Latch assemblies and systems are disclosed. One latch includes a latch and a receiver. The latch has a housing and a pin extending from the housing. The pin is mounted for longitudinal movement along a pin axis. The latch further includes a motor coupled to move the pin longitudinally. The receiver defines an aperture extending along a receiver axis and positioned to receive the pin of the latch. The receiver has a retainer biased toward the receiver axis. The latch assembly has an open position in which the pin is extended distally along the pin axis and received in the aperture, and a latched position in which the pin is retracted proximally along the pin axis while the retainer is engaged with the pin. One latch system includes a plurality of latch assemblies configured to move to the latched position after all latch assemblies are in the open position.

A fastening system for attaching two components with a spring force is disclosed. The fastening system utilizes O-rings to provide the spring force, eliminating the need for any metal components. The O-ring may be disposed in an O-ring holder that has a plurality of spokes. When compressed, indentations are created in the O-ring by the spokes. The number of spokes and their size and shape determine the spring force of the fastening system. In another embodiment, vertically oriented O-rings are utilized. The fastening system may be used to fasten various components of an ion source.

A fastening system for attaching two components with a spring force is disclosed. The fastening system utilizes O-rings to provide the spring force, eliminating the need for any metal components. The O-ring may be disposed in an O-ring holder that has a plurality of spokes. When compressed, indentations are created in the O-ring by the spokes. The number of spokes and their size and shape determine the spring force of the fastening system. In another embodiment, vertically oriented O-rings are utilized. The fastening system may be used to fasten various components of an ion source.

Latches are disclosed. One latch includes a housing, a cap, a bushing, and a ball. The housing is configured for engagement to the panel. The housing has a longitudinal axis and defines an aperture along the longitudinal axis. The aperture includes a cutout area. The cap and the bushing are mounted within the aperture for rotation about the longitudinal axis. The cap comprises an outer surface including a drive projection and a cutout area. The bushing comprises an upper surface and a sidewall positioned between the cap and the housing. The sidewall defines a drive surface positioned to contact the drive projection of the cap and an opening. The ball is positioned within the opening of the bushing. The ball is configured to be positioned at least partially within the cutout area of the housing or the cutout area of the cap.

Latches are disclosed. One latch includes a housing, a cap, a bushing, and a ball. The housing is configured for engagement to the panel. The housing has a longitudinal axis and defines an aperture along the longitudinal axis. The aperture includes a cutout area. The cap and the bushing are mounted within the aperture for rotation about the longitudinal axis. The cap comprises an outer surface including a drive projection and a cutout area. The bushing comprises an upper surface and a sidewall positioned between the cap and the housing. The sidewall defines a drive surface positioned to contact the drive projection of the cap and an opening. The ball is positioned within the opening of the bushing. The ball is configured to be positioned at least partially within the cutout area of the housing or the cutout area of the cap.

A locking mechanism for applying in a computer case is disclosed. The locking mechanism comprises: an actuating unit and a locking member. The actuating unit is pivotally connected to one of two vertically-disposed side plates of the computer case by one end thereof, and comprises a pivot member and a latching member. In the present invention, the actuating unit rotates along a first direction parallel to the vertically-disposed side plate, so as to decrease space required by operating the locking mechanism. Such that the locking mechanism brought advantages of great space-saving, high capacity and low cost of production cost.

A locking mechanism for applying in a computer case is disclosed. The locking mechanism comprises: an actuating unit and a locking member. The actuating unit is pivotally connected to one of two vertically-disposed side plates of the computer case by one end thereof, and comprises a pivot member and a latching member. In the present invention, the actuating unit rotates along a first direction parallel to the vertically-disposed side plate, so as to decrease space required by operating the locking mechanism. Such that the locking mechanism brought advantages of great space-saving, high capacity and low cost of production cost.

Provided is a door latch including a latch mechanism, secured to an appliance such as a self-cleaning oven, which locks an appliance door to the appliance. The latch mechanism includes a latch bracket mounted to a surface of the appliance. A latch hook is mounted within the latch bracket for reciprocal movement between locking and unlocking positions. The latch hook pivotally engages a receptacle mounted on the door, to lock the door to the appliance. A flexible cable is retained inside a flexible conduit. A first end of the flexible cable is connected to the latch hook for displacing the latch hook into the locking position for pivotal engagement with the receptacle. An electric actuator is connected to a second end of the flexible cable for producing operative movement of the flexible cable within the flexible conduit to displace the latch hook between the locking and unlocking positions.

A latch assembly is provided that includes a latch arm having a rotational axis and an engagement surface on a distal end of the latch arm a length from the rotational axis. The engagement surface is stowed in a stowed state of the latch arm. The latch arm is configured to receive a pushing force to depress the latch arm a predetermined distance along the rotational axis. The latch assembly also includes a turret assembly having a top end with the latch arm mounted thereon. The turret assembly is configured to, in response to the pushing force being applied to the latch arm, raise and rotate the latch arm about the rotational axis to thereby transition the latch arm from the stowed state to a deployed state in which the engagement surface is exposed.

A latch assembly is provided that includes a latch arm having a rotational axis and an engagement surface on a distal end of the latch arm a length from the rotational axis. The engagement surface is stowed in a stowed state of the latch arm. The latch arm is configured to receive a pushing force to depress the latch arm a predetermined distance along the rotational axis. The latch assembly also includes a turret assembly having a top end with the latch arm mounted thereon. The turret assembly is configured to, in response to the pushing force being applied to the latch arm, raise and rotate the latch arm about the rotational axis to thereby transition the latch arm from the stowed state to a deployed state in which the engagement surface is exposed.