;

)

6.3 The " Rational Method' (Salvoto 1982) can be used to conservatively estimate the discharge Gow from '

the SNEC site restdting from stormweter runoff. The aquathn is as foNow:

Q = A*l*R where Q = Runoff in ft 8/ time period A = Aree in ft2 1 = lmperviousn6es ratio R = Rainleil rate in ft/ time period Assuming the drainage ares (A) of concem is the entire SNEC she (1.148 acres), then A = 50,007 ft .

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l SNEC Soil Erosion and Sedimentation Control Plan 0 I The choice of an imperviousness ratio (1) is based on the site having a negligible amount of impervlous cover, vegarmiinn rated as bare to light and a sod consistency ranging from grs.vol to gravel sand mixtures wth sitt and clay compnatinn ranging from high to none (USEPA 1976).

Hence, an average i for the SNEC site = 0.39.

The 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> rnaximum rainfall with a ten-year probabuity of occurrence was found to be 4.5 inches (NOAA 1961) for the Sexton vicinity

, Another approach is to use the average of what is consadored the normal montNy ramielt (NOAA l

1982), This average, for the Saxton vicinity, is found to be 3.04 inches.

Hence, considering a 10-year maximum rainfall event, the total runoff from the SNEC site is l calculated as follows.

O = A*l*R l Q = (50,007 fta(0.39) (.375 ft/24 hours) )

O = 7,313.5 fta/24 hours i l

3 Using an average montNy rainfall event, the total runoff is estimated to be 4,940.7 ft /mo.

7.0 CONTRQL MEA $ YRS $ DyRING EARTHMOVING AQTIVITIES l

7,1 During earth-moving actMties, the emphasis on erosion control is prevention. Environmental and economic costs are minimized with prevention rather than correction. Key elements towards prevention are:

O Minimtre the area to be disturbed - unnecessary and excessive remwel of vegetation and top sol, etcs or steep slopes increase both the Nkelliood and severity of erosion.

9 Preserve vegetation - avoid unnecessary removal of grasses and other low vegetatiort Vegetation is the best protection against soil erosion. It slows and absorbs surface runoff, binds the soi, and protects the sou surface by dis 6ipating the energy of rainfaN and runoff.

9 Minimize the time of exposure - earthmoving actMties should be scheduled to minimize the time that disturbed soi remains unprotected.

O Gradmg - minimize the need for grading, avoid steep slopes, and folow natural contours to the extent practical 7.2 For those areas where sol disturbance is unavoidable and some erosion likely, or for areas which wel be exposed for an extended time, temporary control measures wel be implemented. Three commonly used methods are:

9 Straw bales or filter fabric fences placed at the toe of slopes to irtercept and detain sediment.

l 9 Seeding - storage pies of sou or areas to be exposed for extended periods may be j stabitzed by seeding with fast growing grasses Sodding also may be practical for drainage l areas.

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! Saxt n Nuciew Egminwntal Corgndon SAXTON NUCLEAR Policy and Procedure Manual 6575-PLN-4542.02 l re. m m.

SNEC Soil Erosion and Sedimentation Control Plan 0 j

e MulcNng - the apr*atian of mulcNng meterials wW minimite erosion unti final stablization

• ' is ==*=hei=hed Types of mulches and their application rates are (Pa DER 1982; Delham 1974):

Tvos of Ground Cover Acoroximate Acolication Rate Hay 1.5 - 2.5 tons / acre (90-100 baies)

SmeN. grain straw 1.5 - 2.5 tons / acre (90100 baies)

Com residue 4 tons / acre

! - Wood chips 10 - 20 tons / acre Wood cotulose fiber 1/2 - 3/4 tons / acre Asphelv emulsion 1,250 gallons /t.cre Stones (2B or 3A) 100 - 186 tons / acre NOTE As a general rule, a layer of five straws or fibers overlapping each other is considered sumcient. Other mulches should cover 75% to 90% of the sou area. j l

I 7.3 Numerous other methods or combmetions of methods are avaBable ranging in eWectiveness from temporary to permanent. In general, temporary methods are usueNy designed to detain sediment wh5e permerant methods are designed to stablize sediment. Further detal on these and other methods of erosion control are prrmoed by the Pa DER in reference 11.8.

8.0 PERMANENT CONTROL. MEASURES 8.1 Upon completion of aN earthmoving projects, final site ernhaintian wil be performed in general, this will Irwolve mulcNng and/or seeding with perennial grasses or legume vegetation. If applicable, pavement and/or stones may be applied.

8.2 A permanent vegetative cover wW be established on bare soE areas. Seeding wW be made immediately after final land shaping or gradmg is completed, or as soon thereafter as seed germmation we occur. A permanent vegetative cover also wGl be established on areas where earthmovmg operations wtl be delayed for an extended period Due to the near horizonts' grade of the SNEC site and the lack of water channels and berts, stabilization devices such as mettresses, blar*ets, gabions, stones or concrete revetments wdl not be necessary if problems should arise details concoming these types of protocuon may be found in J. Trourbier and R. Westmecott (reference 11.11).

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• SAXTON NUCLEAR Policy and Procedure Manuel 6575 PLN-4542.02 Tree Asvieson No.

SNEC Soll Erosion and Sedimentation Control Plan 0 I

8.3 Time is necessary for vegetation to becomo established after seeding The winter ammaan is not I

conducive to germination. Mao, vegetation is difReult to ==*=huah in areas of concentrated surface runoff and high velocity To enhance germiruution, mulch wlN be appiled on any critical erosion sites (see Section 7.2 for quantiles of mulch). Seed mtxtures wel be chosen in accordance with standards consistent with sol drainage and area usage The time, rate and procedures for seeding wel be followed as recommended by the agricultural agent or per reference 11.10.

8.4 Seeding methods indude grain drtis, cultipackers, or conugeted rollers with grass seeding attachments; hand operated cyclone seeders; truck-enounted broadcast seeders; or hydroceeders.

However, because the site area is smed (approximately 1.1 acres), the probable method of seed

)i l

application wel be by hand, cyclone seeder or hg: 3g. The letter also allers the advantage of simultaneous apf*=tian of fertilzers and mulch. l 8.5 Permanent vegetation should include perennial grass or grass 4egume mixtures. Grasses, such as f Kentucky 31 Tall Fescue, Redtop Creepmg Red Fescue, Reed Canary grass, Perenruel Rye grass, Smooth Bromegrass, or Timothy and legumes, such as Crownvetch, Birdefoot Trefoi and #falla, may be used. Also, Crs.r.c2. is already established on a mejor portion of the Company property Lime and fortdizer may also be used if sol conditions are found to be poor.

9.0 MAINTENANQq!

9.1 During earth-moving actMties, au she affected areas wfE be periodically inspected.

9.2 Periodic maintenance will be performed, to identify ske areas which may exhibit erosion due to extreme weather effects or msnmade actMties.

9.3 Preferably, vegetation selected for stabilization wul require Ittle or no maintenance. For this purpose, as noted in Section 8.5, Crowrr 44 is desirable Also, most native grasses, shrubs and trees wul flourish with little or no maintenance.

10.0 GLOSSARY 10.1 Alluviurn - Sediment deposited by flowing waters, as in a rtver bed, flood plain, or delta-10.2 Anticline - The fold that is convex upward or had such an atttude at some stage of development.

10.3 Bedrgqk Any solid rock exposed at the surface of the earth or overtain by unconsolidated meterial.

10.4 Blanket A sheet which is stitched together like a qu8t and fred with Portland cement grout after fixed in place.

10.5 Catch Basin - A structure designed to retain storm water prior to discharge.

10.6 Company Refers to the Pennsytvane Electric Company.

10.7 Conduit - Any channel intended for the conveyance of water, whether open or closed.

10.8 Devonian Ace - In the ordinarily expected rianeNication, the fourth in the order of age of the periods comprised in the Paleozoic era, fadowing the Slurian and succeeded by the Mississippian Also, the system of strata deposited at that time. Sometimes called the Age of Fishes.

8.0 ==

I

1 SAXTON NUCLEAR S**a""*'*""*"'**"'"""*""

Policy and Procedure Manuel 6575-PLN-4542.02 Tree Rowmon No.

SNEC Soll Erosion and Sedimentation Control Plan 0 10.9 .Qig - The angle at which a stratum or any planer feature is inclined from the horizontal. The dip is at a right angle to the strike.

10.10 Earthmovino Activity - Any construction or other activity which disturbs the surface of the land (including, but not limited to, excavations, embankments, land development, subdivision developmert, rmneral extraction and the movmg, depositing and storing of sod, rock or earth).

10.11 Erosion The group of processes whereby sod and rock material is loosened or dissolved and removed from any part of the earth's surface. It indudes the process of weathering, solution, corrosion, and transportation.

10.12 fg A bend in strate or any pioner structure 10.13 Fracture - Breaks in rocks due to intense folding or faulting 10.14 M - Emety crumbled, as wodd be the case with rock that is poorty cemented 10.15 Gabion - A cellular wire cage mettrees wtuch may be used either as a revetment or as a channel lining. Ufo awpar*nocy is over 25 years.

10.16 Gradina Any stripping, cutting, fEing, stock pEing, or any combination thereof, and shen include the land in its cut and f5ed condition.

10.17 Graywake A type of sendstone rnerked by: (1) large detrital quartz and foldspers (phenocysts) set in a (2) prominent to dominent "ciey" amerix (and hence absence of iniItration or mineral cement) which may on low-grade metamorphism (dingenesis) be converted to chlorlie and sericite and partially be replacart by carbonate, (3) a dark color, (4) generally tough and weg indurated, (5) extreme anguiertly of the detrital components (rmerobroccia), (6) presence in smaller or larger quantities of rock fragments, memly chert, quartzite, slate or phyllite, and (7) certain macroscope structures (graded bedding, intralormational cci.po,Te---_n of shale cr slate chips, slip bedding, etc.) and (8) certain rock associations.

10.18 Groundwater - Water occupying all of the voids wthin a geologic stratum.

10.19 Impervious - Not allowing entrance or passage 10.20 Imperviousness Ratio - Ratio of water which runs off to that which inf9trates.

l 10.21 Inflitration - The flow of liquid into a asshmance through pores or other openmgs, connoung flow into a soE in contra 4istinction to the work, percolation, which connotes Sow through a porous ushetence 10.22 Leaume - A member of the legume or puso fam8y, Leaummoese One of the most important and widely dietnbuted plant tem 8ies. The fruit is a " legume" or pod that opens along two sutures when ripe. Flowers are usually papilionaceous (butterty&e). Leaves are attemete, have stipules, and are usually compound Practically al legumes are nitrogen-fixing piants.

10.23 Mattress - A cellular wire cage, usually filled using a backhoe and selective hand packing where necessary.

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j SNEC Soil Erosion and Sedimentation Control Plan 0 l 10.24 MWch A natural or artilleial layer of plant residue or other meterials, covering the land surface

! which conserves moisture, holds soil in place, aids in establishing plant cover, and mrumizes j temperature Suctuations. 1 j 10.25 Perennial 'Present at al seasons of the year.

t 10.26 Permeablity - Capacity for transmitting a Ruid. It is measured by the rate at which a Huld of standard

! viscosity can move through meterial in a given interval of time under a given hydraulic gradient i

! 10.27 Rocheros - That portion of the prar4pm=Han in a drainage ares that is discharged from the area in l stream channels. Types indude runoff, ground water runoff, or seepage.  !

l 10J28 Sandstone - A cemented or otherwise compacted detrital sediment composed predommandy of i quartz grains, the grades of the latter being those of sand. Mineralogical varirAss such as

! feldspethic and glauconitic sendstones are recognized, and also argEleceous, sehesous, calcareous,

' ferrugmous, and other varieties K,wne f, to the nature of the bindmg or comentmg meterial.

l 10.29 Sediment - Soild material, both organic and mineral, that is in suspension, is being transported, or 3

has been moved from its site of origin by air, water or ice, and has come to rest on the earth's l surface either above or below sea level.

i

! 10.30 Setdino Area or Sediment Beein - A d.i-- - ' -. formed from the construction of a herrier or dem i butt at a suitable location to retain sediment and debns.

1, .

? 10.31 JM - A lammated sediment in which the constituent particles are predominently of the ciey grade.

Shale includes the indurated, Isminated, or fleeBe cieystones or siltstones. The ciesvage is that of l

bedding and such other secondary ciesvage or fisssty that is apptcodmetely parallel to bedding.

The secondary cieswege has been produced by the pressure of overtying sediments and plastic flow.

l 10.32 jtt - (1) A sol separate consisting of particles between 0.06 and 0.002 mallmeters in =M:

i diameter. (2) A soli textural class.

i 10.33 Strata - Beds or layers of rock, each being unique in sw

" -i l

i 10.34 Syncline A fold in rocks in which the strata dip inward from both sides toward the axis.

10.36 Water Shed - AN land and water withm the confines of a drainage devide.

11.0. REFERENCES j 11.1 Cc.is,0c; M. of Pennsylvania Department of Environmental Resources 1981. The Cloen Streams

~

Law of Per .gA ,i. (Pt.1987. No 394). 20 pp.

11.2 Dahlem Dennis and Schwartz Fred.1974. Reasonal Standards and Criterie for Stom1weter  !

Maneaement Delaware VeNey Regional Planning Commsesion, Philadelphia, Pennsylvania. 35 pp. I 11.3 General Public Utsities System.1963. ,A_geWion to U.S. Atomic Eneroy Comrnission for Reactor Construction Perndt and Oooratina Ucense - Final Safecuerds Reoort. Variou6y peged 10.0 ==

b i

j Nwnbw

! Sam n Nudear Expennwntal CoiA -

i

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SAXTON NUCLEAR Policy and Procedure Manual 6575-PLN-4542.02 Tate Rowieson No.

i i SNEC Soil Erosion and Sedimentation Control Plan 0 l t 11.4 Ground / Water Technology, Inc.1981. Preliminary Hydroaccioalcal Investigation Samon Nuclear l Experimental Station Sexton. Pennevivania. P.O. Box 99, DenvWe, New Jersey 07834. 21 pp.

i

, 11.5 National Oceanic and Atmospheric Administration.1961 Rainfall Frequency Atlas of the United i States Tech. Pacer No. 40. Wasnington, DC.1115 pp.

11.6 Nrstional Oceanic and Atmospheric Administration.1982. Climatolonecal Date Annual Summary

} Pennsvivenia 1982 Vol. 87 No.13. National Climate Data center, Astevele, NC. 30 pp.

j 11.7 Pennsylvania Department of Environmental Resources. No date. Directory of Sou Erosion and i Sedimentation Control Practices Bureau of Sol and Water Ccc v.;;a6, DMelon of Sol Resources

} and Erosion Control, Room 114, Evangelical Press Bulding, Harrisburg, Pennsylvania. Variously j peged. l 4 11.8 Pennsylvania Department of Environmental Resources.1990. Erosion and Sediment Pogution l Control Proaram. Bureau of Sol and Water Co. . '_-i, Dtvision of Sou Resources and Erosion

contros variously peged 1 f 11.9 Salvato, Joseph A.1982. Environmental Enaineerina and Sanitation Wiey -Interscience j Publication.1,163 pp.

l 11.m The P . f;_s. State University 1981.1981 Auru. 6.T.v Guide. College of Agric Ature Extension i Service, Urdversity Park, Pennsylvania. 72 pp.

2

'1.11 i Troubier, Joachim and Westmacott, Richard 1974. Water Mesources Protection Measures in Land j Development - A Handbook Water Resources Center, University of Ddaware, Newark, Delaware l 19711. 237 pp.

j 11.12 U.S. Environmental Protection Agency. 1976. Erosion and Sediment Control - Surface Minino in the

eastem U S. - Desian EPA Technology Transfer Services Publication EPA 625/3f/6006. 137 pp.

! 12.0 EXHIBITS l .

{ 12.1 Topographic Map 12.2 Aerial Photograph of SNEC l 12.3 Saxton Nuclear Experimental Station (Site Plan) 4 12.4 Geologic Crosa Section i

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i l SAXTON NUCLEAR EXPERIMENTAL PENNSn.VANIA STATION

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i Hopewell. Pa.1969 j Photo Revised 1973 i

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j 1. Raystown Branch of the Juniata RNer 7. Filled Drum Storage Bunker (Demoiished)

2. Containment Vessel 8. Penelec Garage South  ;

3. Control and Auxiliary BuBding (Demolished 9. Penelec Garage Southwest 4 RadioactNe Waste Disposal Facility (Demolished) 10. Penelec Secunty Fence

5. Substation 11. SNEC Secunty Fence i

6. Penelec une Shack 12. Westinghouse Area E2-1 n =. l

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Policy and Procedure Manual 6675-PLN-4542.02 r,s. ammon No.

SNEC Soll Erosion and Sedimentation Control Plan 0 EXHtBIT 4

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