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本文(ASTM E2582-2007(2014) Standard Practice for Infrared Flash Thermography of Composite Panels and Repair Patches Used in Aerospace Applications《航空航天用合成板条和检修片红外闪热成像法的标准实施规程》.pdf)为本站会员(diecharacter305)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 E2582-2007(2014) Standard Practice for Infrared Flash Thermography of Composite Panels and Repair Patches Used in Aerospace Applications《航空航天用合成板条和检修片红外闪热成像法的标准实施规程》.pdf

1、Designation: E2582 07 (Reapproved 2014)Standard Practice forInfrared Flash Thermography of Composite Panels andRepair Patches Used in Aerospace Applications1This standard is issued under the fixed designation E2582; the number immediately following the designation indicates the year oforiginal adopt

2、ion or, in the 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.This standard has been approved for use by agencies of the U.S. Department of Defense

3、.1. Scope1.1 This practice describes a procedure for detecting sub-surface flaws in composite panels and repair patches usingFlash Thermography (FT), in which an infrared (IR) camera isused to detect anomalous cooling behavior of a sample surfaceafter it has been heated with a spatially uniform ligh

4、t pulsefrom a flash lamp array.1.2 This practice describes established FT test methods thatare currently used by industry, and have demonstrated utility inquality assurance of composite structures during post-manufacturing and in-service examinations.1.3 This practice has utility for testing of poly

5、mer compos-ite panels and repair patches containing, but not limited to,bismaleimide, epoxy, phenolic, poly(amide imide),polybenzimidazole, polyester (thermosetting andthermoplastic), poly(ether ether ketone), poly(ether imide),polyimide (thermosetting and thermoplastic), poly(phenylenesulfide), or

6、polysulfone matrices; and alumina, aramid, boron,carbon, glass, quartz, or silicon carbide fibers. Typical as-fabricated geometries include uniaxial, cross ply and angle plylaminates; as well as honeycomb core sandwich core materials.1.4 This practice has utility for testing of ceramic matrixcomposi

7、te panels containing, but not limited to, silicon carbide,silicon nitride and carbon matrix and fibers.1.5 This practice applies to polymer or ceramic matrixcomposite structures with inspection surfaces that are suffi-ciently optically opaque to absorb incident light, and that havesufficient emissiv

8、ity to allow monitoring of the surface tem-perature with an IR camera. Excessively thick samples, orsamples with low thermal diffusivities, require long acquisitionperiods and yield weak signals approaching background andnoise levels, and may be impractical for this technique.1.6 This practice appli

9、es to detection of flaws in a compositepanel or repair patch, or at the bonded interface between thepanel and a supporting sandwich core or solid substrate. It doesnot apply to discontinuities in the sandwich core, or at theinterface between the sandwich core and a second panel on thefar side of the

10、 core (with respect to the inspection apparatus).1.7 This practice does not specify accept-reject criteria andis not intended to be used as a basis for approving compositestructures for service.1.8 This standard does not purport to address all of thesafety concerns, if any, associated with its use.

11、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:2D3878 Terminology for Composite MaterialsE1316 Terminology for Nondestructive

12、Examinations3. Terminology3.1 DefinitionsTerminology in accordance with Termi-nologies D3878 and E1316 and shall be used where applicable.3.2 Definitions of Terms Specific to This Standard:3.2.1 aspect ratiothe diameter to depth ratio of a flaw. Forirregularly shaped flaws, diameter refers to the mi

13、nor axis of anequivalent rectangle that approximates the flaw shape and area.3.2.2 discrete discontinuitya thermal discontinuity whoseprojection onto the inspection surface is smaller than the fieldof view of the inspection apparatus.3.2.3 extended discontinuitya thermal discontinuitywhose projectio

14、n onto the inspection surface completely fillsthe field of view of the inspection apparatus.1This practice is under the jurisdiction of ASTM Committee E07 on Nonde-structive Testing and is the direct responsibility of Subcommittee E07.10 onSpecialized NDT Methods.Current edition approved Oct. 1, 201

15、4. Published November 2014. Originallyapproved in 2007. Last previous edition approved in 2007 as E2582-07. DOI:10.1520/E2582-07R14.2For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume inform

16、ation, refer to the standards Document Summary page onthe ASTM website.Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States13.2.4 first logarithmic derivativethe rate of change of thenatural logarithm of temperature (with preflash temperat

17、uresubtracted) with respect to the natural logarithm of time.3.2.5 inspection surfacethe surface of the specimen that isexposed to the FT apparatus.3.2.6 logarithmic temperature-time plota plot of the natu-ral logarithm of the surface temperature with preflash tempera-ture subtracted on the y-axis v

18、ersus the natural logarithm oftime on the x-axis, where time t=0 is taken to be the midpointof the flash event. Either temperature or radiance may be usedto create the plot.3.2.7 log plotsee logarithmic temperature-time plot.3.2.8 second logarithmic derivativethe rate of change ofthe first logarithm

19、ic derivative with respect to the naturallogarithm of time.3.2.9 thermal diffusivitythe ratio of thermal conductivityto the product of density and specific heat; a measure of the rateat which heat propagates in a material; units length2/time.3.2.10 thermal discontinuitya change in the thermophysi-ca

20、l properties of a specimen that disrupts the diffusion of heat.4. Summary of Practice4.1 In FT, a brief pulse of light energy from a flash lamparray heats the inspection surface of a composite specimen, andan IR camera monitors the surface temperature (or radiance) asthe sample cools. The surface te

21、mperature falls predictably asheat from the surface diffuses into the sample bulk. However,internal thermal discontinuities (for example, voids, delamina-tions or a wall or interface between the host material and a voidor inclusion) modify the local cooling of the surface, and thecorresponding radia

22、tion flux from the surface that is detectedby the IR camera.4.2 Fundamental detectability of a flaw will depend on itssize, depth, and the degree to which its thermal properties differfrom those of the surrounding host material. For a givenflaw-host combination, detectability is a function of the as

23、pectratio of the flaw. The minimum detectable flaw size increaseswith the depth of the flaw. Detectability is highest for largerflaws that are closer to the sample surface and have thermalproperties that are significantly different from the host matrixmaterial.4.3 Operational parameters affecting de

24、tectability includecomponent surface emissivity and optical reflectivity, dataacquisition period, flash lamp energy, and camera wavelength,frame rate, sensitivity, optics and spatial resolution.4.4 This practice describes a single-side accessexamination, in which the flash lamp array (excitation sou

25、rce)and IR camera (temperature sensor) are both located on thesame (inspection) side of the component or material underexamination.4.5 In common practice, signal processing algorithms areused to enhance detectability of flaws that are not detectable inthe raw IR camera signal, and to assist in evalu

26、ation andcharacterization of indications.5. Significance and Use5.1 FT is typically used to identify flaws that occur in themanufacture of composite structures, or to track flaw develop-ment during service. Flaws detected with FT includedelamination, disbonds, voids, inclusions, foreign objectdebris

27、, porosity or the presence of water that is in contact withthe back surface. With dedicated signal processing and the useof representative test samples, characterization of flaw depthand size, or measurement of component thickness and thermaldiffusivity may be performed.5.2 Since FT is based on the

28、diffusion of thermal energyfrom the inspection surface of the specimen to the opposingsurface (or the depth plane of interest), the practice requiresthat data acquisition allows sufficient time for this process tooccur, and that at the completion of the acquisition process, theradiated surface tempe

29、rature signal collected by the IR camerais strong enough to be distinguished from spurious IR contri-butions from background sources or system noise.5.3 This method is based on accurate detection of changesin the emitted IR energy emanating from the inspection surfaceduring the cooling process. As t

30、he emissivity of the inspectionsurface deviates from ideal blackbody behavior (emissivity =1), the signal detected by the IR camera may include compo-nents that are reflected from the inspection surface. Mostcomposite materials can be examined without special surfacepreparation. However, it may be n

31、ecessary to coat low-emissivity, optically translucent inspection surfaces with anoptically opaque, high-emissivity water-washable paint.5.4 This practice applies to the detection of flaws withaspect ratio greater than one.5.5 This practice is based on the thermal response of aspecimen to a light pu

32、lse that is uniformly distributed over theplane of the inspection surface. To ensure that 1- dimensionalheat flow from the surface into the sample is the primarycooling mechanism during the data acquisition period, theheight and width dimensions of the heated area should besignificantly greater than

33、 the thickness of the specimen, or thedepth plane of interest.5.6 This practice applies to flat panels, or to curved panelswhere the local surface normal is less than 30 degrees from theIR camera optical axis6. Equipment and Materials6.1 IR CameraThe camera should be capable of uninter-rupted monito

34、ring of the sample surface for the entire durationof the acquisition. Cameras with automatic internal shutteringmechanisms should allow the shuttering to be disabled duringthe data acquisition period. The camera should provide real-time digital output of the acquired signal. The camera outputsignal

35、should be approximately linear over the (post-flash)temperature range of the sample. The camera wavelengthshould be in either the 2-5 micron range or the 8-14 micronrange, selected such that the test material is not IR translucentin the spectral range of the camera. The optics and focal planeshould

36、be sufficient so that the projection of nine contiguouspixels onto the sample plane is less than or equal to theminimum flaw area that is to be detected.E2582 07 (2014)26.2 Flash Lamp ArrayAt least one flash lamp should beemployed to provide uniform illumination to the samplesurface. The full width

37、at half maximum duration of the flashpulse should be less than or approximately five milliseconds.The array should be placed to avoid a direct path of the flashenergy into the IR camera lens opening. The lamps should beenclosed in a reflector and covered by an optically transparentwindow that suppre

38、sses IR radiation in the camera wavelengthrange (for example, borosilicate glass). The flash lamp arrayshould be enclosed in a protective hood to prevent workers inthe inspection area from direct exposure to the flash, oralternately, the apparatus should be operated in a partitionedarea with appropr

39、iate safety warnings to prevent inadvertentexposure.6.3 Acquisition SystemThe acquisition system includesthe IR camera, flash lamps and a dedicated computer that isinterfaced to both the camera and flash lamps. The acquisitionsystem should be capable of synchronizing the triggering of theflash lamps

40、 and IR camera data acquisition. The system shouldallow data to be acquired before, during and after the flashoccurs.6.4 Analysis SoftwareThe computer software should al-low acquired sequences to be archived and retrieved forevaluation, and allow real time display of the IR camera signal,as well as

41、frame-by-frame display of previously acquired flashsequences which have been archived. The software shouldallow viewing of the logarithmic temperature-time for speci-fied pixels. Additional processing operations on each rawimage sequence (for example, averaging, preflash imagesubtraction, noise-redu

42、ction, calculation of first or second timederivatives) may be performed to improve detectability ofsubsurface features.7. Reference Standards7.1 Detectability StandardA reference standard withknown thermal discontinuities is used to establish operatingparameters of the apparatus and limits of detect

43、ability for aparticular application, and to periodically verify proper perfor-mance of the apparatus.7.1.1 Known discontinuities may be actual flaws, or artifi-cial features that simulate the thermophysical behavior oftypical flaws that are known to occur in the structure ofinterest.7.1.2 At least f

44、ive known flaws of a particular type shouldbe included in the reference standard. The known flaws shouldrepresent the range of aspect ratios for anticipated flaws, andshould include the minimum required detectable flaw size fora given application, as determined by the cognizant engineer-ing organiza

45、tion.7.1.3 If the minimum detectable flaw size requirement is notknown, the reference standard should include at least fiveknown flaws of a given type, spanning the range of aspectratios from 0.5 to 10.7.1.4 If different types of known flaws are to be used, atleast five instances of each type should

46、 be included.7.1.5 Known flaws should be arranged so that edge-to-edgeseparation of adjacent flaws is at least one diameter of thelarger neighboring flaw.7.1.6 Known flaws should be arranged so that the edges ofeach flaw are at least one diameter from the edge of the testsample.7.1.7 If a test stand

47、ard containing actual or simulated flawsis not available, one may be constructed using flat bottom holesmachined into the back side of the panel. It should berecognized that flat bottom holes represent a best case scenariofor detectability, where no heat transfer through the flawoccurs. Actual flaws

48、 are likely to be less detectable.7.2 Uniformity StandardUniformity of the distribution oflight from the flash lamp array may be determined withaluminum plate reference standard.7.2.1 Aluminum plate thickness should be 3 mm.7.2.2 The plate surface should fully cover the field of viewof the apparatus

49、.7.2.3 The examination surface of the plate should have auniform high emissivity finish (for example, flat black paint).Under static conditions, the paint coating should appear uni-form when viewed with an IR camera.8. Calibration and Standardization of Apparatus8.1 CalibrationThe IR camera should be calibrated andmaintained at regular intervals, following the procedure rec-ommended by the manufacturer. Non-uniformity or flat fieldcorrection should be performed according to the manufactur-ers instructions, or more frequently, if required to achieveoptimum camera p

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