A method includes plugging a plug into a socket, wherein the plugging includes pushing the plug into the socket at least up to a point that a latch clicks into the plug and locks the plug in place. Pressing down on a lever that rotates around an axis causes the lever to be pushed down. This results in the latch moving away from the plug and unlocking the plug from the socket, to thereby allow the plug to be separated from the socket.

A contact element for contacting a bipolar plate of a fuel cell stack includes a contact body extending along a longitudinal axis. The contact body has a channel extending along the longitudinal axis and delimited by a pair of channel walls disposed opposite one another in a direction transverse to the longitudinal axis. The channel is adapted to receive a portion of the bipolar plate. The contact body has a contact spring on a first channel wall of the pair of channel walls. The contact spring protrudes into the channel and has a cutting edge directed toward a second channel wall of the pair of channels walls and adapted to contact the bipolar plate.

A plug connector includes a housing and multiple plug terminals. The housing has at least a base portion housing the multiple plug terminals, and a lock mechanism, and a pair of side portions each provided on both right and left sides of the base portion. At each of the side portions in a pair, a step portion is formed. In a state in which the plug connector is fitted in the receptacle connector, side surfaces of the step portions face the receptacle connector through a clearance, and front surfaces of the side portions are closer to the receptacle connector than the side surfaces of the step portions are to the receptacle connector.

Disclosed is an electronic device. According to an embodiment disclosed in this specification, an electronic device may include a first interface, a second interface, an input device generating a specified signal associated with disconnection of a first external electronic device, and a processor operatively connected to the first interface, the second interface, and the input device. The processor may be configured to receive power from the first external electronic device through the first interface in a state where the first external electronic device is connected to the first interface and a second external electronic device is connected to the second interface, and to receive power from the second external electronic device through the second interface when receiving the specified signal generated by the input device. Other various embodiments as understood from the specification are also possible.

A connector (10) according to the present disclosure includes an insulator (20) including an insertion space portion (21) into and from which a cable (70) including a to-be-locked portion (74) can be inserted and removed, an actuator (50) including a locking portion (51) and supported by the insulator (20) rotatably about a rotation axis (C) between a lock position at which the to-be-locked portion (74) and the locking portion (51) engage with each other when the cable (70) is in an inserted state and an insertion/removal position at which the cable (70) can be inserted into and removed from the insertion space portion (21), and a biasing member (60) supported by the insulator (20) and including an abutting portion (64) that abuts on the actuator (50), the biasing member (60) applying a force to bias the actuator (50) toward the lock position through the abutting portion (64), wherein the locking portion (51), the abutting portion (64), and the rotation axis (C) are positioned apart from one another in an insertion/removal direction in which the cable (70) is inserted into and removed from the insertion space portion (21).

A high-current electrical connector (1) is codable for use with a certain mating electrical connector and flexibly and comfortably adaptable to the conditions of a tight installation space in which the high-current electrical connector is used. The insulating body (14) of the high-current electrical connector is retained on the pin contact (11) such that said insulating body can be rotated about the pin axis (S). Thus, the mating electrical connector (4) connected thereto, coded therefor and aligned therewith can be rotatably retained such that the angled cable outlet (42) of the mating electrical connector can be flexibly oriented within the installation space as required.

A support base includes a connector hub having a top end, a bottom end spaced apart from the top end, and a chamber wall extending between the top and bottom ends. The chamber wall defines a chamber within the connector hub. A power interface set may be positioned in the chamber. The power interface set is dimensioned such that an annular support gap is formed between the power interface set and the chamber wall. A cover plate may be coupled to the top end of the connector hub.

It is aimed to reduce connection resistance between a female housing and a male housing without causing the settling of a resilient contact piece of a female terminal fitting. A female connector (F) includes a female housing (10) configured to accommodate female terminal fittings (20) and to be connected to a male housing (50), and a movable portion (31) displaceable between a terminal deforming position where resilient contact pieces (25) are resiliently deformed away from male terminal fittings (60) and a releasing position where the movable portion is disengaged from the resilient contact pieces (25). As the connection of the female housing (10) and the male housing (50) proceeds, a retainer-side slide-contact portion (32) slides in contact with male-side slide-contact portions (55) and the movable portion (31) is displaced from the releasing position to the terminal deforming position.

A connector 10 includes a housing 20 and CPA 30 that assures the state of complete mating between the connector 10 and a mating connector. The housing 20 includes a CPA retention portion 23 that retains the CPA 30. A sliding surface 61, on which the CPA 30 slides, and side walls 62, disposed upright on both the right and left sides of the sliding surface 61, are disposed on the CPA retention portion 23. In the right and left side walls 62, through-holes 63 are opened alternately with respect to a slide direction. The connector, which includes the CPA, includes a housing having a low profile.

The present disclosure discloses a strap connector. The strap connector includes an insulating body having a tongue plate, a number of conductive terminals and a strap unlocking device installed on the insulating body. The strap unlocking device includes a locking piece for locking with a mating connector and a pull strap connected to the locking piece. The strap connector further includes a guide rail piece arranged separately from the locking piece and installed on the insulating body. A part of the pull strap is located between the guide rail piece and the insulating body. As a result, the structure of the strap unlocking device is simplified, and it is convenient to install the strap unlocking device on the insulating body.