In our continuing efforts to investigate methods to characterize the state of fatigue nondestructively and to apply these observations to lifetime predictions, we have initiated acoustic surface wave studies using Al 2024-T351. A smooth bar specimen was designed which can be tested in tension-compression fatigue. Acoustic wedge transducers were mounted on the specimen to sample fatigue induced changes within the gauge section. Data on acoustic harmonic generation were taken as a function of applied external load at any point of the sample\u27s fatigue life. An optical microscope was attached to the load frame to monitor microcrack formation in the gauge section. Significant changes of the second harmonic have been observed as a function of stress and fatigue. First results indicate a decrease of the second harmonic as a function of stress. At about 50% of the fatigue life microcracks initiated at surface intermetallics and a substantial increase of the second harmonic amplitude in the vicinity of zero external applied load was observed

Buck, O.

Inman, R. V.

Morris, W. L.

English

In our continuing efforts to investigate methods to characterize the state of fatigue nondestructively and to apply these observations to lifetime predictions, we have initiated acoustic surface wave studies using Al 2024-T351. A smooth bar specimen was designed which can be tested in tension-compression fatigue. Acoustic wedge transducers were mounted on the specimen to sample fatigue induced changes within the gauge section. Data on acoustic harmonic generation were taken as a function of applied external load at any point of the sample's fatigue life. An optical microscope was attached to the load frame to monitor microcrack formation in the gauge section. Significant changes of the second harmonic have been observed as a function of stress and fatigue. First results indicate a decrease of the second harmonic as a function of stress. At about 50% of the fatigue life microcracks initiated at surface intermetallics and a substantial increase of the second harmonic amplitude in the vicinity of zero external applied load was observed.</p

Buck, O

Morris, W

Inman, R

Digital Repository @ Iowa State University (ISU)

SURFACE WAVE TECHNIQUES FOR PREDICTING THE REMAINING LIFE OF FATIGUE DAMAGED METALS 0. Buck, W. L. Morris, and R. V. Inman Science Center, Rockwell International Thousand Oaks, California g1360 ABSTRACT In our continuing efforts to investigate methods to characterize the state of fatigue nondestruc-tively and to apply these observations to lifetime predictions, we have initiated acoustic surface wave studies using Al 2024-T351. A smooth bar specimen was designed which can be tested in tension-compression fatigue. Acoustic wedge transducers were mounted on the specimen to sample fatigue induced changes within the gauge section. Data on acoustic harmoni c generation were taken as a function of applied external load at any point of the sample's fatigue life. An optical microscope was attached to the load frame to monitor microcrack formation in the gauge section. Significant changes of the second harmonic have been observed as a function of stress and fatigue. First results indicate a decrease of the second harmonic as a func-tion of stress. At about SOt of the fatigue life microcracks initiated at surface intermetallics and a substa.ntial increase of the second harmonic amplitude in the vicinity of zero external applied load was observed. The objective of the present work is to investi-gate the potential of surface acoustic waves and, in particular, acoustic harmonic generation for surface stress measurements and for fatigue life predictions. Acoustic surface waves are particu-larly well suited for such measurements since the acoustic energy is highly localized at the materials' surface. The experimental setup for this work is exhibited in Fig. 1, which shows a fatigue2sample of rectangular cross section (about 1 inch ) installed in an electrohydraullc KTS machine. Also shown are acoustic wedge transducers with the trans-mitting transducers operating at 5 HHz and the receiving transducers tuned to 10 MHz to monitor changes in acoustic harmonic generation as the specimen is fatigued in the MTS machine. An optical microscope (not shown in Fig. 1) has a.l so been used to observe microcrack initiation and growth. Figure 2, bottom, shows the electronics used for harmonic analy-sis of these acoustic surface waves. The finite amplitude signal is yenerated using a pulsed oscillator. A heterodyne receiver served as the frequency spectrum analyzer after detection of the signal by the 10 MHz transducer. The surface wave signals received were quite clean and disappeared completely by pressing a soft object against the specimen's gauge section. To demon-strate surface harmonic generation, several measurements on the derndence of the second harmonic amplitude (A2 at 10 MHz on the first harmonic amplitude (Al at 5 MHz were performed with both A1 and A2 measured at the receiver transducer. As shown in Fig. 2, ~ight-hand side, the theoretically expected A2 a: A] relation was observed. During the early stages of fatigue, harmonic generation was determined as a function of applied load during individual fatigue cycles. Figure 3 shows a typical example o~ such a measure-ment plotted in the quantity A2/A1 (to compensate for anr variations in A1 during t~e fatigue cycle) as a function of the applied2stress. As can be seen from this figure, A2/A1 decreases with increasing applied stress. Such a dependence is expected theoretically, using non-linear theory of elasticity. 112 Har.onic generation as a function of applied load was also determined during the later parts of the fatigue life when the mi crocrack density, as initiated at intermetallics, became high. An example of such a harmonic generation result is shown in Fig. 4, top, with an example of one of the longer microcracks (about 15 ~m, or 0.5 mils, long) shown in Fig. 4, bottom. The results given in Fig. 4 are clearly different from those in Fig. 3. Data similar to the ones shown in Fig. 4 for Al 2024-TSSl were observed repeatedly on specimens with a large microcrack density. It is believed that the 11i crocracks are the cause for the changed narmonic amplitude results, as explained qualita-tively in the following. As postulated by J. H. Richardson (Science Center, Rockwell International) recently, a stress induced crack opening and closing may be considered as an acoustic harmonic generator. Richardson con-sidered i very simple system composed of an unbonded planar interface separating two semi-infinite linear media (see Fig. 5, top). By definition, the unbonded interface cannot support tension and thus it opens up during the tension phase of a wave propagating from one side of the interface to the other. The system is actually linear while the gap in the interface is closed. The origin of the nonlinearity is due to the fact that the time at which the gap opens and closes depends upon the ratio of the stress amplitude of the acoustic wave and the external stress that works to hold the gap closed (Fig. 5, bottom). In the case of a normally incident sinusoidal wave, the gap dynamics will be nonlinear and harmonics will be generated in a reflected or transmitted wave if the ambient stress is less than the stress of the incident wave. Fr01 the above discussions it is expected that harmonic generation at cracks is a mini~m both at maximum tensile and compressive stresses. In the vicinity of zero applied stress, however, harmonic generation should be a maximum. Indications for such an effect may be seen in Fig. 5, top. However, the origin of the large harmonic generation at +50 ksi is unknown at the present time. Further experiments to clarify this situation are underway. The opening and closing of both microscopic and macroscopic cracks has been observed experi-mentally. Figure 6 shows the change in contact area of a macrocrack as a function of the applied stress. Microcracks, as shown in Fig. 4, will behave similarly and thus are thought to be a potential source for acoustic harmonic generation. The conclusion of the present work is summar-ized in Fig. 7. After having generated strong and clean surface waves and Fourier analyzed the received signal, we have observed that the second harmonic decreases roughly by about 20% per ksi stress. Thus the sensitivity of this 113 effect is one to two orders of magnitude larger than that of another acoustic technique, which uses the change of sound velocity as a stress indicator. Harmonic generation also seems to be a very promising tool to detect microcracks as developed during fatigue. The nonlinearities occurring during opening and closing of microcracks have been considered by Richardson recently. The present results indicate that microcracks as little as 15 ~m long (or about 0.5 mils) can be detected by harmonic generation if the density is high enough. Acknowledgement This research was sponsored by the Center for Advanced NDE operated by the Science Center, Rockwell Intern~tional, for the Advanced Research Projects Agency and the Air Force Materials Laboratory under contract F33615-74-C-5l80. OUCTivt TO IIMSTICATt II( I'OTtNTIAl Of SURfACI. WAvtS fOR SlllliAC£ Slli£SS M[ASURIM£NIS AND fOR fAIICUE llf! PRIDICTIO~S . ACOIImC wtDr~ lliAIISOUCERS, C[N[RAIINI) ACOUSIIC SURfACE WAVES 1111 \ MHrl, 1\I:R[ t.OOOmtD ON nt£ SP£CIMCN TO SAMPlE nt£ STAll Of SlliESS AND nt£ STAll Of IATICUE Wll~IN lHI CAUCI SlCIIOII SY I>'(ANS Of ACOUSTIC HARMONIC C[N(!IATIOII 11( UCUR( SHOWS l~ SPICIM[N I'MICH *S fAIICU!O IN T!NSION COMrR£SSIOil IN AN [l[Cf110· HVORAUI.IC MIS MA(.HINl • SHOWN IS Ill[ [l(P[RIM[NIAl APPAI!ATUS FOR HAPMONIC ANAlYSIS Of ACOUSIIC SUltiAC[ II/AVIS. SINUSOIDAl UllliASONIC SURfACE WAVI:S Of rtNIIl AMPLIIUD£ AI '.1 Wh WLRt !1<CIIl0 8Y A PZJ fRANSOUC(R, Tl£ DISIORTtD SIGNAl WAS 0£1£Cit0 USING A II Mllr PZT. A H(TlRODVNI RIC[IVlR SlRvtO A~ IH[ fREOU!NCV SP£CITIUM ANAl Y l{R 8T VIRIU! 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IIIWI).(>offiO('ftl't( ...-o - ---lit> ........ , .......... ~ ., ----~··-Figure 6 M[OIUM Z TRANSMIIltO WAV£ x-.. Figure 5 116 • A POSSIIIli (l(PIA"'IIOH fa.! TK VARIAtiON IN lOC 1Az1A111 WitH SllllSS IMY t£ ACOUStiC HAOMONIC cuo.AIIOH AI IH( CIAC<t OP(NI ANO Cl05!1 UNoot Sl1US5 11 M. OICHA0050H. SCI~ COOtOI • • II<( OOICIN 01 II<( NOHUH(ARIIY IS 0\J( 10 M fACT TMA.T fH( TIM£ 4l 'MtiQt M CAP OPIHS ANO ClOS!S D£P£KOS UPOH lltl IAtiO I• IOF II<( STMIS AMPlll\10£ Of 114( ACOUStiC w.\Y! AHO Ill£ OO£RNAl Slii(SI WHICH TRI£1 10 Q.OII IHE CAP • Ill STRONC AND ClEAN ACO\JSTIC SURFACE WAV£ SIGNALS HAV£ BEEN PROO\JCED ON SPECIMENS SUITABLE FOil ltNSION·COMPRESSION FATIGUE. 121 Pill Oil TO Ml CROCRACK FORMATION HARMONIC c:o.tRATION OECRU.SES Willi INCREASING APPLIED STRESS IS£NSITIVITY- 20J>IIOO Ksll. THUS 1\iE W.CHNIQU( IS POTENTIALLY USEFUL TO OETECT IDNC RANCE INTERNAL STRESSES. ()I .. CROCRACKS ARE A POSSIBLE SOURCE FOR ACOUSTIC HARMONIC GEI6ATION. MICROCRACKS AS SMALL AS IS pm IllS mllsl MIGHT BE OETECTED. RIRlliER RES£ARCH IN THIS AREA IS NEEOED HOWEVER. Figure 7. Conclusions 

Surface Wave Techniques for Predicting the Remaining Life of Fatigue Damaged Metals

Morris, W.

Inman, R.

https://lib.dr.iastate.edu/cgi/viewcontent.cgi?article=1017&amp;context=cnde_yellowjackets_1977

Surface Wave Techniques for Predicting the Remaining Life of Fatigue Damaged Metals

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Digital Repository @ Iowa State University (ISU)

Digital Repository @ Iowa State University (ISU)