An adapter plug for a charging port of an electric vehicle includes a housing, a first electrical connector, and a second electrical connector. The housing has circuitry disposed therein. The first electrical connector is integral to the housing, faces a first direction, and has a first profile. The first profile is configured to mate with the charging port and connect the circuitry to the charging port. The second electrical connector is integral to the housing, faces a second direction opposing the first direction, and has a second profile. The second profile matches the charging port. The second profiled is configured to mate with a connector head of a charging station and connect the circuitry to the connector head.

A connector 10 is provided with a plurality of terminals, a plurality of wires, a housing made of resin and including a tubular receptacle and a holding portion projecting from the receptacle, and a plate projecting from the housing toward an outer peripheral side of the receptacle. The terminal includes a first extending portion arranged side by side with the plate in a plate thickness direction of the plate and extending in parallel to the plate and a second extending portion extending to the outer side from the first extending portion. The first extending portion, the second extending portion and the plate are embedded in the holding portion. The second extending portion extends obliquely with respect to the first extending portion to be more separated from the plate in the plate thickness direction toward the outer side.

A terminal is to be connected to a mating terminal having a flat surface portion. The terminal includes a conductive main body having an abutment surface, an annular terminal spring, the annular terminal spring being held on the abutment surface and a fastener holding the annular terminal spring on the abutment surface. The fastener includes a main body shaft being inserted into a central space of the annular terminal spring, a first end of the main body shaft being fixed to the conductive main body, and a plurality of arm portions extending outward in a radial direction of the fastener from a second end of the main body shaft, the second end being opposite to the first end, the plurality of arm portions being configured to hold the annular terminal spring at a contacting portion of the annular terminal spring, the contacting portion contacting the abutment surface.

A conductive terminal to be mated with a mating terminal includes: a base; and a mating end at a front of the base for mating with the mating terminal, the mating end including a first mating portion for contacting with the mating terminal and a second mating portion arranged in front of the first mating portion for contacting with the mating terminal, wherein the first mating portion includes a first protrusion, the second mating portion includes a second protrusion, the first protrusion and the second protrusion protrude toward same side of the conductive terminal, the contacting direction and manner between the first protrusion and the mating terminal are different from the contacting direction and manner between the second protrusion and the mating terminal.

A separable and reconnectable connector for semiconductor devices is provided that is scalable for devices having very small contact pitch. Connectors of the present disclosure include signal pins shielded by pins electrically-coupled to ground. One or more signal pins in a contact array are electrically-shielded by at least one ground pin coupled to a ground plane. Embodiments thereby provide signal pins, either single-ended or a differential pair, usable to transmit signals with reduced noise or cross-talk and thus improved signal integrity. Embodiments further provide inner ground planes coupled to connector ground pins to shield pairs of differential signal pins without increasing the size of the connector. Inner grounding layers can be formed within isolation substrates incorporated into connector embodiments between adjacent pairs of signal pins. These buried ground layers provide additional crosstalk isolation in close proximity to signal pins, resulting in improved signal integrity in a significantly reduced space.

An elastic contact element of the electrical connector is provided and has an upper ring, a lower ring, and a plurality of elastic flat bodies connected to and located between the upper ring and the lower ring. Each one of the elastic flat bodies is strip-shaped and forms a contact portion. The elastic flat bodies are spaced apart from each other and divided into several groups according to different height positions of the contact portions. Each one of the contact portions protrudes toward a center axis. Because the elastic flat bodies are divided into several groups according to different height positions of the contact portions, the elastic flat bodies contact an inserted male probe at various positions.

A connector set includes a right angle type inner connector and a relay connector. First external-side contact portions and second external-side contact portions are disposed at different positions in a substrate perpendicular direction. However, first inner-side contact portions and second inner-side contact portions are disposed at the same position in the substrate perpendicular direction.

A hybrid edge connector includes an insulative housing with a slot lined with signal terminals, in a signal portion, and power terminals in a power portion. The power terminals may be made with multiple layers, with each layer formed into one or more fingers. Each finger may be configured to make contact with an edge of a card inserted in the slot such that each terminal has multiple contact points to the card and can carry a large current. To support a large current, the card may be a hybrid card, with a signal portion formed using a conventional PCB manufacturing techniques and a power portion formed with one or more blades mechanically coupled to the signal portion. The slot in the connector housing may have different widths in the signal and power portions and the center lines of those portions may be offset with respect to each other.

An electrical connector includes a mating section for receiving the mating tab therein. The mating section has a first contact arm and a second contact arm. The first contact arm is spaced from the second contact arm by a first slot. The first contact arm has a first length which is different than a second length of the second contact arm. A first normal force exerted by the first contact arm on the mating tab is equal to a second normal force exerted by the second contact arm.

A charging inlet assembly includes a housing extending between a front and a rear. The housing has a DC section including DC terminal channels that are configured to receive DC terminals. The housing has an AC section including an AC module chamber. The DC section is configured for mating with a DC charging connector at the front. The AC section is configured for mating with an AC charging connector at the front. The charging inlet assembly includes an AC charging module removably received in the AC module chamber. The AC charging module includes an AC insert extending between an insert front and an insert rear. The AC insert includes AC terminal channels between the insert front and the insert rear. The AC charging module include AC terminals received in the AC terminal channels. The AC terminals are terminated to ends of AC cables extending from the insert rear. The AC terminals and the AC cables are removable from the housing with the AC insert.