A back-and-forth movement device includes a guiding section that regulates an operation between a case-side member and a forward/backward member, and a guided section to be guided by the guiding section. In the back-and-forth movement device, a case partly includes a proximate wall portion that is in proximity to the forward/backward member, the guiding section is provided on a side opposite to the forward/backward member with respect to the proximate wall portion, and an engaging section of a restriction member and an extending portion of the guided section extend substantially parallel to each other on the side opposite to the forward/backward member with respect to the proximate wall portion.

An activation device for at least two spatially separated motor vehicle closure units, for example for a tailgate latch on the one hand and a fuel filler door latch on the other hand. The activation device possesses a linear drive with a linear actuator. Dependent on its activation direction, the linear drive impinges either the first motor vehicle closure unit or the other second motor vehicle closure unit. According to the invention, dependent on its actuating direction, the linear actuator impinges at least a pivotable activation lever to interact with either the first motor vehicle closure unit or the other second motor vehicle closure unit.

An activation device for at least two spatially separated motor vehicle closure units, for example for a tailgate latch on the one hand and a fuel filler door latch on the other hand. The activation device possesses a linear drive with a linear actuator. Dependent on its activation direction, the linear drive impinges either the first motor vehicle closure unit or the other second motor vehicle closure unit. According to the invention, dependent on its actuating direction, the linear actuator impinges at least a pivotable activation lever to interact with either the first motor vehicle closure unit or the other second motor vehicle closure unit.

A linear reciprocating-motion apparatus includes at least one movable member (10, 30) supported by a housing (90) and being capable of undergoing linear reciprocating motion in a range that includes a first position, a second position, and a third position; a stopper (50) supported by the housing to be displaceable between a blocking position that blocks the at least one movable member and a nonblocking position that does not block the at least one movable member, and is displaced to the nonblocking position in response to a specific operation; an intermittent mechanism (100, 200) that interacts with movement of the at least one movable member and assumes a specific state once every two times that the at least one movable member moves to the third position; and a switch (SW1) that, in response to the specific state, is switched from a disconnected state or a connected state to the other thereof.

A linear reciprocating-motion apparatus includes at least one movable member (10, 30) supported by a housing (90) and being capable of undergoing linear reciprocating motion in a range that includes a first position, a second position, and a third position; a stopper (50) supported by the housing to be displaceable between a blocking position that blocks the at least one movable member and a nonblocking position that does not block the at least one movable member, and is displaced to the nonblocking position in response to a specific operation; an intermittent mechanism (100, 200) that interacts with movement of the at least one movable member and assumes a specific state once every two times that the at least one movable member moves to the third position; and a switch (SW1) that, in response to the specific state, is switched from a disconnected state or a connected state to the other thereof.

To improve the operability of the pushrod, in the lid opening and closing device, the sleeve supports the pushrod, and the cam protrusion of the pushrod is inserted into the cam hole of the sleeve so as to be relatively movable. When the pushrod reciprocates in the axial direction, the cam hole guides the cam protrusion, and the pushrod rotates. The sleeve has a small-diameter tubular portion, a large-diameter tubular portion, and a connecting portion that connects them. These two tubular portions are separated in the axial direction, and the cam hole is arranged between them. That is, the sleeve is composed of a single member. Thus, compared with the case where the sleeve is composed of two members, small-diameter and large-diameter tubular portion, that are assembled to the case, it is possible to suppress the displacement of both end faces in the width direction of the cam hole.

To improve the operability of the pushrod, in the lid opening and closing device, the sleeve supports the pushrod, and the cam protrusion of the pushrod is inserted into the cam hole of the sleeve so as to be relatively movable. When the pushrod reciprocates in the axial direction, the cam hole guides the cam protrusion, and the pushrod rotates. The sleeve has a small-diameter tubular portion, a large-diameter tubular portion, and a connecting portion that connects them. These two tubular portions are separated in the axial direction, and the cam hole is arranged between them. That is, the sleeve is composed of a single member. Thus, compared with the case where the sleeve is composed of two members, small-diameter and large-diameter tubular portion, that are assembled to the case, it is possible to suppress the displacement of both end faces in the width direction of the cam hole.

This disclosure relates to a fuel or charging port door assembly of a motor vehicle. In particular, this disclosure relates to a fuel or charging port door assembly configured to permit a door to open when an override force is applied using an assist tool, for example. An example vehicle includes a door configured to move relative to a body of the vehicle between open and closed positions. The door is a fuel door or a charging port door. The vehicle also includes a lock assembly including a base and a tip. The base is configured to hold the tip during normal operating conditions, and the base and tip are configured to separate upon application of an override force to the door.

This disclosure relates to a fuel or charging port door assembly of a motor vehicle. In particular, this disclosure relates to a fuel or charging port door assembly configured to permit a door to open when an override force is applied using an assist tool, for example. An example vehicle includes a door configured to move relative to a body of the vehicle between open and closed positions. The door is a fuel door or a charging port door. The vehicle also includes a lock assembly including a base and a tip. The base is configured to hold the tip during normal operating conditions, and the base and tip are configured to separate upon application of an override force to the door.

This disclosure describes manual release systems for electrified vehicle charge port locks. In some embodiments, a vehicle key may be used to manually override a position of the charge port lock. In other embodiments, a pull button and cable arrangement may be used to manually override the position of the charge port lock. The pull button may be packaged under a vehicle hood and, in some embodiments, may be mounted to either a cooling system component or a grille support structure.