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Home My WebLink AboutDRC-2006-001143 - 0901a0688080569cTHIRD QUARTER RADIONUCLIDE EMISSIONS TEST COI\DUCTED AT INTERNATIONAL URANIUM (USA) CORPORATION NORTH YELLOW CAKE SCRUBBER BLANDING, UTAH September 14-15,2006 by: TETCO 90 East Main Lehi, UT 84043 Phone (80r) 768-0973 Fax (801) 768-0880 - Date of Report: :- October 2412006 Prepared for: International Uranium (USA) Corporation 6425 S Hwy 91 Blanding, Utah 84511 CERTIFICATION OF REPORT INTEGRITY Technical Emissions Testing Company (TETCO) certifies that this report represents the truth as well as can be derived by the methods employed. Every effort was made to obtain accurate andrepresentative data and to comply with procedures set forth in the Federal Register. I I L l;iJ Itr I I L L TABLE OF CONTENTS Introduction Test Purpose PAGE Test Location and Type ofProcess . Test Dates Pollutants Tested Test Participants and Methods Applied Deviations From EPA Methods Quality Asswance Summary of Results Emission Results Process Data Description of Collected Samples Discussion of Errors or Inegularities Percent Isokinetics Source Operation ProcessControlDevicesOperation ......5ProcessRepresentativeness ......5 Sampling and Analysis ProcedtnesSamplingPortlocation.... .....6SamplingPointlocation.. ......6SamplingTrainDescription. .....6 SamplingandAnalyticalProcedures .... .......7QualityAssurance .......7 Appendices A: Complete Results and Sample Calculations B: Raw Field Data C: Laboratory Data and Chain of Custody D: Raw Production Data E: Calibration Procedures and Results F: Related Correspondence I I I I I Table I II m TV LIST OF TABLES Measured Radionuclide Emissions Percent Isokinetics Sampling Point Location Complete Results ...AppendixA LIST OF FIGURES Figure 1 Facility Schematic Representation . . . . Appendix D2 Schematic of Method 5/l 14 Sampling Train . . Appendix E - INTRODUCTION - Test Purpose This testwas conductedto determine thetotal radionuclideemissions fromtheNorth yellow Cake Scrubber exhaust in terms of Curies per dry standard cubic foot (Cildscf). u Test Location and Type of Process Intemational Uranium (USA) Corporation is located about 5 miles south of Blanding, Utah. - Uranium ore is processed into yellow cake, which is shipped to other facilities for additional processing. There are two yellow cake dryers with individual scrubbers. The North Yellow Cake dryer was the only operating dryer at the time of the test. The South Yellow Cake Dryer is currently - not operational. A facility schematic is shown as Figure I in Appendix D. Test Dates All testing was completed September l4-15, 006. v Poilutants Tested and Methods Applied The tests were a determination ofradionuclide emissions in accordance with EPA Method 5/1t4. Test run filters and front wash residues were sent to Energy Laboratories in Casper Wyoming for radionuclide analysis. Test Participants Test Facility Wally Brice David Turk State Agency None TETCO Paul R. Kitchen Joseph Kitchen Deviations From EPA Methods None - Oualitv Assurance Testing procedures and sample recovery techniques were according to those outlined in the - Federal Register and the Quality Assurance Handbookfor Air Pollution Measurement Systems. : SUMMARY OF RESULTS Emission Results Table I presents the findings of the test in Curies per dry standard cubic foot. Table fV inAppendix A has more detailed information. Process Data The process was operated according to standard procedures. All pertinent process data wasavailable for recording by agency personnel. Scrubber water flow *d prrrr*, readings were recorded and are found in Appendix D. Production data will be submitted bylnternational Uranium. Description of Collected Samples All test filters were lightly covered with a yellowish colored particulate. The front washes were clear in appearance. A second run was attempted on the 146 but approximately 168 minutes into the test a high vaculnn caused water to be drawn from the first impinger into the filter holder. This voided the run and no attempt was made to recover any portion of the sample train. A successfrrl third run was completed on September l5th. North Yellow Cake Scrubber 6.986E+05 9.6438+05 Percent Isokinetic Samnling Each ofthe tests were isokinetic within the + l0% of lXI%criterion specified in the Federal Register. They also meet the Utah State Department of Environmental Quality, Division of Air Quality specification of isokinetic sampling point by point. Isokinetic values for each test run are presented in Table II. SOURCE OPERATION Process Control Devices Operation All process control devices were operated normally. Recorded scrubber water flow and pressure readings were recorded and are found in Appendix D. Process Representativeness The facility was operated normally. Production data will be submitted by Intemational Uranium. Sampling Port Location The inside diameter of the North Yellow Cake stack is 18.0 inches. The two, four-inch diameter sample port are located 6.3 diameters (9.5 feet) downstream from the last disturbance and 6.3 diameters (9.5 feet) upstream from the next disturbance. Figure I in Appendix D is a schematic of the stack. Samnling Point Location Table III shows the distance of each sampling point from the inside wall according to EPA Method 1. Each point is marked and identified with a wrapping of glass tape and numbered. These points are determined by measuring the distance from the inside wall. Sam Point Distance I 2 aJ 4 5 6 7 0.58 1.89 3.49 5.81 12.t9 14.51 16.11 Sampling Train Description To determine the actual emission rates for this stack, 40 CFR 60, Appendix A, Methods l- 5/ll4werc followed. All samplingtrainsweremade ofinertmaterials, (Teflon, stainless steel andglass)toprevent interference of the sampled gas and particulate. The stack analyzers used to conduct Methods l-5/ll4 are constucted to meet the specifications outlined in the CFR. The temperature sensors are K-type thermocouples. Heater, vacuum and pitot line connections have been designed to be interchangeable with all units used by the tester. A 316 stainless steel probe liner was used for the tests. Figure 2 in Appendix E is a sketch of the Methods 5/l l4 sampling train. Sample boxes were prepared for testing by following the prescribed procedures outlined in Methods 5/114. Sampling and Analytical Procedures All sampling and analytical test procedures were as specified in 40 CFR 60, Appendix A, Methods 5/114. Ouality Assurance All equipment set-up, sampling procedures, sample recovery and equipment calibrations were carried out according to the procedures specified in 40 CFR 60 and.the Quality Assurance Handbook for Air Pollution Measurement Systems. APPENDIX A: Complete Results and Sample Calculations B: Raw Field Data C: LaboratoryDataand Chain of Custody D: Raw Production Data E: Calibration Procedures and Results F: Related Correspondence APPENDIX A Complete Results Nomenclahue Sample Equations A eMb NqlhYdlq€k€ TABLE IV COMPLETE RESULTS, RADIONUCLIDES INTERNATIONAL I.JRANIUM CORPORATION (IUC) NORTH YELLOWCAKE SCRUBBER EXTI,AUST DimensionsSymbol Date Filter # Begin End Pb. AH Y Vm T- {ap Wt*c T, ce Do Coz o2 N2&CO Vmoa Vw Bw. xd Md Ms Yol T" As PG Pbo P. Q' Q" vs Curies Crad ERrad Description Run #l 91r4t2006 4800 8:44 l2:00 24.35 1.354 1.002 143.146 9t.2 0.3047 550.5 r92 0.84 0.3715 2.00 17.80 80.20 112.275 2s.9s6 0.1 39 0.861 29.03 27.50 99.8 119.3 t.767 -0.03 24.28 24.278 1.388+03 2.t6E+03 1.22E+03 950.0 8.461 6.986E+05 Run #3 9/15/2006 4802 8: l7 I l:54 24.30 1.431 r.002 r46.167 82.5 0.3177 603.4 192 0.84 0.3715 1.80 18.00 80.20 rt6.272 28.450 0.r37 0.863 29.01 27.50 98.9 I 18.6 1.767 -0.03 24.23 24.228 1.44E+03 2.25E+03 1.28E+03 1300.0 I l.l8l 9.643E+05 Date Time Tcst Bcgan TimeTest Ended Meter Bilometric Pressue Orifice Pressue Drop Meter Calibration Y Faaor Volune Gas Sampl€+-Mets ConditioDs Avg MeterTempenhre Sq Root VelocityHad Weight Water Collecled Duration ofTest Pitot Tube Coefficimt Nozde Dimoter Volme % Cabon Dioxide Volm 7oOrygm Volrm % Nirogfl md Cubon Monoxide Volme Ghs Sampled (Stadad) Volw Walcr Vapor Fractim H2O in Stek G6 Fnctim of Dry Gas Moleolar Wt. Dry Gas MolmrluW. StrckGd Percent Isokinetic Avg Stack Tmpenhre Stack Cross Scctional Area Stack Static Pr6src Sample Port Baromeric Pressure Stack Prcssue Stack Gas Volwtric FIow Rate (Srd) Stack C8s Volmetric Row Rate (Actual) Velocity of Stack Gd Radionuclides per smple Concmaatim of Radionrclides Emisaon Rate of Radionuclides In. Hg. Abs In. H2O dimmsionless cf r Root In. H2O Gmm Minules Dimensisrls Inches Perctrt Ptrc€nt Pscflt dsf scf Fraction Frutim lMbnol lb/lbmol Perc€nt T SC. Ft. ln. H2O In. Hg. Abs In. Hg. Abs dscfin cfrr Sm pci pCild$f pCi/lr AVG 119.0 1.41E-r-03 2.218+6 ;$ 1.25E+03 J-Y 9.821 83r48+05 Saturat€d moisture fraction used in all calculations for runs I & 2 as the measured moisture was supenaturated \A _{+}6 a.AE'+3 t.e5f+9\: : V ' f-fh"^,ul^ia lf" IQ** \rn, 4 -rupr.l bc:f,cr u'^ t)'glt** 7 \ u):tr^i! 5.t, M5 Nomenclature o/ol: percent isokinetic, percent As = stack cross-sectional area (ft3) ASAP = see {AP Btu = unit heat value (British thermal unit) B* = fraction of water in stack gas Cs = cono€lltration of particulate matter, back half (grldscf,lb/dscf, etc.) Cs= concortration of particulate matter, front half (grldscf,lb/dscf, etc.) Cmetat = concentration of metals (pp-, t g/ft3, etc.) atomic symbol replaces "metal,' COz= percent carbon dioxide in the stack gas Co: pitot tube coefficient (0.84) Cx @"d: species symbol replaces x. Cx ("o,,) : acfual'gas concentration corrected to required percent 02 AH: orifice pressure drop (inches H2O) AHg = orifice pressure (inches H2O) AP = 51ask flow pressure differential (inches H2O) D, = diameter of the stack (feet) Dn= nozzle diameter (inches) EA: percent excess air ERs = emission rate of back half particulate (lb/hr) ERF: emission rate of front half particulate (b/hr) ER -s. = emission rate per mmBtu or ton of fuel etc. ERx = emission rate of compound which replaces x k-fact = multiplier of test point AP to determine test point AH L = length ofrectangular stack (inches) mlltu = thousand Btu M6 = molecular weight of stack gas, dry basis (lb/lb-mol) Mp = rlasS of particulate on filter (mg) Mpp = lnoss of particulate mafter on filter and probe (mg) mmBtu = million Btu ' M. = molecular weight of stack gas, wet basis (gigmol) N2 = percent nitrogen in the stack gas 02 : percent oxygen in the stack gas {AP = average of the square roots of AP (may also be referred to as ASAP) Pb, = absolute barometric pressure at the dry gas meter (inches Hg) Pbo = absolute barometric pressure at the sample location (inches Hg) P6 = stack static pressure (inches H2O) P. = absolute stack pressure (inches Hg) Po6 = absolute pressure at standard conditions (29.92 inches Hg.) 0 : time of test (minutes) Q" = stack gas volumetric flow rate (acfrn) Q, = stack gas volumetric flow rate (dscfrn) Qw: wet stack gas std. volumetric flow (ft3lmin, wscfm) Ts = stack temperature fF) Tsta = absolute temperature at standard conditions (52Sk) Tt= see0 M5 Nomenclature um: mean molecular speed (cm/s) Vm = sample volume (ft3) at meter conditions vrrrtd = volume standard (dscf), sample volume adjusted to 68T and29.92 inches Hg. V,: velocity of stack gas (fpm) V*. = volume water vapor (scf) at 68T and 29.92 inches Hg. W = Width of rectangular stack (inches) Wt*" = weight of the condensed water collected (grams) Xa = fraction of dry gas Y : meter calibration Y-factor (dimensionless) Method 5 0/oI : Vmo6 . (T, + 460). rc39/ (0 . Vs. P, . & . Dn2) A.=(Ds2/4)'n B*: V* I (Vmr,a +V*) Ce=Ms.0.01543/Vmo6 Cr: MO.0.01543 /Vmr6 Cx 1"orr;: Cx(u*; . (2O.9 - desired %O2) / Q0.9 - acfialo/oO2) D.r=2.L.W/(L+W) Dnd". = ^l 1o.ozee. (pb, + 0.0735) / (T, + 460). ce . xd . {(T, + 460). Mr) / (p, . Ap)l} EA : (%O2 - 0.5 o/oCO) / 10.264 o/oN2 - (yoo2 - 0.5 %CO)l ERs = Cs. Qr.0.00857 ERp: Ct. Q. . 0.00857 ER..s, = ERx / (mmBtu / hr) K-fact=846.72.Dn4.AH6. Cl.xo'.Md.pr.(T,+460)i M..(T,+460).(pb.+aH/13.6)J Ma = CO2 . 0.44 + Q,2. 0.32 + Nz .0.28 M.: (Ma . XJ + (18 . 8,,) P,: Pbo + (Pc / 13.6) Qo = Vr'A, Q, : Qa. Xd . Ps . Toa / [(Ts + 460). Poa] Qw: Q' / Xa Vrrsd = Vm . Y . Trtd . (Pb, + Nl / 13.6)/ [Psa. Gm + 460)J V, : 85.49. 50 . Cp. {ap. { 11t, + 460)/(p,. Ms)l v*.: wt*" .0.04715 X6: I -8.',. APPENDIX B Preliminary Velocity Traverse and Sampling point Location Data Particulate Field Data I I N Stack Dia. Ports are Ports are 18" 9.5' Rcfercnce: Ott 9.5' Upstrean from next disturbance Downstrcam &om last disturbancc PreliminaryN Y Cake Scrb Comments: Facility Intemational Uranium Stack Identification North Yellow Cake Dryer Scrubber Date /(5e,0{ 2ab Barometric Pressure Static Pressure (Po) ^. o3 in HrO Estimated Moisture @w,) 4-16 o/o Sample Height from Ground 70 feet Traverse Point Percent Dianieter Distance From:Ports TD Reference A B c D E F I 3.2 0.58 0.58 llb,o'l s ,,1 ,ors 7 2 10.5 r.89 1.89 ,OS ,,1 ,o, 0 J 19.4 3.49 3.49 '6 .*J 1 ,to 1 4 32.3 5.81 5.81 -.ro ?"S ,,,. H 5 67.7 t2.t9 12.19 .tz 3 lt? ,r) 7 6 80.6 L4.51 14.51 ,o ,," 3 o" .tt 7 89.5 16.11 16.1I 4.td t tal. 4,n 8 96.8 L7.42 17.42 zl ,o1 b tt! b,r> Averages: Ts llB.Q ZFlow rt,l AP ,otb {ap .}oso 5 Z Flow AP KEY:> 5///'/ risra oat" str*t Plant: Intemational Uranium O","t trl TETCOriltel!)}0_ Samplc Box_/_ Location: North Ycllowsakc Dryer Scrubbcr owtarcc PavI 2 /(,rU.,a rorar |tlS.tfb/lA.glSto Jt.b+ lQoQ vage-LorJ Run# / 1) A Diamcter _18,,_ port Rcfcrcnce 0.0, Portsarc 9.5' Upstream from nextdislurbancf, Assumed Moisturc 4-13 % Probe &_-- "r__p,r_Nozlc Calibration ,2IJ- .!7t 3rz_ .r7z lvg D" .3?/f inchcs caseaetfa3 Consolc 3v-r,l;,*FZ- AH@ /.b3t inHro Baromctric pressurcs ev^ 21.7f inng Pb, 2q.29 tnHsp(, -. of in Hro L.rl Ch€k: gI9 E$l t'tnin O.@3 O.eOO vtinuga?.Q 7,O PibrRrr! A@ O,OO tn{,o ,23 ,L< watercolteaea 15O .{ g Timc Sampled , /? 2 min Revicw 0gg2q t1 9 ( t pl riovoata shcct ri r,",-4 go-l]ETl,'?,. r*--0- Plant: International Uranium Ort",Orr:r*oc= t?avl ?-orCll C Location: Nonh Ycllowcakc D 'cr Scrubbcr e"g" / o1__-/ Run# ? I I N {)V A Diameter _l8"_ port Refcrence 0.0, 9.5' Upstrum from nexl disrutancr Assumed Moisture 4-13 o/o Probe -ZV--"r__yV_ Nozzle Calibntion,t$o .'Eo -itt .7sl AvgD" .3&f inchcs c,aseae F47-.-.2_ Consolcy-r"",or7E ^Ha t,bt, inP,2o Baromotric Pressurcs Pb^ 2.l.rt tn*s Pb, 3'l .Zg in:Hg e,,_-1o.]_ in uro Ldl Chcl: &s nt,nh ]?.ota wans Z2.O pitonm O.OO rote .L{ P$! Watcr Collected Time Sampled min Rcvicw Tnws Poid ,\fu! 5+Gf1l.<'t g+"r+r.l l3:32 t3:75 15, tz lu:oQ to bla" ou\ P?ol ,+afi* tu oo 1o bton) 6,1 ,p11uLes ifrL-r^d Data shect , rn -1p z.J tl"l?* "*__zLPlanr: International Uranium - on' t5 S.ff nug" / orJ Run# ? J\V A Diamcter _18',_ port Rcfercnce _0.0,,arE 9.5' Upstreem from ne)(tdistu$ance last Assumcd Moisture 4-13 o/o Probc eJk__--7r__gg!__ Nozzle Calibration , )V | .3! | = .31e 372 avgo". 37lf inctrcs Gas eag J'o .3 Consolc 3 "-F"aor-TdAHo l. /.,39, inH,O Baromctrio prqssures Pb^ J'/,)e tnHs Pb, )'f , L3 ;aguPu -'?3 in HroLcntchet: LCg ee$ dt^tn O.oOb O.onr vrcin*e ZZ.O ?.O PilorRaro O.OO 0 aO tnHzo .Z€ ,L< l4ta.lt ?/t S,o1lg LZ.qo rgq+)aqo Water Collectcd Timc Samptcd /? Z min R*iew /Zf Location: Nortlr ycllogcakc prygr Sjrubber Trwe Pdnr ./z.{, ,t ght lrr^r" -lr\X va,t*5,ve - b[o.lg4"Ar! -tt+rg lt:t{i o^,'l- D.4t( Tub"s APPENDIX C Sample Recovery Gas Analysis Data (ORSAT) Chain of Custodv ? Method: Run:t.Sampte so* A Filter Number: .lgoo il4PTNGERS'. FilterNumber: 48ot . Finalkl Initial6y Net 1g1 ''. RINSES Initials P'K r rotaf k) 55o.9 Frdt--------- ..-.------ -- cHrcr;----- - I Initial o Initials Final1gy Initial 1s1 I\lat /-\ RINSES : -'CHrCt,Final lnitial Net Final _r -s tMPINGERg Filter Number:q@> l::-/'t-L.tl lnitials PEr , lKFinalGt Initialtg) Net 1g1 Total€y (o03,'{ Final Initial Sample Box: iiiNsES' .Net HrO Final cH2clr : pmt ]n{ernot,ona-f uro-,'u,n^.Lo" tio, N. Ytfioa(oke \-..ven 5".Analytical Method___9BS4T_ ,.,:i::11*d- Gas Bag No. J-o3 Ambient r" pT Operator f?ta oate nSqfo| Test No. LGasBagNo.-FJ Ambient Temp 7 t Qperator PTtc oate rtlsufOb Test No. 7dasnagNo.:F- Ambient Temp ?.O Operator 1F.t4. Gas RUN Average Net Volume I 2 3 Acturl Rcrdiop Nct Actuel Rcedine Nct Actu!l Rcrdins Nct CO,Z.o 2,o ?-o z-o z-o Z-o z-o Or (Net is Actual 02 Reading Minus Actual 3Oz Readine)./1- 8 t 7.8 t1.g t7g t1-t t78 r7.g Y2 (Net is 100 Minus {ctual 02 Reading).80-z 8o'z 8o'z 80.z Gas RUN Average Net Volume I 2 J Acturl Rcrding uit -,\Acturl ) Rcrdioo Nct Actud Rcrdioe NC. Cot /.8 \UV Lg t-g t-8 1.8 t-3 /-g Or (Net is Actual 02 Reading Minus Actual 3Or Readine). It.ffr,18-o t1.?t3.o | ?.8 r 8.o r ?.o \2 (Net is 100 Minus {,ctual O, Reading).(o.z 8o.z 80.?90,2 Gas RUN Average Net Volume I 2 3 Aclu.l Rcrdios Ncl Acturl Rcrdirs Nct Arlurl Rcedins Ncl CO,t.a t,6 f.8 t.g 1-g t.8 t.9 O2 (Net is Actual O, Reading Minus Actual lO, Readins). tq,8 t6.o t?-8 18 .o r?.8 ,8.O r8.a \2 (Netis l00Minus {ctual 02 Reading).(o.L 90.L go .?80.L CO is not measured, as it has the same molecular weight as N2 TETC O ^::"*".T:;;:;"iEI;;:, 9oEastMain,trhi,Utah 84043 r 801-258-09?3 r FAX 801-768-0880 Chain of Custod Sample Identification Lecovery Date Sample Descriotion 9l14/06 Filter Probe Acetone Wash 4800 Filter 4800 Front Gravimetric EPA Method 5 Gravimetric -PAMethod 5 -Gravimetric4800 Back Impinger Catch 4802 Filter EPA Method 5 Gravimetric EPA Method 5 Gravimetric EPA Method 5 -Gravimetric 9nst06 Filter 4802 Front Probe Acetone Wash 4802 Back Impinger Catch Filter EPA Method 5 Gravimetric EPA Method 5 Filter Front Probe Acetone Wash Back Gravimetric Impinger Catch Sampled by: Recovered by: Relinquished by: Received by: ?ot k KlJh^ Date: Pou( iL t4.A"n Date: Date: 7-/f-ae Relinquishedby: / , 4L/, Date: ?-r/y'a/ Received By: Analyzed By: Date: Date: unless otherwise indicated, all samples remain in the custody of rETCo. chain of Gustogy. and Analylical Request Record page / ot I PLEASE PRINT, provide as much information as possible. Refer to conesponding notes on reverse side. gompany Narn€l tr", {arn' /,'on " / (,too, rL'r^ ,roj€cl Nem3, Pws F, Fetmfi F, Etc.l a'e\fiil)P's lvy q / Dlan/ r'n* tl T lt/ft f :ontact Nemo, Phone, Fax, E-rnall: W" //y Etr'c1 V3t 67r-)2/t. € 7/-?27r Samplgr Name lf other ttpn Contactla-/ tr/c/r-,/2 /aa ,0x lat 76(-??7t lnvoice Addr6ss: Jarat 4jan,c -/ ELI Quote #: Report Required For: pOnrulWWfp E DW O Special Report Formats - ELI must be notlfled prlor to sample submittral for the following: Heuc El nzuE LevetvEl Other EDD/EDT E Format eo€ Ei9'5=fi49XFaP.*P flg: djtg,EF.U*:5s E MATRIX A ul L'l ol il EI rl :s It D o trJI(J EulIU U) -i(- E5e E E Notify ELI prior to RUSH sample submittral for additlonal Shlpped by: charges and scheduling Cooler lD(s) E5o E E q,lE ?- // "t)r- //' Or/c e {i. ,ir7'd AnolYs2 Receipt Temp , oc Custody Seal Y Nlntact Y N Signature Y N Match Lab lD SAMPLE IUb,N I II.IL;Al IUN (Name, Location, Intoryal, otc,) Collectlon Date Gollecuon Tlme' ,&0o E'/ lu )?hrlx 6F F //+> 12-, /.L -- ' 7"i Dc "k". )5 2 W Y.fu:z t:,'//r-)q/illt 6F Fft,\ /---/. 'i lU 2.-t- Pr"h- )U' 5 6 r[el 7 EI0cA E 10 : Custody Record MUST be Signed R.lktqubh€dby(pdnl): D|tdllno: _ ShDln:,@,& q/>/ae /t2a /U'fu Re.trao Dy (Pm0: Et8lr/ThF: Slgmturo: R.[nqubtr.dby(p.h0: Drbrlm: s|endl|t:Rsc.ivd by (Fht): Dats/Tlns: Stgnanrc: Samplc Dlsposal: Rctum to ollent - Lab Dlsoosal: \,. LA,EOR.ATORY USE ONLYSample Type: * oifacUoris - In certarn crrcumrtancor' ""*L:':lJ:i*::""8::griffil5l;aixn*;#:r1]!E*fi 1"":H,r,s::J..t.r*lfijffisor rocom'rera rhc anarveb ."q,"rrca. Msit our web site at www.energylab.com for additional information, downloadable fee schedule, forms, & links. APPENDIX C Sample Recovery Gas Analysis Data (ORSAT) Chain of Custody Lab Analysis ENER6J LASOR/{TOHIES. rNc. 2393 Solt Crcek Highwoy Be6Ot PO Bol( 3258 Cmper, W\l gA60? vaicet 307.235,0518. Tolf Frce voice: ggg.a35.o5l5 . Fox: w7.zg4.t6ggE-nroil Addrress: cawt@e4eryrylab.con r visit orrn web page at: www.energyrob.com Acsfitl,iltE covER SHEET ,o, .frt /' - Fox Mrmber: Connpany: Fnom: This FAX contains pqcs includiry this coven sheet.Z DATAf PRELx,l rNARy The foltowirg doto has not bqen proofed for emors nor has doto been reviewed by grnlity ossuronce/grnlitycontrol personnel. tr DArA REsuLrs 4kiffio Qrntity ossurcnce/gunlity control persor*rel haw proofed the following doio for errors. o TH EP, I r N F O R ti 4rr o N R E Q U E s r E D Cqtfidllttidrry Stotcncnt This focsinilc til?ssogB Gontoins infurnnfion frcrn Encrgy Labomtorics, fnc. ard rmy be confi&ntial or prMlegcd- The infornotion is irtan&d lobe fon the u$ of the irdiviri|El or entity m|rd obovu' ff you ore mt the intardcd ftcipicht, bc omrc rhor aly disclosrc. copying, distrihdion oruse of thc conf"nts of this l|tc33o9a is prohibiled rf pr received fhis et:ctronic rnesogc in error, pleose notify rs irnrnrfictity uy rcpV fox oefelephone ol l-88E-23S0515. Revised 07-17-Ot LABORATORY ANALYTICAL REPORT Cliont Intenretional Uranium (USA) Corp Sits Narre: Not lndicated Report Date: 1O24lOo Lab lD: C06091296-@l Gfient Sample lD: Filter 4BCD combined with Beaker 24Matrlx: Filter Gollection Date: 0914/(}6 IlateReceived: 09i26/OB $cuAndysesResult Unlts eua$fter RL OCL llethod Anatysb Oats, By RADIONUCUDES . TOTAL Uranium. Adivity 950 pcilFinet 0.2 St/t/6020 1002106 23:21 /bws Lab lD: C06O9123&@2 Cllent Sampfe lD: Fitter 4802 conbined with Beaker 25Matrix: Fllter Colloctlon Date: 09/15O5 DabReceived: 09/26O0 MCUAnafsesResult Units eustifier RL eCL Me$od Anotpis mrBy RADIOiIUCUDES -TOTAL Uranium, Activity 1300 pCilFitter O.2 SVm020 fin2rc6z3:2'ttus Report RL -Anatytg raporthg limit.Deflnlsons: aCL - euality control uhil. MCL - ltlaximum conlaminant le,veL ND - l.lot delcded at the nportirg Imil APPENDIX D Figure 1. Facility Schematic Representation Scrubber Process Data D Inte rtnati onal lJraniumFacility: Stack rdentin"u,lon, North Yellow Cake Scrubber cu Distance upstream from next disturbance, feet Distance downstream from last distubance. feet y: Distance of Sample Level to floor, feet O: Stack Inside Diameter. inches Estimated Moisture, percent Estimated Temperature, oF Estimated Velocity, frm Number of Ports 9.5' B:9.5', 65' 19" Near Saturation 70-125 1.100 l+a+l Control Unit Type: Figure l. Facility Schematic Representation :Q'h.t'c-L't 6ei o'hohah o'h o'h o't-, Q'hohol" Ug bs b's =lofS{7 -7f"-S ot',ll gv: o\ t'ltct 00".Q I b?'. b 4o' p qhrYz ; 41 7./---\ @) WrL 90"9 lhir., L\,"-L -$h:l 0'1" | 1 a1g:-Ll @ 9t, :ll Ql:t1 4h "ot\1,'.ol ss .b o€.b Lo "bth *on:,J u'ho's )e o'Q t's a's l's 8'e L'g b'L 4'€4c b'c a'h L'L L- t- L'Lq'L t.aIY ls l's x.9 e'9z'9 z'st's ,.rOg ry) .tc f n i.llntr; Y(W ---: 0)'L 4,'L 0'ut)'L /) t- 1't'q'L L'L L'L L.L L't&'r 9=^ t- 9' t- lrL\J?t{Q qd J4rn1 oTf"tcS v'.tl4J ttsqn'u,e -J,q 22 *lPly Y+tW APPENDIX E Calibration ofthe console dry gas meter(s), pitot tubes, nozzles diameters, and temperature sensors were carried out in accordance with the procedures outlined in the Quality AssuranceHandbook. The appropriate calibration data are presented in the following pages. The nozzle calibrations are recorded on the first page of the field data sheets. Figure 2. Schematic of Method 5/ll4 Sampling Train Meter Box Calibration Data and Calculations Forms Post-test Dry Gas Meter Calibration Data Forms Tlpe S Pitot Tube Inspection Data Sample Box Temperature Sensor Calibration E Iirrpcrs!-rt$1 FDbYl:dilffiJ -il tjDo I FUTlbo .i , ''''.: - Irqinpf Train gptionel; IrhV * Replaced . EyAl tsqu\E ont corrcbrsdr I'I 'l IlTI I I'.t.t 'ruger/l,( -^-.--\ I /lTypes{r,r,o. \ Shck uruGoosened< l,h?do \\ FbstTracod Casslited Probe \CtEck Enaty sfica C€l Ar-Tght |,trrp Ivhmrnrter ', A I I Gtass Fiilter l-bkbf l'b*dArea tlirll iii i 'ln, liil Iri lit TI I I I I -J lirr YyuEr llll tlll B'* ililtU ilt FIGURE L .SCHEI,IATIC RBPRESENTATION O, fu OO4t1r 'nl,rNc TRAIN METHOD 5 DRY GAS METER CALIBMTION USING CRIT'CAL ORIFICES 1) 2l 3) 4', DATE: METER PARTIT serect three citcar ormces to oaribrate the dry ga' meter which braoket the expec-ted operating range.Recod barometric pressure before anO "n", orflOratton pro""Orr"l'Run at tested \€c!um (from O.dfic€ Calibraflon R€port), ti" p.i* "Orn"necessary to achla/e a minimum total \olume of S oubic fBet.Record data and infomaflon tn the GREEN osil", Vi[Oil c"ff. "re cabutated.Facility FINALl, tl AVO (PL) 25.39 MEIER SERIAL f CRITICAL ORIFICE SET SERIAL * ',,;irr" j Jlois*'.' gir**, i grs,!$e,' BAROMETRIC EqUIPMENT ID *IF Y VARTATION EXCEEDS 2.OO%, ORIFICE SHOULD BE RECALTBRATED I t ffi:ffiHrffiH:ffi vqr*, = *,tPbq +@ ^lTottb r =v!l:c-Vm<at 0.997 g+* :0.S94 jo,ge! 1.91 l.00ri t4q +sF t4t1 f;007 tr999 roos :lzn7i,1 :!,O70ll:: r!,?99i1 :l.o*r;r, :lcio I tzos,':l ii#fl ,C{9s 4{707 :::::i{+# fiapl .4.3qt5 r1t€E, i€s $rge ,!{tr!r , qie963 .441,31 :, . AVO r 1#l f49,. r 4:rFs3 . AVG: 4:2?ai 4.s252,,, 4.i2qtr ' AVG. .fr:63 .o.04 s€g .1.76 1# i.rs :]|, 1.66 lEg' l;d5' 1.9 1S 1.VUSING THE CR]TICALORIFICES AS CAUERATON SIANOARDS: Ths fdo$ing equsrom io us€d b cdcrrare.he eunao vcuma ot * pas6€d urough he oGM, vn (8t0, and ho cfirhd odrhr,vc ('rd), 8nd tho Dcfrr cdbarbn hh, y. Th.uc equahns re auiorurey rer,ra.o m uo sprs&hoot $o's. vmp,a1 = Kr*yr*Pbar+llH /13,6) tm (r) (2) (3t = Nel \olume of ga8 sample passed through DGM, conected to standard condition8Kr = i7.64 h/tn. H! (Engtish), O.385S.I(/mm Hg (Metrtc) - -' - T, = Abootut DcM .vg. i.mpcntup CR . English, .K. Mofic) = volume of gas .ample pa8'ed through the crltloal orlfice, ooffecled to standard condiflohsTd : AbEolute rmbi.nt bmFr.tur. fR . Engtirh, oX . Mctic)K = A\€rag. K, hstor fiom Crttcal Odficc Cslib||tone OGM calibration hc'tor ELAPSED TrME (MtNl offi*j: :ffiffiffi**ffiffi x, ffiffi?4,q : [,.,,is!oi l I 0,$, AvERAGE DRy eAs METER cALTBRATT.N FAcroR, " " [@l AVEMGEAHq=lETl or'= (ffi,)'^"(ry) Console #3 Callbrauon METHOD 5 DRY GAS METER CALIBRATION USING CRITICAL ORIFIGES DATE: METER PART *: 1) sslecl thrc€ critical orific€s to calibrate the dry gas met€r whlch bracket the oxp€ctcd operating rangc,2) Record barom€tric pre$ure bafor€ and aftsr calibretion procoduB. 3) Run at t$tad vacuum (tKrm Oriticc Calibration Rcport), for a pcriod of tima necr3sary to achlcve r minimum total voluma of S cublc fgot. 4) Rccord data and information in thc GREEN cr[s, yELLow cels are carcuratad. BAROIIIETRIC PRESSURE EQUIPIIENT ID *: Il,.',q ffil AVG (Pbl 25,35 ITl ' fmlFii l, ,r, | ,trir...Tj.Fl I , ,.1 r lo.Coool'-rs Iffiiffiffiiffi i|i i:liriir;!iritr:u::rl :it!t USING THE CRITICAL ORIFICES A3 CALIBRANON STANDARDS: Thc following cquauons arc uced to calculetc thc atendsrd volumcs of air pars€d through th€ DGM, vh(8td)' and lh. critlcal oriflco, Ve (std), lnd th. DGM calibration faclor, Y. Thcsq cquailonc arc automatic€ly vm,.,^ = 1g, * y^. Pbar + (N! | 13'6),TM vq,--, = y'* Pbar * @ JTamb . .ltiirol' : , ,, I :'l : : : : i i : : ! I I i I I , : i i. . : : i:,iii{!ti{f$ri 6,0115 6.032 5.030 tF Y VAR|AT|ON EXCEEDS 2.OO%, ORIFICE SHOULD BE RECALIBRATEO 1,011 1.010 1.O14 AVG r 1.012 0,00 AVG 3 AVG. 1.6it 1.63 1.62 .0 ,0 ,0 ,0 .0 .o (1) (21 ., Vcrr,^I=-Y^ut, FaCility lnternational Uranlum.North yellowcaks Dryer Scrubber 79,76 81.5 t! 0.00 0.00 0,00 0.00 0.00 0,00 ' Nst vorumc of gas Eampr. pass6d through oGM, conected to standard conditiong K! . i7.64.Mn. Hg (Engtirh), O.3sS8 olvm Hg (M€rrtc) Tn = Abgolut. DGM evg. temperstur. (oR - EnglBh, oK _ Met ic) ' volum€ ot gas sample pabsed through the critical orifice, corrected to standard conditiongT6 : Ab$luto mbisnt t6mp.€turc fR - Engtbh,.K . Mot ic) K = Avoragc K tactor from Criilcal Ormca Cslibrsti;n ELAPSED Tn E (UtN) e j,ii,,...i1;,.:l' ,j;,''::itt!l ;rZa,l,i;';;,t[ :];;;:tttl i;,,'lz ,: rii ,,1 :-,:ro ,iii3l:i Hp| 4.20s8 4'2s12 "l | 4.rsr4 4.22lg I e.Pq I l 136,, l 4.1sz' 4.2ose FfrffiIiltrIffiffiIT]E- AVERAGE DRy cAs MEIER cALtBRAIoN FAcroR, ,. lffil AVERAGEAHo.I 1.63 | *." (ffi)'*(Y) i, ilij1;:[;i1,il;;iii .;:: ; l:;1;i1.1; ,,r ; .1. I l: : r : ir ! i i: :i I l '", '' ' ,.l,,; ..::. ai,, i:iiii;i:i; ii;il ilriiiri i:li iiliilii!:il::l dtrffi iilt: rlll i:Iiilt'iiti:lliti r : ! i i: I : : I I : i I I i i: I i i I : ir;iiiirIi t::t:tr:! (3)! DGM calibratlon tactot Consol€ #3 Calibratlon o'g,' t:z/-? i" ( Type S Pitot Tube Inspectiolr Dgta : .: pitotTubcldeatification: 21- Z q=.2)T ;n. P1: 3.fT in Ps= .)fO in. PB Is Pe:Pa ? J Is 1.05.q < q < 1.50 .Dr?---=- c'1<10" o,=l J o P^ cr2 < l0o 9rS5o Pr= g 9r<5o Zs0.125 in.. O)Ain. w<0.03t25 in. W= .0 L3 in Thc pitot tube mects the qpccificatiors for a catibrAioo factor of 0.&4? J ou: 2- o o- | oP2- | z= 'Tcmriraturc Scosor Calibration Type S Pitot Tube Inspection Data D,= ,7lr in. g o,=l' Ar=l' ,'\Fz= <---.-_-:- z z= .O33 . i". N6 in.w= Thcpitottubcmcersthespecilicatiorn foracalibrarioa tbctorof0.E4? V/ e^= ,! 4l ;n. Ps= ''l1l Is pa=ps? V Is 1.05. D, < q < 1.50 ,qZ--T C1 < l0o ct=' .O o2 < l0o ip,s5' F:<5o ZsO.l25m. W<0.03125 in- :J pu Sample Box Temperature Sensor Calibration Datc: l]-3a-afiatibriloc 4 tr//"/r.n *"rr*;Z; UnitID Temperature Difference CF) / F APPENDIX F The testing protocol and other correspondence related to the tests are included here. QUARTERLY EMISSION TESTING PROTOCOL FOR RADIONUCLIDE PARTICULATE MATTER AT TNTERNATIONAL I'RANIUM (USA) CORPORATION BLANDING, UTAH YELLOW CAKE NORTII DRYER SCRUBBER August 30' 2006 Project Organization and Responsibilitv The following personnel and the testing contractor are presently anticipated to be involved in the testing program. The Utah Deparfrnent of Environmental Quality, Division of Air Quality (DAQ) and EPA may have their own personnel to observe all phases including the process. Company Contacts lnternational Uranium (USA) Corporation Wally Brice 435-678-2221 P.O. Box 809 Blanding, Utah 84511 TETCO Dean Kitchen 801-768-0973 90 East Main Paul R. Kitchen Lehi, Utah 84043 Facility and Location lnternational Uranium's White Mesa Mill is located 6 miles south of Blanding, Utah on Higlrway 191. The Mill processes uranium ore. There are two yellow cake dryers with individual scrubbers but only the Yellow Cake North Dryer is currently in operation and will be tested. Test Objective This test will be conducted to measure the radionucleide emissions on the scrubber that serves the Yellow Cake ore processing operation at the facility. Testing procedures will include accumulating process and production data as well as testing for Radionucleide emissions using EPA Method5/114. Test Schedule Testing will follow this protocol for the third quarter of 2006 and the first and third quarters of 2007. Testing in the third quarter of 2006 is scheduled for September l3-15, 2006. Notification of test dates in other quarters will be sent as they are scheduled by the facility. Site Access The sample site is located on the building roof and is accessed by stairs and ladders inside the building. Potential Hazards Moving Equipment - Yes Hot Equipment - Yes Chemical - Yes Other - Radioactive Process Data All operational and instrumentation data will be made available to DAQ personnel. The facilitv will run at normal conditions. Ouali(v Assurance All testing and analysis in these tests will be conducted according to EPA Methods 5/114. 2. Reporting Reporting will be prepared by the testing contractor according to EPA Quality Assurance Guidelines. A complete copy of raw data and test calculations summary will be included in the reports. All process and production data will be recorded by lnternational Uranium (USA) personnel for inspection by DAQ and EPA, if requested. Test Procedures Radionuclide emission testing will be conducted on the scrubber exhaust stack according to EPA Method 5/114. Specific procedures are as follows: 1. The sample locations and the number of sample points will comply with the requirements of EPA Method 1. The inside diameter of the Yellow Cake North Dryer Scrubber stack exhaust is l8 inches. The ports are located 114 inches (6.3 diameters) upstream from the next disturbance and 114 inches (6.3 diameters) downstream from the last disturbance. EPA Method 2 will be used to determine the gas stream velocity. Type "S" pitot tubes will be used with a Co factor of 0.84. Dual inclined/vertical manometers with graduations of 0.01 inches of water will be used. If the flows are below .25 inches of water a more sensitive manometer will be used. The graduation marks on it are .005 inches of water. Direction of gas flow will be checked for gas cyclonics prior to testing. If the average deviation is over 20 degrees, then straightening vanes will be installed or other arrangements agreeable to DAQ will be made. Test run time will be at least 60 minutes for each test run. EPA Method 3 will be used to determine the gas stream dry molecular weight if the exhaust gas is not ambient. An integrated flue gas sample will be taken from the exhaust line after the dry gas meter orifice during each test run and analyzed at the completion of the test with an Orsat to determine the molecular weight of the effluent gas stream. If the exhaust gas is ambient air then TETCO will use a dry molecular weight of 28.84 lb/lbmol (20.9 percent C.2, 79.1percent Nr) in all calculations. EPA Method 4 will be followed to determine the gas stream moisture content. Probe liners will be 316 stainless steel for all tests. The glass fiber filters used will meet the requirements of EPA Method 5/114. aJ. 4. 5. 6. 7. 8. The barometric pressure will be measured with a barometer which is periodically checked against a mercury barometer. The barometer will be checked prior to testing to assure an accurate barometric pressure. 9. All current calibration data is submitted with this protocol, except nozzfe calibration which will be done at the test site. Nozzle calibration witl be included on the first page of each set of run sheets for each respective test run. Any calibration that is not cunent will be re-calibrated prior to the test dates. 10. Any necessary preparation and clean-up by the contactor will be performed in the contactor's sampling trailer or a clean area on International Uranium's property. Laboratory work and analysis will be completed by the conhactor and Energy Laboratories as soon as possible after the test project. 11. Verbal results will be reported to Wally Brice of lntemational Uranium (USA). The written report will follow within 30 days following the completion of the test. 12. If maintenance or operating problems arise during the test, the test may be stopped. This determination will be made by lntemational Uranium (USA) representatives and operating personnel in consultation with DAQ representatives Estimates of Test Parameters The values below are estimates of the stack flow rates and temperatures. These are estimates only and are not intended to reflect permitted values. Velocity fom 1100 Moisture % Near Saturation Appendix A Facility Schematics Yellow Cake North Dryer Scrubber Faci,i,v: Inte frnati onal Uranlum Stack rdentiri.u,ion. North Yellow Cake Scrubber a: Distance upstream from next disturbance, feet p: Distance downstream from last disturbance, feet 7: Distance of Sample Level to floor, feet O: Stack Inside Diameter. inches Estimated Moisture, percent Estimated Temperature, oF Estimated Velocity, fum Number of Ports 9.5' 9.5' 65' 18" Near Saturation 70-125 1.100 l+a+1 Control Unit Type:Yellow Cake Processing t cl l, Figure l. Facility Schematic Representation Appendix B !- Calibration Data METHOD 5 DRY GAS METER CALIBMTION USING CRITICAL ORIFICES 1) selec{ three crnrcar odfices to cailbrEt€ tho dry gas meter which bracket the e,p6cted operatng rang€.2) RGcord barom€tru F€s3u1€ bGfo.e rnd alter aaltbailon prooedut!.3) Run at t€ltsd vrouum (hom Orillcs Callbration Rsport), tor ! pcrlo{, of tlm€naoo8ary to aohl! ! a mlnlmum total \olurn€ d E ouua lb!t,4) Reaord data 8nd Infomsilm In thG oREEN ocrb, yELLc'l/r/ ocile are carcurated. ffi ffi ffi ffiffiffi IIETER SERIAL* CRffiCAL ORIFICE SET SER|/AL f Facility FII'IAL lffi+l AVO (Pbil 25,39SAROI|E Rtc PRESsURE 0n H EQUIPTIEI{I IO'I IF Y VARIATION EXCEEDS 2.@X. ORIFICE SHOULD BE RECALIARATEO t 2 3 I 2 3 I 2 3 USIIIS THE CRTTEALORTEES A8 CruERATION 6TAilDAROS: Th! ftloiog cq'Jllom rs u..d b cdcd& hc ruxbd vdumi d €l p$sod tmugh ho oclt, v. (8u], dd hc qllcd o.ilc., Vc (sts), a|d lhe DGM cdbcton ffir, Y. The Gquaton! ac aubmslcdycdcuabdln h! ryShootdov.. (11 vm,n=Krlvn.Pbar+(ry1\3.6) ffiffi Hffi ffi :::::,i::::::,i:;:::.: : .:: ...,.:: :,,:ti*lf,f i,, ,,:,, ,149S,1: ,,, ,, ,' jg,gpl, i,i,g49*l.,.1,,.,,,sAgq::' ., : :, +pi, t:i:t.liiiI,,i t., +:ingra,,,: ,, ." ;* AvG - ': :b:- :.:::i ::ii'i:i::.: :.,,,.::: ::1 ,.T: :.i11#',:.,.,,. 1#:: , ,i l9P? :.,Ceg:i : : .4a1pg ., Ig 'l ii,3cbd.. . ...,'t:sss3: . t;ooo AVO -:r: .lr.| ,',..... ., !i!.Q$!:l:lr 4123!1; l: ,:i: .i. ..i ::{€9, , ': 4!s4?': , :f4p',1'r , :EE3le "AVG. ts'j4i ,r+q .l;008 i iriod: r;lllg::i ,, r$Ig:iii l:.:I:7!:: : ir:6C.,:t,, i.::Lsc.ii'I !:66i,:: .... ,:.1:65ii, @ "1' ,.,,,,,,, ''1.6i , . , ,l-ct,, 1:el r Net \rolum€ of gr3 slmpte pes€€d thot€h DGM, con€cted to stlndard oonditons Kr ' 17.O1wln. tb (pngllth), 0.3SgE 1(/mm Hg (M.dc)f, - Atrotutr DGM 1ry. tompcmUr fR - EnglLh, oK. Mrtic) . volume d gaa 6amplc passed though th€ crlUcal odflce, ooreoted !o standard condiilonsTd 3 Aholut rmbLntUmfnEn fF. Engtbh,cK. Meic) K 3 Av.ner K hcbr |toflr Cdtcal Otfic! Crllbntoo AvERAGE DRycAs METER cALTBRATIoN FAcToR,"=@l AvErtAcE alto =lrerfll o""" (uffi,)'*(ry) (z',)velat = K\Pfe# Y =V:*.lmtal (3t r OGM oallbratlon lbctor Comole #3 Callbrailon METHOD 5 DRY GAS METER CALIBRATION USING CRITICAL ORIFICES 1) Scr€d thrG6 qiucar ori'cca to c€ribfatr th€ dry g". mc!.r s'hidl brack.t th. oxpcc{ld opcratng rang€.2) R.co.d b.rom€tlc pna.turrr bldor. .nd eltcr celtbraifon xocoduc.3) Run .t tartcd vrcuum (trom Orlltc. Callbra[on Rcport), ior e porlod of tmcnco!.rary b .chh. a mlnlmum lohl volum. d E qJbb,.ai.4) R@rd dat and Inform.Uon In Ot. CREEX c.L, yELLOW cclr rn c.tcutrt d. , TETERSERIAL CR|NCAI ORIFICE SET SER|AI INIIUL *o*rr*" ,*rurr*a un "or,lllrlEQUIPIENTID|: I Conrotrtt I IF Y VARAIION EXCEEDS 2.0096 ORIFICE SHOULD BE RECALTBRATED RMI.| *rl AVG IP|') 26.42 l-ll ' l-."" 1L"J:m+Ft;l;m| | .l;T;ll-;lrffi| | . l.rr.rT;i t.175 a00t 5,20a arG3 9.11i2 6.16t ,.14 E,1U t l23 USING IHE CRffiCAl OR|FICES AS CAUBRATTOI STAilDARDST rhe lblordng equatons E|r us€d b cdorbh bo shrdard rtums ot rlr psss€d b|!Wh t\O DGM, v. (s6), aflr $6 glftd orillca, Vo (sts), a|{ be DGtt catbraton f&r, y. llreco equa0one ao &b|nalcaly cahjabd h Ue lpo*he€t above. vmsa., = K,' y^. llgffJ 13-'6) vc1"at= *"'o{'?\lICtnD TI:28 f6. 76 7aco 76.76. 76.16 76.60 74.00 fa.25 1'119! LW. 4.3360 AVGr 0.96E lxsl 0.984 90! g,cz 1.49 1d0 1.49 Llt l.5a 1.il 1.Q L€ 1,8 Silt.l0i ct:t 7at ttiLTSl 8tt.e0! Ett.co3 tc+ota t6a"o6ao 8C3.iar aaa.t9t c7+ti22 E7132il 87e,,46 l-,;l| ''.t. It;IEg | 0..2 | l---;l Eil HI rr.zc I {5931 4.5709 a!320t 1-2979 ,,!!oz ..2e6o 4.3210 4.3112 43084 Avc. 9.991 {,3184 0.999 4.3079 0.999 l.lotc a.99SAvcE g.9gg 0.e86 LZ: 0.995 9€9t b.eeo 0! (2) r Nrt voluma Ef gas rample pa$cd through DGM, coar€cled b standard conditongtq . i7,Af htn. H9 (Engil$), O.3E5E.K,ryr He 0&rdc) T. , Ab.old. DGM ryg. tmp.n0n (h _ Eneil.h, k - Mtt|c) ' volumc of gas rampto peatrd through thc crldcal ortf,ca, comc,tad to at ndrrd condiuonrTd i Ab.oln rnbbnt rfr|psll.r (t - E ,ghr,. a - M.!b) K g AVJICE Kt ctrfon Cilfc.t Orlfic. Ceilb..ton Y =v"u',v^r^ OutoF 32 63 116 32 g2ri ENVIRONMENTAL SUPPLY COMPANY 8:lz83a ulg.00t t3amr qal0{ taS.l0a tat 30t It 71 7a 7t 83 3e 71 tt 71 n ct 73 7:t 7E EO f-lts I l__aql ..3700 l-r* ll.r"l ..!212 | ..ao ll2.trl 1.&u cg ,t 71 79 lo tt 7a 7a 77 t0 70 73 71 70 8t 70 71 f5 7i 7a 70 7a 7a 7E 7l f1 7t 7t n 7A AVERAcE oRY GAs TTETER cALrBRArtoN FAcroR, y : l-6t-l AVERAGE aHn =l-T3dt-l AHqr 1 o.rse'lt ax /y^tgg[\vJerd)/ \ v- / Tampcnfura Sonro]!Rcfomnca lnOF OF(3). DGM c.llbnilon f.clor 32 63 119 Console {14 Calibratlon ( METHOD 5 DRY GAS METER CALIBRATION USING CRITICAL ORIFICES 1) Sel€c-t 'hra€ cdticel orflicar io ceribratc thr dry g' mctcr whrcfi br.ck i rh. .r*€cr.cr opcrarng rangr.2) Rccord b.romcfic prltluo b.,lbr. .nc mrr jiunuon pJr-,3) Run .t torlrd vrcuum (trom Ortfto. C.fibntm R.pon), iii" ai* , orn.noco$ery b .chl.vc a mlnlmum btal rolumc ol S orblc fcct.4) Rc€rd dalE and Iniormeuon ln th. GREET{ calr, YELLOW c.I! rr. cltcuLtrd. DATE: UETER PARTT: IETER SERI{. I: CRlTlcEL OruNCE SET SEruAL r: 2tt-all 296.ala 29t alt tOtJfiIO loL20 totaz amlt/3ta.E8t 31a,tt!lla.Slt 319.tcl s2atE t2t3tm 33o.3t1 rito.t71 335,37a 33t 37a IrlO.SEl! AAROTETRTC PRESIIURE (tn H EQUIPIIENT ID T: at at t3 ff 7A Ct a v 7e 79 tt u It 7t to at tt g,7'8l at a,89 tt a2 tt ta ,o tl t2 FNAI_t*"1 AVG (Pb) 25,t7 IF Y VARIATION EXCEEDS 2.OO!T, ORIFICE SHOULD BE RECruARATED l.|,|rt o.eeq 0.99.1 E'ffi[;l:mFI I, ['-'T;-l l-;lrffiF| | .l.'..T;.l vrlut= *""u{'P al IAmD Y =Y",,*,v^u* t ooa t.001 t.002 t.act !.00a t 00Go a00l 5,003 r,000 71.7t 00.7t 82 It.00 t{.7t E6,2t 86.25 86.76 IEJt /r.t'180 L1253 1.1Ut rlJll! /tlOt8 4.0951 Leo 4.O2 tsl i.63 rd3 l,el t!1 l,!1 1,42 lJ3 l,tt 'Avs. 0.Sg! 4.5885 t.o.tl ..175't 1,011 ,l.ltl6 !4CZ AVG - l.oto ..r.te8 lJ92 aJ,M l.oo2 5J2'4 t99IAvcr lJ0! 4.!I USll{O nE CTTICAL ORTRCES Ag CALlgRA.not gtAlD nDgi The brorin cque0.n. a,r us.d b c.rcurar, t F stsrdsd rcrfirr of et g$s€d tru|gh u|o DGlr, v, (ru), gd ho crlfcdodflor, V. (s6), and he DGM c$.atDn facbr, y, Ihola oqusfms r'r arbmEfE ly cah,lsbd fn Ura spnedd,sot abovo. Yilu't = K, * yn, Pfor + l4!l 113'6)(rl l2l ! Net vorum€ of gar sempt pasrad thrcugh DGM, cofilcbd to standard condi0ons' K, . f 7.A{ hIn. }tg (Eneild,), O.3S5S lgu,rn Hg (Mrf|c} . T, r Abrold. DeM .v9. trnp.rdw (h - Englth. 1< - M.t tc) t volumc of g.r 3empb pa!3ad thEugh lh. oducsl orilic!, comciod to shndard condltonrTd I AbFtut ..nbt nt t.|ryrrrtn fn - ern[$, 1< - f,b!lc] K r Ayrngp K Edorfiqn Cd0cal Ortic. Csllbnuon aH" ('ffi,)"*(ry) Tampcrtture SansoERdcrrncc lnToF OutoF 31 T7 111 31 75 111 30 77 1t3 [.MAL at l9 at 80 8t 0t c0 02 80 8t 0t a2 ot 12 E' +- | + z!o_-l 4.rs6i 4.187s t_ zlo | +rzrtr ,.1!t! I .,.r | | aEo | fi$! ..142aEEffiEfr|''-l t-;t HH H# AVERAGE DRYGAS iIETER CAUARATIOTI FAGTOR, Y T I_1.OOr| Ar/ERAGEAHo=fTEiS-.l (3). DGM c.llbraton faclor Console ll5 Calibration METHOD 5 DRY GAS METER CALIBRATION USING CRITICAL ORIFICES 1) ?',) 3) 4' seloct rhree crilicsr orifices ro c€ribrato tho dry gas mot€r whroh bracket the exp.cted operaling range.Record barometric prcsure boforo and afier cellbrelion procedure, Flun at te€led v€cuum (from Orlfice Catibrailon Report), ior a perlod of limenecossery to echiove a mlnimum total volumo of S oublc feol.Record data snd Informailon in the GREEN c€[e, yELLOW cers sre oarouraled. METER SERIAL * CRITICAT ORIFICE SET SERIAL 'A BAhOMETRIC EqUIPIENT ID * FINALl"iil AVO (Pbrl 25.70 IF Y VARIATION EXCEEDS 2.OO%. ORIFICE SHOULD BE RECALTARATED ffi ffi ffi ;t:sgg*i ::: {sl6t:: I..a3092:! ii#l+.. ,:X#,,lg:sdzc,' .l:S,?0?i , : lr;0o3 .{#ii.,..l.,.'.'.: lil{12 ::.: : : I . ' ', : :,t:007 ffirffiil [..=lE#l Hffil:::::0re :'l .42;45!l l+ll.asili AVG r i,oii7 r;i:r.::,: 'l:001: -:0.999,' :1-005 i: oAa : ,{1.{:t, ' AVGg . r:::i602 _::,::t.,:i :: t:::.:::::i .:: _.: :-,,;!g':, W , 'slez '4:2P :fAXs' "o.isr ,:44pir, , ll!e{ , tssl AvG ' o'ii8 ,$.0?l (11 (2',t u 66 120 Out oF u 66 120 ENVIRONMENTAL SUPPLY COMPANY ffiHtfrlillffilffit { i,,,i.il l :ogrit::t ir' 'l ffi. ii*trilr ffiiiffil ffiffi ffilil'*fr* ffiri'$fii'i ffi:,,90.If r,, biloe r:ir1i75 ::::,.:::t:i il:!l!i-oo irr r'diiie vm,-.^ = K, "vm'PbE+(NI /13'6) IM vs<,a>= *'t'u3-'tP ^t I cmb f =v"roo'Ymod, 1 2 3 1 2 3 USING THE CRITICAL ORTFICES AS CALIBRATION STANDARDS: The fobwing equatiNs eg usod to c€buHs tirre stildrd rclrFs ol tir passed h]u:gh ua DGtvl, v. (sld), rd t|e critbalo.ifio6,vo (std), ''d the oGM cslbralbn f*tor, y. Th6ss squstbns sB anomaticaly csbubled in fu spr.ad$Fat sbcryo. E Net volume of gas sample passed through DGM, con€cted lo slandard conditions K, = 17.64 "R/in. H9 Gngtish), O.gS58 1(rmm Hg (Uetdc) T. = Absotute DGM a\tr. tEmpersture CR - Engtish, oK _ M6t ic) r volums of gas sample pass€d through tha cdilcal orttice, correc,ted to slandard condilionsTo = Absolub ambient tomperatun fR - Engilsh, oK - Metic) K = Awrage K factor trom Cdtcal Orifics Catibration AVERAGE DRy GAs ME'ER .ALTBRAT.N FACroR, y = |rildfrtl AVEMGEAH"= AHj= ( o.zoe 1'? aH /V_l$l)\v.,{std)/, \ v- / Temperature SensorsRetcrence lnOF oF 33 67 121 (3)= DGM callbrallon facior Console 116 Calibration Type S Pitot Tube Inspection Data - : .: PilotTitbc ldafincation: Z7,;^"r*,.0,-rOIW\t .l 4= -Z5o in. P^= 53? io. Is Pe:Ps ? ;tIsl.05.qSq<l.50.Drt y' ' tt1'< l0o ot =' -t Yr- =j4 in. z Fr= z= .Ql D n. g W30.03125 in.w: - oo3 tn. The pitot tubc meets lhe specifications for a calibration factor of0.g4? cr2 < l0o : 0rS5o z I #z P2<5"9z= Z<O.l25ir.. .: .PitotTirbcldcntification: 21 - Z -ra'h .LJwirL--....:...: P1= 3 .tro in Pg= .)f,O iD. . Is Pa=Pe? Is 1.05.Q< q< l.50.Dt? c1'< l0o a2 < l0o 9rS5o c1 =' J 'o / H- W3 0.03125 ilr.w= .oL3 n Thc pitor tubc mccf.thc spccifcatiors for a catibratioo frctor of 0.g4? J _ 2_o 'Fr=Oo l Fr<5o z 230.125ir.. R-r z=-- 'o)(in' Ypz Type S PitotTube&rspectiofr Data i : Pitot Tubc ldcntification: f,-7 - 6 'rc*niciaa: K.a -{^-, Gort q= , J7r in. c-r=l''8: loDr - I Fr- O, ' m. $i/= db 'Thc pitot. tube mcefs thc gpccifications for a calibrarion faao r of O.UI / n^= ,!4[ n Pa = '.'14 | Is Pa=Ps ? Is 1.05 : D, < D, < l-50 ,Dr? r/ d1 < tOo dr=' .O o ,at 1 l0o ''.i Fr35o .Fr < 5e z:.o33 -€,", H- crl<ld c2 < I0o A 2aoPI -.J I a 2ao Ws0.03l5iD. ."'' W= The pitot tubc mccts thc st*cificatiou for a crlibrarion fraor of 0.t4? . >(-\DrE 7u u in. ra- JS-e/ in. . p"= ]f4. ;r,. Is P^=P"7' ,/ Is I.05.4 S D, S l:50.4 ?-- - orE' '.2 'o .t o R:- 2 . ola_- ;. 0 Datc:q lZ-z? -or Q (rv I Dr=- Z Sn h. Ps= Is P^=P"7' t/t.os'q<Dr3r,so.qrl ra- 3 f,y' in 3r-q i" l*ar=' I ' g o,'tO' o1 < l0' ,,' ._, FrSf F: i5o si= w= .4t2 in \lo j F; 1-Z Zs0.125in. W 3 O03125 iD. Thgpitottubcmcctsthcspocifrcrtiors foracalibration facforofil.8 4? r./ Refcrcnce: Datc:q tz-?-z -oS- g ; . 'rirotruu"td*tifi..rioo: ld- E I I \ c; < l0o t Fl35o Frtf Zs0.l2Sin |. Ws0.03125io. " fu= Thc pitot tubc mcets thc spccifications for a crribntion factor of0.g4? 0r= g; .l o z; .O O'l i- i m. D,= ,37t i,. e"= .1177 ea- .</.27 tn. lIL . Is Pe=pa ? VJIs I.05.qS D,< t.50..D.? { 'or=-. './ 'o ar=Oo al o.. v Sarple Box Temperature Sensor Calibration I \ l \ r Oomplote iterm 1, 2, and3, Also complete it6m 4 fi ResHcted Deltvery is deslr€d..r Prfntyou,r na4e and addrcss on the rwersd ;so tha! wB. can r€tm the candto you,r Atactr thts card to tbe back of tho mdlpleL€, orontro tontf sPace Perrn'tts. l. ArtHeAddassed to: tr Ag€nt C. Dato of t)61tu€ry gt tr Yes ,8, Ho Elnwrca l Eo.o.o. 4. R€sfrfcisdD€lh,€ty? @ta Fa)EYes 7;4t*J Spatt ul--h b*Q PrD . tsoX tlttlSzo 4"t t tKc G(y W ^f.iltt4 - 482o \ I 3".S€rvlc6Typo Fc€fiifl6d Mall tr EarssMall E negntersO tl Rettnh€c€lptforMdtrttar.tdho -2. Ardch l{trl$€t sa 0bo.@€, Ps Fonn '1., Febrr,rary 9on€sdoR€tm.R€peFt 102595'o2-DFlerc | ?00,*-ff 5E- noo:,-zzu10oas? I I