Efficient Numerical Modeling of the Magnetization Loss on a Helically Wound Superconducting Tape in a Ramped Magnetic Field

Abstract

We investigate theoretically the dependence of magnetization loss of a helically wound superconducting tape on the round core radius R and the helical conductor pitch in a ramped magnetic field. Using the thin-sheet approximation, we identify the two-dimensional equation that describes Faraday's law of induction on a helical tape surface in the steady state. Based on the obtained basic equation, we simulate numerically the current streamlines and the power loss P per unit tape length on a helical tape. For R w0 (where w0 is the tape width), the simulated value of P saturates close to the loss power (2/π)P flat (where P flat is the loss power of a flat tape) for a loosely twisted tape. This is verified quantitatively by evaluating power loss analytically in the thin-filament limit of w0/R→ 0. For R w0, upon thinning the round core, the helically wound tape behaves more like a cylindrical superconductor as verified by the formula in the cylinder limit of w0/R→ 2π, and P decreases further from the value for a loosely twisted tape, reaching (2/π)2 P flat.