Журнал Российского общества по неразрушающему контролю и технической диагностике
The journal of the Russian society for non-destructive testing and technical diagnostic
 
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23 | 11 | 2024
2023, 09 September

DOI: 10.14489/td.2023.09.pp.027-041

Murav’eva O. V., Brester A. F., Vladykin A. L.
REGULARITIES OF THE FIELD FOCUS OF THE THROUGH-TYPE ELECTROMAGNETIC ACOUSTIC TRANSDUCER OF TRANSVERSE WAVES
(pp. 27-41)

Abstract. The article presents the results of experimental and theoretical research of the influence of the characteristics of a through-type electromagnetic-acoustic transducer and testing object on the focusing parameters of transverse waves using COMSOL Multiphysics. It is shown that in the radial plane of the section, the formation of a converging spherical front is observed, in the axial plane – close to a flat front. The influence on the focusing factor and the diameter of the focal spot of the diameter of the object, the operating frequency and the quality factor of the excitation pulse is presented. The developed model of the formation of the focus zone of the through-type EMAT can be used in the analysis of the acoustic path of the mirror-shadow method of multiple shadow, depending on the characteristics of the object and control parameters.

Keywords: acoustic wave focusing, through-type electromagnetic acoustic transducer, transverse wave, simulation.

O. V. Murav’eva (Kalashnikov Izhevsk State Technical University, Izhevsk, Russia, Udmurt Federal Research Center, Ural Branch, Russian Academy of Sciences, Izhevsk, Russia) E-mail: Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.
A. F. Brester, A. L. Vladykin (Kalashnikov Izhevsk State Technical University, Izhevsk, Russia) E-mail: basharova.af @gmail.com, Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.

1. Rudenko O. V. (2022). Nonlinear Acoustics in Medicine: A Review. Physics of Wave Phenomena, 30(2), 73 – 85. DOI: 10.3103/S1541308X22020066. EDN:IAQTPU.
2. Chupova D. D., Rosnitskiy P. B., Gavrilov L. R. et al. (2022). Compensation for distortions of focused ultrasound beams during transcranial irradiation of the brain at different depths. Akusticheskiy zhurnal, 68(1), 3 – 13. [in Russian language] DOI: 10.31857/S0320791922010014. EDN: WZMRBZ.
3. Andreeva T. A., Berkovich A. E., Bykov N. Yu. et al. (2020). High Intensity Focused Ultrasound: Thermal Heating and Destruction of Biological Tissue. Zhurnal tekhnicheskoy fiziki, 90(9), 1516 – 1527. [in Russian language] DOI: 10.21883/JTF.2020.09.49685.54-20. EDN: OEKCOO.
4. Osipov L. V., Kul'berg N. S., Leonov D. V. et al. (2018). Three-dimensional ultrasound: technologies, development trends. Meditsinskaya tekhnika, 309(3), 39 – 43. [in Russian language] EDN: NRLLKN.
5. Osipov L. V., Kul'berg N. S., Leonov D. V. et al. (2020). 3D Ultrasound: Features of Volume Data Visualization. Meditsinskaya tekhnika, 320(2), 51 – 55. [in Russian language] EDN: MECVNJ.
6. Pankov V. V., Pomerantsev D. S. (2020). Ultra-sound testing with using of the phased array probes. Basic principles. Part 1. Phased array technology, terminology and standardization. Kontrol'. Diagnostika, (3), 38 – 43. [in Russian language] DOI: 10.14489/td.2020.03.pp.038-043. EDN: FMKUDC.
7. Titov V. Yu. (2021). Investigation parameters ultrasonic device on phased arrays. Focusing modes for ultrasonic device type of OmniScan. Kontrol'. Diagnostika, 278(8), 24 – 35. [in Russian language] DOI: 10.14489/td.2021.08.pp.024-035. EDN: ENILTU.
8. Kachanov V. K., Sokolov I. V., Kontsov R. V. et al. (2019). Using the “focusing to a point” algorithm for standard-free measurement of ultrasound velocity in tomography of building structures made of concrete. Defektoskopiya, (6), 20 – 29. [in Russian language] DOI: 10.1134/S0130308219060034. EDN: IMSJVX.
9. Bazulin A. E., Bazulin E. G., Vopilkin A. H. et al. (2022). Inspection of Samples from Polymer Composite Materials Using Ultrasonic Antenna Arrays. Defektoskopiya, (6), 3 – 16. [in Russian language] DOI: 10.31857/ S013030822206001X. EDN: BMGAYP.
10. Efimov I. M. (2019). Modern equipment for ultrasonic testing of welded joints. V mire nerazrushayushchego kontrolya, 22(3), 36 – 40. [in Russian language] DOI: 10.12737/article_5d5fd14cb04e89.60292443. EDN: FEYZZI.
11. Morokov E. S., Levin V. M. (2019). Spatial resolution of acoustic microscopy in the visualization of interfaces in the bulk of a solid material. Akusticheskiy zhurnal, 65(2), 190 – 196. [in Russian language] DOI: 10.1134/ S0320791919020102. EDN: YYEMGL.
12. Shevaldykin V. G., Samokrutov A. A. (2022). Digital focusing of the aperture when probing the test object by all elements of the antenna array in one transmission-reception cycle. Defektoskopiya, (2), 13 – 27. [in Russian language] DOI: 10.31857/ S0130308222020026. EDN: IJZPAT.
13. Bazulin E. G. (2017). Ultrasonic testing of welded joints of pipeline type Du800. Part 1. Reconstruction of the image of reflectors by the method of digital focusing with an antenna. Defektoskopiya, (3), 12 – 26. [in Russian language] EDN: YIXPHH.
14. Samokrutov A. A., Shevaldykin V. G. (2017). Evaluation of defects in ultrasonic testing by digital focused array technique. The conditions, possibilities, boundaries of the applicability. Kontrol'. Diagnostika, (9), 6 – 18. [in Russian language] DOI: 10.14489/td.2017.09.pp.006-018. EDN: ZEOPOR
15. Tkocz J., Greenshields D., Dixon S. (2019). High power phased EMAT arrays for nondestructive testing of ascast steel. NDT & E International, 102, 47 – 55. DOI: 10.1016/j.ndteint.2018.11.001.
16. Thring C. B., Fan Y., Edwards R. S. (2016). Focused Rayleigh wave EMAT for characterisation of surface-breaking defects. NDT & E International, 81, 20 – 27. DOI: 10.1016/j.ndteint.2016.03.002.
17. Liu J., Liu S., Zhang C. et al. (2022). A New Focused EMAT Design with Narrow Magnet to Achieve Both A0-Lamb Signal Enhancement and Waveform Distortion Correction. IEEE Sensors Journal, 15, 14786 – 14798. DOI: 10.1109/JSEN.2022.3185616.
18. Thring C. B., Hill S. J., Dixon S., Edwards R. S. (2019). The effect of EMAT coil geometry on the Rayleigh wave frequency behavior. Ultrasonics, 99. DOI: 10.1016/j.ultras. 2019.06.007.
19. Clough M., Fleming M., Dixon S. (2017). Circumferential guided wave EMAT system for pipeline screening using shear horizontal ultrasound. NDT & E International, 86, 20 – 27. DOI: 10.1016/j.ndteint.2016.11.010.
20. Hongyu Sun, Songling Huang, Qing Wang et al. (2020). Orthogonal Optimal Design Method for Point-Focusing EMAT Considering Focal Area Dimensions. Sensors and Actuators A: Physical, 312. DOI: 10.1016/j.sna.2020.112109.
21. Sun H., Wang S., Huang S. et al. (2020). Point-Focusing Shear-Horizontal Guided Wave EMAT Optimization Method Using Orthogonal Test Theory. IEEE Sensors Journal, 20(12), 6295 – 6304. DOI: 10.1109/JSEN.2020.2976198.
22. Min He, Wenze Shi, Chao Lu et al. (2023). Application of pulse compression technique in metal materials cracks detection with LF-EMATs. Nondestructive Testing and Evaluation, 45 – 66. DOI: 10.1080/10589759.2022.2066664
23. Suhorukova O. B., Shvetsova N. A., Shvetsov I. A. et al. (2018). Theoretical calculations and numerical simulation of focused ultrasonic fields. Vestnik Rostovskogo gosudarstvennogo universiteta putey soobshcheniya, 70(2), 154 – 165. [in Russian language] EDN: XRKYWT.
24. Shvetsov I. A., Shcherbinin S. A., Astaf'ev P. A. et al. (2018). Numerical modeling and optimization of acoustic fields and designs of high-intensity focusing ultrasonic transducers. Izvestiya Rossiyskoy akademii nauk. Seriya fizicheskaya, 82(3), 405 – 408. [in Russian language] DOI: 10.7868/S0367676518030328. EDN: YTFVWT.
25. Murav'eva O. V., Petrov K. V. (2019). Acoustic field formed under conditions of pulsed radiation-reception on the surface of an elliptical cylinder. Akusticheskiy zhurnal, 65(1), 110 – 119. [in Russian language] DOI: 10.1134/ S0320791919010064. EDN: YWYHDF.
26. Petrov K. V., Murav'eva O. V., Myshkin Yu. V., Basharova A. F. (2019). Modeling of magnetic, electric and acoustic fields of a transducer for testing cylindrical objects. Defektoskopiya, (2), 16 – 24. [in Russian language] DOI 10.1134/S0130308219020027. EDN YYTNIT.
27. Michurov A. V., Sokolkin A. V. (2020). Calculation of the influence on the acoustic field of refractions and reflections on curved surfaces of shells of revolution. Defektoskopiya, (1), 31 – 43. [in Russian language] DOI: 10.31857/S0130308220010042. EDN: MZVWEM.
28. Gutiérrez M. I., Vera A., Leija L. et al. (2017). Acoustic field modeling of focused ultrasound transducers using non-uniform radiation distributions. 14th International Conference on Electrical Engineering, Computing Science and Automatic Control (CCE), 1 – 4. Mexico. DOI: 10.1109/ICEEE.2017.8108871.
29. Jun Zhang, Yi Chen, Liuqing Yang. (2019). Numerical calculation and measurement for the focus field of concave spherical acoustic lens transducer. MATEC Web Conference, 283. DOI: 10.1051/matecconf/201928305007.
30. Borisov V. I., Sergeev S. S., Prokopenko E. N. et al. (2017). The structure of the acoustic field of radiation of focusing piezoelectric transducers. Vestnik Belorussko-Rossiyskogo universiteta, 54(1), 119 – 127. [in Russian language] DOI: 10.53078/20778481_2017_1_119. EDN: YFMGUH.
31. Yushchenko V. P., Edvabnik V. G., Gofman O. V. et al. (2020). Method for reconstructing an object image using an annular array. Avtometriya, 56(6), 68 – 77. [in Russian language] DOI: 10.15372/AUT20200608. EDN: IWLKQF.
32. Shvetsov I. A., Shcherbinin S. A., Shvetsova N. A. et al. (2019). Experimental study of high intensity focused ultrasonic fields generated by piezocomposite transducers. Ferroelectrics, 539(1), 118 – 125. DOI: 10.1080/00150193.2019.1570021. EDN: PNDGRJ.
33. Rybyanets A. N., Shvetsov I. A., Petrova E. I. et al. (2019). Numerical simulation and optimization of acoustic fields and designs of composite HIFU transducers. Ferroelectrics, 543(1), 48 – 53. DOI: 10.1080/00150193.2019.1592447.
34. Ermolin K. S., Shelkovnikov Yu. K., Osipov N. I. (2019). Investigation of the model of propagation of ultrasonic vibrations in an immersion medium with a sample. Polzunovskiy al'manah, (4), 39 – 43. [in Russian language] EDN: UNYECR.
35. Murav'eva O. V., Sokov M. Yu., Myshkin Yu. V. (2018). Formation of the acoustic field of the transducer in threaded parts. Intellektual'nye sistemy v proizvodstve, 16(4), 45 – 56. [in Russian language] DOI: 10.22213/2410-9304-2018-4-45-56. EDN: VQLEPG.
36. Murav'eva O. V., Myshkin Yu. V., Nagovitsyn A. A. (2023). On the issue of increasing the efficiency of a through electromagnetic-acoustic transducer of longitudinal waves. Defektoskopiya, (3), 3 – 13. [in Russian language] DOI: 10.31857/ S0130308223030016. EDN: OOQZWK.
37. Petrov K. V., Sokov M. Yu., Murav'eva O. V. (2018). The Influence of Design Features of a Pass-Through Electromagnetic-Acoustic Transducer on the Results of Inspection of Cylindrical Objects. Vestnik IzhGTU im. M. T. Kalashnikova, 21(2), 135 – 146. [in Russian language] DOI: 10.22213/2413-1172-2018-2-135-146. EDN: URBGKH.
38. Murav'ev V. V., Budrin A. Yu., Sintsov M. A. (2020). Structuroscopy of heat-treated steel bars by the propagation velocity of Rayleigh waves. Intellektual'nye sistemy v proizvodstve, 18(2), 37 – 43. [in Russian language] DOI: 10.22213/2410-9304-2020-2-37-43. EDN: VGDDFW.
39. Murav'eva O. V., Murav'ev V. V., Basharova A. F. et al. (2020). Effect of Heat Treatment and Structural State of Steel 40Kh Bar Gauge on Ultrasonic Wave Velocity and Poisson's Ratio. Stal', (8), 63 – 68. [in Russian language] EDN: MKTWDN.
40. Murav'ev V. V., Murav'eva O. V., Vagapov T. R. et al. (2023). Acoustic and electromagnetic properties of blanks of barrels of civilian guns. Intellektual'nye sistemy v proizvodstve, 21(1), 59 – 70. [in Russian language] DOI: 10.22213/2410-9304-2023-1-59-70. EDN: KBBVGW.
41. Verzhbitskiy V. M. (2013). Numerical methods of mathematical physics. Moscow: Direkt-Media. [in Russian language]
42. Murav'eva O. V., Brester A. F., Murav'ev V. V. (2022). Comparative Sensitivity of Informative Parameters of the Electromagnetic-Acoustic Mirror-Shadow Method on Multiple Reflections in the Control of Bars. Defektoskopiya, (8), 36 – 51. [in Russian language] DOI: 10.31857/ S0130308222080048. EDN: BQEKGO.

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