A latch assembly includes a forkbolt biased to rotate in a first direction about a first pivot point, and a detent biased to rotate in a second direction about a second pivot point, the detent configured to engage with the forkbolt in at least two different positions. The latch assembly further includes a lever having a first end coupled to the detent and a second end biased toward the forkbolt. The latch assembly further includes a switch configured to detect a position of both the forkbolt and the combined lever and detent.

A glove box assembly includes a glove box housing and a glove box door movable between a first, closed position and a second, open position relative to the glove box housing to selectively provide access to an interior of the glove box housing. An actuation system is connected to the glove box door and a control mechanism is operably coupled to the actuation mechanism. The actuation mechanism is operable in response to the control mechanism to move the glove box door to one of the closed position or the open position.

Door operator (10) for an overhead door system (400), said door operator (10) being configured to move a door (401) of said door system (400), comprising: a first electric motor (100), a second electric motor (200), a planetary gearing (300), a control unit (11) configured to control the first (100) and second electric motor (200), and wherein the first electric motor (100) is connected to a first planetary gearing input shaft (301) and the second electric motor (200) is connected to a second planetary gearing input shaft (302), and wherein a planetary gearing output shaft (303) is associated with a shaft (402) for movement of the door (401).

Examples of the disclosure relate to example systems and methods for operating a door opening system for a vehicle. An example system includes a motorized door, and a sensor configured to detect obstacles within a travel path of the motorized door. The system also includes one or more processors configured to receive a door control signal, and in response to the door control signal, determine whether an obstacle had been detected within the travel path of the motorized door. In response to determining that an obstacle has been detected, the one or more processors can block activation of the motorized door.

The present invention relates to a sectional 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 (5) of the opening (2) and a second frame section (6) at a second side (7) of the opening (2), a door (8) arranged to be moved between an open (0) and closed (C) position and comprising a plurality of horizontal and interconnected sections (9) connected to the door frame (3) at least a drive unit (10) mounted on a first section (9) of the plurality of sections (9), wherein the drive unit (10) is moveably connected to the first frame section (4) and the drive unit (10) is moveably connected to the second frame section (6), the drive unit (10) comprise at least one motor (11) connected to at least one battery (12) arranged to power the at least one motor (11), and the drive unit (10) is arranged to move the door (8) from the closed position (C) to the open position (0).

Disclosed is a method (50) of providing finger pinch protection at a hinge area of a swing door-based entrance system (1) having a motorized automatic door operator (30) for opening (2) of the swing door (10) in an automatic mode of the entrance system (1), wherein the entrance system (1) also has a manual mode in which a human user may cause opening and closing of the swing door (10) by manual force. The method involves monitoring (52), by a first sensor function (S1), for presence of a person or object in a first zone (PD) at the first door leaf surface (12-1) and non-proximate to a vertical door edge (14). The method also involves monitoring, by a second sensor function (S2), for presence of a person or object in a second zone (PDHA) at the first door leaf surface (12-1) and proximate to said vertical door edge (14). When any of the first sensor function (S1) or second sensor function (S2) detects presence in the first zone (PD) or second zone (PDHA) in the automatic mode during an ongoing opening of the swing door (10), the automatic door operator (30) is controlled so as to stop opening of the swing door (10). When the second sensor function (S2) detects presence in the second zone (PDHA) in the manual mode, the automatic door operator (30) is controlled so as to counteract an attempt by a human user to manually open the swing door (10). A corresponding entrance system (1) is also disclosed.

A method for controlling a door, comprising the steps of storing energy during a manual opening of a door, sensing an object within a doorway, selectively applying a force derived from the stored energy, to close the door, based on the sensing of an object in the doorway. The closure is preferably controlled by an electronic control. A door closing device comprising an energy storage device for storing energy during door opening and releasing the stored energy to subsequently close the door, a damping system for damping a closure of the door, a sensor for detecting an object within a doorway, having an output, a controllable device for selectively restraining the energy storage device from closing the door, and a control system for controlling the controllable device based on the output.

A window regulator includes a carrier plate, a guide rail, an ascending-side wire and a descending-side wire, a driving portion, and a turnaround portion. The driving portion includes a rotating drum, a reducer, and a driving motor including a yoke portion that is arranged to be adjacent to one side of the reducer in an orthogonal direction orthogonal to the ascending/descending direction. The guide rail is arranged so as to in the orthogonal direction overlap only the ascending-side wire fed out from a first wire feeding-out position at the one side of the rotating drum in the orthogonal direction toward the turnaround portion between the ascending-side wire and the descending-side wire fed out from a second wire feeding-out position at an other side of the rotating drum in the orthogonal direction toward the carrier plate.

A vehicle includes a vehicle body having a door frame defining a door aperture, a vehicle door, a rail mounted on the vehicle body, a roller unit mounted on the vehicle door and configured to move along the rail and allow the vehicle door to open and close in a sliding mode and a swing mode, a center rail extending from an edge of the door aperture, and a center roller unit including rollers configured to be guided along the center rail, a roller bracket having the rollers mounted thereon, a roller-side hinge element connected to the roller bracket, and a door-side hinge element rotatably connected to the roller-side hinge element, wherein the roller-side hinge element and the door-side hinge element are releasably connected.

A sunroof structure of a vehicle includes at least one first mount for being mounted to a vehicle body of the vehicle, a window panel for being disposed to a hollow portion of the vehicle and having a main body and second and third mounts disposed on a bottom side of the main body, a transmission member including first and second rotational shafts rotatably disposed with the first and second mounts respectively and at least one crank connected with the first and second rotational shafts, and a link pivotally connected between the third mount and a pivot mount of the vehicle body. As a result, the window panel is drivenable to close or open the hollow portion. The sunroof structure greatly increases the open area of the hollow portion, and provides the side shielding function for the vehicle when the window panel is opened.