A support bracket assembly for supporting a pair of bushing well interrupter devices provided within a transformer enclosure that encloses a transformer. The support bracket assembly includes a mounting bracket assembly rigidly secured to a parking stand on the enclosure and including a plurality of mounting bosses. The support bracket assembly further includes support brackets, a first adjustable link secured to one of the mounting bosses on the mounting assembly and a mounting boss on a support bracket, a second adjustable link secured to another one of the mounting bosses on the mounting assembly and a mounting bosses on a support bracket, and a third adjustable link secured to mounting bosses on two support bracket, where the first, second and third adjustable links form a triangular configuration.

A support bracket assembly for supporting a pair of bushing well interrupter devices provided within a transformer enclosure that encloses a transformer. The support bracket assembly includes a mounting bracket assembly rigidly secured to a parking stand on the enclosure and including a plurality of mounting bosses. The support bracket assembly further includes support brackets, a first adjustable link secured to one of the mounting bosses on the mounting assembly and a mounting boss on a support bracket, a second adjustable link secured to another one of the mounting bosses on the mounting assembly and a mounting bosses on a support bracket, and a third adjustable link secured to mounting bosses on two support bracket, where the first, second and third adjustable links form a triangular configuration.

The disclosure generally relates to an exemplary enclosure that protects an electrical network protection element in various environments such as when the enclosure is submerged in water or when the enclosure is placed in an underground vault that may be flooded during rain. The enclosure has a gasket that includes a first portion having a sloping surface which provides a continuously incremental amount of sealing in cooperation with a beveled edge of a door of the enclosure and a second portion having a flat surface which is compressed by a wedge projection in the door and provides water tight sealing as well. The enclosure includes a locking bar having a tapered portion, which moves into an opening in a flange of the enclosure and automatically creates a continuously incremental amount of pushing force upon the door against the gasket when a pivotable handle is operated for closing the door.

The disclosure generally relates to an exemplary enclosure that protects an electrical network protection element in various environments such as when the enclosure is submerged in water or when the enclosure is placed in an underground vault that may be flooded during rain. The enclosure has a gasket that includes a first portion having a sloping surface which provides a continuously incremental amount of sealing in cooperation with a beveled edge of a door of the enclosure and a second portion having a flat surface which is compressed by a wedge projection in the door and provides water tight sealing as well. The enclosure includes a locking bar having a tapered portion, which moves into an opening in a flange of the enclosure and automatically creates a continuously incremental amount of pushing force upon the door against the gasket when a pivotable handle is operated for closing the door.

The disclosure generally relates to an exemplary enclosure that protects an electrical network protection element in various environments such as when the enclosure is submerged in water or when the enclosure is placed in an underground vault that may be flooded during rain. The enclosure has a gasket that includes a first portion having a sloping surface which provides a continuously incremental amount of sealing in cooperation with a beveled edge of a door of the enclosure and a second portion having a flat surface which is compressed by a wedge projection in the door and provides water tight sealing as well. The enclosure includes a locking bar having a tapered portion, which moves into an opening in a flange of the enclosure and automatically creates a continuously incremental amount of pushing force upon the door against the gasket when a pivotable handle is operated for closing the door.

The disclosure generally relates to an exemplary enclosure that protects an electrical network protection element in various environments such as when the enclosure is submerged in water or when the enclosure is placed in an underground vault that may be flooded during rain. The enclosure has a gasket that includes a first portion having a sloping surface which provides a continuously incremental amount of sealing in cooperation with a beveled edge of a door of the enclosure and a second portion having a flat surface which is compressed by a wedge projection in the door and provides water tight sealing as well. The enclosure includes a locking bar having a tapered portion, which moves into an opening in a flange of the enclosure and automatically creates a continuously incremental amount of pushing force upon the door against the gasket when a pivotable handle is operated for closing the door.

The present invention provides underground equipment enabling the internal heat of a buried box to be stably discharged to the outside without an external power source. In one embodiment, underground equipment comprises: a buried box of which the top is open; a cover part inserted into the buried box so as to cover the top; and air-conditioning parts which are disposed at the cover part, and which ventilate or close the inner space of the buried box according to the inflow of external water, wherein the inner space of the buried box is closed by means of the lower surface of the cover part, and a heat exchange part for allowing heat to be exchanged between rainwater and the inner space when the rainwater flows therein is disposed at a position of the cover part that differs from the arrangement position of the air-conditioning parts.

The present invention provides underground equipment enabling the internal heat of a buried box to be stably discharged to the outside without an external power source. In one embodiment, underground equipment comprises: a buried box of which the top is open; a cover part inserted into the buried box so as to cover the top; and air-conditioning parts which are disposed at the cover part, and which ventilate or close the inner space of the buried box according to the inflow of external water, wherein the inner space of the buried box is closed by means of the lower surface of the cover part, and a heat exchange part for allowing heat to be exchanged between rainwater and the inner space when the rainwater flows therein is disposed at a position of the cover part that differs from the arrangement position of the air-conditioning parts.

An enclosure for a network protector in an electrical distribution network includes a cabinet body that defines an interior region that accepts the network protector. The cabinet body three electrodes sealed with and electrically isolated from the cabinet body and each other, which extend through the cabinet body to establish electrical connection between corresponding terminals of the network protector and the electrical distribution network. First and second doors are pivotably connected to opposing sides of the cabinet body and have respective contact surfaces to seal against the cabinet body. A first gasket is disposed along a distal edge surface of the first door, and a second gasket is disposed along a distal edge surface of the second door. At least a portion of the first gasket and the second gasket have conformal shapes that sealingly mate with each other when the first and second doors are in a closed position.

An enclosure for a network protector in an electrical distribution network includes a cabinet body that defines an interior region that accepts the network protector. The cabinet body three electrodes sealed with and electrically isolated from the cabinet body and each other, which extend through the cabinet body to establish electrical connection between corresponding terminals of the network protector and the electrical distribution network. First and second doors are pivotably connected to opposing sides of the cabinet body and have respective contact surfaces to seal against the cabinet body. A first gasket is disposed along a distal edge surface of the first door, and a second gasket is disposed along a distal edge surface of the second door. At least a portion of the first gasket and the second gasket have conformal shapes that sealingly mate with each other when the first and second doors are in a closed position.