In the 1996 QNDE Conference, we presented a parametric forward model [1], which has been recently named MESSINE (Model for Electromagnetic Simplified Simulation In Nondestructive Evaluation), to predict eddy current signal. The proposed model first discretizes the eddy current distribution into current loops. A parametric description of the shape of these loops is given according to the observation of the results obtained with a three-dimensional finite element code which provides a realistic distribution of the induced currents. The loops’ inductances and resistances are then calculated. By considering the system constituted of the coil and the current loops as a « multi-transformer», their current intensity is determined. The impedance change, which is the component of the eddy current signal, can then be deduced. The model was validated in the case of axisymmetric configurations. Comparisons with both analytical (Dodd and Deeds [2]) and numerical models showed very good agreements. Then the proposed model was applied to three-dimensional configurations. Impedance changes of a coil along rectangular through-wall slot were calculated. Comparisons with experimental results show a fairly good agreement for the impedance change phases, but a poorer one for the impedance change amplitudes. Investigations were made to improve the parametric description of the current loop deformation. One of the solutions to improve the parametric description is presented here

Benoist, B.

de Barmon, B.

Gaillard, P.

La, R.

Lengellé, R.

Talvard, M.

English

La, Remy

de Barmon, Benoit

Talvard, Michel

Benoist, Bruno

Lengellé, Régis

Gaillard, Paul

HAL Descartes

Recent development of MESSINE, a 3D Eddy Current Model

HAL-CEA

International audienceIn the 1996 QNDE Conference, we presented a parametric forward model [1], which has been recently named MESSINE (Model for Electromagnetic Simplified Simulation In Nondestructive Evaluation), to predict eddy current signal. The proposed model first discretizes the eddy current distribution into current loops. A parametric description of the shape of these loops is given according to the observation of the results obtained with a three-dimensional finite element code which provides a realistic distribution of the induced currents. The loops’ inductances and resistances are then calculated. By considering the system constituted of the coil and the current loops as a « multi-transformer», their current intensity is determined. The impedance change, which is the component of the eddy current signal, can then be deduced. The model was validated in the case of axisymmetric configurations. Comparisons with both analytical (Dodd and Deeds [2]) and numerical models showed very good agreements. Then the proposed model was applied to three-dimensional configurations. Impedance changes of a coil along rectangular through-wall slot were calculated. Comparisons with experimental results show a fairly good agreement for the impedance change phases, but a poorer one for the impedance change amplitudes. Investigations were made to improve the parametric description of the current loop deformation. One of the solutions to improve the parametric description is presented here

Hal-Diderot

Recent Development of MESSINE, a 3D Eddy Current Model

R. La

B. de Barmon

B. Benoist

M. Talvard

R. Lengellé

P. Gaillard

Crossref

In the 1996 QNDE Conference, we presented a parametric forward model [1], which has been recently named MESSINE (Model for Electromagnetic Simplified Simulation In Nondestructive Evaluation), to predict eddy current signal. The proposed model first discretizes the eddy current distribution into current loops. A parametric description of the shape of these loops is given according to the observation of the results obtained with a three-dimensional finite element code which provides a realistic distribution of the induced currents. The loops’ inductances and resistances are then calculated. By considering the system constituted of the coil and the current loops as a « multi-transformer», their current intensity is determined. The impedance change, which is the component of the eddy current signal, can then be deduced. The model was validated in the case of axisymmetric configurations. Comparisons with both analytical (Dodd and Deeds [2]) and numerical models showed very good agreements. Then the proposed model was applied to three-dimensional configurations. Impedance changes of a coil along rectangular through-wall slot were calculated. Comparisons with experimental results show a fairly good agreement for the impedance change phases, but a poorer one for the impedance change amplitudes. Investigations were made to improve the parametric description of the current loop deformation. One of the solutions to improve the parametric description is presented here.</p

Digital Repository @ Iowa State University (ISU)

RECENT DEVELOPMENT OF MESSINE, A 3D EDDY CURRENT MODEL R. Lat , B. de Bannon, B. Benoist, and M. Talvard "Commissariat a l'Energie Atomique" (CENCEREMIST A) GiffY vette 91191, France R. Lengelle and P.Gaillard "Laboratoire de Modelisation et de Sfirete des Sysremes" University of Teclmology of Troyes Troyes 10000, France INTRODUCTION In the 1996 QNDE Conference, we presented a parametric forward model [1], which has been recently named MESSINE (Model for Electromagnetic Simplified Simulation In Nondestructive Evaluation), to predict eddy current signal. The proposed model first discretizes the eddy current distribution into current loops. A parametric description of the shape of these loops is given according to the observation of the results obtained with a three-dimensional finite element code which provides a realistic distribution of the induced currents. The loops' inductances and resistances are then calculated. By considering the system constituted of the coil and the current loops as a « multi-transformer », their current intensity is determined. The impedance change, which is the component of the eddy current signal, can then be deduced. The model was validated in the case of axisymmetric configurations. Comparisons with both analytical (Dodd and Deeds [2]) and numerical models showed very good agreements. Then the proposed model was applied to three-dimensional configurations. Impedance changes of a coil along rectangular through-wall slot were calculated. Comparisons with experimental results show a fairly good agreement for the impedance change phases, but a poorer one for the impedance change amplitudes. Investigations were made to improve the parametric description of the current loop deformation. One of the solutions to improve the parametric description is presented here. t New affiliation : "Departement du Genie des Systemes Industriels" , University of Teclmology of Troyes. Troyes 10010. France Review of Progress in Quantitative Nondestructive Evaluation, Vol 17 Edited by D.O. Thompson and D.E. Chimenti, Plenum Press, New York, 1998 221 PARAMETRIC DESCRIPTION IMPROVEMENT In the fonner parametric description of the current loop defonnation, we did not take into account the defonnation of their section: the section was supposed constant along each current loop, whereas, by the finite element code, it can be observed that the section varies along the current loops. The improvement consists of taking into account this variation. Nearby the slot, the current loops tighten up, their section become smaller (fig. 1). Let us call SA the section of the current loop at the point A, where the current loop begins to be bent, and SB the section at the point B, where the section is the smallest. According to the observation, from point A to point B, the current loop section decreases continuously. We tried to characterize this decrease by a linear function or by an exponential function. As we obtained some fairly good results with these two analytical functions, others were not tested. Let's w be the curvilinear coordinate along the current loop path, with point A being the coordinate system origin (WA = 0). WB is the curvilinear coordinate of point B. In the case of the linear decrease, the section from point A to point B is described by the function SL : In the case of the exponential decrease, the section from point A to point B is described by the function SE : (1) (2) In fonnulas (1) and (2), it can be seen that the section expression depends on the ratio S B / SA' By some simplifying assumptions, this ratio can be estimated. Slot I A TOP view Side view I Sfl ~ rr I S B L... ---7-,'<-.-11 Slot Top view ide view Figure 1. Current loop section defonnation 222 The section at a point of a current loop is inversely proportional to the current density at the same point : SA fB (3) where h is the current density at the point A and ls. the one at the point B. Let us consider an horizontal layer of current loops of thickness e and intensity I (fig. 2). During the current loop defonnation, the intensity I is conserved. By assuming that the defonnation does not modify the thickness e and that the current density is uniformly distributed at the tip of the slot, fB can be expressed as : I fB =- with 1= LfAiSAi e .C where fA; and SAi are the current density and section of a current loop at point Ai. In definitive, according to (3) and (4), we have: SB fA·e .C S;= LJAiSAi As the fA;'s are not a priori known, to estimate them, we first assumed that the current density was unifonn across the layer section: J Ai = 1, Vi . With (6), the ratio S B / SA becomes: SB e .C S;= LSAi (4) (5) (6) (7) Using (7), the functions (1) and (2) describing the section decrease can be calculated. By describing the section variation, a more realistic parametric description of the current loops' shape is then obtained. Other finer approximations of the ratio S B / SA are currently investigated. z+ Plate conductor with thickne c Current loop layer with intensity I . I Deformed current loops' layer. B I~!:I~~~~~~~~~~~ at the tip of the lot, I with intensity I c --------~ __ ~~~~~~~~~~~~~--L-e Slot Figure 2. Defonnation of a current loop layer. 223 RESULTS OF THE IMPROVEMENT The new parametric description had been tested with a linear decrease and a exponential decrease of the section from point A to point B. Comparisons with experimental results were done along the slot axis, with the same plate and the same coil described in paper [1]. For each frequency, the parameters c 1 , c2 and c3, defined in paper [1], are optimized with respect to the impedance changes due to a 10 mm length slot, measured experimentally at the center of the slot. The origin of the x-axis in any figures, given below, corresponds to the slot center. The first tests on a 10 mm and a 20 mm slot at 240 kHz show that the exponential decrease gives better results than the linear one (fig. 3 and 4) : at the tip of the 10 mm slot and along the 20 mm slot, the curves obtained with the exponential decrease are closer to the experimental curves than the ones obtained with the linear decrease. Further tests were done to compare results obtained with the exponential decrease to results obtained with section being kept constant (fig. 5,6,7,8,9 and 10). These figures show results obtained with a 4mm, a lOmm and a 20 mm slot, at 240 kHz and 500 kHz. Other results are given in [3]. For any slot and any frequency, the new parametric description considerably improves the agreement between impedance change amplitudes calculated by the model and these measured experimentally. AMPUTIJOE 10 : ~--~===*~~~~~~~ -0- Expenence . .... " ....... -a- Model . secUon With hnur decrease -6- Model . seeliOn With exponenllaJ decrease . . .. .. .. "" .. .. .. .. ~ o 6 7 9 10 .(mm) PHASE IW r---~----~====a===~~ __ ~~ 100 80 I 60 40 ........ 1*1. section with uponcnILlI decrease ' 20 O+---__ ~--~----~----~--~~--__ ~--~----~----~--~ 224 o 6 9 . (mm) Figure 3. Impedance change along the 10 mm slot at 240 kHz, comparison between exponential decrease section and linear decrease section. 10 AMPLITUOe §: 6 -0- &pcr.:=rwx ! 120 100 80 60 40 20 0 0 -0- Model. seaJon with In2r de~.ue -6- Model. rctJon with exponerMaal decrease 'Imm) PHASE r--<>--:-::Ex---pe-nence-------, .. -Q- Model .seC1ion with lmclI decrease ....a- Modcl .$ClC1lon with exponeruW decrellSe 2 6 , (nun) 10 II 12 13 14 10 II 12 13 14 Figure 4. Impedance change along the 20 mm slot at 240 kHz, comparison between exponential decrease section and linear decrease section. AMPLITUDE 9 : 1 6 " -0- Experience 9: ! ....... Model. COnstant secUon ¥ "" ~ ~ Model , .section with exponenllal decrease I np:oI 0 101 0 6 ,(mm) PHA E 120 100 80 60 -0- Experience 40 ~ Model. constant seeuon 20 ~ Model, sectIOn With e~ponen(laI decrease 0 0 6 9 , (nun) Figure 5. Impedance change along the 10 mm slot at 240 kHz, comparison between constant section and exponential decrease section. IS IS 10 10 225 10 S 6 .. -0- EJlperience i e. 226 ~ Model. corutant secllon -6- Modcl , scaion w1th c:liponentJaI deClase 10 II 12 13 14 x (mm) PHA E 120 100 80 ....0- Expenence -e- Model . constant section 60 -b- Mockl. sectlOn W\th e.:.:ponentw decrease 40 20 0 0 6 10 \I 12 \3 14 1(11YT\) Figure 6. Impedance change along the 20 mm slot at 240 kHz, comparison between constant section and exponential decrease section. Figure 7. Impedance change along the 4 mm slot at 240 kHz, comparison between constant section and exponential decrease section. 15 AMPLITUDE 25 IS 10 --0- Expenence -0- Model. C'onstitnl .s«rion -0- Model, secltOn Wllh exponentIAl decrease TIP9i O+-______ ~----~------_r------~----~=·~~~I----~------~==~~~----~~----~ ¥ g o 120 100 0 60 40 20 0 0 >(mm) PHASE T1i>OI I > (Imt) 6 Figure 8. Impedance change along the 10 mm slot at 500 kHz, comparison between constant section and exponential decrease section. AMPLITUDE 30 ~t=~~~~~==~~~~~-*==~~~ 20 e: IS 10 ~ ~ o 10 \I 12 13 14 ;tI;(mm) PHASE 120 100 80 60 --0- Expc.rience -0- Model. caMlllOl secUon 40 -A- Model. sec.lOn Wd:h exponemLlll decrease 20 0 0 6 10 \I 12 13 14 .(mm) Figure 9. Impedance change along the 20 mm slot at 500 kHz, comparison between constant section and exponential decrease section. 10 10 15 15 227 ... ~ .. e AMPLITUDE -0- Experience -0- Model. con.slant scclion ....0- Model. section with exponential decrease 4 2 Topol -O+-__ .-__ ~ __ ~~m~.~~~t __ ~ __ ~ __ r-__ ~~~~~~~ __ ~ __ ~ __ ~ o 120 100 80 60 40 20 0 ·20 0.5 1,5 2 2,5 -o- Expc..nencc -0- Model, consllml scctlon -0- Model . stC1ion wuh t:cponemlAl decrease Tip of 0.5 2.5 3.5 x(mm) PHASE x (lI'11n) 4 4.5 4.5 5,5 6 6.S 5:5 Figure 10. Impedance change along the 4 mm slot at 500 kHz, comparison between constant section and exponential decrease section. CONCLUSION The flrst results obtained by the MESSINE eddy current parametric model [1] showed a poor agreement with experimentation results. In this paper, an improvement of the model is proposed: current loops' section variation is taking into account in the parametric description. This variation is described by an analytical function. Results obtained with the new parametric description are much closer to the experimentation results. Current investigations aim at extend the parametric description to non through-wall slot and to other positions of the coil (coil off slot axis). REFERENCES l. R. La, B. Benoist, B. de Barmon, R. Lengelle, P. Gaillard, 1. Reuchet, "An Eddy Current Model Based on Parametric Description of Current Loops", Review of Progress in Quantitative Nondestructive Evaluation, VoL 16A, 1997, pp.295-302. 2. C.V. Dodd, W.E. Deeds, "Analytical Solutions to Eddy-Current Probe-Coil Problems", Journal of Applied Physics, VoL39, number 6, May 1968, pp.2829-2838. 3. R. La, "Modelisation Phenomenologique des Signaux Courants de Foucault en vue de la Caracterisation des Defauts des Tubes de Generateurs de Vapeur", Ph.D. dissertation, University of Technology of Compiegne, 1996. 228 

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Recent Development of MESSINE, a 3D Eddy Current Model

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