An open roof assembly for use in a vehicle roof of a vehicle comprises a moveably arranged closure member for selectively covering or at least partially exposing an opening in the vehicle roof. Further, an electric motor operatively coupled to the closure member is provided for moving the closure member. A control unit is operatively coupled to the electric motor for controlling the closure member. The control unit is configured to control a position of the closure member during normal driving conditions, and to release control of the position of the closure member, when a vehicle acceleration exceeds a predetermined acceleration threshold. Thus, upon a high force on the closure member, induced by the high acceleration and weight of the closure member, damage may be prevented by absorbing the high forces in a motion of the closure member and a resistance of the electric motor.

An open roof construction for a vehicle having a roof opening in a roof part, comprising a panel, and a first device for moving the rear side of the panel towards a raised position relative to the closed position and above an adjoining roof part. The control slide and the lifting member are guided by a guide rail having grooves and extending in longitudinal direction alongside the opening and below the adjoining roof part. A support lever cooperates with the control slide and supports the panel in positions in which it is above the adjoining roof part. The support lever is guided in the guide rail and is adapted to also pass through the passage opening. The support lever takes over support of the panel from an intermediate guide connection of the lifting lever and the intermediate guide connection is then disengaged from the guide curve in the control slide.

A cover for a vehicle roof, which may have a pane, an anti-splinter layer arranged on the inside face of the pane, and a lighting device having a luminous layer, wherein the luminous and anti-splinter layer forms both the anti-splinter layer and the luminous layer in this one layer and in particular the lighting device contains at least one luminous unit, which is designed to radiate light into the luminous and anti-splinter layer at a lateral edge region of the luminous and anti-splinter layer.

A cover for a vehicle roof, which may have a pane, an anti-splinter layer arranged on the inside face of the pane, and a lighting device having a luminous layer, wherein the luminous and anti-splinter layer forms both the anti-splinter layer and the luminous layer in this one layer and in particular the lighting device contains at least one luminous unit, which is designed to radiate light into the luminous and anti-splinter layer at a lateral edge region of the luminous and anti-splinter layer.

A drive system including a guide rail arrangement fixed to a roof module, a drive slide, a front-side lifting arrangement, a rear-side extension mechanism, and a profiled support part. The lifting arrangement and the extension mechanism interact with the profiled support part such that the profiled support part is guided in a force-controlled manner between a closed, ventilating and open positions of the roof part. The coupling device end region remote from the extension mechanism has a coupling slide which is guided in the guide rail arrangement and which comprises a blocking element that can be moved in the vertical direction. A stationary latch recess is provided in the guide rail arrangement, and the drive slide has a receiving area. Depending on the position of the drive slide, the blocking element is moved into the latch recess or into the receiving area in a force-controlled manner by mechanical control contours.

1. Glass cover unit of a sliding roof system for an automotive vehicle and method for its production.

2.1 A glass cover unit comprising a glass cover and a metallic carrier arrangement and an in-place foamed synthetic material, said foamed material being provided in a boundary area of the glass cover and fixing the metallic carrier arrangement in relation to a bottom side of the glass cover, wherein a sealing insert is provided between a top side of the metallic carrier arrangement and the bottom side of the glass cover to ensure spacing of the top side of the metallic carrier arrangement from the bottom side of the glass cover, is known.

2.2 According to the invention, the sealing insert is a sealing bead configured using a deformable material which extends in an annular shape on the metallic carrier arrangement, which adheres to the metallic carrier arrangement, and has bead ends adjoining in alignment joint to joint.

2.3 Use with passenger vehicles.

1. Glass cover unit of a sliding roof system for an automotive vehicle and method for its production.

2.1 A glass cover unit comprising a glass cover and a metallic carrier arrangement and an in-place foamed synthetic material, said foamed material being provided in a boundary area of the glass cover and fixing the metallic carrier arrangement in relation to a bottom side of the glass cover, wherein a sealing insert is provided between a top side of the metallic carrier arrangement and the bottom side of the glass cover to ensure spacing of the top side of the metallic carrier arrangement from the bottom side of the glass cover, is known.

2.2 According to the invention, the sealing insert is a sealing bead configured using a deformable material which extends in an annular shape on the metallic carrier arrangement, which adheres to the metallic carrier arrangement, and has bead ends adjoining in alignment joint to joint.

2.3 Use with passenger vehicles.

A vehicle includes a roof panel assembly and a sunroof glass panel. The roof panel assembly defines an opening. The sunroof glass panel has an arm extending from a side thereof. The sunroof glass panel is configured to cover the opening in the roof panel assembly and operable between a closed position, an open position, and a tilted position. The arm extends outwardly past a periphery of the opening in the roof panel assembly. The arm is configured to engage the roof panel assembly to restrict movement of the sunroof glass panel relative to the roof panel assembly.

A roof system comprises a stationary part configured to be attached to a fixed roof and includes guide rails on opposite sides of a roof opening. The guide rails slidably support an operating mechanism for a panel and include guide grooves bordered by guide flanges. The operating mechanism includes a driving slide for a panel front support, and a panel rear support. The rear support is connected to a panel bracket guide of a panel bracket extending alongside a corresponding edge of the panel. The panel bracket guide slidably engages the rear support so as to enable the panel to slide with respect to the rear support when the front support is driven by the driving slide. The front support engages a guide rail groove of an upright flange of each guide rail while the panel bracket guide extends mainly on the other, inner side of said upright flange.

A roof system comprises a stationary part configured to be attached to a fixed roof and includes guide rails on opposite sides of a roof opening. The guide rails slidably support an operating mechanism for a panel and include guide grooves bordered by guide flanges. The operating mechanism includes a driving slide for a panel front support, and a panel rear support. The rear support is connected to a panel bracket guide of a panel bracket extending alongside a corresponding edge of the panel. The panel bracket guide slidably engages the rear support so as to enable the panel to slide with respect to the rear support when the front support is driven by the driving slide. The front support engages a guide rail groove of an upright flange of each guide rail while the panel bracket guide extends mainly on the other, inner side of said upright flange.