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本文(ASTM E537-2007 317 Standard Test Method for The Thermal Stability Of Chemicals By Differential Scanning Calorimetry《用差式扫描量热法测定化学制品热稳定性的标准试验方法》.pdf)为本站会员(李朗)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

ASTM E537-2007 317 Standard Test Method for The Thermal Stability Of Chemicals By Differential Scanning Calorimetry《用差式扫描量热法测定化学制品热稳定性的标准试验方法》.pdf

1、Designation: E 537 07Standard Test Method forThe Thermal Stability Of Chemicals By Differential ScanningCalorimetry1This standard is issued under the fixed designation E 537; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revision, the year

2、 of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon (e) indicates an editorial change since the last revision or reapproval.INTRODUCTIONCommittee E-27 is currently engaged in developing methods to determine the hazard potential ofchemicals. An estim

3、ate of this potential may usually be obtained by the use of program CHETAH 7.0to compute the maximum energy of reaction of the chemical or mixture of chemicals.2The expression “hazard potential” as used by this committee is defined as the degree ofsusceptibility of material to ignition or release of

4、 energy under varying environmental conditions.The primary purpose of this test method is to detect enthalpic changes and to approximate thetemperature of initiation and enthalpies (heats) of these events. Differential scanning calorimetry offersthe advantage of using very small specimens on the ord

5、er of a few milligrams.1. Scope1.1 This test method describes the ascertainment of thepresence of enthalpic changes in a test specimen, usingminimum quantities of material, approximates the temperatureat which these enthalpic changes occur and determines theirenthalpies (heats) using differential sc

6、anning calorimetry orpressure differential scanning calorimetry.1.2 This test method may be performed on solids, liquids, orslurries.1.3 This test method may be performed in an inert or areactive atmosphere with an absolute pressure range from 100Pa through 7 MPa and over a temperature range from 30

7、0 to800 K (27 to 527 C ).1.4 SI values are the standard.1.5 There is no ISO standard equivalent to this test method.1.6 This standard may involve hazardous materials, opera-tions, and equipment. This standard does not purport toaddress all of the safety concerns associated with its use. It isthe res

8、ponsibility of the user of this standard to establishappropriate safety and health practices and determine theapplicability of regulatory limitations prior to use. Specificsafety precautions are given in Section 8.2. Referenced Documents2.1 ASTM Standards:3E 473 Terminology Relating to Thermal Analy

9、sis and Rhe-ologyE 691 Practice for Conducting an Interlaboratory Study toDetermine the Precision of a Test MethodE 967 Test Method for Temperature Calibration of Differ-ential Scanning Calorimeters and Differential ThermalAnalyzersE 968 Practice for Heat Flow Calibration of DifferentialScanning Cal

10、orimetersE 1445 Terminology Relating to Hazard Potential ofChemicalsE 1860 Test Method for Elapsed Time Calibration of Ther-mal Analyzers3. Terminology3.1 Definitions:3.1.1 Specific technical terms used in this standard aredefined in Terminologies E 473 and E 1445.3.2 Definitions of Terms Specific t

11、o This Standard:3.2.1 DSC curvea record of a differential scanning calo-rimeter where the change in heat flow (Dq) is plotted on theordinate and temperature or time is plotted on the abscissa (seeFigs. 1 and 2 and Terminology E 473).1This test method is under the jurisdiction of ASTM Committee E27 o

12、n HazardPotential of Chemicals and is the direct responsibility of Subcommittee E27.02 onThermal Stability and Condensed Phases.Current edition approved Oct. 1, 2007. Published October 2007. Originallyapproved in 1976. Last previous edition approved in 2002 as E 537 02.2A complete assessment of the

13、hazard potential of chemicals must take intoaccount a number of realistic factors not considered in this test method or theCHETAH program.3For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume

14、information, refer to the standards Document Summary page onthe ASTM website.1Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.FIG. 1 Typical DSC Curve with ExothermE537072FIG. 2 DSC Curve Illustrating a Melting Process Immediately Fol

15、lowed by an Exothermic DecompositionE5370733.2.2 peakthat portion of a thermal curve that is attribut-able to the occurrence of a single process. It is normallycharacterized by a deviation from the established baseline, amaximum deflection, and a reestablishment of a baseline notnecessarily identica

16、l to that before the peak (see Fig. 1).NOTE 1There will be instances when upon scanning in temperaturean endotherm will be observed that is immediately followed by or is inconjunction with an exotherm as shown in Fig. 2. These types ofcompeting reactions make it difficult and at times impossible to

17、locate thetrue peak and onset temperatures.3.2.3 peak temperature (Tp)the temperature correspond-ing to the maximum deflection of the DSC curve.3.2.4 onset temperature (To)the temperature at which adeflection from the established baseline is first observed.3.2.5 extrapolated onset temperature (Te)em

18、pirically, thetemperature found by extrapolating the baseline (prior to thepeak) and the tangent at the inflection point on the leading sideof the peak to their intersection (see Fig. 1).3.2.6 reactionany transformation of material accompa-nied by a change of enthalpy that may be endothermic orexoth

19、ermic.3.2.7 thermal stabilitythe absence of a reaction (for thepurposes of this test method only, see 3.2.6).4. Summary of Test Method4.1 In DSC, a measurement is made of the heat flow (Dq)associated with the observed change of enthalpy. Provisionsare made to measure the absolute temperature (T) of

20、the sampleor reference or the average temperature of both.4.2 A sample of the material to be examined and of athermally inert reference material are placed in separateholders.4.3 The sample and reference materials are simultaneouslyheated at a controlled rate of 2 to 20 C/min under anequilibrated at

21、mosphere. A record of Dq on the ordinate ismade as a function of temperature (T) on the abscissa.4.4 When the sample undergoes a transition involving achange of enthalpy, that change is indicated by a departurefrom the initially established baseline of the heat flow record.4.5 The onset temperature

22、(To), extrapolated onset tempera-ture (Te), and the integrated peak area (enthalpy) are deter-mined and reported.5. Significance and Use5.1 This test method is useful in detecting potentiallyhazardous reactions including those from volatile chemicalsand in estimating the temperatures at which these

23、reactionsoccur and their enthalpies (heats). This test method is recom-mended as an early test for detecting the thermal hazards of anuncharacterized chemical substance or mixture (see Section 8).5.2 The magnitude of the change of enthalpy may notnecessarily denote the relative hazard in a particula

24、r applica-tion. For example, certain exothermic reactions are oftenaccompanied by gas evolution that increases the potentialhazard. Alternatively, the extent of energy release for certainexothermic reactions may differ widely with the extent ofconfinement of volatile products. Thus, the presence of

25、anexotherm and its approximate temperature are the most signifi-cant criteria in this test method (see Section 3 and Fig. 1).5.3 When volatile substances are being studied, it is impor-tant to perform this test with a confining pressurized atmo-sphere so that changes of enthalpy that can occur above

26、 normalboiling or sublimation points may be detected. As an example,an absolute pressure of 1.14 MPa (150 psig) will generallyelevate the boiling point of a volatile organic substance 100 C.Under these conditions exothermic decomposition is oftenobserved.5.4 For some substances the rate of enthalpy

27、change duringan exothermic reaction may be small at normal atmosphericpressure, making an assessment of the temperature of instabil-ity difficult. Generally a repeated analysis at an elevatedpressure will improve the assessment by increasing the rate ofchange of enthalpy.NOTE 2The choice of pressure

28、 may sometimes be estimated by thepressure of the application to which the material is exposed.5.5 The four significant criteria of this test method are: thedetection of a change of enthalpy; the approximate temperatureat which the event occurs; the estimation of its enthalpy and theobservance of ef

29、fects due to the cell atmosphere and pressure.6. Limitations6.1 A host of environmental factors affect the existence,magnitude, and temperature of an exothermic reaction. Some,including heating rate, instrument sensitivity, degree of con-finement, and atmosphere reactivity, will affect the detectabi

30、l-ity of an exothermic reaction using this procedure. Therefore,it is imperative that the qualitative results obtained from theapplication of this test method be viewed only as an indicationof the thermal stability of a chemical.7. Apparatus7.1 The equipment used in this test method shall be capable

31、of displaying changes of enthalpy as a function of temperature(T), and shall have the capability of subjecting the sample cellto different atmospheres of equilibrated pressures.7.2 Differential Scanning Calorimeter (DSC)the essentialinstrumentation required to provide the minimum differentialscannin

32、g calorimetric capability for this test method include:7.2.1 A test chamber composed of:7.2.1.1 Furnace(s), to provide uniform controlled heating ofa specimen and reference to a constant temperature or at aconstant rate within the applicable temperature range of thismethod,7.2.1.2 Temperature sensor

33、, to provide an indication of thespecimen/furnace temperature to 60.5 K,7.2.1.3 Differential sensor, to detect a temperature or heatflow difference between the specimen and reference equivalentto 0.2 mW,7.2.1.4 Means of sustaining a test chamber environment ofinert (for example, nitrogen, helium or

34、argon) or reactive (forexample, air) gas at a purge rate of 50 6 5 mL/min,NOTE 3Typically, at least 99 % pure nitrogen, argon or helium isemployed when oxidation in air is a concern. Unless effects of moistureare to be studied, use of dry purge gas is recommended and is essential foroperation at sub

35、ambient temperatures.NOTE 4Other purge gas rates may be used but shall be reported.E5370747.2.1.5 Temperature controller, capable of executing a spe-cific temperature program by operating the furnace(s) betweenselected temperature limits (ambient temperature to 800 K) ata rate of temperature change

36、of from 2 to 20 K/min constant to60.1 K/min, andNOTE 5The temperature range of the apparatus and the experimentmay be extended to 120 K with the use of appropriate cooling or to 1273K or greater with suitable apparatus.7.2.1.6 Recording device, either digital or analog, capable ofrecording and displ

37、aying any portion of the differential heatflow on the ordinate as a function of temperature on theabscissa, including the signal noise.7.2.2 If experiments are to be carried out under pressureconditions:7.2.2.1 Pressure vessel, or similar means of sealing the testchamber at any applied pressure with

38、in 0.10 to 1.27 MPa (0 to170 psig) pressure limits required by this test method,7.2.2.2 Pressurized gas source, capable of sustaining aregulated gas pressure in the test chamber between 0.10 and1.27 MPa (0 and 170 psig),7.2.2.3 Pressure transducer, or similar device to measurethe pressure inside the

39、 test chamber to 65 % including anytemperature dependence of the transducer,7.2.2.4 Pressure regulator, or similar device to adjust theapplied pressure in the test chamber to 65 % of the desiredvalue,7.2.2.5 Ballast, or similar means to maintain the appliedpressure in the test chamber constant to 65

40、%,7.2.2.6 Valves, to control pressurizing gas in the test cham-ber or to isolate components of the pressure system, or both.7.2.3 If subambient temperatures are desired:7.2.3.1 Cooling system, to hasten cool down from elevatedtemperatures and to sustain an isothermal subambient tempera-ture.7.3 Cont

41、ainers, (pans, crucibles, vials, etc.) which are inertto the specimen and reference materials and which are ofsuitable structural shape and integrity to contain the specimenand reference in accordance with the specific requirements ofthis method.7.4 Balance, with a capacity of 100 mg or greater to w

42、eighspecimens or containers, or both, to a sensitivity of 6 10 g.8. Safety Precautions8.1 The use of this test method as an initial test for materialwhose potential hazards are unknown requires that precautionsbe taken during the sample preparation and testing.8.2 Where particle size reduction by gr

43、inding is necessary,the user of the test method should presume that the material issensitive to stimuli such as friction and electrostatic discharge.Accordingly, appropriate test shall be conducted on thosematerials prior to grinding. Use of suitable protective equip-ment is always recommended when

44、preparing materials ofunknown hazard. If a Material Safety Data Sheet is available,it shall be acquired and studied prior to handling unknownmaterials.8.3 The use of this test method may require operation atelevated temperatures and pressures.All precautions associatedwith such temperatures and pres

45、sures should be observed.8.4 Toxic or corrosive effluents, or both, may be releasedwhen heating the material and could be harmful to thepersonnel or the apparatus. Use of an exhaust system to removesuch effluents is recommended.9. Calibration9.1 Perform any calibration procedures recommended bythe a

46、pparatus manufacturer as described in the Operatorsmanual.9.2 Calibrate the temperature signal within 6 2 C usingPractice E 967.9.3 Calibrate the heat flow signal within 61 % using TestMethod E 968.9.4 Calibrate the time signal within 60.5 % using TestMethod E 1860.10. Sample and Reference Materials

47、10.1 The selection of an adequate sample size will dependupon the availability of the material, the degree of dilutionrequired, the sensitivity of the instrument, the magnitude of thechange of enthalpy, and the heating rate. Additionally, samplesize must be compatible with the potential for a sudden

48、 largeenergy release. This test method should, therefore, be carriedout on as small a quantity of material as possible, typically 1 to50 mg.10.2 Samples should be representative of the material beingstudied including particle size and purity.10.3 The reference material must not undergo any thermaltr

49、ansformation over the temperature range under study. Typicalreference materials include calcined aluminum oxide, glassbeads, silicone oil, or an empty container.11. Recommended Conditions of Tests11.1 Specimen Size A 5-mg specimen is generally consid-ered adequate. Decrease the specimen size if the response isgreater than 8 mW.NOTE 6For materials whose characteristics are unknown, it is safestto start with a specimen size of no more than 1 mg, and then increase thesize if the exothermic response is insufficiently large.11.2 Heating RateArate of 10 to 20 C/min

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