An in-ground enclosure for housing electrical components is provided. The in-ground enclosure can include an outer shell defining an internal compartment housing a lift system, an equipment rack structure connected to the lift system, an upper panel comprising a compartment opening for accessing the internal compartment, an enclosure cover adapted to cover the compartment opening and for removably sealing the compartment opening. In certain uses, a telecommunications base station may also be provided. The telecommunications base station can include the in-ground enclosure and a cellular base station, with the cellular base station including an antenna coupled to signal processing equipment and a power supply.

An in-ground enclosure for housing electrical components is provided. The in-ground enclosure can include an outer shell defining an internal compartment housing a lift system, an equipment rack structure connected to the lift system, an upper panel comprising a compartment opening for accessing the internal compartment, an enclosure cover adapted to cover the compartment opening and for removably sealing the compartment opening. In certain uses, a telecommunications base station may also be provided. The telecommunications base station can include the in-ground enclosure and a cellular base station, with the cellular base station including an antenna coupled to signal processing equipment and a power supply.

A chamber for a fueling system includes a housing configured to organize electrical lines based on electrical characteristics. The electrical lines are routed through the electrical transition chamber and extend between a plurality of inlets and a plurality of outlets of the chamber. Additionally, the chamber may include at least one entry seal for carrying the electrical lines into and/or out of the electrical transition chamber. The entry seal includes an electrofusion winding and a compression fitting.

A chamber for a fueling system includes a housing configured to organize electrical lines based on electrical characteristics. The electrical lines are routed through the electrical transition chamber and extend between a plurality of inlets and a plurality of outlets of the chamber. Additionally, the chamber may include at least one entry seal for carrying the electrical lines into and/or out of the electrical transition chamber. The entry seal includes an electrofusion winding and a compression fitting.

A cable management unit including a support assembly for mounting a patch panel, such as to a wall. The support assembly may include first and second anchor members adapted to be anchored to the wall, and first and second support arms hingedly coupled to the first and second anchor members at first and second hinge points, respectively. The first and second support arms may be adapted to be coupled to the patch panel. A chassis the patch panel may be supported by the first and second support arms. The first and second support arms may be configured to pivot about the first and second hinge points respectively between storage and access positions. The first and second support arms may extend outward from the wall in the access position and may be substantially parallel to the wall in the storage position.

Precast utility enclosure aprons for buried utility enclosures that have an angled top surface to direct water, ice and debris away from the center of the apron and to limit damage to the apron and utility enclosure caused by impacts to the apron.

A system for servicing cable includes a field-end assembly and a live-end assembly, each mounted on a support structure having at least one drive mechanism operable to cause relative linear movement between the field-end assembly and the live-end assembly. A drilling-and-shorting assembly can create a short circuit in a field-end of the cable, and a continuity tester can test the integrity of the short-circuit. The field end of the cable can then be ejected from the system, and an end-cap-cradle assembly can position an end cap on a live end of an electrical cable and test its installation.

An outdoor enclosure provides weather protection for electrical equipment. More particularly, an outdoor enclosure having a cover flush with the floor or the ground and an interior space beneath the floor or ground is provided. The interior space is maintained in a water-tight condition when the cover of the enclosure and a door within the cover are closed and a drain is provided in the floor of the interior space to allow water to drain from the interior space if and when such water enters the enclosure. Electrical cables and a receptacle with ground fault protection are stowed within the enclosure and pulled through the door in the cover when a user needs access to electrical power via the receptacle.

An outdoor enclosure provides weather protection for electrical equipment. More particularly, an outdoor enclosure having a cover flush with the floor or the ground and an interior space beneath the floor or ground is provided. The interior space is maintained in a water-tight condition when the cover of the enclosure and a door within the cover are closed and a drain is provided in the floor of the interior space to allow water to drain from the interior space if and when such water enters the enclosure. Electrical cables and a receptacle with ground fault protection are stowed within the enclosure and pulled through the door in the cover when a user needs access to electrical power via the receptacle.

A flow restrictor for installation in a connection having a terminus opening into an underground vault. The flow restrictor includes an annular restriction device and a concentration member. The annular restriction device is configured to be installed in the annulus near the terminus opening and to restrict a flow of one or more gases through the annulus of the connection. The concentration member is configured to concentrate the flow and includes a through-channel configured to allow the concentrated flow to flow between the underground vault and the annulus.