A high voltage wet-mate connection assembly (1) with electrically non-connected and connected modes, comprising a receptacle part (100) and a stab part (200). The stab part has an axially movable connection body (250) moving between non-connected and connected positions. The assembly has a connected mode metal encapsulation (50) encapsulating the contact location (40) at a shield distance from the contact location when in the connected position. The connected mode metal encapsulation (50) is in electrical contact with a main receptacle conductor (109), thereby having the same electric potential as the main receptacle conductor (109).

An electrical connector includes an insulating body and multiple conductive terminals. Each conductive terminal has: a main body portion; an elastic arm bending and extending upward from the main body portion; a through slot running through the elastic arm, forming a first elastic arm and a second elastic arm at two opposite sides thereof; and a contact portion bending and extending upward from the elastic arm. A width of the first elastic arm is greater than a width of the second elastic arm. The contact portion defines a virtual center line along an extending direction thereof. A gap between an inner side wall of the first elastic arm on a side thereof adjacent to the through slot and the center line is smaller than a gap between an inner side wall of the second elastic arm on a side thereof adjacent to the through slot and the center line.

A connector comprises an adapter and a first receptacle adapted to be assembled onto a first end of the adapter. The adapter includes an outer contact, an inner contact, and an insulator between the outer contact and the inner contact. The first receptacle includes a first outer terminal in electrical contact with a first end of the outer contact, a first inner terminal in electrical contact with a first end of the inner contact, and a first insulative body between the first outer terminal and the first inner terminal. The first outer terminal includes a plurality of first elastic contact structures. Each of the first elastic contact structures has an elastic arm and a first contact point formed on the elastic arm. The first contact point is adapted to elastically electrically contact an inner wall of the first end of the outer contact.

Exemplary embodiments are disclosed of thermal management assemblies suitable for use (e.g., configured for heat spreading, etc.) with transceivers (e.g., small form-factor pluggable (SFP) transceivers, SFP+ transceivers, quad small form-factor pluggable (QSFP) transceivers QSFP+ transceivers, XFP transceivers, etc.) and other devices (e.g., memory card readers, etc.). In exemplary embodiments, a thermal management assembly comprises at least one flexible heat spreading material (e.g., a single graphite sheet, multiple graphite sheets, etc.) including portions wrapped (e.g., in different non-parallel directions, in parallel directions, etc.) around corresponding portions of a part, which may be configured to be coupled to and/or along a side of a device housing. The at least one flexible heat spreading material may be operable for defining at least a portion of a thermally-conductive heat path around the corresponding portions of the part.

An electrical connector is described for electrically connecting an electrical component of a printed circuit board (PCB) to a power bus bar or a housing. The connector includes an electrically conductive element configured for attachment to a surface of the PCB, and a resiliently displaceable electrically conductive feature extending from the electrically conductive element and configured to contact a surface of the bus bar or housing. In response to contact with the surface of the bus bar or housing, the resiliently displaceable electrically conductive feature is urged toward the bus bar or housing to maintain contact therewith and establish an electrical connection between the bus bar or housing and the electrical component of the PCB.

A connector includes a fixed housing provided with a first side wall extending along an array direction of plural signal terminals, and a second side wall extending along an array-orthogonal direction that is orthogonal to both a fitting direction and the array direction. Each of the signal terminals spans between the first side wall and a movable housing, and a power source terminal span between the second side wall and the movable housing.

A card edge contact pair for electrically coupling printed circuit board assemblies is provided. The card edge contact pair includes a first contact body and a second contact body. The first contact body includes a first solder joint end and a first deflection end. The second contact body includes a second solder joint end and a second deflection end. The card edge contact pair further includes an integral carrier component. The integral carrier component is detachably coupled to the first contact body and the second contact body.

The construction of a medical device having a disposable element is disclosed. Detachable elements comprising a body having a retention feature, an electrical contactor, and sensors are also disclosed. Further disclosed are detachable elements comprising a body having a hole and a retention pocket, an electrical contactor, and a printed circuit board assembly (PCB) in contact with the innermost surface of the body that forms the retention pocket. Further disclosed are detachable elements comprising a body having an opening and a printed film comprising conductive elements, where the conductive elements comprise a sensor configured to be aligned with the opening to expose the sensor. Further disclosed are reusable components having matching retention features.

An electrical terminal includes a base, a first elastic arm and a second elastic arm formed side by side by extending upwardly from an upper end of the base, and a protruding portion. The first elastic arm has a mating portion, and the second elastic arm has a contact portion. The protruding portion protrudes and extends from a first side of the first elastic arm, and the first side of the first elastic arm is adjacent to the second elastic arm. A lower surface of the protruding portion has a contact surface overlapping with the contact portion in a vertical direction, such that the contact portion upwardly abuts the contact surface. When the chip module presses downwardly on the electrical terminal, the contact portion can move on the contact surface, such that the chip module does not need to press downwardly on the contact portion with a relatively large pressure.

The present invention suppresses variation of the position of a contact part in an installed state of a short-circuit terminal. This short-circuit terminal (4) comprises a base (40); a contact part (44); a folded part (41); an opposing part (42); and an overhang part (43). The base (40) has a flat plate shape. The contact part (44) contacts a pair of terminal fittings (2), and is able to short circuit the pair of terminal metal fittings (2). The folded part (41) is extended out so as to be folded back from the base (40). The opposing part (42) is extended facing from the folded part (41) toward the contact part (44), and the gap with the base (40) is formed so as to be smaller than the gap between the opposing inner surfaces of a short-circuit terminal holding chamber (13). The overhang part (43) is extended from the opposing part (42) up to the contact part (44), and is formed so that the gap with the base (40) is greater than the gap between the opposing inner surfaces of the short-circuit terminal holding chamber (13).