Abstract: Systems having fluid conduit carriers for holding different portions of a fluid conduit and methods of using the same are disclosed herein. According to an aspect, a system includes a fluid conduit comprising a first portion and a second portion that are fluidly connected to each other for carrying cooling fluid proximate to a first electronic component and a second electronic component of a computing device. The system also includes a first fluid conduit carrier configured to hold the first portion of the conduit. Further, the system includes a second fluid conduit carrier configured to hold the second portion of the conduit. The first fluid conduit carrier and the second fluid conduit carrier are configured to connect to one another.

Abstract: Systems having fluid conduit carriers for holding different portions of a fluid conduit and methods of using the same are disclosed herein. According to an aspect, a system includes a fluid conduit comprising a first portion and a second portion that are fluidly connected to each other for carrying cooling fluid proximate to a first electronic component and a second electronic component of a computing device. The system also includes a first fluid conduit carrier configured to hold the first portion of the conduit. Further, the system includes a second fluid conduit carrier configured to hold the second portion of the conduit. The first fluid conduit carrier and the second fluid conduit carrier are configured to connect to one another.

Abstract: A low overhead hinge assembly comprising a stationary hinge plate and a rotating hinge plate. The stationary hinge plate having a stationary hinge plate body portion and a plurality of stationary hinge plate digits coupled to the stationary hinge plate body portion, each of the stationary hinge plate digits having an opening therein. The rotating hinge plate having a rotating hinge plate body portion and a plurality of pins coupled to the rotating hinge plate body portion, wherein the stationary hinge plate digits are configured to be engaged with the rotating hinge plate pins so that each of a plurality of the rotating hinge plate pins is inserted into an opening in one of the stationary hinge plate digits so as to pivotally couple the rotating hinge plate to the stationary hinge plate.

Abstract: A low overhead hinge assembly comprising a stationary hinge plate and a rotating hinge plate. The stationary hinge plate having a stationary hinge plate body portion and a plurality of stationary hinge plate digits coupled to the stationary hinge plate body portion, each of the stationary hinge plate digits having an opening therein. The rotating hinge plate having a rotating hinge plate body portion and a plurality of pins coupled to the rotating hinge plate body portion, wherein the stationary hinge plate digits are configured to be engaged with the rotating hinge plate pins so that each of a plurality of the rotating hinge plate pins is inserted into an opening in one of the stationary hinge plate digits so as to pivotally couple the rotating hinge plate to the stationary hinge plate.

Abstract: An electronic module rack system includes a rack housing and opposing first and second rail members attached to the housing. A stabilizer bar is attached to the first and second rail members. The rail members support a cable trough assembly, and at least one cable separator retainer extends from the cable trough assembly. A method for managing cables for an electronic module includes connecting a first cable to the electronic module and connecting a second cable to the electronic module. The first cable is placed in a cable trough assembly and the second cable is placed in a cable separator retainer extending from the cable trough assembly. A cable support system includes a cable trough assembly and means for supporting cables outside the cable trough assembly.

Abstract: A system permitting vertical and horizontal movement of a first board for proper mating of a first connector on the first board to a second connector on a second board. The first board being aligned pivots about a pivot pin, which is mounted on a mechanical plate at a first end of the board that is opposite to a second end of the board to which a first connector is mounted. This pivoting allows transverse (horizontal) movement of the first board. The first board floats on springs located between the first board and the mechanical plate to which the first board is mounted. These springs afford longitudinal (vertical) movement of the first board, while also providing a friction fit between the first board and the mechanical plate. When the first connector is aligned properly with as second connector on a second board, the first and second connectors can be mated.

Abstract: A hand tightened locking pin using a unique internal cam configuration to lock the pin assembly. The pin assembly includes a sleeve and a locking cam unit. The sleeve includes anti-rotation protrusions that match a keyhole in a first metal plate to prevent rotation of the sleeve. The pin assembly is inserted through the keyhole of the first metal plate and a circular hole in a second metal plate that lies on the first metal plate. When the locking cam unit, which is inside the sleeve, is rotated, a lower portion of the sleeve expands, locking the first and metal plates together. The cam is locked in position by concave shaped ends that mate over bulges in the lower portion of the sleeve. A locked/unlocked indicator on top of the pin assembly indicates when the concave shaped ends are mated with the bulges.