An articulating slanted back soft top assembly for 4-door and 2-door SUVs. A fabric cover is supported by a frame that is at least partially articulatable from at least a closed position to at least one open air position. The frame includes at least one forward fabric support bow member and at least one rearward fabric support bow member. The rear fabric support bow member being positioned when in the closed position in a manner which allows the fabric to clear a sport bar or “roll bar” member of a vehicle in the closed position such that a rear portion of the top is angled from the vertical when viewing the vehicle from the side.

A utility task vehicle includes a vehicle body including an opening. A door is positioned adjacent the opening. The door is configured to pivot about a first axis between an open position and a closed position. A window assembly is positioned adjacent and operably coupled to the door. The window assembly is configured to pivot about a second axis between an open position and a closed position. Rotation of the window assembly about the second axis is driven by rotation of said door about the first axis. In combination, the door and the window assembly substantially seal the opening of the vehicle body.

A door mirror structure comprises a door-mirror body portion, a mirror base having a tip-end portion fixed to the door-mirror body portion and a base-end portion provided away from the tip-end portion, a rotational support axis connected to the base-end portion and rotatably supporting the door-mirror body portion and the mirror base between a mirror-use position and a mirror-storage position, and an electromotive rotational unit provided to rotate the door-mirror body portion and the mirror base between the mirror-use position and the mirror-storage position around an axis line of the rotational support axis. The electromotive rotational unit is provided at a side door. The rotational support axis is provided to be inclined such that an upper side thereof is located on an inward side in a vehicle width direction.

A door mirror structure comprises a door-mirror body portion, a mirror base having a tip-end portion fixed to the door-mirror body portion and a base-end portion provided away from the tip-end portion, a rotational support axis connected to the base-end portion and rotatably supporting the door-mirror body portion and the mirror base between a mirror-use position and a mirror-storage position, and an electromotive rotational unit provided to rotate the door-mirror body portion and the mirror base between the mirror-use position and the mirror-storage position around an axis line of the rotational support axis. The electromotive rotational unit is provided at a side door. The rotational support axis is provided to be inclined such that an upper side thereof is located on an inward side in a vehicle width direction.

A vehicle door according to an exemplary embodiment enhances coupling strength through structural coupling by molding a window frame of a door module assembled between a door trim and the door panel with a separate aluminum injection product, and insert-injection molding a coupling portion of the window frame to a module body, and a groove is formed along the coupling portion of the window frame coupled to the module body to easily distinguish respective parts and serve to carry out sealing in injection molding.

A vehicle door according to an exemplary embodiment enhances coupling strength through structural coupling by molding a window frame of a door module assembled between a door trim and the door panel with a separate aluminum injection product, and insert-injection molding a coupling portion of the window frame to a module body, and a groove is formed along the coupling portion of the window frame coupled to the module body to easily distinguish respective parts and serve to carry out sealing in injection molding.

A panel top assembly adapted for a vehicle including a pivotal portion that is rotatable between a closed position and open sunroof position, the pivotal portion is coupled to guide assemblies to selectively slide rearward to another top open position. There is provided a removable hard rear window, a rear hard drip rail; and a pair of removable hard rear side window assemblies on the side of the vehicle that wrap around to the back of the vehicle creating clear rear hard corners and that are also in sealing engagement to the rear window. The rear hard drip rail and pivotal portion selectively drop down at an angle into the rear cargo area of the vehicle when a fully open top experience is desired.

The present application relates to a heat generating side window, for a vehicle, comprising: a substrate comprising an upper edge, a lower edge, a front edge and a rear edge; a heat generating member positioned adjacently to the substrate; an upper busbar positioned on the heat generating member and electrically connected to the heat generating member; and a lower busbar positioned on the heat generating member and electrically connected to the heat generating member.

The present application relates to a heat generating side window, for a vehicle, comprising: a substrate comprising an upper edge, a lower edge, a front edge and a rear edge; a heat generating member positioned adjacently to the substrate; an upper busbar positioned on the heat generating member and electrically connected to the heat generating member; and a lower busbar positioned on the heat generating member and electrically connected to the heat generating member.

A method for producing a safety tempered vehicle glazing unit, includes a. tempering a glass pane at a tempering temperature; b. cooling the tempered glass pane to a first temperature T1 above room temperature; c. coating the tempered glass pane with a dispersion of an organic resin at the first temperature T1, and d. drying and cooling to room temperature Tr.