The present invention relates to an insulating support for a power switchgear that insulates and supports the main body of a power switchgear provided in atmospheric air between a generator and a main transformer. The insulating support includes a core part that is molded only from a resin material and has a cylindrical shape; an exterior covering part that is molded only from a rubber material, is attached to an outer peripheral face of the core part, and includes a plurality of pleated parts; an end metal fitting that is attached to one end of the core part and is attached to the main body of the power switchgear; and an end metal fitting that is attached to the other end of the core part and is provided on the ground surface.

The present invention relates to an insulating support for a power switchgear that insulates and supports the main body of a power switchgear provided in atmospheric air between a generator and a main transformer. The insulating support includes a core part that is molded only from a resin material and has a cylindrical shape; an exterior covering part that is molded only from a rubber material, is attached to an outer peripheral face of the core part, and includes a plurality of pleated parts; an end metal fitting that is attached to one end of the core part and is attached to the main body of the power switchgear; and an end metal fitting that is attached to the other end of the core part and is provided on the ground surface.

A damping configuration for an oscillatably mounted, electrical energy transmission device includes a supporting frame which is connected to stationary abutments through a plurality of damping elements. A group of first and second damping elements which have damping rates dimensioned so as to differ from one another and which act in parallel, connect the supporting frame to the abutments. Favorable damping of both weaker and stronger movements, for example caused by an earthquake, is ensured due to a combination of damping elements having differently dimensioned damping rates.

An insulator that may be self-centering is disclosed. The insulator includes an alignment feature that allows it to self-center during installation. In some embodiments, the insulator is created with a captive fastener with a specific alignment feature. The internal cavity of the insulator is formed so as to have a corresponding alignment feature. When tightened, the captive fastener is pressed into the alignment feature of the internal cavity, allowing it to self-center. In other embodiments, the mating electrode is also modified to include a corresponding alignment feature. For example, in some embodiments, the alignment feature on the electrode comprises a specially shaped depression, while the insulator has a corresponding protrusion. In other embodiments, the insulator also has a protective shield.

An insulator that may be self-centering is disclosed. The insulator includes an alignment feature that allows it to self-center during installation. In some embodiments, the insulator is created with a captive fastener with a specific alignment feature. The internal cavity of the insulator is formed so as to have a corresponding alignment feature. When tightened, the captive fastener is pressed into the alignment feature of the internal cavity, allowing it to self-center. In other embodiments, the mating electrode is also modified to include a corresponding alignment feature. For example, in some embodiments, the alignment feature on the electrode comprises a specially shaped depression, while the insulator has a corresponding protrusion. In other embodiments, the insulator also has a protective shield.

Disclosed is a method of manufacturing an insulating sheet, comprising: forming at least a groove on a flat sheet; a first cutting step for cutting a side surface of the groove by irradiating a laser beam to a side surface of the sheet; a second cutting step for cutting the insulating sheet to completely separate the groove from the insulating sheet by irradiating a laser beam from above the groove having the side surface cut; a tape attaching step for attaching a tape to an outer surface of the insulating sheet; and a bending step for bending one end portion of the surface of the insulating sheet having the tape attached toward a place where the tape is attached. It is possible to mass-produce the insulating sheets having a three-dimensional shape, regarded as being difficult to manufacture with a mold.

Disclosed is a method of manufacturing an insulating sheet, comprising: forming at least a groove on a flat sheet; a first cutting step for cutting a side surface of the groove by irradiating a laser beam to a side surface of the sheet; a second cutting step for cutting the insulating sheet to completely separate the groove from the insulating sheet by irradiating a laser beam from above the groove having the side surface cut; a tape attaching step for attaching a tape to an outer surface of the insulating sheet; and a bending step for bending one end portion of the surface of the insulating sheet having the tape attached toward a place where the tape is attached. It is possible to mass-produce the insulating sheets having a three-dimensional shape, regarded as being difficult to manufacture with a mold.

An insulating support includes a pillar-shaped portion made of resin, a metal insert buried in one end surface of the pillar-shaped portion in an axial direction, a metal insert buried in the other end surface of the pillar-shaped portion in the axial direction, and one protrusion made of the resin and provided in a ring shape and integrally with the pillar-shaped portion on an outer circumferential surface of the pillar-shaped portion on a side of the metal insert. The metal insert includes a first cylindrical base portion and a first distal end portion. The metal insert includes a second cylindrical base portion and a second distal end portion. A whole of the first distal end portion is disposed within an extended range of the protrusion in the axial direction.

A bus support includes a corona shield portion and a bus support portion on the corona shield portion. The bus support portion includes an insulator engagement ledge including one or more mounting apertures configured to receive a fastener therethrough for mounting the bus support to an insulator. The bus support portion includes first and second bus support walls extending upwardly from opposite sides of the insulator engagement ledge. Each bus support wall includes a U-shaped channel defined therein that is configured to receive and support a cylindrical and/or tubular bus conductor. The corona shield portion and the bus support portion form a monolithic structure.

A bus support includes a corona shield portion and a bus support portion on the corona shield portion. The bus support portion includes an insulator engagement ledge including one or more mounting apertures configured to receive a fastener therethrough for mounting the bus support to an insulator. The bus support portion includes first and second bus support walls extending upwardly from opposite sides of the insulator engagement ledge. Each bus support wall includes a U-shaped channel defined therein that is configured to receive and support a cylindrical and/or tubular bus conductor. The corona shield portion and the bus support portion form a monolithic structure.