A stationary induction apparatus includes a core, a first winding, a second winding, and an insulating structure arranged between facing surfaces of the first winding and the second winding. The insulating structure is located between the facing surfaces of the first winding and the second winding. The insulating structure includes a first insulator having a cylindrical shape with the core as its central axis, and first insulating spacers arranged between the first winding and the first insulator and between the second winding and the first insulator. The first insulator includes a first nonlinear resistive layer containing a nonlinear resistive material having a nonlinear volume resistivity that decreases when an electric field is higher than a threshold. The first nonlinear resistive layer is provided in a portion of the first insulator which is at least in contact with one of the first insulating spacers.

Provided is an electronic component including a coil portion including a base including a conductive metal, and a terminal portion that is connected to a predetermined circuit board. A front surface of the base is covered, and the terminal portion is exposed.

Provided is an electronic component including a coil portion including a base including a conductive metal, and a terminal portion that is connected to a predetermined circuit board. A front surface of the base is covered, and the terminal portion is exposed.

A high voltage switch comprising: a high voltage power supply providing power greater than about 5 kV; a control voltage power source; a plurality of switch modules arranged in series with respect to each other each of the plurality of switch modules configured to switch power from the high voltage power supply, and an output configured to output a pulsed output signal having a voltage greater than the rating of any switch of the plurality of switch modules, a pulse width less than 2 s, and at a pulse frequency greater than 10 kHz.

A high voltage switch comprising: a high voltage power supply providing power greater than about 5 kV; a control voltage power source; a plurality of switch modules arranged in series with respect to each other each of the plurality of switch modules configured to switch power from the high voltage power supply, and an output configured to output a pulsed output signal having a voltage greater than the rating of any switch of the plurality of switch modules, a pulse width less than 2 s, and at a pulse frequency greater than 10 kHz.

The invention is directed to a stationary induction electric device that can reduce loss. To this end, the stationary induction electric device is provided with a first iron core block erected and formed in an annular shape, a second iron core block configured to surround the outer periphery of the first iron core block, a winding wound around the first and the second iron core blocks, a first support plate supporting the upper portion of the first iron core block from below, and a second support plate supporting the upper portion of the second iron core block from below, and a curvature radius of a curved portion appearing on the outer periphery of the lower portion of the second iron core block is made larger than a curvature radius of a curved portion appearing on the outer periphery of the upper portion of the second iron core block.

The invention is directed to a stationary induction electric device that can reduce loss. To this end, the stationary induction electric device is provided with a first iron core block erected and formed in an annular shape, a second iron core block configured to surround the outer periphery of the first iron core block, a winding wound around the first and the second iron core blocks, a first support plate supporting the upper portion of the first iron core block from below, and a second support plate supporting the upper portion of the second iron core block from below, and a curvature radius of a curved portion appearing on the outer periphery of the lower portion of the second iron core block is made larger than a curvature radius of a curved portion appearing on the outer periphery of the upper portion of the second iron core block.

A coil device includes a first coil wound around a winding axis, and a second coil substantially overlapping the first coil when viewed from a winding axis direction of the first coil. The second coil includes first and second portions adjacent to each other in the winding axis direction. The first and second portions extend so that the directions of electric current flowing through the first and second portions are opposite to each other, and a coil opening is provided between the first and second portions.

A coil device includes a first coil wound around a winding axis, and a second coil substantially overlapping the first coil when viewed from a winding axis direction of the first coil. The second coil includes first and second portions adjacent to each other in the winding axis direction. The first and second portions extend so that the directions of electric current flowing through the first and second portions are opposite to each other, and a coil opening is provided between the first and second portions.

A transformer for use in a rail vehicle and/or for rail applications, including a core which is at least partially surrounded by at least one coil is, with regard to the objective of providing a transformer in which the geometry of a coil can be selected to be as variable as possible, characterized in that the core is produced from individual segments, wherein the total cross-sectional surface-area of the core is greater than or equal to the sum of the individual cross-sectional surface-areas of the segments and wherein at least two individual cross-sectional surface-areas differ from each other and/or from the total cross-sectional surface-area in terms of their size and/or geometric shape.