A connector for sealably engaging contacts therein and permitting reliable disengagement thereof includes a first unit having one or more elongated shafts. Each elongated shaft includes at least one first contact. The connector further includes a second unit having a body with one or more channels therein. Each channel includes at least one second contact. Each channel is configured to receive at least a portion of one of the elongated shafts therein to permit electrical connection of the one or more first contacts to the respective one or more second contacts. The second unit further includes an axial slit extending radially outwardly from each channel toward an outer surface of the body of the second unit. Each slit of the second unit is a circumferentially discontinuous portion of the channel configured to prevent the second unit from forming a constrictive belt around the one or more elongated shafts therein.

An operating member (11) is displaceable to an assembled position, an initial position and a connection position with respect to a housing (10) and proceeds with a connecting operation of the housing and a mating housing (12) by cam engagement with the mating housing (12) when being displaced from the initial position to the connection position. The housing (10) includes resilient locks (25, 26) configured to restrict a displacement of the operating member (11) in a direction opposite to that from the assembled position toward the initial position by resiliently locking the operating member (11) at the assembled position and restrict a displacement of the operating member (11) in a return direction from the initial position to the assembled position by resiliently locking the operating member (11) at the initial position.

An electrical connector assembly for mating with a mating connector assembly. The connector assembly includes a housing with a cable receiving portion and a mating portion. The housing has a first surface and an oppositely facing second surface. The mating portion has a mating projection which extends from the first surface in a direction away from the second surface. The mating projection has a circular cross-sectional configuration. The mating projection has an angled wall which extends from the first surface to a mating face, the angled wall is angled relative to a plane of the first surface and a plane of the mating face. The mating face has contacts which extend therethrough. The contacts has circular engagement sections arranged concentrically about a center of the mating face. A nonconductive coating applied to the angled wall.

An electrical connector includes: a metallic cover; an insulative frame molded inside the metallic cover; a metal injection molded (MIM) support and a contact module received by the MIM support, the contact module having a rear base, a front tongue, and an upper and a lower rows of contacts extending through the base and exposing to two opposite faces of the tongue, the MIM support having a pair of side arms flanking the two rows of contacts; and an insulator molded outside the MIM support and the contact module and secured to the insulative frame.

A sealable FFC connector includes a housing, a plurality of contacts, a sealing member, and an actuator. The housing includes a slot configured to receive a mating component. The contacts are held in the housing and are configured to be in electrical contact with the mating component when the mating component is in a mated position in the slot. The sealing member includes at least a portion supported by the housing. The actuator is coupled to the housing and is movable from an opened position, in which the mating component may be inserted in the slot, to a closed position, in which a biasing force is applied on the sealing member such that, when the mating component is in the mated position in the slot, the sealing member provides a seal to prevent moisture and debris from entering the slot.

A power transfer system includes a port panel assembly including a port panel, a locating pocket formed in the port panel, locking ports arranged in the locating pocket, and terminal assemblies attached to a rear side of the locating pocket and having conductive terminals, and a power transfer assembly having a transfer housing with access ports and terminal retainers, latches housed in the transfer housing to engage the locking ports, a spring arranged between the latches and pressing the latches to protrude outwardly from the transfer housing through the access ports, and connection members arranged in the terminal retainer and adapted be connected to an electric device. When the power transfer assembly is inserted into the port panel assembly, tip portions of the latches are inserted into the locking ports to be secured to the port panel assembly, and the connection members contact the conductive terminals of the port panel.

Disclosed is a motor bracket of a multicopter flying robot. The motor bracket for the multicopter flying robot disclosed in the present invention includes: a body 110 receiving a rotary motor 500 therein which is used in the multicopter flying robot, a connection portion 120 which is formed on the outer surface of the body and receives two power supply lines 510 and 520 connected to a power terminal of the rotary motor 500, and a power supply member 300 which is pushed into the connection portion 120 and electrically contacts the at least two power supply lines 510 and 520. The connection portion 120 includes a spatial separation portion 122 which performs a function of forming separated spaces of which the number is the same as the number of the at least two power supply lines 510 and 520.

Disclosed is a motor bracket of a multicopter flying robot. The motor bracket for the multicopter flying robot disclosed in the present invention includes: a body 110 receiving a rotary motor 500 therein which is used in the multicopter flying robot, a connection portion 120 which is formed on the outer surface of the body and receives two power supply lines 510 and 520 connected to a power terminal of the rotary motor 500, and a power supply member 300 which is pushed into the connection portion 120 and electrically contacts the at least two power supply lines 510 and 520. The connection portion 120 includes a spatial separation portion 122 which performs a function of forming separated spaces of which the number is the same as the number of the at least two power supply lines 510 and 520.

A connector includes a first housing and a second housing having facing surfaces facing each other. One of the first and second housings includes a receiving portion open forward in a front end part and the other includes a rotating portion to be arranged in the receiving portion in the front end part. The second housing is rotated with respect to the first housing about an axis passing through the rotating portion in the receiving portion along a width direction and is coupled to the first housing. The first housing includes a lock receiving portion open forward and rearward in the front end part. The second housing includes a locking portion projecting toward the first housing and to be fit to the lock receiving portion in the front end part. The locking portion includes a wide restricting portion, and the lock receiving portion includes a wide restriction receiving portion.

A sensor arrangement and cable for use in process automation, including a sensor having at least one sensor element for recording a value in process automation, a first interface for transmitting a measured value depending on the measured value to a second interface, the first interface including a first mechanical, and a cable for transmitting the value to a superordinate unit, the cable including said second interface, which is complementary to the first interface, and a second mechanical coupling complementary to the first mechanical coupling, wherein the second interface and mechanical coupling are arranged in a cable housing, wherein the sensor is detachably connectible to the cable by the first mechanical coupling and the second mechanical coupling, characterized in that the second mechanical coupling is arranged at an angle less than 180° to the longitudinal axis of the cable housing.