STRUCTURE IDENTIFICATION BY MICROINDENTATION AND ACOUSTIC EMISSION

1. KASPERKIEWICZ

2. Institute of Fundamental Technological ResearchPolish Academy of Sciences (IPPT PAN) 00-049 Warszawa, Swietokrzyska 21 STRUCTURE IDENTIFICATION BY MICROINDENTATION AND ACOUSTIC EMISSION Janusz Kasperkiewicz KASPERKIEWICZ

3. 1. MICROINDENTATION TESTS - techniques, measuring setup, etc. - testing cement paste - testing concrete 2. ACOUSTIC EMISSION IN MICROINDENTATION EXPERIMENTS 3. AE SIGNALS AND THEIR ANALYSIS 4.MACHINE LEARNING DATA PROCESSING 5. THE EXPERIMENT ON COMPONENTSIDENTIFICATION 6. CONCLUSIONS KASPERKIEWICZ

4. ( ~ a continuation of the Paisley 2003 paper - DSI setup, CP, concrete... ) ACOUSTIC EMISSION and AE SIGNALS PROCESSING MACHINE LEARNING IDENTIFICATION of the components KASPERKIEWICZ

5. Vickers indenter LVDT sensor tested area KASPERKIEWICZ

6. KASPERKIEWICZ

7. D1 D2 D.S.I. D1 ≈D2 ≈ 550μm Cement Past – water-cement ratio: 0.60; loading level: 40 N KASPERKIEWICZ

8. D1 ≈D2 ≈ 350μm aggregate air void D2 air void aggregate D1 Concrete; loading level: 45 N KASPERKIEWICZ

9. D 1 . 85437 F = HV 2 D KASPERKIEWICZ

10. cement paste (each point an average of about 10 indentations) KASPERKIEWICZ

11. cement paste with metakaolin KASPERKIEWICZ

12. cement paste ... metakaolin effect KASPERKIEWICZ

13. cement paste ... fly ash effect KASPERKIEWICZ

14. 0 1 2 ... ... 19... ... 24 25 1pd ... 0pd 2pd ... ... 23pd 25pd ...24pd a set of 52 indentation imprints for example: upper imprints No-s: 1, 6÷9, 11÷18 - aggregate KASPERKIEWICZ

15. No.1 No.7 No-s: 1, 7 ... - aggregate KASPERKIEWICZ

16. No.3 No.3 – air void edge KASPERKIEWICZ

17. concrete ... (time effect observations) KASPERKIEWICZ

18. HV – approx.: ( rock ) D . . = 7 00006 δ 1700 MPa 4300 ( test No.: 5sR9 ) 2700 5300 165 (No.1) 170 (No.6) F 1 . 85437 F = HV 2 D δ KASPERKIEWICZ

19. HV – approx.: ( cement paste ) 650 1500 470 MPa 1000 KASPERKIEWICZ

20. ( a sample under consideration ) 600 700 HV – approx.: 1400 500 MPa 1000 164 (No.0) KASPERKIEWICZ

21. it is possible to evaluatethe strength of the material; what about theidentification of its composition? KASPERKIEWICZ

22. Acoustic Signal Sensor AEMonitoringSystem AE Signaldetection,recording,etc. SoundWave SoundWave IndentationNoiseSource AcousticEmissionWave KASPERKIEWICZ

23. ( signal from the Test No.: 5sR9 05 ) amplitude: -1.5 to +1.5 V time: 0 to 5 s KASPERKIEWICZ

24. time: 5 s KASPERKIEWICZ

25. time: 2 s KASPERKIEWICZ

26. time: 2 s KASPERKIEWICZ

27. time: 0.5 s KASPERKIEWICZ

28. time: 0.3 s KASPERKIEWICZ

29. time: 0.14 s KASPERKIEWICZ

30. time: 0.003 s KASPERKIEWICZ

31. time: 0.4 ms KASPERKIEWICZ

32. time: 0.1 ms ( about 100 μs ) KASPERKIEWICZ

33. ( no silica CP ) ( silica CP ) ( stone aggregate ) KASPERKIEWICZ

34. KASPERKIEWICZ

35. ( signal transformation ) KASPERKIEWICZ

36. Different possibilities of AE signal representations Natural representation Fourier, (FT, FFT) Windowed Fourier Wavelet analysis KASPERKIEWICZ

37. initial 440 ms KASPERKIEWICZ

38. time [ms] time: 0.4 ms KASPERKIEWICZ

39. KASPERKIEWICZ

40. t[ms] ( Test No.: 5sR9 05 ) H (375kHz÷39kHz) M (46kHz÷18kHz) NOISE L (6kHz÷4kHz) KASPERKIEWICZ

41. lzdH - No. of events in range HlzdM - No. of events in range MlzdL – No. ... etc. senHsenMsenL sazHsazMsazL - ... amplitude in range L serial No. indent class (e.g. "a", "cp1", ...)material composition ... etc. KASPERKIEWICZ

42. tests results database ( in Excel ) aggregate cement paste ITZ KASPERKIEWICZ

43. ( Machine Learning ) KASPERKIEWICZ

44. Rec. No. 219 air content 7.3%fc28 45 MPaair voids spacing 0.21 mmaggregate ?...silica No Rec. No. 113 air content 2.4%fc28 27 MPaair voids spacing 0.23 mmaggregate ?...silica No Rec. No. 116 air content 4.5%fc28 26 MPaair voids spacing 0.25 mmaggregate granite...silica No Rec. No. 115 air content 4.5%fc28 26 MPaair voids spacing 0.25 mmaggregate granite...silica No Rec. No. 2 air content 6%fc28 ?air voids spacing 0.25 mmaggregate granite...silica Yes Rec. No. 114 air content 4.5%fc28 26 MPaair voids spacing 0.25 mmaggregate gravel...silica Yes Rec. No. 1 air content 2.4%fc28 37 MPaair voids spacing 0.35 mmaggregate basalt...silica No positive examples negative examples KASPERKIEWICZ

45. Machine Learning solutions: • AQ algorithms (Michalski) • See 5 (Quinlan) • WinMine (Microsoft) • ?... KASPERKIEWICZ

46. WinMine KASPERKIEWICZ

47. ┌ 23.00 ≤ lzdM ≤ 233.50 ┐ AND ┌ sazM < 28.00 ┐ KASPERKIEWICZ

48. summary of the tests here there was no silica KASPERKIEWICZ

49. Microindentationand AE (Acoustic Emission) observations make possible identification of structural characteristics of concrete materials. In particular possible was an indirect identification of a silica additive presence in hardened concrete. It is expected that the same approach could be used to discriminate signals in aggregate grains (stone) from those and in cement paste or mortar. The procedure involves AE signal transformation followed by machine learning rules detection processing, resulting in hypotheses formulated in everyday language. KASPERKIEWICZ

50. The experiments should be continued, aimed - e.g. – to establishing what are optimal settings of AE data acquisition system, structural points better identification, selection of the proper procedure timing, etc. The proposed procedure may by important for hardened concrete diagnostics, perhaps also in case of certain forensic analysis situations, when the problem is to find out whether a silica fume was actually used as a component of a given concrete mix or not. KASPERKIEWICZ