RESEARCH ON THE DISTRIBUTION OF MAGNETIC FIELD IN REINFORCED CONCRETE BEAMS AFTER DAMAGE BASED ON THE FORCE–MAGNETIC COUPLING MODEL, 130-137.

Yu-chao Xia and Zhen Li

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References

  1. [1] A.A. Dubov, A study of metal properties using the method of magnetic memory, Metal Science & Heat Treatment, 39(9), 1997, 401–405. https://doi.org/10.1007/BF02469065.
  2. [2] A.A. Dubov, Monitoring the stressed-strained state of pipelines, Tyazheloe Mashinostroenie, 11, 2004, 33–35.
  3. [3] D.W. Yin, B.S. Xu, S.Y. Dong, et al., Characteristics of magnetic memory signals for medium carbon steel under static tensile conditions, Journal of Central South University, 12(s2), 2005, 107–111. https://doi.org/10.1007/s11771-005-0020-2.
  4. [4] M.L. Zhang, Z.Y. Guo, X.B. Han, B. Wang, H.T. Wei, and Q. Gao, Analysis of coupled water and heat transfer in frozen soil based on mathematical module of COMSOL multiphysics, Science Technology and Engineering, 18(33), 2018, 7–12.
  5. [5] Z.H. urek, Magnetic contactless detection of stress distribution and assembly defects in constructional steel element, Ndt & E International, 38(7), 2005, 589–595. https://doi.org/10.1016/j.ndteint.2005.02.011.
  6. [6] M. Roskosz and M. Bieniek, Evaluation of residual stress in ferromagnetic steels based on residual magnetic field measurements, Ndt & E International, 45(1), 2012, 55–62. https://doi.org/10.1016/j.ndteint.2011.09.007.
  7. [7] J.M. Lin, F.B. Lin, C.J. Lin, and S.F. Lin, Development of EMS-2000 metal magnetic memory diagnostic instrument, Nondestructive Testing, 24(4), 2002, 168–170.
  8. [8] A.A. Dubov, Diagnostics of austenitic-steel tubes in the super heaters of steam boilers using scattered magnetic fields, Thermal Engineering, 46(5), 1999, 369–372.
  9. [9] A.A. Doubov, Express method of quality control of a spot resistance welding with usage of metal magnetic memory, Welding in the World, 46(spec), 2002, 317–320.
  10. [10] P. Wang, S. Zhu, G.Y. Tian, et al., Stress measurement using magnetic Barkhausen noise and metal magnetic memory testing, Measurement Science & Technology, 21(5), 2010, 055703.
  11. [11] F. Melquiond, A. Mouroux, J. Jouglar, et al., History dependence of magneto mechanical properties of steel, Journal of Magnetism & Magnetic Materials, s157–158(157), 1996, 571–572.
  12. [12] N. Saeid, T. Alireza, and G. Reza, Neuro-predictive controller for stabilization of gimbal mechanism with crosscoupling, Mechatronic Systems and Control, 49(3), 2021. https://doi.org/10.2316/J.2021.201-0198.
  13. [13] R. Sudhir, Decentralized control for stabilization of coupled pendulums using h -based integral sliding mode control, Mechatronic Systems and Control, 48(1), 2020. https://doi.org/10.2316/J.2020.201-0013.
  14. [14] I.M. Gadala, B. Li, M.Q.-H. Meng, and C.W. de Silva, An expert system for motor sizing using mechanical dynamics and thermal characterization, Mechatronic Systems and Control, 48(1), 2020. https://doi.org/10.2316/J.2020.201-0032.
  15. [15] W. Zhang, Study on the Influence of Steel Corrosion on Seismic Capacity of Concrete Piers (Shijiazhuang Tiedao University, 2018).
  16. [16] Y. Liang, C. Ren, H. Niu, and J. Li, Time varying seismic performance analysis of durability damaged rigid frame bridge pier in offshore environment, Journal of Railway Science and Engineering, 16(04), 2019, 968–975.
  17. [17] G.X. Guo, Study on the Influence of Different Corrosion Locations and Hydrodynamic Pressure on the Seismic Performance of RC Bridge Piers (Ludong University, 2019).
  18. [18] S.W. Zhang, Study on Seismic Hydrodynamic Pressure of Bridge Pier in Deep Water (Institute of Engineering Mechanics, CEA, 2019).

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