A rack adapted for receiving one or more components is disclosed. The rack includes a backplane, a pair of side panels extending from the backplane and internal support members on each side to receive and mechanically guide an initial alignment of components upon their initial insertion in the rack. A pair of male connectors mounted to the backplane is configured to mate with a corresponding pair of female connectors of each component to mechanically guide a final alignment of each component when the component is further inserted in the rack. Mechanical guidance may also be provided by, or supplemented with, a connection capable of providing liquid cooling to the rack. A system including the rack and the component inserted in the rack is also disclosed.

A coaxial connector assembly includes a connector module having a connector body that includes contact channels. The coaxial connector assembly includes coaxial contacts received in the corresponding contact channels having a center contact, a conductive shell coaxial with the center contact and an insulator between the center contact and the conductive shell. The coaxial connector assembly includes positioning adapters received in the corresponding contact channels having an adapter body forming an adapter bore that receives the coaxial contact. The adapter body engages the retention feature to position the coaxial contact relative to the adapter body and engages the connector body to position the coaxial contact in the contact cavity. The adapter component enables multiple coaxial contact sizes to be used in the same connector module contact channel.

A system and method of mounting and electrically contacting a first printed circuit board perpendicularly onto a second printed circuit board within a housing includes inserting the first printed circuit board into an upper part of the housing using a stop surface arranged on an inner side surface of the upper part of the housing and arranged to support the electrical contacting and assembly, locking the first printed circuit board in the upper part of the housing using a locking system, and mounting the upper part of the housing with the locked printed circuit board on a lower part of the housing in which the second printed circuit board is mounted.

Power supply systems are provided for carrying electrical power from a power source to a circuit board mounted on a housing, shelf, cabinet, etc. for supporting networking equipment. A busbar assembly, according to one embodiment, includes a pair of conductive strips configured to carry electrical power. The pair of conductive strips are arranged on a front-facing surface of a non-conductive vertical substrate. The busbar assembly further includes one or more alignment blocks configured to hold the pair of conductive strips in a fixed position with respect to the non-conductive vertical substrate. Each of the one or more alignment blocks is configured to guide a pair of power connectors of a circuit board for making electrical contact with the pair of conductive strips, while allowing simultaneous mating of signal connectors on the circuit board with signal connectors on the substrate, when the circuit board is being installed in a housing.

A storage device includes a casing; a drive that records data; a controller that controls a data processing of the drive; and a midplane that connects the drive to the controller, in which the midplane includes a plurality of split midplanes which are replaceable, a drive side connector is disposed on a drive side of the split midplane, and the drive side connector is connected to the drive.

Power supply systems are provided for carrying electrical power from a power source to a circuit board mounted on a housing, shelf, cabinet, etc. for supporting networking equipment. A busbar assembly, according to one embodiment, includes a pair of conductive strips configured to carry electrical power. The pair of conductive strips are arranged on a front-facing surface of a non-conductive vertical substrate. The busbar assembly further includes one or more alignment blocks configured to hold the pair of conductive strips in a fixed position with respect to the non-conductive vertical substrate. Each of the one or more alignment blocks is configured to guide a pair of power connectors of a circuit board for making electrical contact with the pair of conductive strips, while allowing simultaneous mating of signal connectors on the circuit board with signal connectors on the substrate, when the circuit board is being installed in a housing.

A coaxial connector assembly includes a connector module having a connector body that includes contact channels. The coaxial connector assembly includes coaxial contacts received in the corresponding contact channels having a center contact, a conductive shell coaxial with the center contact and an insulator between the center contact and the conductive shell. The coaxial connector assembly includes positioning adapters received in the corresponding contact channels having an adapter body forming an adapter bore that receives the coaxial contact. The adapter body engages the retention feature to position the coaxial contact relative to the adapter body and engages the connector body to position the coaxial contact in the contact cavity. The adapter component enables multiple coaxial contact sizes to be used in the same connector module contact channel.

An alignment member for aligning electrical components. The alignment member includes a base, a telescoping portion and a spring. The base has a first spring receiving cavity which extends from a first end of the base to a spring engaging shoulder. The telescoping portion has a second spring receiving cavity with a spring cooperating surface. The spring is positioned in the first spring receiving cavity of the base and in the second spring receiving cavity of the telescoping portion. The spring has a length which is approximately equal to or slightly larger than the length of a cavity formed by the spring receiving cavity and the base receiving cavity when the alignment member is in an extended position. The spring is retained in a biased position to keep the telescoping portion extended until a force is applied to the telescoping portion by the mating alignment member.

An electrical device includes a connection part and a cover part connected to the connection part. A mounting part is accommodated and situated in the connection part, and a first circuit board is connected to the mounting part in a coded manner. A second circuit board is situated in the cover part, which is connected to a frame part in a coded manner. The first circuit board is connected to a plug connector part, and the second circuit board is connected to a mating plug connector part. A leading guide for a plug connection is provided on the mounting part, which becomes active when the cover part is connected to the connection part. The frame part being able to be connected to the mounting part in a coded manner.

Blind mate connection techniques and associated connectors are disclosed. Blind mate connectors provide connections where visual inspection at time of connection may not be available. Stacking tolerance increases when connectors have a different set of datums (e.g., a different relative orientation) relative to adjacent connectors. Different datums permit twinning two printed circuit boards (“PCBs”) prior to insertion into a slot of a chassis. Each connector may be attached to a respective PCB utilizing a spring and offset feature to provide a standoff on a respective PCB. Control of standoff and rotational movement (e.g., via brackets) allows each individual connector to have a “float” for improved insertion tolerance. Connector pairs may connect through an opening in a midplane while simultaneously connecting to the midplane. Switch trays and node trays may be inserted through opposing sides of a chassis and be connected through the midplane of that chassis.