A helical jumper connector includes a helical support member configured to support a wire. The helical support member includes a first leg having a first helical winding and a second leg having a second helical winding that defines a second axial opening. The first axial opening and the second axial opening are coaxial with the wire when the first helical winding and the second helical winding are wrapped around the wire and cooperatively engage with one another to support the wire. A jumper casting is configured to receive the helical support member. The helical support member and the jumper casting are electrically conductive such that the helical jumper connector forms an electrically conductive pathway to carry electrical current from the wire. A method of making a helical jumper connector assembly includes applying a compression force to a helical jumper connector comprising a helical support member received in a jumper casting.

A helical jumper connector includes a helical support member configured to support a wire. The helical support member includes a first leg having a first helical winding and a second leg having a second helical winding that defines a second axial opening. The first axial opening and the second axial opening are coaxial with the wire when the first helical winding and the second helical winding are wrapped around the wire and cooperatively engage with one another to support the wire. A jumper casting is configured to receive the helical support member. The helical support member and the jumper casting are electrically conductive such that the helical jumper connector forms an electrically conductive pathway to carry electrical current from the wire. A method of making a helical jumper connector assembly includes applying a compression force to a helical jumper connector comprising a helical support member received in a jumper casting.

Provided is a harness protector, wherein a wire harness can easily be formed into a planar shape (with an oblate cross section), and maintained in that state. The harness protector is provided with: a protector body further provided with a roughly tabular-shaped bottom-plate section onto which a wire harness is to be placed, and a holding plate section that is integrally formed on one side of the bottom-plate section in pivotable state, and crushes the wire harness into an oblate cross-section shape, along with the bottom-plate section; and tying bands that anchor the holding plate section onto the bottom-plate section, in a state of having the holding plate section crushing the wire harness into an oblate cross-section shape.

Provided is a harness protector, wherein a wire harness can easily be formed into a planar shape (with an oblate cross section), and maintained in that state. The harness protector is provided with: a protector body further provided with a roughly tabular-shaped bottom-plate section onto which a wire harness is to be placed, and a holding plate section that is integrally formed on one side of the bottom-plate section in pivotable state, and crushes the wire harness into an oblate cross-section shape, along with the bottom-plate section; and tying bands that anchor the holding plate section onto the bottom-plate section, in a state of having the holding plate section crushing the wire harness into an oblate cross-section shape.

An electronic component includes: a laminate busbar structure comprising at least two busbar layers separated by an insulating layer; a transistor connected to the laminate busbar structure on a first side thereof; and a capacitor that is mounted on the first side of the laminate busbar structure and is positioned further away from the laminate busbar structure than the transistor, the capacitor having respective planar terminals parallel to each other and perpendicular to the laminate busbar structure, each of the planar terminals comprising a rectangular member with one side thereof connected to the capacitor and an opposite end connected to a corresponding one of the busbar layers.

An electronic component includes: a laminate busbar structure comprising at least two busbar layers separated by an insulating layer; a transistor connected to the laminate busbar structure on a first side thereof; and a capacitor that is mounted on the first side of the laminate busbar structure and is positioned further away from the laminate busbar structure than the transistor, the capacitor having respective planar terminals parallel to each other and perpendicular to the laminate busbar structure, each of the planar terminals comprising a rectangular member with one side thereof connected to the capacitor and an opposite end connected to a corresponding one of the busbar layers.

The present disclosure provides a grounding structure, a method for assembling the same and a gas-insulated transmission line. The grounding structure includes a grounding guide defining a guiding hole and a grounding support fixed on the grounding guide and defining a cavity for accommodating a grounding contact. The grounding contact is arranged in the cavity and protrudes through the guiding hole on the grounding guide. The grounding contact is moveable along the wall of the cavity by a grounding spring accommodated in the cavity to realize the adaptive adjustment of the installation position. The grounding structure can be pre-assembled in an accurate and efficient way to avoid the components therein damaging, thereby improving the reliability and safety of the grounding structure and the gas-insulated equipment in which the grounding structure is used.

The present disclosure provides a grounding structure, a method for assembling the same and a gas-insulated transmission line. The grounding structure includes a grounding guide defining a guiding hole and a grounding support fixed on the grounding guide and defining a cavity for accommodating a grounding contact. The grounding contact is arranged in the cavity and protrudes through the guiding hole on the grounding guide. The grounding contact is moveable along the wall of the cavity by a grounding spring accommodated in the cavity to realize the adaptive adjustment of the installation position. The grounding structure can be pre-assembled in an accurate and efficient way to avoid the components therein damaging, thereby improving the reliability and safety of the grounding structure and the gas-insulated equipment in which the grounding structure is used.

An in-line power disconnect assembly for electrical power distribution systems is provided. The in-line power disconnect assembly includes a first end section, a second end section, at least one insulator positioned between the first end section and the second end section, and a switch assembly positioned between the first end section and the second end section. Each of the first and second end sections include a conductor clamp that can be rotated or twisted relative to a longitudinal axis of the first or second end section between a clamping position and an open position.

An in-line power disconnect assembly for electrical power distribution systems is provided. The in-line power disconnect assembly includes a first end section, a second end section, at least one insulator positioned between the first end section and the second end section, and a switch assembly positioned between the first end section and the second end section. Each of the first and second end sections include a conductor clamp that can be rotated or twisted relative to a longitudinal axis of the first or second end section between a clamping position and an open position.