A refrigerator preventing a door thereof from drooping downward and allow the door to be automatically closed. The refrigerator includes a body, a storage compartment provided in the body, a front thereof being open, a door rotatably coupled to the body to open and close the storage compartment, a support unit coupled to a center of a lower portion of the body, the support unit including at least one rotating member arranged to protrude from a front of the body to correspond to a position of the lower portion of the door, and at least one droop prevention unit coupled to the lower portion of the door at a position corresponding to the rotating member, and supported by the rotating member to prevent the door from drooping downward, the droop prevention unit cooperating with the rotating member to support the door in an upward direction when the door is closed.

A furniture drive for driving a movable piece of furniture includes an electric motor, an actuator which is preferably movable back and forth between two end positions for exerting force on the piece of furniture that is to be driven, and a gear mechanism connected between the electric motor and the actuator, and the electric motor is designed as an axial flux motor.

A furniture drive for driving a movable piece of furniture includes an electric motor, an actuator which is preferably movable back and forth between two end positions for exerting force on the piece of furniture that is to be driven, and a gear mechanism connected between the electric motor and the actuator, and the electric motor is designed as an axial flux motor.

A furniture drive for driving a movable furniture part, including a housing, an electric motor, and a bearing device via which the electric motor is mounted in and/or on the housing. The bearing device includes a damping element made of a sound-absorbing material, an actuator, preferably movable back and forth between two end positions, for exerting force on the furniture part to be driven, and a transmission connected between the electric motor and the actuator. A coupling device connects the electric motor, preferably a shaft of the electric motor or a gear connected thereto, to the transmission. The coupling device consists at least partially of a sound-absorbing material, and the housing has a maximum width of less than 18 mm, preferably less than 16 mm.

A furniture drive for driving a movable furniture part, including a housing, an electric motor, and a bearing device via which the electric motor is mounted in and/or on the housing. The bearing device includes a damping element made of a sound-absorbing material, an actuator, preferably movable back and forth between two end positions, for exerting force on the furniture part to be driven, and a transmission connected between the electric motor and the actuator. A coupling device connects the electric motor, preferably a shaft of the electric motor or a gear connected thereto, to the transmission. The coupling device consists at least partially of a sound-absorbing material, and the housing has a maximum width of less than 18 mm, preferably less than 16 mm.

Example embodiments provide a sliding system with improved mechanisms. According to embodiments, the sliding system may include a drive mechanism, a frame, a supporting device, and a connecting device. The drive mechanism is configurable to move a sliding panel along at least one track. The frame may house at least a portion of the drive mechanism. The supporting device may be detachably connected to the frame. The connecting device detachably connected the drive mechanism to the sliding panel.

Example embodiments provide a sliding system with improved mechanisms. According to embodiments, the sliding system may include a drive mechanism, a frame, a supporting device, and a connecting device. The drive mechanism is configurable to move a sliding panel along at least one track. The frame may house at least a portion of the drive mechanism. The supporting device may be detachably connected to the frame. The connecting device detachably connected the drive mechanism to the sliding panel.

A device for mechanically adjusting a component comprising a bracket having a first sidewall and a second sidewall, where the first sidewall comprises a first opening and the second sidewall comprises a second opening. A tapered channel may be formed between the first opening and the second opening. The device further comprises a connector and a receiver that work together with the bracket to provide an adjustment mechanism for supporting and adjusting an angle of incline of a wheeled gate used in fencing or other applications.

A device for mechanically adjusting a component comprising a bracket having a first sidewall and a second sidewall, where the first sidewall comprises a first opening and the second sidewall comprises a second opening. A tapered channel may be formed between the first opening and the second opening. The device further comprises a connector and a receiver that work together with the bracket to provide an adjustment mechanism for supporting and adjusting an angle of incline of a wheeled gate used in fencing or other applications.

A load-bearing accessory includes a hinge, a frame and a connector. The frame includes an adjustment portion and a support portion. The distance between the adjustment portion and the support portion is adjustable. A first end of the connector is connected to the hinge, and a second end of the connector is connected to the adjustment portion. One of the hinge or the frame that is located at the upper position of the load-bearing accessory is configured to support the connector, and the connector is configured to support the other one of the hinge or the frame that is located at the lower position of the load-bearing accessory.