A roof system for a vehicle includes a fixed roof element, forming a fixed roof segment of a vehicle roof bounding a passenger compartment and situated in a rear area of the vehicle roof, a roof opening and closing mechanism, which allows a relative movement of a movable roof element in relation to the fixed roof element and/or a relative movement of a movable roller blind in relation to the vehicle roof. The fixed roof element is designed as a single-piece roof element having at least one impact energy absorption section and at least one receiving section locally distinct from the impact energy absorption section for receiving electrical and/or mechanical function elements, by which or in the interplay of which with other function elements a movement of the movable roof element for opening and closing of the roof opening and/or driving the roller blind can be effectuated.

A soft top assembly which includes lift assist and improved fabric management. The assembly includes front side rails pivotally connected to rear side rails. A plurality of fabric control bows with control linkages provide fabric control to the top material during pivoting of the front side rails. A first and second gas strut are attached to the rear side rails to assist lifting and controlled motion as the top is moved between a closed position and open sunroof position, as one strut is fully loaded and compressed while the other strut is fully loaded and open, for lift assist and dampening.

A wind deflector for a sliding roof system has a pivotable upper bracket in the raised state of the wind deflector, a pivotable lower bracket in the raised state of the wind deflector, a first elastic raising element, and a flow deflecting part which is fastened to central webs of the brackets and bridges the space between the central webs in the raised state of the wind deflector. The flow deflecting part extends obliquely upwards and opposite to the direction of travel between the central webs. The first elastic raising element is associated with the upper bracket and is configured to urge the upper bracket into the pivoted-up position. A sliding roof system is furthermore shown.

A wind deflector for a sliding roof system has a pivotable upper bracket in the raised state of the wind deflector, a pivotable lower bracket in the raised state of the wind deflector, a first elastic raising element, and a flow deflecting part which is fastened to central webs of the brackets and bridges the space between the central webs in the raised state of the wind deflector. The flow deflecting part extends obliquely upwards and opposite to the direction of travel between the central webs. The first elastic raising element is associated with the upper bracket and is configured to urge the upper bracket into the pivoted-up position. A sliding roof system is furthermore shown.

A vehicle roof having a cover which is movably mounted on the vehicle roof by a bearing mechanism and is adjustable between a closed and a ventilation position in which at least the rear cover edge is raised, the cover being adjustable by the bearing mechanism in such a way that, in the closed position of the cover, the rear cover edge assumes a defined vertical position relative to a roof area portion which adjoins the roof opening or the cover in the region of the rear cover edge, wherein, according to the invention, the cover in its closed position rests on at least one supporting element which is held fixedly on the roof side in a position central with respect to the roof opening and below the rear cover edge and which supporting element holds the cover in its defined vertical position relative to the roof area portion.

A sliding roof system for a motor vehicle comprises a front lifting mechanism and a rear lifting mechanism which are assigned to a front and a rear edge respectively of a cover of the sliding roof system, as well as a connecting element which is arranged between the front and the rear lifting mechanisms. The rear lifting mechanism includes a lifting carriage with at least one lifting slotted guide, a lifting lever which is pivotably attached with one end to a fixed bearing and the other end of which has a guide element for the cover, and a translating lever which is pivotably connected to the lifting lever between its ends, wherein the translating lever is coupled to the lifting carriage by means of two sliders.

A sliding roof system for a motor vehicle comprises a front lifting mechanism and a rear lifting mechanism which are assigned to a front and a rear edge respectively of a cover of the sliding roof system, as well as a connecting element which is arranged between the front and the rear lifting mechanisms. The rear lifting mechanism includes a lifting carriage with at least one lifting slotted guide, a lifting lever which is pivotably attached with one end to a fixed bearing and the other end of which has a guide element for the cover, and a translating lever which is pivotably connected to the lifting lever between its ends, wherein the translating lever is coupled to the lifting carriage by means of two sliders.

A glass panel assembly for use in a roof of a vehicle, comprises a glass panel, a frame and an elongate lighting device. The glass panel comprises an interior main surface and the interior main surface of the glass panel is configured to be directed to a passenger compartment of the vehicle. The frame is adhered to the interior main surface and comprises a shaped element. The shaped element is one of a recess and a protrusion. The elongate lighting device is coupled to the frame by a mating shape engaging the shaped element. The lighting device is configured to directly illuminate at least a part of said passenger compartment.

A glass panel assembly for use in a roof of a vehicle, comprises a glass panel, a frame and an elongate lighting device. The glass panel comprises an interior main surface and the interior main surface of the glass panel is configured to be directed to a passenger compartment of the vehicle. The frame is adhered to the interior main surface and comprises a shaped element. The shaped element is one of a recess and a protrusion. The elongate lighting device is coupled to the frame by a mating shape engaging the shaped element. The lighting device is configured to directly illuminate at least a part of said passenger compartment.

A movably arranged vehicle component is operatively coupled to and may be driven by an electric motor. The electric motor is supplied with a motor current to drive the movement of the vehicle component. A method for detecting a movement obstruction comprises the steps of supplying the electric motor with a supply voltage, thereby supplying the motor current; determining a frequency content of the motor current; and analysing the frequency content to determine whether the movement obstruction is present or not. A motor control system is configured to perform the above-mentioned method.