An electrical system includes modules and a frame structure for mechanically supporting the modules successively in an arrival direction of cooling air. Each module includes a cooling element in heat conductive relation with one or more electrical components. The frame structure mechanically supports the modules so that the cooling elements are substantially in the same attitude and successively in the arrival direction of the cooling air. The cooling elements are shaped so that, when the modules are mechanically supported by the frame structure, the cooling elements conduct cooling air in a direction deviating from the arrival direction of the cooling air. Furthermore, at least a part of a flank of the heat transfer portion of each cooling element is oblique with respect to the arrival direction of the cooling air. Thus, each of the cooling elements receives a fresh portion of the cooling air.

The disclosed apparatus may include (1) a Field-Replaceable Unit (FRU) that (A) is designed to mate with a backplane of a telecommunications system and (B) facilitates communication among computing devices within a network and (2) at least one helical ejector that (A) is coupled to the FRU, (B) fastens to a housing of the telecommunications system to enable the FRU to mate with the backplane of the telecommunications system, and (C) includes at least one spring that, when the helical ejector is fastened to the housing of the telecommunications system, applies a force on the FRU that pushes the FRU toward the backplane of the telecommunications system. Various other apparatuses, systems, and methods are also disclosed.

A fiber panel system includes a chassis and at least blades configured to mount to the chassis. Each blade is moveable relative to the chassis between a retracted (closed) position and at least one extended position. Cable slack is managed at the front and/or rear of each chassis to facilitate movement of the blades without pulling or bending the cables beyond a maximum bend limit. Each blade may be locked into one or more positions relative to the chassis.

A fiber panel system includes a chassis and at least blades configured to mount to the chassis. Each blade is moveable relative to the chassis between a retracted (closed) position and at least one extended position. Cable slack is managed at the front and/or rear of each chassis to facilitate movement of the blades without pulling or bending the cables beyond a maximum bend limit. Each blade may be locked into one or more positions relative to the chassis.

An electrical system includes modules and a frame structure for mechanically supporting the modules successively in an arrival direction of cooling air. Each module includes a cooling element in heat conductive relation with one or more electrical components. The frame structure mechanically supports the modules so that the cooling elements are substantially in the same attitude and successively in the arrival direction of the cooling air. The cooling elements are shaped so that, when the modules are mechanically supported by the frame structure, the cooling elements conduct cooling air in a direction deviating from the arrival direction of the cooling air. Furthermore, at least a part of a flank of the heat transfer portion of each cooling element is oblique with respect to the arrival direction of the cooling air. Thus, each of the cooling elements receives a fresh portion of the cooling air.

A tower-mounted networking device facilitates deploying a remote station without having to build a custom station aside a radio tower. The networking device's chassis comprises a mounting bracket, which includes a curved contour for mounting the networking device on the radio tower. Also, the chassis can be resistant to weather intrusion, by not including a vent, to allow the networking device to be installed outdoors. The networking device can include a first power port coupled to an external connection line from a source external to the tower, such that the external connection line provides at least power to the networking device. The networking device can use the power to power a set of antenna mounted on the radio tower. The networking device can also relay a network connection between a pair of antennas, and/or between an antenna and a network connection to an Internet service provider.

Telecommunication equipment includes a rack and telecommunication devices attached to the rack with mounting screws. A head of at least one of the mounting screws is shaped to constitute a grounding connector so that a connector terminal of a grounding cable is connectable to the grounding connector without loosening, detaching, or otherwise changing the position of the mounting screw. The other end of the grounding cable is connectable for example to clothes of a maintenance person so as to prevent static electricity from damaging electronic components of the telecommunication devices during maintenance work. There is no need for a separate grounding connector and its mounting screw because the at least one mounting screw of the telecommunication devices is arranged to act not only as the mounting screw but also as the grounding connector.

A tower-mounted networking device facilitates deploying a remote station without having to build a custom station aside a radio tower. The networking device's chassis comprises a mounting bracket, which includes a curved contour for mounting the networking device on the radio tower. Also, the chassis can be resistant to weather intrusion, by not including a vent, to allow the networking device to be installed outdoors. The networking device can include a first power port coupled to an external connection line from a source external to the tower, such that the external connection line provides at least power to the networking device. The networking device can use the power to power a set of antenna mounted on the radio tower. The networking device can also relay a network connection between a pair of antennas, and/or between an antenna and a network connection to an Internet service provider.

Disclosed is a novel connector module structure, to be installed in a system to form connection between at least two functional modules. The connector module provides jumper connection capabilities, i.e., allowing one of its connection terminals to form electrical connection with a connection terminal of one or more particular non-adjacent connector modules.

A network switch subrack in a cabinet system is configured to bear a network switch. The network switch subrack includes an outer frame that is configured to be plugged into the cabinet. The outer frame includes a cavity sized to accommodate the network switch. The network switch subrack further includes a fastening assembly that is disposed in the outer frame and configured to fasten the network switch in the cavity in the outer frame. The network switch subrack further includes a transfer module having a first end pluggably connected to the cabinet system and a second end pluggably connected to the network switch.