Abstract: Systems for optimizing mounting points for coaxial RF connectors, including a printed circuit board (PCB) comprising a coaxial radio frequency (RF) connector; a faceplate comprising an opening adapted to receive the coaxial RF connector; and a bushing positioned within the opening, wherein the coaxial RF connector is positioned within the bushing.

Abstract: A system, an article of manufacture, and a method are disclosed. The system includes a set of components in an enclosure. The set of components includes electronic devices and airflow moving components configured to maintain airflow across the electronic devices from a front plenum of the enclosure to a rear plenum of the enclosure and direct air from the rear plenum through the first heat exchanger. The set of components also includes a first heat exchanger configured to circulate a cooling liquid and a second heat exchanger configured to maintain a constant temperature of the cooling liquid, wherein the constant temperature is a temperature of the cooling liquid within a threshold distance from a selected temperature.

Abstract: An electronic component system includes a chassis that includes a body, an electrically isolated portion, and an insulator disposed between the electrically isolated portion and the body, wherein the insulator is comprised of a first electrically insulating material. The electronic component system further includes a first electronic component mounted to the electrically isolated portion, and a second electronic component mounted to the body and electrically connected to the first electronic component.

Abstract: A system, an article of manufacture, and a method are disclosed. The system includes a set of components in an enclosure. The set of components includes electronic devices and airflow moving components configured to maintain airflow across the electronic devices from a front plenum of the enclosure to a rear plenum of the enclosure and direct air from the rear plenum through the first heat exchanger. The set of components also includes a first heat exchanger configured to circulate a cooling liquid and a second heat exchanger configured to maintain a constant temperature of the cooling liquid, wherein the constant temperature is a temperature of the cooling liquid within a threshold distance from a selected temperature.

Abstract: A cable connector retaining system includes a cable connector retaining assembly having a connector block and a movable retention block with a connector retention fastener, e.g., a threaded fastener. The system also includes a plate having a connector mounted thereon and a connector retention feature, e.g., a threaded hole, positioned adjacent to the connector. The connector block has a connector housed in an overmold jacket and connectable to the plate's connector. The connectors may be USB-type connectors, for example. The retention block is movably mounted to the connector block's overmold jacket so that the retention block's connector retention fastener may be aligned with the plate's connector retention feature. Once aligned, the connector retention fastener may be engaged with the connection retention feature. Movement of the retention block allows a single cable connector retaining assembly to be used for multiple plate configurations (i.e., with the connector retention feature at different positions).

Abstract: A connector coupling mechanism comprises a housing coupled to a first connector; and, a force applying device connected to the housing and being movable between docking and undocking positions; wherein in response to the force applying device moving to the docking position, a mechanical advantage is provided for facilitating a firm coupling of the first and second connector assemblies. In addition, the force applying device provides a mechanical advantage in response to the force applying device moving to undocking position for facilitating easy unplugging. The coupling mechanism provides a latching arrangement for releasable and positive retention of the force applying device in the docked position for preventing against inadvertent unplugging. A connector assembly coupling system is provided as well as a method of coupling connector assemblies.

Abstract: A connector coupling mechanism comprises a housing coupled to a first connector; and, a force applying device connected to the housing and being movable between docking and undocking positions; wherein in response to the force applying device moving to the docking position, a mechanical advantage is provided for facilitating a firm coupling of the first and second connector assemblies. In addition, the force applying device provides a mechanical advantage in response to the force applying device moving to undocking position for facilitating easy unplugging. The coupling mechanism provides a latching arrangement for releasable and positive retention of the force applying device in the docked position for preventing against inadvertent unplugging. A connector assembly coupling system is provided as well as a method of coupling connector assemblies.

Abstract: A cable connector retaining system includes a cable connector retaining assembly having a connector block and a movable retention block with a connector retention fastener, e.g., a threaded fastener. The system also includes a plate having a connector mounted thereon and a connector retention feature, e.g., a threaded hole, positioned adjacent to the connector. The connector block has a connector housed in an overmold jacket and connectable to the plate's connector. The connectors may be USB-type connectors, for example. The retention block is movably mounted to the connector block's overmold jacket so that the retention block's connector retention fastener may be aligned with the plate's connector retention feature. Once aligned, the connector retention fastener may be engaged with the connection retention feature. Movement of the retention block allows a single cable connector retaining assembly to be used for multiple plate configurations (i.e., with the connector retention feature at different positions).

Abstract: An assembly and associated installation method for a server or other electronic equipment enclosure installable into a rack by a single person without adverse tolerance stack-up problems. A mounting bracket is attached to each end of a sliding rail coupled to the server or other equipment enclosure. The mounting bracket includes pins which are inserted into mounting apertures in the posts of the rack to temporarily retain and hold the sliding rail in the rack. Subsequently, a single user can then insert screws or other mechanical fasteners to securely attach the mounting bracket and sliding rail coupled thereto to the rack. The mounting bracket is fixedly secured to the rack and the sliding rail is permitted to move, translate or pivot relative to the mounting bracket to account for tolerance stack-up issues or other abnormalities in the dimensional fit between the server and rack system.

Abstract: A ground from a printed circuit board to the frame of an electronic system is formed by a biaxially-compressible conductive spring that is captivated between the printed circuit board and a plastic stiffener to which the board is fastened. The spring makes contact with a ground pad on the underside of the printed circuit board. As the board is fully installed in the electronic system, standoffs attached to the system frame make contact with the conductive spring, completing the ground path. Keyhole-shaped cutouts in the printed circuit board secure the board without the use of tools. When the board assembly is lowered onto the standoffs, the head of the standoff passes through the circular opening of the keyhole. The board assembly is secured in place by sliding it on the standoffs to a position in which the head of the standoff is over the narrower slot portion of the keyhole.

Abstract: A ground from a printed circuit board to the frame of an electronic system is formed by a biaxially-compressible conductive spring that is captivated between the printed circuit board and a plastic stiffener to which the board is fastened. The spring makes contact with a ground pad on the underside of the printed circuit board. As the board is fully installed in the electronic system, standoffs attached to the system frame make contact with the conductive spring, completing the ground path. Keyhole-shaped cutouts in the printed circuit board secure the board without the use of tools. When the board assembly is lowered onto the standoffs, the head of the standoff passes through the circular opening of the keyhole. The board assembly is secured in place by sliding it on the standoffs to a position in which the head of the standoff is over the narrower slot portion of the keyhole.

Abstract: An assembly and associated installation method for a server or other electronic equipment enclosure installable into a rack solves both the issues of a single person installation method, as well as tolerance stack-up problems. A mounting bracket is attached to each end of a sliding rail coupled to the server or other equipment enclosure. The mounting bracket includes pins which are inserted into mounting apertures in the posts of the rack to temporarily retain and hold the sliding rail in the rack. Subsequently, a single user can then insert screws or other mechanical fasteners to securely attach the mounting bracket and sliding rail coupled thereto to the rack. Advantageously, the mounting bracket is fixedly secured to the rack and the sliding rail is permitted to move, translate or pivot relative to the mounting bracket to account for tolerance stack-up issues or other abnormalities in the dimensional fit between the server and rack system.

Abstract: A hinge assembly has a hinge door that is pivotally mounted to a hinge base. The door has a flat body with a pair of square tabs extending laterally from one end. The hinge base has a flat frame with a rectangular aperture. A pair of parallel, rigid flanges extend from the aperture in the frame. Each flange has an entry hole that leads into a diagonal slot. The slots terminate in circular recesses. The hinge door is installed in the hinge base to form the assembly by initially positioning the tabbed end of the door diagonally in the aperture. The tabs are then elevated slightly above the frame and rotated into alignment with the entry holes. The door is angled into alignment with the diagonal slots and lowered in that plane. This motion causes the tabs to move past the entry holes, through the slots, and into the circular recesses to form the hinge assembly. The recesses closely receive the tabs on the door to allow pivotal motion therebetween.