Robust solutions of inverse problems in electromagnetic non-destructive evaluation

Altpeter, I.; Becker, R.; Dobmann, Gerd; Kern, R.; Theiner, W.A.; Yashan, Andreij

doi:10.1088/0266-5611/18/6/328

Cited by 58 publications

(41 citation statements)

References 7 publications

(17 reference statements)

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“…7, there are two peaks in each group of MBN signals, the lower peak depends on the content of cementite and the higher peak is caused by ferrite phase. 19) Though the micro-defect information is included in the MBN signals, a proper signal index is very important to correlate the defect information and the signal. Index values (feature parameter of MBN signals) such as the "Energy" of the MBN signal have been proposed.…”

Section: Testing Principle and Procedures 231 Mbn Methodsmentioning

confidence: 99%

Quantitative Nondestructive Evaluation of Plastic Deformation in Carbon Steel Based on Electromagnetic Methods

et al. 2014

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Plastic deformation may occur in a mechanical structure during its manufacturing and service process, and may cause serious problem in the structural integrity. Therefore, a reliable pre-service or in service quantitative non-destructive evaluation (NDE) of plastic deformation is very important especially for a structure after suffering giant load such as a large earthquake. However, there is still no satisfactory method being established for the quantitative NDE of plastic deformation in key structures such as those of a nuclear power plant. For this purpose, three electromagnetic NDE methods, i.e., Magnetic Barkhausen Noise (MBN), Magnetic Incremental Permeability (MIP) and Magnetic Flux Leakage (MFL) method are studied via experiments in this paper to investigate their feasibility for evaluation of plastic deformation in carbon steel SS400. A special testing system integrated these three electromagnetic NDE methods is established to measure the magnetic property of testpieces with different plastic deformation, which was introduced by a tensile testing machine. It is found that the measurement signals of all these three methods have clear correlation with the plastic strains and show coincident tendency, which reveals the validity of these methods for the quantitative evaluation of plastic deformation. Among these methods, the MFL signals are of higher stability and repeatability but of relative low spatial resolution. The MBN method can give better resolution but of bigger standard deviation and is also not valid to evaluate a plastic strain of large scale. On the other hand, the MIP signals are more sensitive to the liftoff of sensor and to the remanent magnetization status, i.e. of more noise. Therefore, to measure the feature parameters of these three methods at the same time with an integrated testing system and to evaluate the plastic strain through signal fusion may give a better detectability and evaluation precision.

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Section: Testing Principle and Procedures 231 Mbn Methodsmentioning

confidence: 99%

Quantitative Nondestructive Evaluation of Plastic Deformation in Carbon Steel Based on Electromagnetic Methods

et al. 2014

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“…2 is a characteristic of the material and/or component being considered. A large number of parameters have been derived from a variety of research work performed [17,18], where Fraunhofer IZFP has currently identified 42 of those. Major characteristics of a magnetic hysteresis is the saturation level, the magnetic flux at H = 0 called remanence and the field strength required to achieve B = 0 called coercivity.…”

Section: Magnetics Phenomenamentioning

confidence: 99%

Electromagnetism as a means for understanding materials mechanics phenomena in magnetic materials

Boller

Altpeter

Dobmann

et al. 2011

Materialwissenschaft Werkst

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Electromagnetic properties are an interesting means for monitoring a variety of materials' mechanical properties in ferro- and paramagnetic materials non-destructively. Those properties include uni- und multi-axial stress states as well as plasticity and fatigue damage and can be measured at macro- as well as at microscopic scales, depending on what measurement equipment will be used. The article describes the general electromagnetic phenomena to be considered as well as the equipment to be used before presenting a variety of different experimental results from which the materials mechanical properties mentioned above can be directly derived being an ideal means for monitoring the health of any magnetic metallic structure

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“…Generally in a quasi-static frequency triangular waveform magnetic excitation condition, the excitation voltage (V E ) applied across the coil around the EM yoke is linearly related to the applied magnetic field strength (H a ) measured at the centre of the air gap between the poles of an EM yoke (in open magnetic flux path circuit). But, in the presence of a different ferromagnetic material placed between the poles of the EM yoke (to achieve closed magnetic flux path circuit), both the V E and the tangential surface magnetic field (H T ) measured on the surface of the ferromagnetic material show non-linear distortion which is considered as an influence of magnetisation of the ferromagnetic sample introduced between the poles of the EM yoke [7][8][9][10][11][12][13]. Since the magnetisation process is strongly influenced by the microstructure and stresses in ferromagnetic materials, the non-linear distortion behaviour of V E and H T is expected to have some relationship and could distinguish subtle differences in the magnetisation process between different ferromagnetic materials.…”

Section: Introductionmentioning

confidence: 99%

Unique correlation between non-linear distortion of tangential magnetic field and magnetic excitation voltage – Unexplored ferromagnetic phenomena and their application for ferromagnetic materials evaluation

Moorthy

2016

Journal of Magnetism and Magnetic Materials

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a b s t r a c tUnexplored ferromagnetic phenomena of non-linear distortion of tangential magnetic field (H T ) and that of excitation voltage (V E ) across the electromagnetic (EM) yoke, in the presence of a ferromagnetic material between the poles of the EM yoke, have been uniquely correlated in this study. Both the H T and V E show similar distortion behaviour, but in the opposite direction, with unique shape for each ferromagnetic sample with different microstructural conditions. Interestingly unique correlation between) profiles and their ability to distinguish different magnetisation behaviour of ferromagnetic material with different microstructures have also been discussed in this study. One to one correlation between the distortion of H T and V E shown in this study is clear evidence that both these parameters are strongly influenced by the same mechanism of magnetisation process, but in different ways. The systematic changes in the height and position of the peak and the trough on the time derivative profiles of V E and H T reflect the subtle differences in the magnetisation process for each microstructural condition of the steel. This study reveals the new scientific insight and good potential of this novel as well as very simple approach of distortion analysis of H T and V E for understanding the influence of material properties on the mechanism of magnetisation process and also their suitability for variety of applications related to materials evaluation of ferromagnetic components and structures.

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Robust solutions of inverse problems in electromagnetic non-destructive evaluation

Cited by 58 publications

References 7 publications

Quantitative Nondestructive Evaluation of Plastic Deformation in Carbon Steel Based on Electromagnetic Methods

Quantitative Nondestructive Evaluation of Plastic Deformation in Carbon Steel Based on Electromagnetic Methods

Electromagnetism as a means for understanding materials mechanics phenomena in magnetic materials

Unique correlation between non-linear distortion of tangential magnetic field and magnetic excitation voltage – Unexplored ferromagnetic phenomena and their application for ferromagnetic materials evaluation

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