Removable roofing system comprising a motor inserted inside a drum (2), a cord, a compensation device (4), two rigging rails (5a, 5b), at least one guide arch (6a) and removable roofing, the at least one guide arch (6a) being connected to the cord and to the removable roofing, and being designed so that each of its ends slides in a rigging rail (5a, 5b), the cord passing along each rigging rail (5a, 5b) and through the compensation device (4) and being connected at its two ends to the drum (2) so that the rotating of the drum (2) by the motor causes the cord to move in a direction dependent on the direction of rotation of the drum (2), deploying or retracting the removable roofing by moving the at least one guide arch (6a), each rigging rail (5a, 5b) being equipped with at least one end pulley (21a, 21b) and with at least two corner-block deflecting pulleys (20a, 20b, 23a, 23b) which are designed to guide the cord from the compensation device towards the at least one end pulley (21a, 21b), and the compensation device (4) is designed to automatically compensate for variations in cord tension.

A window regulator, including: a first guide rail; a first cursor slidably mounted to the first guide rail; a second guide rail spaced from the first guide rail; a second cursor slidably mounted to the second guide rail; a housing that is not mounted to a lower end of the first guide rail or the second guide rail; a motor mounted to the housing and operably coupled to the first cursor and the second cursor such that operation of the motor will cause the first cursor to slide along the first guide rail and second cursor to slide along the second guide rail; a cable drum rotationally mounted to the housing, the cable drum being operably coupled to the motor and a first cable secured to the cable drum at one end and the first cursor at another end; a second cable secured to the cable drum at one end and the second cursor at another end; a third cable secured to the first cursor at one end and the second cursor at another end; a first cable sheath surrounding the first cable that extends from a first feature of the first guide rail to the housing; a cable tensioner associated with the first cable sheath; a second cable sheath surrounding the second cable that extends from the housing to a second feature of the second guide rail; and a third cable sheath surrounding the third cable that extends from the a second feature of the first guide rail to a first feature of the second guide rail, wherein the window regulator is configured for raising and lowering a window of a frameless door assembly of a vehicle.

A window lift for a motor vehicle contains a functional support for at least one guide rail, which slidably guides a rail slider for retaining a vehicle window, and a cable drive device. The cable drive device has an actuating drive and a cable drive housing, into which a cable drum, which can be coupled to the actuating drive and can be rotated about an axis of rotation, is or can be received, around which cable drum a pull cable is or can be wrapped. The cable drive housing has a bottom plate and a number of cylindrical wall elements for receiving the cable drum. The functional support has, at the periphery of a through-opening for the coupling of the cable drum to the actuating drive, a joining contour for establishing a form-locking connection to the cable drum housing when the cable drum is inserted therein.

A console assembly for use in a vehicle provided with a floor. The console assembly includes a guide member, coupled to the vehicle floor, a moving portion, a gearbox assembly, a transmission assembly, and a disengaging device. The gearbox assembly includes a gear configured to rotate about a rotational axis in a first rotational direction and a second rotational direction to move the moving portion between a first position and a second position. The transmission assembly is configured to operate in a number of operating states, including an engaged state and a disengaged state. The disengaging device is configured to change the operating state of the transmission assembly between the engaged state and the operating state so that the moving portion is movable while the transmission assembly is in the disengaged state.

A sensor apparatus for a movable barrier system having a rotatable drum and an elongate member that winds up on and pays out from an external surface of the rotatable drum. The sensor apparatus includes a base portion, a sensing portion, and a controller. The sensing portion senses a first spaced apart proximity of the elongate member relative to the sensing portion and a second spaced apart proximity of the elongate member relative to the sensing portion. The controller detects a change in the proximity of the elongate member relative to the sensing portion without the elongate member contacting the sensing portion.

A sliding-door drive device includes: a motor; a speed reducing mechanism reducing rotation of the motor; opening and closing cables having respective one ends secured to a sliding door of a vehicle; an opening drum, having the opening cable wound therearound, to be rotated by the motor through the speed reducing mechanism; and a closing drum, having the closing cable wound therearound, to be rotated by the motor through the speed reducing mechanism. Further, rotation axes of the motor, the opening drum, and the closing drum are parallel, and the opening drum and the closing drum are arranged parallel in radial directions thereof.

The present disclosure is directed to overhead door assemblies and operating systems. Disclosed herein is a drive drum that is compatible across a variety of overhead door types, including, for example, standard lift doors, vertical lift doors, and high lift doors. The drive drum of the present disclosure comprises a first cable groove section and a second cable groove section, opposite the first cable groove section, wherein at least one of the first cable groove section or the second cable groove section is in a non-linear graduated arrangement.

A cable-operated drive mechanism for a powered motor vehicle sliding closure panel and method of construction of the cable-operated drive mechanism is provided. The cable-operated drive mechanism includes a cable drum mechanism having a first cable drum supported for rotation about a first drum axis and a second cable drum supported for rotation about a second drum axis. A first cable winds and unwinds about the first cable drum in response to rotation of the first cable drum in opposite directions and a second cable unwinds and winds about the second cable drum in response to rotation of the second cable drum in opposite directions. A drive member is operably coupled to at least one of the first cable drum and second cable drum to drive the first and second cable drums in unison with one another.

The present disclosure is directed to overhead door assemblies and operating systems. Disclosed herein is a drive drum that is compatible across a variety of overhead door types, including, for example, standard lift doors, vertical lift doors, and high lift doors. The drive drum of the present disclosure comprises a first cable groove section and a second cable groove section, opposite the first cable groove section, wherein at least one of the first cable groove section or the second cable groove section is in a non-linear graduated arrangement.

A drive mechanism control system and method of operation are provided. The system includes a motor for rotating an output shaft about a primary central axis. The system also includes a powered drive mechanism including a rotatable component attached to the output shaft. The system also includes a coil and a target attached to the rotatable component and configured to have a fluctuating inductive coupling with the coil. The system additionally includes an electronic control unit coupled to the coil and configured to generate a magnetic field adjacent to the target using the coil. The electronic control unit senses a variation of the magnetic field due to the fluctuating inductive coupling with the target as the rotatable component is rotated. The electronic control unit is also configured to determine an absolute position of the rotatable component based on sensing the variation of the magnetic field.