Object: To reduce the size of a device. Solution to Problem: A switching module according to one aspect of the present disclosure is a module used in a power conversion circuit. The switching module includes a case member formed to extend in a first direction and a second direction, one or more switching elements disposed to face the case member in a stacking direction orthogonal to the first direction and the second direction, and a pressing member configured to press at least part of the one or more switching elements toward one side in the stacking direction via the case member. The one or more switching elements are disposed closer one end portion of both end portions of the case member in the second direction.

A switch assembly of a reactive power compensation apparatus may include a first switching module having a first stack structure perpendicular to a supporting module, a second switching module having a second stack structure perpendicular to the supporting module, the second switching module being connected in parallel with the first switching module, and first and second supporting members disposed above and below the first and second switching modules.

A method of assembling a switching module may arrange a first pressing member on a first supporting member, stack a plurality of switches and a plurality of cooling plates on the first pressing member along a vertical direction, arrange a second pressing member and a supporting member on the uppermost cooling plate, support the first supporting member and a second supporting member using a plurality of supporting rods, press the first pressing member using a pressing device to separate between the first pressing member and the first supporting member, and insert a third pressing member between the first pressing member and the first supporting member.

A switching module may include a plurality of cooling plates stacked along a vertical direction, a switch disposed between the cooling plates, a first supporting member disposed below the lowermost cooling plate, a second supporting member disposed above the uppermost cooling plate, first and second pressing support portions disposed between the lowermost cooling plate and the first supporting member, and a pressing member disposed between the uppermost cooling plate and the second supporting member.

Each of the first and second switching modules may include first through (n+1)th cooling plates stacked along a vertical direction with respect to the support module; first through nth switches respectively disposed between the first through (n+1)th cooling plates; a first electrode plate disposed on the (n+1)th cooling plate; a first supporting member disposed on the first electrode plate; a first pressing member disposed between the first electrode plate and the first supporting member; a second electrode plate disposed below the first cooling plate; a second supporting member disposed below the second electrode plate; and a second pressing member disposed between the second electrode plate and the second supporting member.

A switch assembly of a reactive power compensation apparatus may include a first switching module having a first stack structure perpendicular to a supporting module, and a second switching module having a second stack structure perpendicular to the supporting module, the second switching module being connected in parallel with the first switching module. Each of the first and second switching modules may include a plurality of cooling plates stacked along a vertical direction with respect to the supporting module, and a plurality of switches disposed between the plurality of cooling plates. The cooling plate may include an engagement portion disposed on one side of the upper surface to be located at a normal position by guiding the switch.

A panel system may include a core body having opposite sides and switching devices mounted to at least one of the opposite sides of the core body, a housing in which the core body and the switching devices are disposed, gate drivers coupled to a first side of the housing and to the switching devices, and connectors coupled to one or more other sides of the housing and to the switching devices. The connectors may receive and conduct a voltage to collector terminals of the switching devices. The gate drivers may conduct a gate voltage to gate terminals of the switching devices. The switching devices may control conduction of the voltage out of the housing via the connectors as an alternating current.

An electrical system and apparatus for powering and cooling a static transfer switch (STS) assembly are provided. The electrical system includes an STS assembly, which includes at least two silicon controlled rectifiers (SCRs) for at least one power phase of the STS assembly, where the at least two SCRs are for incoming power sources that are opposing to each other. The electrical system includes a cooling system located between the at least two SCRs for the incoming power sources that are opposing to each other for the at least one power phase of the STS assembly. The electrical system further includes a plenum structure, where the cooling system is mounted in a middle of the plenum structure, and the STS assembly is arranged around the cooling system.

An electromagnetic shield including a base portion and opposing recess walls extending from the base portion at an angle with respect to a plane in which the base portion extends, so as to, together with the base portion, define a recess. At least one recess wall may be arranged such that it has a distal edge with respect to the base portion, wherein the distal edge includes a cylindrical portion. In alternative or in addition, at least one recess wall may be arranged such that at least a portion thereof curves outwards or inwards with respect to the recess.

A shell structure for a thyristor trigger unit comprises an integrally-formed shell body with a holder and a cuboid structure, and a side plate. The cuboid structure is a cuboid with an opening in its front where an open face is formed at the front opening of the cuboid. The cuboid further includes a rear panel, a left panel, a right panel, an upper panel, and a lower panel. The holder includes a square retaining plate and two triangular stiffener plates. The square retaining plate is formed by a bottom panel extending towards a side of the left panel in a long side direction of the cuboid while the triangular stiffener plates are fixedly connected between the square retaining plate and the left panel. The side plate is mated with and detachably mounted on the open face to produce a sealed 6-face cuboid structure by sealing off said open face.