An apparatus is described. The apparatus includes a dual-in line memory module (DIMM) socket having a first electrical circuit component embedded in a latch of the DIMM socket. The first electrical circuit component has a first exposed electrical contact that is to contact or not contact a second exposed electrical contact of a second electrical circuit component that is embedded in a housing of the socket depending on whether a corner of a DIMM is or is not properly inserted into the DIMM socket.

An electrical connector including a compressible lossy member is provided. The electrical connector comprises an insulative member, a plurality of terminals supported by the insulative member and disposed in a row along a row direction, and a compressible lossy member disposed in a recess of the insulative member. The lossy member includes a body portion elongated in the row direction and a plurality of projections extending from the body portion. The projections of the lossy member project toward and make contact with contact surfaces of first terminals of the plurality of terminals. At least a part of the body portion is compressible and is in a state of compression when the projections are pressed against the first terminals.

A power supply device includes a housing, a circuit board and a conductive spring contact. The housing has a receiving structure. The circuit board is disposed in the housing. The conductive spring contact is disposed in the receiving structure and includes a base portion, a contact portion and a curved portion. The contact portion is connected to the base portion and is bent relative to the base portion. The contact portion extends between the circuit board and a wall portion of the receiving structure, and the contacts the circuit board. The curved portion is connected to the contact portion and abuts against the wall portion.

A power connector includes a housing and a clamp group disposed in the housing. An insertion opening is formed at one end of the housing, and the insertion opening is configured to plug in a plug. The clamp group includes an inner clamp and an outer clamp. An insertion slot is formed in the inner clamp, and the insertion slot is opposite to the insertion opening and is configured to accommodate a front end portion of the plug. The outer clamp is disposed to extend over the inner clamp. When the plug passes through the insertion opening and is plugged into the insertion slot, a contact end of the outer clamp close to the insertion opening presses against a conductive surface of the plug. A contact segment of the inner clamp also presses against the conductive surface of the plug.

A cable harness supplies a plurality of electric devices which are in a distributed arrangement in a device housing. A first connection point of the cable harness has a plug connector on the side of the cable harness. At least the electric devices which are supplied via the first connection point are connected to the first plug connector on the side of the cable harness by way of a device-side plug connector and an adapter that is plugged together with both plug connectors.

A plug-in connector having terminal provided in terminal receiving cavities. The terminals have memory card engagement sections. A memory card receiving slot is provided in the housing. The memory card receiving slot spans the terminal receiving cavities. A portion of the memory card receiving slot is in alignment with each of the terminal receiving cavities. An elongated opening extends between the memory card receiving slot and the terminal receiving cavities. A memory card is positioned in the memory card receiving slot. The memory card stores data which is identifiable to the specific device and allows the data to be easily conveyed.

The present application relates to an electrical connector and an electronic product. The electrical connector includes a metal terminal; an insulating body configured to fixing the metal terminal; a metal shield covering an outer side of at least a portion of the insulating body; a metal latch connected to the insulating body, and provided with a ground terminal thereon, and wherein the insulating body, the metal shield, and the metal latch enclose an accommodating space; and a brazing solder disposed at least partially within the accommodating space, and the brazing solder being configured to be melted during welding and to fixedly connect the metal shield and the metal latch after being cooled, such that the metal shield is electrically connect to the metal latch.

An electrical connector assembly includes a housing having a card slot at a mating end configured to pass through a panel opening of a panel forward of the panel for receiving a circuit card. A cable end of the housing is rearward of the panel. The electrical connector assembly includes contacts held in the housing. The electrical connector assembly includes cables terminated to the contacts and extending from the housing. The electrical connector assembly includes a connector mounting bracket having a collar surrounding a window receiving the housing. The connector mounting bracket has mounting latches extending from the collar with latch fingers configured to be coupled to the panel. The connector mounting bracket includes a biasing element configured to engage the panel to bias the panel against the mounting latches.

Methods and apparatus for differential I/O (input/output) cards using compression mount technology (CMT) connectors. Assemblies include a CMT connector having an array of spring-loaded pins or contacts that are configured to contact respective CMT contact pads on a pair of printed circuit board (PCBs), such as an add-in card (AIC) and a motherboard. Stacked assemblies are also disclosed including multiple CMT AIC or PCIe modules communicatively coupled using on module CMT connectors. The connector solutions may be used for AICs without changing the overall PCB form factor outline of existing AICs employing edge connectors. Under a stacked assembly of multiple CMT PCIe modules interconnected by on module CMT connectors, wiring in the PCBs is configured to provide signaling supporting multi-lane PCIe or CXL links for each CMT PCIe module. The CMT connector approach also is scalable and can support more pins/contacts to facilitate additional I/O bandwidth.

A connector for a networking cable assembly includes a substrate, a first set of contacts on a first surface of the substrate that electrically connect to leads of a first cable, and a second set of contacts on the first surface of the substrate that electrically connect to leads of a second cable. The first set of contacts are spaced apart from the second set of contacts in a first direction by an amount that enables the second cable to be stacked on the first cable and passed over the first set of contacts to electrically connect to the leads of the second cable.