ASTM C1331-2001(2012) Standard Test Method for Measuring Ultrasonic Velocity in Advanced Ceramics with Broadband Pulse-Echo Cross-Correlation Method《用宽带脉冲反射交互作用法测量高级陶瓷中超声速率的标准试验方法》.pdf

《ASTM C1331-2001(2012) Standard Test Method for Measuring Ultrasonic Velocity in Advanced Ceramics with Broadband Pulse-Echo Cross-Correlation Method《用宽带脉冲反射交互作用法测量高级陶瓷中超声速率的标准试验方法》.pdf》由会员分享，可在线阅读，更多相关《ASTM C1331-2001(2012) Standard Test Method for Measuring Ultrasonic Velocity in Advanced Ceramics with Broadband Pulse-Echo Cross-Correlation Method《用宽带脉冲反射交互作用法测量高级陶瓷中超声速率的标准试验方法》.pdf（7页珍藏版）》请在麦多课文档分享上搜索。

1、Designation: C1331 01 (Reapproved 2012)Standard Test Method forMeasuring Ultrasonic Velocity in Advanced Ceramics withBroadband Pulse-Echo Cross-Correlation Method1This standard is issued under the fixed designation C1331; the number immediately following the designation indicates the year oforigina

2、l adoption 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.1. Scope1.1 This test method describes a procedure for measurementof ultrasoni

3、c velocity in structural engineering solids such asmonolithic ceramics, toughened ceramics, and ceramic matrixcomposites.1.2 This test method is based on the broadband pulse-echocontact ultrasonic method. The procedure involves a computer-implemented, frequency-domain method for precise measure-ment

4、 of time delays between pairs of echoes returned by theback surface of a test sample or part.1.3 This test method describes a procedure for using adigital cross-correlation algorithm for velocity measurement.The cross-correlation function yields a time delay between anytwo echo waveforms (1).22. Ref

5、erenced Documents2.1 ASTM Standards:3B311 Test Method for Density of Powder Metallurgy (PM)Materials Containing Less Than Two Percent PorosityC373 Test Method for Water Absorption, Bulk Density,Apparent Porosity, andApparent Specific Gravity of FiredWhiteware ProductsE494 Practice for Measuring Ultr

6、asonic Velocity in Materi-alsE1316 Terminology for Nondestructive Examinations2.2 ASNT Document:Recommended Practice SNT-TC-1A for NondestructiveTesting Personnel Qualification and Certification42.3 Military Standard:MIL-STD-410 Nondestructive Testing Personnel Qualifica-tion and Certification52.4 A

7、dditional references are cited in the text and at end ofthis document.3. Terminology3.1 Definitions of Terms Specific to This Standard:3.1.1 back surfacethe surface of a test sample which isopposite to the front surface and from which back surfaceechoes are returned at normal incidence directly to t

8、he trans-ducer.3.1.2 bandwidththe frequency range of an ultrasonicprobe, defined by convention as the difference between thelower and upper frequencies at which the signal amplitude is 6dB down from the frequency at which maximum signalamplitude occurs.3.1.3 broadband transduceran ultrasonic transdu

9、cer ca-pable of sending and receiving undistorted signals over a broadbandwidth, consisting of a thin damped piezocrystal in abuffered probe (search unit).3.1.4 buffered probean ultrasonic search unit as defined inTerminology E1316 but containing a delay line, or buffer rod,to which the piezocrystal

10、 is affixed within the search unithousing and which separates the piezocrystal from the testsample (Fig. 1).3.1.5 buffer rodan integral part of a buffered probe,usually a quartz or fused silica cylinder that provides a timedelay between the excitation pulse from the piezocrystal andechoes returning

11、from a sample coupled to the free end of thebuffer rod.3.1.6 cross-correlation functionthe cross-correlationfunction, implemented by a digital algorithm, yields a timedelay between any two (ultrasonic) echo waveforms. This timeis used to determine velocity (1).1This test method is under the jurisdic

12、tion of ASTM Committee C28 onAdvanced Ceramics and is the direct responsibility of Subcommittee C28.03 onPhysical Properties and Non-Destructive Evaluation.Current edition approved Aug. 1, 2012. Published November 2012. Originallyapproved in 1996. Last previous edition approved in 2007 as C133101(20

13、07). DOI:10.1520/C1331-01R12.2The boldface numbers in parentheses refer to the list of references at the end ofthis test method.3For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume informatio

14、n, refer to the standards Document Summary page onthe ASTM website.4Available fromAmerican Society for NondestructiveTesting (ASNT), P.O. Box28518, 1711 Arlingate Ln., Columbus, OH 43228-0518, http:/www.asnt.org.5Available from Standardization Documents Order Desk, DODSSP, Bldg. 4,Section D, 700 Rob

15、bins Ave., Philadelphia, PA 19111-5098, http:/www.dodssp.daps.mil.Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States13.1.7 dispersionvariation of ultrasonic velocity as a func-tion of wavelength, that is, frequency dependence of velocity

16、.3.1.8 front surfacethe surface of a test sample to whichthe buffer rod is coupled at normal incidence (designated as testsurface in Terminology E1316.3.1.9 group velocityvelocity of a broadband ultrasonicpulse consisting of many different component wavelengths.3.1.10 test samplea solid coupon or ma

17、terial part thatmeets the constraints needed to make the ultrasonic velocitymeasurements described herein, that is, a test sample or parthaving flat, parallel, smooth, preferably ground or polishedopposing (front and back) surfaces, and having no discreteflaws or anomalies unrepresentative of the in

18、herent propertiesof the material.3.1.11 wavelength ()distance that sound (of a particularfrequency) travels during one period (during one oscillation), = v/f, where v is the velocity of sound in the material andwhere velocity is measured in cm/s, frequency in MHz, andwavelength in cm, herein.3.2 Oth

19、er terms or nomenclature used in this test method aredefined in Terminology E1316.4. Significance and Use4.1 The velocity measurements described in this test methodmay be used to characterize material variations that affectmechanical or physical properties. This procedure is useful formeasuring vari

20、ations in microstructural features such as grainstructure, pore fractions, and density variations in monolithicceramics.4.2 Velocity measurements described herein can assesssubtle variations in porosity within a given material orcomponent, as, for example, in ceramic superconductors andstructural ce

21、ramic specimens (2,3).4.3 In addition to ceramics and ceramic composites, thevelocity measurements described herein may be applied topolycrystalline and single crystal metals, metal matrixcomposites, and polymer matrix composites.4.4 An alternative technique for velocity measurement isgiven in Pract

22、ice E494.5. Personnel Qualifications5.1 It is recommended that nondestructive evaluation/examination personnel applying this test method be qualified inaccordance with a nationally-recognized personnel qualifica-tion practice or standard such asASNT SNT-TC-1A, MILSTD410, or a similar document. The q

23、ualification practice orstandard used and its applicable revision(s) should be specifiedin a contractual agreement.5.2 Knowledge of the principles of ultrasonic testing isrequired. Personnel applying this test method should be expe-rienced practitioners of ultrasonic examinations and associatedmetho

24、ds for signal acquisition, processing, and interpretation.5.3 Personnel should have proficiency in computer signalprocessing and the use of digital methods for time andfrequency domain signal analysis. Familiarity with Fourier andassociated transforms for ultrasonic spectrum analysis is re-quired.6.

25、 Apparatus and Test Sample6.1 Instrumentation (Fig. 1 and Fig. 2) for broadbandcross-correlation pulse-echo ultrasonic velocity measurementshould include the following:6.1.1 Buffered Probe:6.1.1.1 The buffer rod, which is an integral part of the probe(search unit), should be a right cylinder with sm

26、ooth flat endsnormal to the axis of the probe.6.1.1.2 The center frequency of the buffered probe shouldproduce a wavelength within the sample that is less than onefifth of the thickness of the sample.6.1.1.3 The buffer rod length, that is, time delay should bethree times the interval between two suc

27、cessive back surfaceechoes.6.1.1.4 The wave mode may be either longitudinal or shear.6.1.2 Pulser-Receiver, with a bandwidth that is at least twicethat of the buffered probe. The bandwidth should includefrequencies in the range from 100 kHz to over 100 MHz.6.1.2.1 The pulser-receiver should have pro

28、visions for con-trolling the pulse repetition rate, pulse energy level, pulsedamping, and received signal gain.6.1.2.2 The pulser-receiver should provide a synchroniza-tion pulse and signal output connector.6.1.3 Waveform Digitizing Oscilloscope (A/D Board), busprogrammable, to window and digitize t

29、he echo waveforms.6.1.3.1 A minimum 512-element waveform array with amaximum data sampling interval of 1.95 ns is recommended.For better waveform resolution, a 1024-element array with adata sampling interval of 0.97 ns may be needed.6.1.3.2 Vertical Amplifier, bus programmable module.6.1.3.3 Time Ba

30、se, bus programmable module with a reso-lution of at least 5 ns per division and several time base rangesincluding a fundamental time base of at least 200 ns.6.1.4 Digital Time Delay Module, bus programmable, tointroduce a known time delay between the start of two separatetime gates, that is, window

31、s each of which containing one oftwo successive back surface echoes.NOTE 1B1and B2are first and second back surface echoes,respectively, and T is time interval between the echoes.FIG. 1 Cross Section of Buffered Ultrasonic Probe (a) and Prin-ciple Echoes (b) for Velocity MeasurementC1331 01 (2012)26

32、.1.4.1 Separate windows are preferred for waveform digi-tization. Each waveform should occupy from 60 to 80 % of thewindow.6.1.4.2 The time synthesizer should have an accuracy of 61ns with a precision of 60.1 ns.6.1.5 Video Monitors, (optional) one analog, one digital forreal-time visual inspection

33、of echo waveforms and for makinginteractive manual adjustments to the data acquisition controls.6.1.6 Computer, with adequate speed and storage capacity toprovide needed software control, data storage, and graphicscapability.The software should include a fast Fourier transform(FFT) algorithm package

34、 containing the cross-correlation al-gorithm.6.1.7 Couplant Layer, to establish good signal transferbetween the buffer rod and test sample. The layer should be asthin as possible to minimize couplant resonances and distortionof the echo waveforms.6.1.7.1 The couplant should not be absorbed by or beo

35、therwise deleterious to the test sample.6.1.7.2 Dry coupling with a thin polymer may be usedwhere liquid contamination by or absorption of liquids by thetest sample or part must be avoided.6.2 The test sample or part should have flat parallel oppos-ing surfaces in the region where the velocity measu

36、rements aremade. This will assure good coupling between the transducerand sample and also produce valid echoes for velocity mea-surements.6.2.1 Lack of precision in the measurement of the testsample thickness can undermine the nanosecond precision withwhich pulse-echo travel times can be measured. T

37、herefore, thesample thickness should be measurable to an accuracy of60.1 % or better.6.2.2 For most engineering solids, the sample thicknessshould be at least 2.5 mm. There is a practical upper bound onsample thickness, for example, if the sample is too thick, theremay be considerable signal attenua

38、tion, beam spreading, anddispersion that render the signal useless.7. Procedure7.1 Use instrument control software routines to start andcontrol the interface bus; perform procedures such as optimiz-ing intensity, voltage, and time on the waveform digitizingoscilloscope; control the digital time dela

39、y module; andacquire, store, and process data.7.1.1 A cross-correlation algorithm should be part of theFFT software.7.1.2 The arguments needed to implement the cross-correlation algorithm are the time domain waveform arrays,that is, digitized echoes B1and B2(Fig. 1).7.2 Prepare samples with front an

40、d back surfaces that aresufficiently smooth, flat, and parallel to allow measurement ofthe test sample thickness to an accuracy of 0.1 % or better.7.3 Couple the sample to the transducer to obtain two strongback surface echoes.7.3.1 Apply pressure to minimize the couplant layer thick-ness. A backing

41、 fixture may be necessary to apply pressure.7.3.2 Care shall be taken to avoid coupling the sample to thebacking fixture and thereby losing echo signal strength byleakage.7.3.3 A dry, hard rubber or composite material with arough-machined or sawtooth surface is recommended for thebacking fixture.7.4

42、 Determine the precise positions, in the time domain, ofthe start of the windows containing echo waveforms B1and B2and program the digital time delay module to sequentially setthese delays.7.4.1 The oscilloscope time base should be adjusted so thateach waveform occupies 60 to 80 % of its window.Wind

43、ow fillmay be as low as 20 % and still produce acceptable results.7.4.2 During data acquisition, the time synthesizer shouldsequence through the predetermined time positions.7.5 The waveform digitizing oscilloscope (A/D device)should be programmed to automatically maximize the echowaveform amplitude

44、 and intensity settings.FIG. 2 Instrumentation Diagram for Acquiring and Separately Windowing Two Successive Back Surface Echoes, B1and B2, for Cross-Correlation Velocity MeasurementC1331 01 (2012)37.6 Digitize back surface echoes B1and B2into separate512-element waveform arrays. Signal averaging ma

45、y be nec-essary to accurately capture subtle features of the waveforms.Signals with high SNR (signal-to-noise ratio) can be accuratelydigitized by only a few signal averagings while signals withlow SNR may require as much as 32 signal averagings.7.7 Ultrasonic velocity is determined by measuring the

46、 timedelay between two successive echoes returned by the backsurface of the test sample. These are shown as the twoseparately-windowed echoes B1and B2(Fig. 3).7.7.1 Echoes B1and B2are separately windowed to getmaximum time and voltage resolution. This is done by preset-ting the digital time delay mo

47、dule to produce two windows thatcapture echoes B1and B2with window start times D1and D2,respectively.7.7.1.1 The centroid of echo B1occurs at time D1+ T1.7.7.1.2 The centroid of echo B2occurs at time D2+T2.7.7.2 If the sample thickness and other constraints are met,it should be possible to digitally

48、 overlap echoes B1and B2asin Fig. 4. Dispersion has occurred if echo B2is spread outrelative to B1and does not have the same zero crossings as B1. If too pronounced, dispersion and beam spreading may beavoided by reducing the sample thickness.7.7.3 The travel time interval T between B1and B2is given

49、by T = C + W , where W = D2 D1and C is the echodisplacement time obtained by means of the cross-correlationalgorithm.7.7.4 The cross-correlation algorithm is applied to the echowaveforms B1and B2to provide the value for the echodisplacement time C.7.8 After acquiring waveform records for echoes B1and B2,use the cross-correlation algorithm to obtain the echo displace-ment time,C, relative to the zero reference.7.9 Use the cross-correlation algorithm which transforms B1and B2into the frequency domain, multiplies the complexconjugate of B2(f)byB1(f), and transforms t