The present disclosure relates to an ambidextrous hinge. The ambidextrous hinge includes a first knuckle with a first engagement feature, a second knuckle with a second engagement feature, and a third knuckle movably coupled between the first knuckle and the second knuckle. The third knuckle includes a third engagement feature that engages the first engagement feature to cause the ambidextrous hinge to lock in a first open position when used as a first swing hinge. The third knuckle includes a fourth engagement feature that engages the second engagement feature to cause the ambidextrous hinge to lock in a second open position when used as a second swing hinge.

A hinge for a vehicle hood is provided. The hinge includes a hinge lower fixed to a vehicle body, and a hinge upper fixed to the hood and rotatably supported relative to the hinge lower. The hinge upper includes a first member rotatably supported relative to the hinge lower, and a second member fixed to the hood and relatively movable relative to the first member. The hinge further includes a first lock configured to be engageable with the first member to restrict rotation of the first member relative to the hinge lower. The first member and the second member are integrally rotatable relative to the hinge lower in a normal operation of opening and closing the hood. When the hood is caused to pop up, the first lock engages with the first member and the second member is relatively movable relative to the first member.

An automatic door opening system including a door having a top portion, a bottom portion, a hinged portion, and an opening portion. The system includes an opener connected to the door adjacent the opening portion and configured to selectively receive electrical current. The system includes a magnet disposed on the opening portion of the door such that the magnet is adjacent the opener when the door is in the closed position. The system includes a microcontroller in electric communication with the electromagnet wherein a memory contains processor-executable instructions to receive a door activation input and, in response to receiving the door activation input, activate the electromagnet to apply a magnetic force against the magnet and push the door between the closed position and the open position. The system may also include a closer configured to selectively return the door to the closed position.

A G-sensor for an automobile tray, and more particularly, a G-sensor for an automobile tray wherein a G-sensor for preventing a tray cover from being opened by an external force generated when the vehicle travels is modularized. The G sensor includes a lever configured to rotate around a hinge shaft, a slider coupled to the lever and guided along a key hole according to the state of rotation of the lever, a weight coupled to the lever for endowing a rotational moment of the lever around the hinge shaft, and a spring to provide the lever with power such that the same returns to the original condition.

A continuous hinge includes first and second leaves, an upper pivot, and a lower pivot. The first leaf is configured to secure to a first panel and the second leaf is configured to secure to a second panel. The first and second leaves each have an uppermost end adjacent a top end of the respective panel and a lowermost end adjacent a bottom end of the respective panel. The upper pivot is formed between the first and second leaves adjacent the uppermost ends thereof. The lower pivot is formed between the first and second leaves adjacent the lowermost ends thereof. The first and second leaves are configured to pivot relative to one another between a closed position in which the first and second panels are aligned on edges with one another and an open position in which the first and second panels are out of alignment with one another.

A system is used to control access into a vehicle having a vehicle body defining a vehicle interior, a vehicle exterior, and an access opening. The vehicle also has an access door for selectively covering and uncovering at least a portion of the access opening. The system includes a latch configured to selectively fasten the door to the vehicle body and release the door therefrom. The system also includes a cable configured to operate the latch and thereby release the door from the vehicle body. The system additionally includes a door presenter configured to shift the door away from the vehicle body. The system also includes a mechanism configured to sequentially actuate the cable and the door presenter. The system further includes an electric motor configured to power the mechanism such that the door is shifted away from the vehicle body by the door presenter after the door is released.

Methods and apparatus to adjust door operations in response to surface pressure loads are disclosed. An apparatus includes sensor feedback analyzer circuitry to detect a surface pressure load acting on a door based on feedback from a sensor. The door includes a panel to move along a track. The apparatus also includes operations controller circuitry to control operations of the door. The operations controller circuitry is to automatically adjust an operation of the door in response to detection of the surface pressure load.

A cinching system includes: a profile configured to determine a first time series of target values for cinching a closure closed; an adjustment module configured to determine an adjustment value based on at least one operating parameter; an adjusting module configured to generate a second time series of target values for cinching of the closure by adjusting at least one of the target values of the first time series based on the adjustment value; and a power control module configured to: apply power to a cinching motor when the closure is partially closed, where the cinching motor is configured to cinch and fully close the closure; and based on a comparison of a measured value of the cinching motor and one of the target values of the second time series, selectively one of: decrease power applied to the cinching motor; and disconnect the cinching motor from power.

An example retention assembly has a motor assembly and a self-locking worm drive coupled thereto. A cam is fixed to a worm gear of the worm drive. The retention assembly has an actuation shaft including a follower. The actuation shaft is displaceable over a displacement range via rotation of the cam. The retention assembly has a securement member with a securement member follower, the securement member coupled to a portion of the actuator shaft. The retention assembly has a housing cam included as part of the retention assembly housing and against which the securement member follower is biased. The securement member are in an open state when the actuation shaft is in a first position. The securement member swings outward to a retaining position as the actuation shaft is moved to a second position.

In one aspect, a method is provided for controlling access to a facility including a movable barrier and a plurality of loading docks. The method includes receiving, from a user device associated with a vehicle, a check-in communication that includes a check-in identifier. The method includes receiving a verification communication that verifies a presence of the vehicle relative to a sensor associated with the movable barrier. The method further includes causing a movable barrier operator associated with the movable barrier to move the movable barrier between closed and open positions in response to the check-in identifier indicating authorization to access the facility and in response to receiving the verification communication. Further, the method includes selecting a particular loading dock from the plurality of loading docks and communicating a loading dock identification representative of the particular loading dock to the user device to direct the vehicle to the particular loading dock.