A charging plug includes a housing, two charging pins, and an elastic piece. The housing includes a main body portion having an arrangement surface and a protruding portion. The protruding portion is connected to the main body portion and located on the arrangement surface. The protrusion portion has an upper surface, a first side surface and a second side surface opposite each other and connecting to the upper surface. The charging pins are disposed in the housing and extend out of the protrusion portion. The elastic piece is disposed on the protruding portion of the housing and located between the charging pins. The elastic piece covers the first side surface, the upper surface and the second side surface and has at least one positioning portion, and the positioning portion is adapted to be engaged with at least one slot of a casing.

A connector that is difficult to be released from a state fitted to a mating connector when an unexpected external force acts on the connector, and is removed from the mating connector with a small operating force when intentionally releasing the fitted state. An unlocking member of the connector for releasing this connector from the fitted state includes a releasing portion for releasing an elastic locking portion of the mating connector from a state caught by a catching portion of a connector body fitted to the mating connector, and a sliding portion for sliding on the connector body. The connector body includes a supporting portion for slidably supporting the sliding portion. A guide surface is formed on the supporting portion for guiding the sliding portion such that the releasing portion is displaced toward the elastic locking portion, to thereby release the caught state.

An actuator capable of enhancing versatility is provided. The actuator prevents a charging connector from coming off a power receiving connector, and includes: a hollow housing; and a driving mechanism that is housed in the housing. The driving mechanism includes: an electric motor; a cam member that is driven by the electric motor; and a lock pin that interlocks with the cam member and moves from an initial position to a restricting position where the charging connector is prevented from coming off. A rotation axis of the cam member is arranged substantially perpendicular to a reference plane defined by a line segment running in the direction of plugging the charging connector and a line segment extending from the housing toward the power receiving connector.

An electrical connector comprises a housing, an electrical connection assembly received in the housing, and a locking mechanism mounted on an outer surface of the housing and configured to releasably lock the electrical connector and a mating electrical connector together. The locking mechanism includes a handle, a locking member adapted to be engaged with a locking structure on the mating electrical connector, the locking member connected to the handle such that the mating electrical connector is unlocked when the handle is pulled, and a fixing member mounted on the outer surface of the housing and adapted to position the locking member and the handle between the fixing member and the housing.

The present invention relates to an electrical connector comprising a first connector portion, a second connector portion and a locking mechanism, wherein the first connector portion has a first electrical contact element and at least one magnet, and wherein the second connector portion has a second electrical contact element and at least one second magnet with a polarity which is reversed in relation to the first magnet, wherein the first and the second contact element are designed to establish an electrical connection between the first and the second connector portion for power and/or data transmission, and wherein the locking mechanism is of self-locking design.

A connector includes a body and a contact that is inserted into the body. The contact includes a protruding part that is protruded in a direction orthogonal to an insertion direction of the contact, a protrusion that is provided on an outer periphery of the contact, and an overhanging part that overhangs in the direction orthogonal to the insertion direction. The body includes, on an inner surface thereof, a guide groove that is fitted with the protruding part and is extended in the insertion direction, a housing part that has an internal dimension for press-fitting the contact, which includes the protrusion, thereto, and a press-fitting part that has an internal dimension for press-fitting the contact, which includes the overhanging part, thereto. An insertion distance A of the protruding part, an insertion distance B of the protrusion, and an insertion distance C of the overhanging part satisfy a relation A>B>C.

A connector includes a body and a contact that is inserted into the body. The contact includes a protruding part that is protruded in a direction orthogonal to an insertion direction of the contact, a protrusion that is provided on an outer periphery of the contact, and an overhanging part that overhangs in the direction orthogonal to the insertion direction. The body includes, on an inner surface thereof, a guide groove that is fitted with the protruding part and is extended in the insertion direction, a housing part that has an internal dimension for press-fitting the contact, which includes the protrusion, thereto, and a press-fitting part that has an internal dimension for press-fitting the contact, which includes the overhanging part, thereto. An insertion distance A of the protruding part, an insertion distance B of the protrusion, and an insertion distance C of the overhanging part satisfy a relation A>B>C.

The present invention discloses a connector for flat conducting wires that is directed into the insertion opening, the front end comes in contact with the first locking protrusion and the second locking protrusion of the connector, respectively causing the first elastic arm and the second elastic arm to deform, thereby causing the first operating part and the second operating part to move towards the third surface until the indented notches correspond to the first locking protrusion and the second locking protrusion, which subsequently causes the first elastic arm and the second elastic arm to return to their former position by means of elastic force, latch-locking the front end of the flat conducting wire in the accommodating space, and through exerting an external force on the upper portion of the first operating part and the upper portion of the second operating part to unlatch and separate from the accommodating space.

An electrical connector comprises an insulative module loaded with terminals therein and a mounting member. The insulative module defines a pair of panel-supporting surface at each opposite end thereof, and a cavity going through one panel-supporting face. The mounting member comprises a board main receiving in the cavity and an operating portion projecting outwards. The insulative module defines a pair of elastic arms slanting into the cavity and each slates away from the panel-supporting face. The board main defines a pair of locking recesses at opposite edges thereof. The elastic arms are locked with the locking recesses in condition that the mounting member slides upwards beyond the panel-supporting faces.

An electrical data connector comprises a plug that is configured for insertion in a longitudinal direction into a complementary receptacle. The plug includes a connector element that is configured to be received within the receptacle and carries a plurality of electrical connectors, a body that is located externally of the receptacle when the connector element is inserted into the receptacle, and a releasable locking mechanism for locking the plug positively to the receptacle to prevent unintentional removal of the plug from the receptacle. The locking mechanism includes a locking element carried by the connector that is configured for movement between a locked configuration in which it protrudes from the connector element and an unlocked configuration in which it does not protrude substantially from the connector element, a locking control, provided on the body, for manually actuating the locking mechanism, and a drive mechanism that connects the locking control to the locking element, whereby operation of the locking control actuates the locking element. The drive mechanism includes at least one longitudinal sliding element that is connected to the locking control and at least one transverse sliding element that is connected to the locking element, wherein said longitudinal and transverse sliding elements are located in a common plane and are configured such that longitudinal movement of the longitudinal sliding element drives transverse movement of the transverse sliding element, thereby actuating the locking element.