An actuator includes a piston assembly movably disposed within an assembly housing having a fixedly supported end and an opposing end that receives a movable piston assembly. The piston assembly includes a piston rod and an attached piston head having a fixed orifice as well as an orifice with a check valve to create rate control of the assembly. Hydraulic fluid is caused to move through the axially movable piston head based on compressive and tensile loads imparted to the assembly. A plurality of pre-loaded springs are configured to selectively provide pressure relief in the event the orifices of the piston become clogged, wherein the plurality of pre-loaded springs, such as disc springs, further provide an energy absorbing function of the assembly based on loading conditions.

A retraction device, in particular for pull-out guides, has a housing, in which a guide for a linearly movable slider and a guide track for a driver attached to the slider are provided. The driver can be coupled with an activator and a damper comprising a damper housing and a piston rod is provided between the housing and the slider. There is a pull-out guide with a stationary guide rail and a running rail which is movable relative to the guide rail.

A closure mechanism is described, the closure mechanism comprising: a base; a carriage movable along the base; a catching mechanism movable along the carriage; a first resilient mechanism connecting the base and the catching mechanism; and a second resilient mechanism connecting the carriage and the catching mechanism.

A sliding door system includes a door frame and a sliding door leaf that can move relative thereto. A catch is arranged either on the door frame or on the sliding door leaf, which can be coupled to a drive element of a feed device arranged on the respective other component. The feed device has a spring energy store and a cylinder-piston unit. The cylinder-piston unit has a piston that separates a displacement chamber from a compensation chamber. A passage cross-section between the displacement chamber and the compensation chamber can be changed in a load-dependent manner by a piston disk that can be applied at a piston end side. The tension force of the tension spring of a minimal effective length is between 1.5 and 3.5 times the total static friction force of the sliding door leaf and the resistance of the cylinder-piston unit at the maximum passage cross-section.

A device is provided for controlling the motion of a movable member such as a sliding door. The device comprises two springs (10, 11). Each spring has its own catch (19, 22) for releasably holding it in a pre-loaded condition. The catches are releasable by motion of the door to apply force to its closing movement. The catches are arranged so that one of the springs will exert force on the door before the other.

A door system includes a door having a housing mounted in the bottom edge of the door that retains a bottom seal and a second channel for receiving a guide. A seal is formed adjacent the periphery of the door between the door and a door opening in a structure when the door is in the closed position. The seal includes deformable gaskets that extend between the structure and the door to form a seal around the door opening. A first soft close device is mounted adjacent the open positon and a second soft close device is mounted adjacent the closed position. A single activator pin is mounted on the door and positioned such that the activator pin engages the first soft close device as the door nears the open positon and engages the second soft close device as the door nears the closed position.

A guide system is hingedly connected to a second furniture part, and has a rail arrangement including a guide rail having a longitudinal direction for guiding the furniture parts, and a carrier movably mounted transversely to the longitudinal direction of the guide rail. The carrier can be moved into a transfer position in which the carrier adjoins the guide rail in the longitudinal direction such that a guiding device to be connected to one of the furniture parts and movable along the guide rail can be transferred to and from between the guide rail and the carrier. The guide system includes a column connected to the carrier, the column being arranged vertically, and can be moved together with the carrier transversely to the longitudinal direction of the guide rail. The first furniture part is connected to the guiding device, and the second furniture part is movably connected to the column.

The present invention relates to a refrigerator having a structure of a receptacle apparatus, which enables efficient utilization of a space for storing an object to be refrigerated or an object to be frozen, and a door or a cover which is for opening or closing the receptacle apparatus. Provided is a refrigerator, according to an embodiment of the present invention, comprising: a first storage chamber provided above a cabinet; a second storage chamber positioned below the first storage chamber; a partition wall which is for partitioning the first storage chamber and second storage chamber vertically and of which the upper surface maintains a level position; an accommodation unit recessed downward from the upper side of the partition wall, forming a receptacle space and having an input port, into which an object to be stored is input, formed on the upper part thereof; an accommodation unit door provided so as to be movable in the direction parallel to the upper side of the partition wall and for selectively opening or closing the input port; and a position fixing unit provided on the rear of the accommodation unit door and for restraining the movement of the door when the accommodation unit door moves backward and opens the input port.

The invention relates to a furniture hinge (10) with a hinge arm (20) and a fastening portion (30), wherein the hinge arm (20) and the fastening portion (30) are pivotably connected to one another via a multi-axis articulated connection (40), and wherein a damping element (60), which damps in a deflection direction, for damping the movement of the hinge arm (20) and a spring (76) for adjusting the hinge arm (20) with respect to the fastening portion (30) are provided. It is provided here that the damping element (60) is mounted in such a way that, during a folding movement of the hinge arm (20) from a first end position into a second end position, a maximum or a minimum deflection of the damping element (60) is carried out within an adjusting movement of the damping element (60) caused by said folding movement. As a result, a furniture hinge which can be produced cost-effectively and which allows damped opening and closing of the hinge arm is provided.

Provided is a sliding door device which can move a support shaft attached to a sliding door along an inclined portion of a rail by using a pull-in device. The rail (6a) is provided with the straight portion (11) for linearly guiding the support shaft attached to the sliding door (2) and the inclined portion (12) which is inclined with respect to the straight portion (11) and obliquely guides the support shaft. The straight portion (11) of the rail (6a) is provided with the pull-in device (15) which can capture a trigger (18) provided on the straight portion (11) of the rail (6a) and linearly move along the straight portion (11) of the rail (6a) when the sliding door (2) is closed. A pull-in force transmission part (20) for moving the support shaft along the inclined portion (12) of the rail (6a) is coupled to the pull-in device (15).