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Abstract

Torsion tests on 50 Mn steel wire were implemented and illustrated in this research to probe into the relationship between normal components of self-magnetic-flux-leakage (SMFL) signals H _p(y) and early damage of steel wire subjected to torsional stress. Besides, a modified model with due consideration of coercivity and permeability varying with equivalent stress at elastic-plastic stage was presented to simulate H _p(y) signals of steel wire under torsion accurately. Relevant numerical simulations of magneto-mechanical coupling were performed. The results show that using zero crossing point (ZCP) of H _p(y) signals to identify defect location does not apply to steel wire under torsion. However, there is crest (or trough) showing on magnetic signal curve prior to fracture. By utilizing location of crest (or trough), damage could be positioned accurately and ultimate fracture point could be forecasted in advance as well. Furthermore, simulation results obtained from the modified model are consistent with test results. Not only can study results demonstrate that MMM technique could be used for determining early damage of steel wire under torsion, but also provide certain reference for quantitative analysis about the relationship between damage and H _p(y) signals.

Keywords

Steel wire torsion magnetic memory method damage location magneto-mechanical coupling

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References

Chien

C.H.

LeClair

R.A.

and Costello

G.A.

, Strength and fatigue life of wire rope, Journal of Structural Machines 213(2) (1998), 213–223.

Zhang

Wang

D.G.

Zhang

D.K.

S.R.

and Wang

D.A.

, Dynamic torsional characteristics of mine hoisting rope and its internal spiral components, Tribology International 109(2017) 182–191.

Jomdecha

and Prateepasen

, Design of modified electromagnetic main-flux for steel wire rope inspection, Ndt & E International 42(1) (2009), 77–83.

Yao

Deng

and Wang

Z.D.

, Numerical studies to signal characteristics with the metal magnetic memory-effect in plastically deformed samples, Ndt & E International 42(2) (2012), 7–12.

Doubov

A.A.

, A study of metal properties using the method of magnetic memory, Metal Science & Heat Treatment 39(9–10) (1997), 401–405.

Doubov

A.A.

, Screening of weld quality using the magnetic metal memory effect, Weld in the World 41(3) (1998), 196–199.

Doubov

A.A.

, Development of a metal magnetic memory method, Chemical & Petroleum Engineering 47(11–12) (2012), 837–839.

Yao

Wang

Z.D.

Deng

and Shen

, Experimental research on metal magnetic memory method, Experimental Mechanics 52(3) (2012), 305–314.

Huang

H.L.

Jiang

S.L.

Yang

and Liu

Z.F.

, Stress concentration impact on the magnetic memory signal of ferromagnetic structural steel, Nondestructive Testing & Evaluation 29(4) (2014), 377–390.

10.

K.S.

Qiu

X.Q.

and Tian

X.S.

, Investigation of metal magnetic memory signals of welding cracks, Journal of Nondestructive Evaluation 36(2) (2017), 20–27.

11.

Bao

M.L.

Y.B.

and Lou

H.J.

, Quantitative characterization of stress concentration of low-carbon steel by metal magnetic memory testing, Materials Evaluation 75(3) (2017), 397–405.

12.

Kolařík

Šimeček

Kříž

and Čapek

, Using the Barkhausen-noise analysis and metal-magnetic-memory method for material characteristics under fatigue damage, Materiali in Tehnologije 51(3) (2017), 437–441.

13.

Zhong

L.Q.

L.M.

and Chen

, Simulation of magnetic field abnormalities caused by stress concentrations, IEEE Transactions on Magnetics 49(3) (2013), 1128–1134.

14.

Yao

Shen

Wang

Z.D.

and Wang

Y.S.

, Three-dimensional finite element analysis of residual magnetic field for ferromagnets under early damage, Journal of Magnetism & Magnetic Materials 354(3) (2014), 112–118.

15.

Shi

P.P.

Jin

and Zheng

X.J.

, A general nonlinear magnetomechanical model for ferromagnetic materials under a constant weak magnetic field, Journal of Applied Physics 119(145103) (2016), 1–8.

16.

Wang

Z.D.

Yao

Deng

and Ding

K.Q.

, Quantitative study of metal magnetic memory signal versus local stress concentration, NDT & E International 43(6) (2010), 513–518.

17.

Kuleev

V.G.

and Tsar’Kova

T.P.

, Magnetoelastic effect in plastically deformed ferromagnetic steels in weak magnetic fields, Physics of Metals & Metallography 108(3) (2009), 217–225.

18.

Jiles

D.C.

and Li

, A new approach to modeling the magnetomechanical effect, Journal of Applied Physics 95(11) (2004), 7058–7060.

19.

Hornreich

R.M.

Rubinstein

and Spain

R.J.

, Magnetostrictive phenomena in metallic materials and some of their device applications, Magnetics IEEE Transactions on 7(1) (1971), 29–48.

20.

Wang

Z.D.

and Wang

Y.S.

, A review of three magnetic NDT technologies, Journal of Magnetism & Magnetic Materials 324(4) (2012), 382–388.

21.

Jiles

D.C.

, The effect of compressive plastic deformation on the magnetic properties of AISI 4130 steels with various microstructures, Journal of Physics D Applied Physics 21(7) (1988), 1196.

22.

Makar

J.M.

and Tanner

B.K.

, The effect of plastic deformation and residual stress on the permeability and magnetostriction of steels, Journal of Magnetism & Magnetic Materials 222(3) (2000), 291–304.

23.

Shi

P.P.

Jin

and Zheng

X.J.

, A magnetomechanical model for the magnetic memory method, International Journal of Mechanical Sciences 124 (2017), 229–241.

24.

Stupakov

Pal’A

Tomáš

Bydžovský

and Novák

, Investigation of magnetic response to plastic deformation of low-carbon steel, Materials Science & Engineering A 462(1) (2007), 351–354.

25.

Iordache

V.E.

Hug

and Buiron

, Magnetic behaviour versus tensile deformation mechanisms in a non-oriented Fe–(3 wt.%)Si steel, Materials Science & Engineering A 359(1) (2003), 62–74.

26.

S.Q.

S.C.

Wang

Sun

H.J.

and Ren

G.C.

, Bending experimental study of structural steel beam on magnetic field gradient based on modified Jiles-Atherton model, International Journal of Applied Electromagnetics & Mechanics 55(3–4) (2017), 1–13.

27.

Daniel

and Hubert

, Equivalent stress criteria for the effect of stress on magnetic behavior, Magnetics IEEE Transactions on 46(8) (2010), 3089–3092.

28.

Wang

Z.D.

Deng

and Yao

, Physical model of plastic deformation on magnetization in ferromagnetic materials, Journal of Applied Physics 109(8) (2011), 72–687.

29.

Ren

J.L.

and Lin

J.M.

, Fundamental theory of electromagnetism, in: Electromagnetic Nondestructive Testing, Beijing Science Press, 2008, pp. 32–33. (In Chinese).

Damage location and numerical simulation for steel wire under torsion based on magnetic memory method

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