Evaluation of Mechanical Property of 24CrNi Alloy Steel Using Reconstituted Hysteresis Loops Parameters Using Magnetic Barkhausen Noise
LYU Ruiyang1, 2, SONG Kai2, DONG Shiyun2, MEN Ping2, KANG Xueliang2, YAN Shixing2, LIU Xiaoting2
1 Key Laboratory of Nondestructive Testing of Ministry of Education, Nanchang Hangkong University, Nanchang 330063, China 2 National Key Laboratory for Remanufacturing, Army Academy of Armored Force, Beijing 100072, China
Abstract: To estimating the uniformity of microstructures and the mechanical properties of alloy steel quickly, quantitatively and non-destructively, a comprehensive evaluation of the reconstituted hysteresis characteristic parameters based on the magnetic Barkhausen noise non-destructive testing method was conducted. The low-frequency sine wave was used as the excitation signal to analyze the mapping relation between the reconstituted hysteresis parameters of the magnetic Barkhausen noise signal and the hardness, tensile strength-microstructure of the alloy steel. The calibration model for quantitative evaluation of the strength of alloy steel was carried out, and the calibration model was verified. The research shows that the reconstituted residual magnetism, reconstituted hysteresis loss can be used as quantitative parameters to predict the hardness as well as tensile strength of alloy steel specimens,the prediction error of calibrated model will increase while the constituted parameters exceed the specific interregion. The reconstituted coercivity and reconstituted maximum magnetic permeability cannot be used to predict the hardness and tensile strength of alloy steel but can be used as an important reference for material microstructure uniformity of alloy steel.
吕瑞阳, 宋凯, 董世运, 门平, 康学良, 闫世兴, 刘晓亭. 24CrNi合金钢力学性能重构磁滞参量定量评价[J]. 材料导报, 2020, 34(14): 14168-14174.
LYU Ruiyang, SONG Kai, DONG Shiyun, MEN Ping, KANG Xueliang, YAN Shixing, LIU Xiaoting. Evaluation of Mechanical Property of 24CrNi Alloy Steel Using Reconstituted Hysteresis Loops Parameters Using Magnetic Barkhausen Noise. Materials Reports, 2020, 34(14): 14168-14174.
1 Qian Z C, Huang H H, Jiang S L, et al. Journal of Electronic Measurement and Instrumentation, 2016, 30(4),506(in Chinese). 钱正春, 黄海鸿, 姜石林, 等. 电子测量与仪器学报, 2016, 30(4), 506. 2 Wu D H, Liu Z T, Wang X H. Chinese Journal of Scientific Instrument, 2017, 38(6), 1490(in Chinese). 吴德会, 刘志天, 王晓红, 等. 仪器仪表学报, 2017, 38(6),1490. 3 Yang Y M, Wang Z, Qin H,et al. Foundry, 2009(3), 287(in Chinese). 杨玉民, 王忠, 秦怀, 等. 铸造, 2009(3), 287. 4 Durin G, Zapperi S. Physics, 2006, 13(4), 461. 5 Barkhausen H. Physik Z, 1919, 20, 401. 6 Parakka A P, Jiles D C, Gupta H, et al. Journal of Applied Physics, 1997, 81(8), 5085. 7 Moorthy V, Vaidyanathan S, Jayakumar T, et al. Journal of Magnetism and Magnetic Materials, 1997, 171(1-2), 179. 8 Monlevade E F, De Campos M F, Franco F A, et al. IEEE Transactions on Magnetics, 2012, 48(4),1465. 9 Anglada-Rivera J, Padovese L R, Capó-Sánchez J. Journal of Magnetism and Magnetic Materials, 2001, 231(2-3), 299. 10 Jiles D C. Czechoslovak Journal of Physics, 2000, 50(8), 893. 11 Sun G M, Liu H, He C F, et al. Journal of Beijing University of Techno-logy, 2019, 45(2), 21(in Chinese). 孙光民, 刘浩, 何存富, 等. 北京工业大学学报, 2019, 45(2), 21. 12 Cheng Z Y, Song K, Men P, et al. Chinese Journal of Scientific Instrument, 2018, 39(10), 117(in Chinese). 程志远, 宋凯, 门平, 等. 仪器仪表学报, 2018, 39(10), 117. 13 Zapperi S, Castellano C, Colaiori F, et al. Nature Physics, 2012, 1,46. 14 Ding S, Tian G Y, Dobmann G, et al. Journal of Magnetism and Magnetic Materials, 2017, 421, 225. 15 ternberk J, Kratochvílová E, Gemperle A, et al. Czechoslovak Journal of Physics B, 1985, 35(11),1259. 16 Wolf R B W P. American Scientist, 1970, 58(4),440. 17 Bertotti G. IEEE Transactions on Magnetics, 1988, 24(1),621.