ASTM D4084-2007(2012) Standard Test Method for Analysis of Hydrogen Sulfide in Gaseous Fuels (Lead Acetate Reaction Rate Method)《气体燃料中硫化氢分析的标准试验方法(醋酸铅反应速率法)》.pdf

1、Designation: D4084 07 (Reapproved 2012)Standard Test Method forAnalysis of Hydrogen Sulfide in Gaseous Fuels (LeadAcetate Reaction Rate Method)1This standard is issued under the fixed designation D4084; the number immediately following the designation indicates the year oforiginal adoption or, in th

2、e case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.1. Scope1.1 This test method covers the determination of hydrogensulfide (H2S) in gaseous fuels. I

3、t is applicable to the measure-ment of H2S in natural gas, liquefied petroleum gas (LPG),substitute natural gas, landfill gas, sewage treatment off gasses,recycle gas, flare gasses, and mixtures of fuel gases. Thismethod can also be used to measure the hydrogen sulfideconcentration in carbon dioxide

4、. Air does not interfere. Theapplicable range is 0.1 to 16 parts per million by volume(ppm/v) (approximately 0.1 to 22 mg/m3) and may be extendedto 100 % H2S by manual or automatic volumetric dilution.1.2 This standard does not purport to address all of thesafety concerns, if any, associated with it

5、s use. It is theresponsibility of the user of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use.2. Referenced Documents2.1 ASTM Standards:2D1193 Specification for Reagent WaterD1914 Practice for Conversion Unit

6、s and Factors Relating toSampling and Analysis of AtmospheresD2420 Test Method for Hydrogen Sulfide in LiquefiedPetroleum (LP) Gases (Lead Acetate Method)D3609 Practice for Calibration Techniques Using Perme-ation TubesD7166 Practice for Total Sulfur Analyzer Based On-line/At-line for Sulfur Content

7、 of Gaseous FuelsE2165 Practice for Establishing an Uncertainty Budget forthe Chemical Analysis of Metals, Ores, and RelatedMaterials (Withdrawn 2007)33. Summary of Test Method3.1 Measurement of H2S is accomplished by ratiometricallycomparing a reading of an unknown sample with that of aknown standa

8、rd using a differential colorimetric detection.Pure H2S is used as a primary standard and mixed volumetri-cally with a sulfur free matrix gas that is ideally similar incomposition to the sample gas. A gaseous sample at constantflow is humidified and passed over lead-acetate-impregnatedpaper. H2S rea

9、cts with lead acetate to form a brown stain on thepaper. The rate of reaction and resulting rate of color change isproportional to the concentration of H2S in the sample. Theanalyzer is comprised of an optical system, a photon detectionsystem, a signal differentiation system of first order, and asig

10、nal output system. When there is no change in the color ofthe tape, and no resulting change in photodetector output, E,the first derivative, dE/dt, is zero. This results in an analyzerthat automatically zeroes when there is no H2S.4. Significance and Use4.1 This test method is useful in determining

11、the concentra-tion of hydrogen sulfide in gaseous samples and in verifyingcompliance with operational needs and/or environmental limi-tations for H2S content. The automated performance operationof this method allows unattended measurement of H2S con-centration. The user is referred to Practice D7166

12、 for unat-tended on-line use of instrumentation based upon the leadacetate reaction rate method.5. Apparatus5.1 Volumetric Measuring DevicesA graduated 10-L cyl-inder (see Fig. 1) having a movable piston for volumetricallymeasuring test gas. Gastight syringes of 0.1 and 0.5-mLvolume for volumetrical

13、ly measuring 100 % H2S. Gas tightsyringes of other volumes can be used. These graduateddevices are not needed when the permeation tube method ofdynamic mixing is used to prepare the reference sample sincethis method will generate a reference mixture.5.2 Sample PumpA pump capable of providing more th

14、an8 mL/s (approximately 1 ft3/h) or less than 1 mL/s at 70 kPa(approximately 10.15 psig). Gas-wetted parts are ideally con-structed from either aluminum or polytetrafluorethylene1This test method is under the jurisdiction ofASTM Committee D03 on GaseousFuels and is the direct responsibility of Subco

15、mmittee D03.05 on Determination ofSpecial Constituents of Gaseous Fuels.Current edition approved Nov. 1, 2012. Published December 2012. Originallyapproved in 1981. Last previous edition approved in 2007 as D4084 07. DOI:10.1520/D4084-07R12.2For referenced ASTM standards, visit the ASTM website, www.

16、astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume information, refer to the standards Document Summary page onthe ASTM website.3The last approved version of this historical standard is referenced onwww.astm.org.Copyright ASTM International, 100 Bar

17、r Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States1(PTFE). Stainless steel may be used when higher safety thanafforded by aluminum or PTFE is required.5.3 Colorimetric Rate of Reaction SensorSelect a deviceof sufficient sensitivity to measure a minimum rate of changeof colo

18、r density corresponding to 0.1-ppm H2S by volume inthe sample gas. (See Fig. 2.)5.4 Recorder, having an adjustable span of 1 to 10-V fullscale with an input impedance of 1 M or higher. A printer orother output means, such as a data logger or DistributedControl System (DCS) , can be used.6. Reagents

19、and MaterialsNOTE 1Warning: Hydrogen Sulfide contained in lecture bottles,permeation tubes or compressed gas cylinders may be flammable andharmful or fatal if ingested or inhaled. Lecture bottles, permeation tubesand compressed gas standards should only be handled in well ventilatedlocations away fr

20、om sparks and flames. Improper handling of compressedgas cylinders containing air, nitrogen or hydrocarbons can result inexplosion. Rapid release of nitrogen or hydrocarbon gasses can result inasphyxiation. Compressed air supports combustion.6.1 Acetic Acid SolutionAdd 50 mL of glacial acid(CH3COOH)

21、 to distilled water or dionized water to make 1 LFIG. 1 Calibration Sample Preparation Cylinder withMovable PistonFIG. 2 Flow System for H2S Measurement Showing Calibration, LPG, and Gaseous Sample ConnectionsD4084 07 (2012)2of solution (5 %). Type II distilled water as specified inSpecification D11

22、93 is satisfactory for the dilution. Waterdionized to 1 megaohm-centimeter is also satisfactory for thedilution.6.2 Reference Gas:6.2.1 Hydrogen Sulfide Source99.5 % by volume purity orbetter. An alternative H2S source is an H2S mixture obtainedusing permeation tube procedures. Hydrogen sulfide gene

23、ratedfrom a solid heated to generate H2S may be used instead of aH2S source if desired. H2S contained in permeation tubes orcompressed gas cylinders may be flammable and harmful orfatal if ingested or inhaled. Permeation tubes and compressedgas standards should only be handled in well ventilatedloca

24、tions away from sparks and flames. (WarningHydrogensulfide is an extremely toxic gas.)6.2.2 Dilution GasesChemically pure grade or purifiedgas. Blend or obtain a sulfur-free gas of the same relativedensity as the sample gas to be analyzed. Blends of gases, ofsimilar composition to the sample gas, ar

25、e prepared from puregases by mixing, using a 10-L cylinder with piston. Pipelinegas scrubbed through activated charcoal and sodiumhydroxide-asbestos absorbent is satisfactory.6.2.3 Gas MixturesAnother alternative H2S source is acertified H2S mixture obtained from a gas standard vendor.Such mixtures

26、are in a sulfur free carrier gas that is of the sametype, or a close approximation, as the gas to be analyzed. Thesemixtures can be either a primary standard, which is then dilutedto the desired H2S concentration using a 10-L cylinder with apiston, or a standard in a pressurized cylinder containing

27、thedesired H2S concentration. Because of the potential fordegradation, H2S mixtures obtained from a gas standardvendor must be properly stored and used only within the statedcertification period. In the event of a discrepancy, H2S mixturesprepared from a 99.5 % by volume or better purity H2S lecture

28、bottle or obtained using permeation tube procedures must beused.6.2.3.1 Compressed Gas StandardsThe protocol for com-pressed gas standards contained in the appendix can be used toensure uniformity in compressed gas standard manufacture andprovide for traceability to a NIST or NMi reference material.

29、6.2.3.2 Compressed gas standard regulators must be appro-priate for the delivery of sulfur gases and attached fittings mustbe passivated or inert to sulfur gases.6.3 Lead Acetate Sensing PaperPrepare in accordancewith Test Method D2420, using appropriate size strips anddrying in an H2S-free environm

30、ent. Commercially availabletest paper has been found satisfactory. Used Lead AcetateSensing Paper should be disposed of in accordance with local,state, and/or federal environmental regulations.6.4 Permeation DevicesHydrogen Sulfide standards canbe prepared using a permeation tube gravimetrically cal

31、ibratedand certified at a convenient operating temperature.At constanttemperature, calibration gases covering a wide range of con-centration can be generated by varying and accurately measur-ing the flow rate of diluent gas passing over the tubes. Thesecalibration gases are used to calibrate the ana

32、lyzer.6.4.1 Permeation System Temperature ControlPermeationdevices are maintained at the calibration temperature within0.1C.6.4.2 Permeation System Flow ControlThe permeationflow system measures diluent gas flow over the permeationtubes within 62 percent.6.4.3 Permeation tubes are inspected and weig

33、hed to thenearest 0.01 mg on at least a monthly basis using a balancecalibrated against NIST traceable “S” class weights or theequivalent. Analyte concentration is calculated by weight lossand dilution gas flow rate as per Practice D3609. These devicesare discarded when the liquid contents are reduc

34、ed to less thanten (10) percent of the initial volume or when the permeationsurface is unusually discolored or otherwise compromised.Used permeation tubes should be disposed of in accordancewith local, state, and/or federal environmental regulations.7. Sampling7.1 Because of the chemical activity an

35、d adsorptive proper-ties of H2S, it is highly desirable to connect the test apparatusdirectly to the sample source using minimum lengths ofstainless steel, hastalloy, aluminum or fluorocarbon samplelines. Do not use copper containing, that is, brass or copperflow system parts. In the event that dire

36、ct sampling is notpractical, clean aluminum, stainless steel, or fluorocarbon linedsample containers may be used. Tedlar bags with inert fittingssuch as polypropylene or equivalent and silica lined samplecontainers can also be used for sample collection. Tedlar bagscontaining sample require protecti

37、on from light and heat. Thecollection of samples that are either in two phases or that willform two phases before analysis can be performed must beavoided. The presence of liquids causes H2S to partitionunequally between the liquid and gas phases. Such a partitionof H2S results in inaccurate measure

38、ment of H2S content.Samples must be analyzed with as little delay as possible andreported as “proximate analyses from cylinders” with length ofresidence time noted. Because of the broad reactivity of H2S,an extended delay between obtaining the sample and analyzingthe sample can result in inaccurate

39、results.NOTE 2Each new sample container to be used for a test specimen canbe filled with a sample and analyzed over a period of time and theresulting data examined to determine the rate of deterioration of thesample. Repeated filling with a representative sample will tend topassivate a container. Ap

40、proximately 10 L (approximately13 ft3)ofsample, at atmospheric pressure, is convenient for analysis and willnormally not deteriorate appreciably within 1 h. Slow instrument responseto changes in H2S concentration indicates the need for a thorough cleaningof the flow system. (See Appendix X1 for a su

41、ggested cleaning proce-dure.) Errors caused by ambient temperature and pressure changes arecompensated for by comparison to a reference standard prepared at thetime of analysis. Preparation of the reference sample is described inSection 11.8. Instrument Preparation8.1 Fill a humidifier or humidifyin

42、g bubbler to the full markwith acetic acid solution. The acetic acid minimizes someinterfering species. Set the range of the analyzer for the rangeexpected in the sample. Connect the pump and set theflowmeter for a nominal flow of 8 mL/s (approximately 1ft3/h). Note: analyte gas can also be delivere

43、d to the analyzerby use of a compressed gas cylinder or a permeation tubeD4084 07 (2012)3device.Alternative flow settings, such as a nominal 1 mL/s, canbe used. Obtain a blank reading by flowing dilution gasthrough the analyzer. Record the reading of the blank sample asB in 12.1. Do not adjust the i

44、nstrument zero until verificationis obtained, that the room air or the carrier gas does not containH2S. Verification is accomplished by analyzing a room air orcarrier gas sample after it has been passed through an activatedcharcoal filter absorbent.9. Calibration9.1 Immediately after preparing the c

45、alibration standard,obtain its response on the analyzer. Practice D3609 is accept-able as an alternative method for preparation of a referencestandard. Certified compressed gas calibration standards ob-tained from a gas standard vendor can also be used to calibratethe analyzer. The analyzer response

46、 is recorded as C in 12.1.Atleast twenty (20) discrete response replicates should be ob-tained to adequately demonstrate the statistical repeatability ofthe analyzer at two times the standard deviations about themean. If the analyzer repeatability response fall outside of thepublished repeatability

47、specifications then appropriate correc-tive action must be taken and the repeatability response of theanalyzer must be redetermined.10. Sample Measurement Procedure10.1 Sampling and Preparation of SamplesAppropriatesampling procedures are critical for meaningful hydrogensulfide determinations and mu

48、st be tailored to the particularsample source.10.1.1 SamplesSamples are delivered to the laboratory inTedlar bags with polypropylene fittings or other inert fittings atatmospheric pressure, protected from heat and light. Samplesare normally analyzed within 24 h of sampling to ensureaccurate measurem

49、ent of hydrogen sulfide in the sample. Theholding time can be extended to the limits of existing datawhen hydrogen sulfide gas retention in a specific matrix isavailable.Alternatively, samples are delivered to the laboratoryin passivated/lined vessels demonstrated to not demonstratesignificant hydrogen sulfide losses in samples over 24 h. Aspart of a QA/QC program, passivated or lined vessels shouldperiodically be examined for continued hydrogen sulfide gasstability and acceptable sample carryover characteristics. Pas-sivated or lined vessels may allow for reli