A door closer system is provided that includes a motor, a spring, a reduction gear set, and a rack and a pinion mechanism. The spring and pinion may be coupled to the rack, and the pinion may be selectively coupled to the gear set. The motor may be selectively mechanically coupled to the gear set. The pinion may rotate in a first direction via the rack as the spring is compressed in a second direction opposite the first direction as the spring is expanded. The motor is operable to rotate and act upon the pinion through the gear set, thereby rotating the pinion in the second direction and assist the spring in closing the door.

An overhead door operator system (1) for opening and closing an opening (2), comprising a door frame (3) comprising a first frame section (4) at a first side (7) of the opening (2) and a second frame section (6) at a second side (5) of the opening (2). The operator system further comprises a door (8) arranged to be moved between an open and closed (C) position, the door (8) being movably connected to the door frame (3) and a drive unit (10), the drive unit (10) comprising at least one motor (11) arranged to move the door (8) from the closed position (C) to the open position (O). An elongated transmission member (19) extends along the first side (7) of the opening (2) and the first frame section (4). The drive unit (10) further comprises a driven transmission member (18) in driving connection with the motor (11). The overhead door operator system (1) further comprises an end cap arrangement (100) attached to the door (8), the drive unit (10) being mounted to an end cap (101) of the end cap arrangement (100).

A method of operating an entry system of a motor vehicle includes monitoring a battery voltage and the entry system continuously using a control circuit of the latch assembly in a non-emergency mode. Power is provided to the control circuit in the event of a loss of power from a main power source using a backup energy source of the control circuit. The method includes transitioning to an emergency mode in response to determining loss of power from the main power source or failure of the component of the entry system. An actuation group associated with the latch assembly is operated with the control circuit using power from the backup energy source of the control circuit in response to determining that actuation from a plurality of pins of a mechanical emergency switch assembly indicates a command from a user to unlatch the closure member in the emergency mode.

An apparatus comprises a base plate configured to be coupled to a door, the door configured to be positioned in an open position and a closed position; a closing mechanism coupled to the base plate and configured to be coupled to a hinge of the door and having an unprimed state and a primed state, the closing mechanism configured to be transitioned between the unprimed state and the primed state by a user; wherein in the unprimed state the closing mechanism is decoupled from operation of the door; and in the primed state the closing mechanism is configured to move the door into the closed position responsive to receipt of a signal, and the closing mechanism is configured to allow movement of the door between the open position and the closed position in absence of the signal.

A movable barrier operator system is provided. The system includes a control circuit, an electric motor; and communication circuitry. The control circuit is configured to control operation of the electric motor based on a control signal received by the communication circuitry.

A household door with an integrated display, and methods for fabricating, installing, and routing power and data to the same are disclosed. The household door includes a door core having a cavity. The household door further incudes a front skin affixed to the door core and having a display window, and a back skin affixed to the door core. The household door further includes a display secured within the cavity and exposed by the display window. The front skin, the back skin, and the display seal the cavity.

The present disclosure provides a smart automated latch mechanism for opening a front trunk of a vehicle and a smart sensor array for detecting when the front trunk of the vehicle is at capacity. The system operates by having an electronic latch mechanism for the front trunk coupled with an infra-red sensor at the interface between the lid and the vehicle bonnet. When a change in temperature is detected in this space by the sensor, an electric motor causes the front trunk to open, removing the need for the user to actually touch the vehicle to open the front trunk. This system combines with a directional sensor array arranged inside the trunk which detects when an object is placed in front of it. The sensor array is arranged at a capacity height of the trunk, and thus allows for automated detection of when an object is in an inappropriate position, preventing damage to the vehicle from closing the front trunk lid on the object.

An animal door unit comprising a front panel, a left rear panel, a left guide, a right rear panel, and a right guide, wherein the front panel comprises an entrance; and a door plate having a plurality of guide holes, the door plate configurable in a retracted state and an open state, wherein, in the retracted state, the door plate traverses the entrance, and wherein, in the open state, the door plate does not traverse the entrance. The animal door unit may include a motor disposed within a module case; and a sprocket in rotational communication with the motor, wherein the sprocket interfaces with the plurality of guide holes, such rotational movement of the sprocket inducing linear movement in the door plate.

Lock mechanism is provided between pawl lever and manual release mean. The present vehicle door latch apparatus includes ratchet member that engages latch and that can be released from latch by release component force F2, latch restraint that prevents ratchet member from being disengaged from latch and powered release means that moves ratchet restraint. Ratchet member includes base lever and pawl lever. When ratchet restraint is moved, base lever is moved to a non-regulated position, where pawl lever can be disengaged from latch by release component force F2. Manual release means is connected to pawl lever. Lock mechanism is provided between pawl lever and manual release means.

A dimmer mechanism is movable by a motor that is powered by solar-charged supercapacitors between a first configuration, in which the dimmer mechanism blocks little of the interior of a skylight tube to maximize light throughput into a room, and a second configuration, in which the dimmer mechanism blocks more of the interior of a skylight tube to reduce light throughput into the room.