The present invention relates to a hinge mechanism for supporting a compartment door pivotally to a compartment frame and/or a housing of a cabinet or a refrigerator, in particular provided for a recreational vehicle like a motor home or caravan. The hinge mechanism comprises at least two receiving sections and at least two engaging sections. Each of the receiving sections is configured to be coupled to one of the compartment door and the frame respectively the housing. Each of the engaging is configured to be coupled to the other of the compartment door and the frame respectively the housing. Furthermore, the present invention refers to a compartment door assembly with such a hinge mechanism and a cabinet or refrigerator with such a hinge mechanism and/or compartment door assembly. Finally, the present invention also refers to a recreational vehicle provided with at least one of the above devices.

A door operating system for moving a door about a vertical pivot axis between a closed position and an open position. The door operating system includes a driver including a free-ended output shaft and linkage for operably connecting to the output shaft of the driver with door. An adjustable and selectively operable coupling is disposed between the free-end of the output shaft of the driver and the linkage. The adjustable coupling has a pair of coaxially spaced and adjustable interfaces. A first adjustable interface is defined between the free-end of the output shaft and the coupling while a second adjustable interface is defined between the coupling and the linkage whereby allowing for a high resolution, angular adjustment of the position of the door.

Electrically-operated inward-swing double doors and inward-swing door driving devices thereof. Each inward-swing door driving device includes a sector gear in coaxial transmission with a door shaft of the inward-swing door, a driving mechanism used for driving the sector gear to rotate, and an unlocking mechanism. The driving mechanism includes a motor gear and a motor driving the motor gear to rotate.

The unlocking mechanism includes a cylinder, a cylinder push rod extending out of the cylinder, and a lock located at the end portion of the cylinder push rod. The tail end of the lock is in transmission connection with a wheel axle of the motor gear. The lock is provided with a lock rotating shaft for rotating horizontally around the lock. The lock rotating shaft is provided with an elastic element for applying twisting resilience force to the lock.

A clutch mechanism for coupling and uncoupling an electric motor and leadscrew has dog-clutch gears that can be engaged by a linear actuator, bell crank, and linkage shaft. Uncoupling force due to narrowed dog teeth are resisted by the alignment of the linkage shaft with the central portion of the bell crank.

A motorized hinge device (1) has a first connection means (3) assigned to be fixed to a structure or framework of an appliance, and connected, at least by means of a connecting rod means (5), to a second connection means (7) assigned to be fixed to a door of the appliance. This second connection means (7) is hinged to the first connection means (3) by means of a hinge pin means (11). An actuator (13) has a body (15) fixed to the first connection means (3) and a movable member (17) which is movable with respect to the body (15) and is connected to the connecting rod means (5). In an operative condition, the actuator means (13) is operated to move, by means of the connecting rod means (5), the door around the hinge pin means (11) between extreme opening (A) and closing (C) conditions, and vice versa.

The present disclosure illustrates a sectional door driving device including a power assembly, a chassis assembly and a driving assembly. The power assembly includes a motor, a gear set and a control unit, and the power assembly is fastened on a main chassis of the chassis assembly. The driving assembly includes two half-gears respectively in semicircular cylinder shape, and each of the two half-gears has a combination surface which is formed with an engagement assembly, and the two half-gears are engaged by the engagement assemblies thereof to form a circular gear to cover a shaft of a sectional door mechanism. The gear set includes an output gear configured to drive the circular gear and the shaft to rotate. The sectional door driving device can be separated from the shaft easily for repair, and the sectional door driving device can also be installed on the existing sectional door easily.

Example aspects of a sliding door assembly, a sliding door system, and a method for using a sliding door system are disclosed. The sliding door assembly can comprise a track assembly defining a track surface and a slot; and a sliding door comprising a door body and a locking pin, the door body defining a left side and a right side opposite the left side, the locking pin proximate the right side, the locking pin removably engaging the slot, and the door body configured to pivot relative to the track assembly proximate the left side.

A clutch mechanism for coupling and uncoupling an electric motor and leadscrew has dog-clutch gears that can be engaged by a linear actuator, bell crank, and linkage shaft. Uncoupling force due to narrowed dog teeth are resisted by the alignment of the linkage shaft with the central portion of the bell crank.

The invention relates to an ejection device for ejecting a movable furniture part from a closed position into an open position along an opening path, comprising a support and a coupling device for coupling the ejection device to the movable furniture part. The coupling device has a coupling piece which can be moved relative to the support and a coupling counter piece which is arranged on the movable furniture part or on a furniture body. The coupling device has a coupling position and a decoupling position, and the ejection device can be coupled to the movable furniture part via the coupling device in the coupling position. The ejection device also comprises a controller, by means of which the coupling device can be switched depending on the opening path, and the coupling device reaches the decoupling position from the coupling position in the event of a specified opening path.

An automated sliding panel mechanism is disclosed. An automated sliding panel mechanism includes a motor attached to a first component of a sliding panel that is configured to move the sliding panel between a closed position and an open position. The mechanism also includes a power source and a rack attached to a second component of the sliding panel and including a base with rack teeth extending from a plane thereof. A gear is rotated by the motor and has gear teeth shaped to mesh with the rack teeth. A manual release mechanism is adapted to move the gear along its axis of rotation, from an engaged position, wherein the gear teeth mesh with the rack teeth to a released position, wherein the gear teeth are disengaged from the rack teeth. The manual release mechanism also includes a holding mechanism adapted to hold the gear in the engaged position and in the released position as selected by a user.