Presented herein are adjustable mounting rail latches that each comprise first and second latch modules. The latch modules each have a first side configured to be attached to at least one equipment unit, and a second side that includes an attachment system configured to be mechanically coupled to a mounting rail. A slide-rail system is integrated with each of the first and second latch modules that is configured to slideably couple the first latch module with the second latch module. Additionally, the adjustable mounting rail latches comprise at least one selectively engageable retention device configured to exert a force on the mounting rail to prevent movement of the first and second latch modules along the mounting rail.

This disclosure provides a field termination assembly (FTA) providing for ease of mounting to a support rail. The FTA provides a lever on a base that cushions against shocks and vibrations during shipment and operation while a housing is mounted on a base secured to a support rail. The base includes a dampener feature which makes it more capable of meeting operation and transportation vibration and shock requirements even for marine applications while still providing high channel density and cable count.

In a system comprising plural functional modules including a control module, the functional modules being aligned closely one next to another and electrically connected to a bus, an addressing method for the functional modules comprises the steps of: The control module sends a photo addressing command comprising a unique address to its downstream functional module. The downstream functional module records the address as its address and sends a next addressing command to a further downstream functional module and a response signal to the control module. Repeat this step, until no response signal is received.

A server rack seismic restraint includes a rear restraint assembly configured to attach to a support surface that is operable to support a data center server rack. The rear restraint assembly includes at least one lateral member positioned to receive the server rack and restrain the server rack against lateral movement based on a force applied to the server rack; and an angled bracket positioned to receive the server rack and restrain the server rack against vertical movement based on the force applied to the server rack. The server rack seismic restraint also includes a front restraint assembly configured to attach to the support surface and engage the server rack to restrain the server rack against vertical movement based on the force applied to the server rack.

Presented herein are adjustable mounting rail latches that each comprise first and second latch modules. The latch modules each have a first side configured to be attached to at least one equipment unit, and a second side that includes an attachment system configured to be mechanically coupled to a mounting rail. A slide-rail system is integrated with each of the first and second latch modules that is configured to slideably couple the first latch module with the second latch module. Additionally, the adjustable mounting rail latches comprise at least one selectively engageable retention device configured to exert a force on the mounting rail to prevent movement of the first and second latch modules along the mounting rail.

An electronics module mounting system includes a baseplate with a main wall, opposite left and right ends spaced apart from each other along an X axis, and opposite first and second spaced-apart edges extending between the left and right ends. The first and second edges are spaced apart along a Y axis. The baseplate includes a first channel that projects outwardly from the main wall and includes a mounting leg that projects outwardly from the main wall and that forms a mounting recess. A module mounting base is connected to the baseplate and includes a mounting tab located in the mounting recess. The mounting base includes a front face to receive and retain an electronics module and a rear face located opposite the front face. A channel recess is located in the rear face and extends between opposite left and right edges of the mounting base. The channel of the baseplate is located in the channel recess. The mounting base includes first and second electrical connectors that are aligned with each other and aligned with the channel recess. A fastener extends through the mounting base at a location aligned with the channel recess such that the fastener is engaged with the channel of the baseplate.

A slide rail assembly includes a sliding rail and a supporting device. The supporting device includes a supporting bracket and a sliding bracket. The supporting bracket defines at least one sliding slot along an extending direction of the supporting bracket, and the sliding bracket defines at least one sliding portion corresponding to the at least one sliding slot. The sliding bracket is slidably connected to the supporting bracket through the at least one sliding portion and the at least one sliding slot, the sliding bracket is mounted to the sliding rail. The supporting device is also disclosed.

An enclosure assembly for housing printed circuit boards and related electrical components having a secured lid that may be removed by-hand.

A quickly-mountable housing of an electronic device includes the holding member and a main body. The main body includes a lateral panel having a first edge, a second edge, a first groove, a second groove, a hooking structure, and two blocks. The first groove extends along a traversal axis and the second groove extends along a longitudinal axis. The hooking structure extends toward the traversal axis from a lower side wall adjacent to the second edge. The two blocks on two sides of the longitudinal axis extend from side walls of the second groove toward the longitudinal axis. The holding member in the second groove is in a closed position where a holding part of the holding member is within the first groove.

A quickly-mountable housing of an electronic device includes the holding member and a main body. The main body includes a lateral panel having a first edge, a second edge, a first groove, a second groove, a hooking structure, and two blocks. The first groove extends along a traversal axis and the second groove extends along a longitudinal axis. The hooking structure extends toward the traversal axis from a lower side wall adjacent to the second edge. The two blocks on two sides of the longitudinal axis extend from side walls of the second groove toward the longitudinal axis. The holding member in the second groove is in a closed position where a holding part of the holding member is within the first groove.