A slide rail assembly includes a first rail, a second rail, a third rail, a synchronization member and a fastening member. The third rail is movably mounted between the first and second rails. The synchronization member and the fastening member are movably mounted to the third rail. The synchronization member is configured to engage with the second rail, such that the second and third rails can be synchronously moved relative to the first rail along an opening direction. When the second and third rails are moved to a first predetermined position, the synchronization member is disengaged from the second rail. When the third rail is moved from the first predetermined position to a second predetermined position along the opening direction, the third rail is fastened to the first rail by the fastening member to prevent the third rail from being moved relative to the first rail along a retracted direction.

A slide rail assembly includes a rail, a moving rail, and a damping device. When the moving rail is moved relative to the rail, the damping device is pushed by the moving rail to provide damping effect.

An access station, which is for presentation of a storage container from an automated storage and retrieval system to an operator at the access station, includes an access module, a drawer, and a first actuator. The access module includes a frame defining a drawer compartment provided within the frame and a front opening for allowing presentation of the storage container. The drawer includes a drawer base and a drawer front. The drawer is movably connected to the frame. The drawer base includes a support on which the storage container can be supported. The first actuator is for moving the drawer relative to the frame between a presentation position in which the drawer is protruding through the front opening of the frame and a retracted position in which the drawer is retracted within the drawer compartment. The access station includes a safety mechanism located above the front opening. The safety mechanism includes a cover, a safety plate, and a safety sensor. The cover is secured to the frame. The safety plate is movable relative to the cover between a non-activated position and an activated position. The safety sensor is for sensing the movement of the safety plate. The access station is configured to allow movement of the drawer relative to the frame when the safety sensor is sensing that the safety plate is in its non-activated position. The access station is configured to stop or reverse the movement of the drawer relative to the frame when the safety sensor has sensed that the safety plate is in its activated position.

The invention relates to an inclined shelf case having a shelf body having at least one inclined shelf which drops away to the take-out side and has an abutting element holding a placed object on the bottom end thereof, wherein the at least one inclined shelf is held to the shelf body via guide rails and is designed as a pull-out running on the guide rails which can be pulled out to the take-out side and having a spring device for decelerating the inclined shelf during the pull-out, which operates between the shelf body and the inclined shelf. According to the invention the spring device has a connection element which has a first connection section, which is connected to the shelf body in an operating position by means of a holder , and which has a second connection section, and the inclined shelf has a fastening holder to which the connection element is fastened via the second connection section in an assembly position, wherein, upon pushing in the inclined shelf with the connection element in the assembly position, the first connection section engages on the holder and wherein the second connection section is removable from the fastening holder.

In an embodiment, an apparatus (e.g., for damping a motion of a drawer in a storage system) comprises a plate to pivotally attach to a first wall of a drawer, the plate comprising a pivot point about which the plate can pivot; a damped gear coupled to the plate, the damped gear having a plurality of gear teeth; and a spring to facilitate pivoting the plate about the pivot point to engage at least one of the plurality of gear teeth with at least one tooth on a rack. In some embodiments, the spring is to pivot the plate from a first configuration to an angular position relative the wall in a second configuration, wherein the at least one of the plurality of gear teeth and the at least one tooth on the rack are fully engaged with one another in both the first configuration and the second configuration.

In an embodiment, an apparatus (e.g., for damping a motion of a drawer in a storage system) comprises a plate to pivotally attach to a first wall of a drawer, the plate comprising a pivot point about which the plate can pivot; a damped gear coupled to the plate, the damped gear having a plurality of gear teeth; and a spring to facilitate pivoting the plate about the pivot point to engage at least one of the plurality of gear teeth with at least one tooth on a rack. In some embodiments, the spring is to pivot the plate from a first configuration to an angular position relative the wall in a second configuration, wherein the at least one of the plurality of gear teeth and the at least one tooth on the rack are fully engaged with one another in both the first configuration and the second configuration.

A release mechanism for a drawer slide latch may include linearly translatable elements. The linearly translatable elements may cause rotation of a lever arm used in latching one drawer slide member to another. The linearly translatable elements may be coupled to a drawer, or be a component mounted to the drawer slide, in various embodiments.

A release mechanism for a drawer slide latch may include linearly translatable elements. The linearly translatable elements may cause rotation of a lever arm used in latching one drawer slide member to another. The linearly translatable elements may be coupled to a drawer, or be a component mounted to the drawer slide, in various embodiments.

The invention relates to an inclined shelf case having a shelf body having at least one inclined shelf which drops away to the take-out side and has an abutting element holding a placed object on the bottom end thereof, wherein the at least one inclined shelf is held to the shelf body via guide rails and is designed as a pull-out running on the guide rails which can be pulled out to the take-out side and having a spring device for decelerating the inclined shelf during the pull-out, which operates between the shelf body and the inclined shelf. According to the invention the spring device has a connection element which has a first connection section, which is connected to the shelf body in an operating position by means of a holder, and which has a second connection section, and the inclined shelf has a fastening holder to which the connection element is fastened via the second connection section in an assembly position, wherein, upon pushing in the inclined shelf with the connection element in the assembly position, the first connection section engages on the holder and wherein the second connection section is removable from the fastening holder.

An anti-pinch device includes a first body and a second body, the first body is fitted to an inner surface of a movable part to be protected (e.g., an inner surface of a drawer) via a fixing surface, and the second body is limited and retained in a first position to abut against the body to be protected (e.g., a cabinet body) via an abutting surface; and when the second body is displaced to a second position, the abutting between the second body and the body to be protected is released, allowing the movable part to be protected to be displaced and closed.