\nFirst, the surface on which the current flows in (the plane to which the positive voltage of the power supply is applied) must be specified. Let us assume that it is the surface A in Fig. 1. The surface where the current flows out is the surface B. Considering the symmetrical parts, the current path goes around. Surfaces A and B must be defined as Bn=0 surfaces. A surface element is defined on the surface A, where the property number is 14. The orientation of the surface can be in either direction in case of SUFCUR, but we will define it to face outward (right-hand thread) from the conductor in order to share it with the surface for calculating the passing current. In the current case, surface A is still created by extending from the line element in the z direction. Sample data for this is prepared in pre_geom2D.neu and 2D_to_3D. Specify the coil area, inflow surface, etc. in the input file. Here, A-\u03d5 is used because it converges faster than the A method. For low frequencies or when SUFCUR is used, the convergence of the ICCG method is better. <\/p>\n
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![\"\"](\"\/product\/EMSolution\/en\/wp-content\/uploads\/sufcur01.png\")
<\/a><\/p>\nFig.1\u3000Surface inflow current source plane<\/p>\n<\/p><\/div>\n<\/div>\n
A portion of the output file output is shown in List.1.<\/p>\n
As in "the "ELMCUR analysis"<\/font><\/a>, the impedance of the coil from the power supply can be obtained as <\/p>\n $$R + j \\omega L = \\frac{(0.0476377 + j0.110901)}{3000}(\\Omega) = 15.88 + j 36.97(\\mu \\Omega)$$ <\/p>\n but there is a resistance of 5 \u03bc\u03a9 added in series with the coil, so the impedance of the coil itself (including the effect of eddy currents in the copper conductor) is $10.88+j36.97\uff08\\mu \\Omega\uff09$. In order to compare with the result in "AC analysis including eddy currents"<\/font><\/a>, the result is converted to 3000Turn equivalent (3000 squared times) values, then it is $97.9+j332\uff08\\Omega\uff09$. Due to the skin effect, the resistance is larger and the inductance component is smaller. Also, since this is a one-eighth model, the overall average heat generation is $6.1196\u00d78=48.95W$.
This value should be equal to the heat generation obtained from the above resistance value: $\\frac{(I^2\u00d7R)}{2}=\\frac{(3000^2\u00d710.88\u00d710^{-6})}{2}=48.96W$. The values are in fact almost the same, indicating that the solution is consistent. The surface passing current value is equal to half of the coil current as set. The sign is different because the direction of the surface is opposite. (The surface of passing current must be defined outward from the conductor.) Fig. 2 shows the current density distribution at phase 0 degrees. Fig. 3 shows the heat generation density distribution. It can be seen that the distribution of coil current and heat generation is inward (larger on the inside). <\/p>\n
![\"\"](\"\/product\/EMSolution\/en\/wp-content\/uploads\/sufcur02.png\")
<\/a><\/p>\n![\"\"](\"\/product\/EMSolution\/en\/wp-content\/uploads\/sufcur03.png\")
<\/a><\/p>\n