An assembly for attaching and detaching an electronics module from a base includes a feedback assembly that provides an operator with tactile feedback on the relative positioning of the module with the base during attachment or detachment of the module to or from the base. The feedback assembly includes cams on the electronics module and a follower attached to an end of a spring arm on the base. The spring arm forms a portion of a wall that guides movement of the module along the base during attachment or detachment of the module.

A connector includes an inner shell, an outer shell, and a gear wheel, wherein the gear wheel is arranged in a rack-and-pinion configuration with a first linear gear, the gear wheel being hinged on the inner shell rotatably with respect to a hinge axis orthogonal to the mating direction. The gear wheel comprises a first set of external gear teeth configured to engage with the first linear gear in the rack-and-pinion configuration, and a second set of external gear teeth configured to engage with a second linear gear of a mating connector, wherein the first set and the second set of external gear teeth are arranged in a same plane. The invention further relates to a connector system comprising the connector.

A connector includes a first connector and a second connector. The first connector includes a pair of housings and a lever that slidably joins the pair of housings relative to each other. The second connector engages with the first connector by sliding relative to the first connector in an axial direction. The pair of housings includes a supporting portion, temporary locking portions, and a guiding portion. The supporting portion is provided on one of the pair of housings and rotatably supports the lever. The temporary locking portions restrict rotation of the lever. A projection is inserted into the guiding portion. The second connector includes an abutting portion abutting on the lever. In a state where the locking of the temporary locking portion is released, the lever converts a force transmitted from the guiding portion to the projection into a reverse force and transmits the converted force to the abutting portion.

A connector includes a first-housing, a second-housing, a shroud, and a stacked-gear. The first-housing defines a guide-slot. The second-housing mates with the first-housing. The second-housing includes a linear-gear-rack extending from a second-outer-surface and engages the guide-slot. The shroud is moveable from an unmated-position to a mated-position. The shroud is longitudinally slideably mounted to and surrounding at least a portion of the first-housing. The shroud also includes a curved-gear-rack having a variable-pitch-radius. The stacked-gear is moveably mounted to the first-housing. The stacked-gear has a round-gear and a cam-gear having the variable-pitch-radius in communication with the round-gear. The round-gear engages the linear-gear-rack within the guide-slot. The cam-gear engages the curved-gear-rack such that the cam-gear moves in response to a movement of the shroud from the unmated-position to the mated-position. Rotation of the round-gear engaged with the linear-gear-rack axially pulls the linear-gear-rack into the guide-slot, thereby pulling the second-housing into the first-housing.

A connector includes a first housing, a second housing, a mate assist slider, and a cam gear. The first-housing has a first outer surface. The second housing is configured to mate with the first housing, and the second housing includes a pin extending from a second outer surface. The connector also includes a mate assist slider moveable from an unmated position to a mated position. The connector also includes a cam gear mounted to the first outer surface. The cam gear moves in response to a movement of the mate-assist-slider from the unmated position to the mated position. The cam gear has a cam slot with an inertial detent. A vibratory feedback is provided to an assembler indicative of a properly positioned connector housing when the pin is moved past the inertial detent.

A connector comprises a wire cover and a lever pivotally attached to the wire cover. The wire cover has a cover lock and a cover biasing member. The lever is rotatable between an unmated position and a mated position. When the lever is in the mated position, the cover lock locks the lever in the mated position and the cover biasing member biases the lever toward the unmated position.

A lever-type connector includes a housing having support holes; a fitting part provided inside the housing and fitted in a counterpart connector; a lever that includes a pair of plate-like portions facing each other in an opposed manner, a connection portion connecting the pair of plate-like portions with each other, and projection portions provided respective outside surfaces of the pair of plate-like portions, the lever being rotatably supported by the housing while the projection portions are engaged with the support holes; and sliding members each includes a guide portion that is slidably supported by the housing and engaged with a part to be guided provided to the counterpart connector, the sliding members being slid depending on a rotation of the lever to depress the part to be guided by way of the guide portion and fit the counterpart connector in the fitting part.

A connector includes a first connector and a second connector. The first connector includes a pair of housings and a lever that slidably joins the pair of housings relative to each other. The second connector engages with the first connector by sliding relative to the first connector in an axial direction. The pair of housings includes a supporting portion, temporary locking portions, and a guiding portion. The supporting portion is provided on one of the pair of housings and rotatably supports the lever. The temporary locking portions restrict rotation of the lever. A projection is inserted into the guiding portion. The second connector includes an abutting portion abutting on the lever. In a state where the locking of the temporary locking portion is released, the lever converts a force transmitted from the guiding portion to the projection into a reverse force and transmits the converted force to the abutting portion.

A connector includes a connector housing, a lever that is movable relative to the connector housing along a first axis from a first position to a second position, and a lock member that is movable relative to the connector housing from a third position to a fourth position. The connector housing is configured to approach a state of fit to the counterpart housing as the lever moves from the first position to the second position. The lock member regulates a movement of the lever by making contact with the lever located at the second position in a state in which the lock member is located at the fourth position, and the lock member is covered with a lever in a state in which the lever is located at the first position or is exposed from the lever in a state in which the lever is located at the second position.

A connector according to an aspect of the present disclosure includes a connector housing, a lever that is movable relative to the connector housing along a first axis in a range from a first position to a second position, and a lock member that is movable relative to the connector housing in a range from a third position to a fourth position. The connector housing is configured to approach a state of fit to the counterpart housing as the lever moves from the first position to the second position. The lock member regulates a movement of the lever by making contact with the lever located at the second position in a state in which the lock member is located at the fourth position, the lock member being movable in the range from the third position to the fourth position along a second axis crossing the first axis.