AC losses in multilayer power transmission cables can be reduced by adjusting the helical winding pitch of each layer to make the layer's current distribution uniform. The optimum helical pitch can be estimated using an electric circuit (EC) model based on the expression that calculates the losses in the superconducting tapes composing the cable. It is known that the losses in a monolayer cable depend on the cable parameters (i.e., the gap between neighboring tapes, number of tapes N, diameter of the cable former and width of the tape). However, regarding Amemiya et al.'s measurement on the losses in monolayer cables, the numerical results of the losses calculated using the Norris formula for an isolated thin strip N times are close to the experimental results. Then, to determine the losses in a three-layer cable that Mukoyama et al. have reported, the losses are calculated by the EC model based on the Norris formula. The helical pitch of each layer is adjusted to make the layer's current distribution uniform in the cable reported by Mukoyama et al. The optimum helical pitches are calculated using the condition where the standard deviation of the layer currents is minimum, and the losses of the cable at the optimum helical pitches are calculated at 1 kA(rms). By comparing the results of these calculations with the previously measured results, it was found that the mean error of the calculated values relative to the measured values is 23.7%, which indicates that the calculation using the EC model is useful as a first approximation.

• 出版日期2011-11