ASTM D7895 D7895M-2014 9765 Standard Test Method for Thermal Endurance of Coating Powders Used for Powder Coating Insulation Systems《用于粉末涂覆绝缘系统的涂覆粉末耐热性的标准试验方法》.pdf

1、Designation: D7895/D7895M 14Standard Test Method forThermal Endurance of Coating Powders Used for PowderCoating Insulation Systems1This standard is issued under the fixed designation D7895/D7895M; the number immediately following the designation indicates theyear of original adoption or, in the case

2、 of revision, the year of last revision. A number in parentheses indicates the year of lastreapproval. A superscript epsilon () indicates an editorial change since the last revision or reapproval.1. Scope1.1 This test method provides a procedure for evaluatingthermal endurance of coating powders by

3、determining thelength of aging time at selected elevated temperatures requiredto achieve dielectric breakdown at room temperature at apre-determined proof voltage. Thermal endurance is expressedin terms of a temperature index.1.2 This test method is applicable to insulating powdersused over a substr

4、ate material of steel.1.3 UnitsThe values stated in either SI units or inch-pound units are to be regarded separately as standard. Thevalues stated in each system are not necessarily exact equiva-lents; therefore, each system shall be used independently of theother. Combining values from the two sys

5、tems is likely toresult in non-conformance with the standard.1.4 This standard does not purport to address all of thesafety concerns, if any, associated with its use. It is theresponsibility of the user of this standard to establish appro-priate safety and health practices and determine the applica-

6、bility of regulatory limitations prior to use. Specific precau-tionary statements are given in Section 7.2. Referenced Documents2.1 ASTM Standards:2D149 Test Method for Dielectric Breakdown Voltage andDielectric Strength of Solid Electrical Insulating Materialsat Commercial Power FrequenciesD1711 Te

7、rminology Relating to Electrical InsulationD5423 Specification for Forced-Convection Laboratory Ov-ens for Evaluation of Electrical Insulation2.2 IEEE Document3IEEE 101A Simplified Method for Calculation of the Re-gression Line3. Terminology3.1 DefinitionsFor definitions of terms used in this testme

8、thod refer to Terminology D1711.4. Summary of Test Method4.1 Specimens are aged in air at a minimum of threetemperatures above the expected use temperature of the mate-rial. Exposure to ambient stress conditions, followed bydielectric proof voltage tests in an electrically conductivesolution, are pe

9、riodically conducted to determine the time ofaging at each elevated temperature required to reduce thebreakdown voltage to a preselected percentage of the originalbreakdown value. These thermal life values are used toconstruct a thermal endurance graph by means of which it ispossible to estimate a t

10、emperature index, corresponding to athermal life as specified in the material specification or asagreed upon between the user and the supplier. It is possiblethat a material will have multiple indices, each correspondingto a different thermal life as required by a given application.5. Significance a

11、nd Use5.1 Amajor factor affecting the life of insulating materials isthermal degradation. It is possible that other factors, such asmoisture and vibration, will cause failures after the materialhas been weakened by thermal degradation.5.2 Electrical insulation is effective in electrical equipmentonl

12、y as long as it retains its physical and electrical integrity.The following are potential indicators of thermal degradation:weight change, porosity, crazing, and generally a reduction inflexibility. Thermal degradation is usually accompanied by anultimate reduction in dielectric breakdown.5.3 This t

13、est method is useful in determining the thermalendurance of coating powders applied over a steel substratematerial.1This test method is under the jurisdiction of ASTM Committee D09 onElectrical and Electronic Insulating Materials and is the direct responsibility ofSubcommittee D09.01 on Electrical I

14、nsulating Varnishes, Powders and Encapsulat-ing Compounds.Current edition approved Nov. 1, 2014. Published November 2014. DOI:10.1520/D7895_D7895M-14.2For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStand

15、ards volume information, refer to the standards Document Summary page onthe ASTM website.3Available from Institute of Electrical and Electronics Engineers, Inc. (IEEE),445 Hoes Ln., P.O. Box 1331, Piscataway, NJ 08854-1331, http:/www.ieee.org.Copyright ASTM International, 100 Barr Harbor Drive, PO B

16、ox C700, West Conshohocken, PA 19428-2959. United States16. Apparatus6.1 Dielectric Breakdown Test SetThe set shall meet therequirements of Test Method D149.6.2 OvensOvens shall meet the requirements of Specifi-cation D5423, Type I.6.3 Electrically Conductive Solution:6.3.1 An appropriate container

17、shall be selected for theelectrically conductive solution.6.3.2 Prepare a solution having a conductivity of at least2.5 mS (millisiemens).NOTE 1A solution comprised of tap water and a solute such as NaClor NH4Cl has been found to be acceptable. Since the water solution is usedto detect (not cause) m

18、aterial decomposition/breakdown, the solution isacceptable for use as long as it meets the minimum conductivityrequirements. It is recommended to change the solution when it becomesdifficult to observe breakdown due to cloudiness or other contamination.6.3.3 During testing, the conductive solution i

19、s at groundpotential. The ground connection, using an immersedelectrode, is made using Nichrome, stainless steel, or othernon-corrosive metal.6.3.4 Fit the container with a cover to prevent evaporationof the solution when not in use.7. Hazards7.1 WarningLethal voltages are a potential hazard duringt

20、he performance of this test. It is essential that the testapparatus, and all associated equipment electrically connectedto it, be properly designed and installed for safe operation.Solidly ground all electrically conductive parts which arepossible for a person to contact during the test. Provide mea

21、nsfor use at the completion of any test to ground any parts whichwere at high voltage during the test, or have the potential foracquiring an induced charge during the test, or retaining acharge even after disconnection of the voltage source. Thor-oughly instruct all operators as to the correct proce

22、dures forperforming tests safely. When making high voltage tests,particularly in compressed gas or in oil, it is possible for theenergy released at breakdown to be sufficient to result in fire,explosion, or rupture of the test chamber. Design testequipment, test chambers, and test specimens so as to

23、 minimizethe possibility of such occurrences and to eliminate thepossibility of personal injury. If the potential for fire exists,have fire suppression equipment available.8. Test Specimens8.1 The substrate material to be used for evaluating integralbus-bar insulation systems shall be steel. It is p

24、referred that theconfiguration of the substrate material be representative of theend application. One configuration that has been found to beuseful is shown in Fig. 1. Alternative configurations areacceptable if agreed to by all interested parties.8.2 The substrate shall be coated with the powder an

25、d curedusing the manufacturers standard process. One end of thespecimens shall be left uncoated for making an electricalconnection during the dielectric strength tests.9. Number of Test Specimens9.1 A set of specimens for thermal aging shall consist of atleast ten specimens. Prepare one set for each

26、 aging temperaturechosen.9.2 The initial value (unaged) set shall consist of at leasttwenty specimens.9.3 The minimum number of test specimens is 50. It isrecommended to prepare extra specimens for situations such asthe need to add additional aging temperatures, or to havereplacement specimens avail

27、able for any specimens that arefound during the screening test to be unsuitable for use inthermal aging.10. Calibration and Standardization10.1 Expose the test material to at least three aging tem-peratures. The preferred number of aging temperatures is four.10.2 Minimum thermal life target values f

28、or the high andlow temperatures shall be selected based on application.10.3 Aging temperatures shall differ by at least 10C.FIG. 1 Example Specimen DimensionsD7895/D7895M 142NOTE 2Experience has shown that the suggested target thermal lifevalues listed in Table 1 are generally satisfactory.11. Selec

29、tion of Aging Cycles11.1 To provide approximately equal exposures to the otherconditionings, and to more accurately determine the propertyendpoint, the heat aging time per cycle shall be shorter for thehigher aging temperatures and longer for the lower agingtemperatures.11.2 Cycle times shall be sel

30、ected such that each setundergoes an adequate (but not excessive) number of cyclesbefore completion. In order to obtain an appropriate number ofcycles, the following adjustments to the cycle time are recom-mended:11.2.1 If no specimens in a set fail by the end of the 4thcycle, double the heat aging

31、period of the test cycle.11.2.2 If three or more specimens in a set fail by the end ofthe 4thcycle, halve the heat aging period of the test cycle.11.2.3 Use observations in the highest temperature set toselect appropriate adjustments to the other temperature sets.NOTE 3Experience has shown that the

32、suggested cycle times in Table1 are generally satisfactory.12. Initial Value Test12.1 To determine an initial dielectric strength level, at leasttwenty specimens shall be selected at random from the sampleand subjected to a voltage breakdown test.12.2 Connect one electrode of the tester to the uncoa

33、ted endof the specimen. Suspend the coated end of the specimen in theelectrically conductive solution described in 6.3.2 (see Fig. 2).The total surface area to be tested shall be sufficient to berepresentative of the intended application.12.3 Apply voltage uniformly to the test electrode in accor-da

34、nce with the guidelines of the Short-Time Test described in12.2.1 of Test Method D149, unless another rate is specified,until breakdown occurs.12.4 Make one measurement on each specimen and com-pute the average dielectric breakdown voltage for the set.Record this as the initial value.13. Screening T

35、est13.1 Prior to thermal aging, all specimens shall be subjectedto a screening test in order to remove defective units. Anyspecimen that cannot pass the screening test shall be discardedand a replacement specimen selected for thermal aging.13.2 Select a screening test voltage level that is a percent

36、ageof the average initial value.13.3 Select a screening test period of time that is expected tocause failure in weak specimens without causing damage to theremaining specimens.NOTE 4Experience has shown that a screening test voltage level of75 % of the initial value for a period of 10 s is generally

37、 satisfactory.13.4 Suspend each specimen in the electrically conductivesolution in the same manner as described for the initial valuetest. Apply voltage uniformly to the test electrode in accor-dance with the guidelines of the Short-Time Test described in12.2.1 of Test Method D149, unless another ra

38、te is specified,until the screening voltage level is achieved. Maintain thevoltage for the screening test period before removing thevoltage from the specimen.13.5 Discard any specimen that breaks down. Specimensthat do not break down during the screening test are acceptablefor use in the thermal agi

39、ng.14. Procedure14.1 Thermal Aging of SpecimensTag four sets of speci-mens by any reliably permanent means and expose the sets inthe oven at each of the selected temperatures. Position the setsso that free movement of air exists across the entire specimen.14.2 Stress Cycling:14.2.1 Following the com

40、pletion of each thermal exposure,all specimens in the set shall be removed from the oven andallowed to cool to 23 6 2C.14.2.2 All specimens shall then be subjected to a coldexposure and allowed to reach equilibrium with the coldenvironment.14.2.2.1 If the coating resin is intended for outdoorapplica

41、tions, the cold exposure temperature shall be minus 20.06 2.0C minus 4.0 6 3.6F.14.2.2.2 If the coating resin is intended for indoorapplications, the cold exposure temperature shall be 0.0 62.0C 32.0 6 3.6F.14.2.3 Following the cold exposure, all specimens shall beallowed to return to 23 6 2C.14.2.4

42、 All specimens shall then be mounted on a shake tableand operated for a period of 10 000 cycles with a 60 Hzoscillating motion and an acceleration of 7 Gs.14.2.4.1 The specimens shall be mounted such that themotion occurs at right angles to the largest flat surface of thespecimen and parallel to the

43、 smallest flat surface of thespecimen (see Fig. 3).14.2.5 Following the vibration exposure, all specimens shallbe placed into a humidity exposure for a minimum of 24 h at25 to 30C 77 to 86F, with the relative humidity adjusted to95 to 100 %.NOTE 5The humidity exposure is intended to minimize the occ

44、ur-rence of trapped air in any potential fractures developed in the coatingduring the previous cycle.14.2.6 The total time required for each stress exposure willbe dependent on the configuration of the specimens used. Theminimum time for each exposure environment shall be the timerequired for the sp

45、ecimens to reach equilibrium with theexposure environment.NOTE 6Experience has shown that exposures longer than the timerequired to reach equilibrium do not influence the test results.14.3 Testing Specimens:TABLE 1 Suggested Cycle Times and Target LivesTemperature Set Cycle Time Target LifeHigh Temp

46、erature 4872 h 400700 hMiddle High Temperature 168 h 10001500 hMiddle Low Temperature 336 h 20003000 hLow Temperature 504 h 5000+ hD7895/D7895M 14314.3.1 Select a proof test voltage level that is a percentageof the average initial value. The same proof test voltage levelshall be used in all subseque

47、nt proof testing.14.3.2 Select a proof test period of time that is expected todetect the onset of thermal decomposition without causingdamage to intact specimens. The same proof test period of timeshall be used in all subsequent proof testing.NOTE 7Experience has shown that a proof test voltage leve

48、l of 50%of the initial value for a period of 10 s is generally satisfactory.14.3.3 Within 1 h of removal from the humidity exposure,subject each specimen to a proof voltage test. Suspend eachspecimen in the electrically conductive solution in the samemanner as described for the initial value test. A

49、pply voltageuniformly to the test electrode in accordance with the guide-lines of the Short-Time Test described in 12.2.1 of Test MethodD149, unless another rate is specified, until the proof voltagelevel is achieved. Maintain the voltage for the proof test periodbefore removing the voltage from the specimen.NOTE 8Testing is permissible on one or more specimens at a time, andis limited only by the physical capacity of the test container. Failures willbe more easily identified if the specimens are tested one-by-one, but theresults will not change w