A dual acting gas strut system for a vehicle such as a sports utility vehicle that allows for easier and safer opening and closing of the soft top roof as well as the rear cargo access area. The gas strut attaches to the soft top frame using a ball stud or pin and clevis, at each end, the ball stud or pin and clevis, which is either attached directly to the soft top frame, or is attached to a bracket which attaches to the soft top frame. Alternatively, the gas strut only attaches to the soft top frame at one end and is attached to the vehicle at the other. Each end is attached using a ball stud or pin and clevis, which is either attached directly to the soft top frame or vehicle, or is attached to a bracket which, is attached to the soft top frame or vehicle.

A linkage for opening and closing a lid through actuation of an electric motor 12 includes a base bracket 21 extending in a longitudinal direction of a vehicle, and a driving lever 14 having one end pivotally connected to the bracket 21 and the other end connected to the lid. The driving lever is driven via a pinion 22 by a sector gear 31 driven by the electric motor. The sector gear is attached to the bracket 21. The electric motor is fixed to a motor bracket 11 and attached via the motor bracket 11 to the bracket. Loosening a member supporting a lateral end portion of the motor bracket 11 and a bolt 41 fixing the bracket 11 to the bracket 21 allows the pinion and the sector gear to be axially disengaged from each other.

A linkage for opening and closing a lid through actuation of an electric motor 12 includes a base bracket 21 extending in a longitudinal direction of a vehicle, and a driving lever 14 having one end pivotally connected to the bracket 21 and the other end connected to the lid. The driving lever is driven via a pinion 22 by a sector gear 31 driven by the electric motor. The sector gear is attached to the bracket 21. The electric motor is fixed to a motor bracket 11 and attached via the motor bracket 11 to the bracket. Loosening a member supporting a lateral end portion of the motor bracket 11 and a bolt 41 fixing the bracket 11 to the bracket 21 allows the pinion and the sector gear to be axially disengaged from each other.

A rearwardly extending golf cart enclosure is disclosed. The golf cart enclosure is movable from a stored position to a deployed position which covers the golf bag storage area of the golf cart. The enclosure includes a plurality of struts which are substantially the same size. The enclosure is mounted to the golf cart rear roof supports via a pair of mounting wings or brackets. The mounting wings include a cam member rotatably mounted to a lower end of the mounting wing. The cam member includes a slot which allows at least one strut to move within the slot as the cam member is rotated to store or deploy the enclosure. The enclosure is mounted to an underside of the golf cart roof such that in the stored position, the enclosure fits underneath the golf cart roof and is protected from the elements or sun by a rear end of the golf cart roof. A metallic member provided on the mounting wing is magnetically coupled to a magnet mounted in the enclosure cover to releasably secure the enclosure in the stored position.

A rearwardly extending golf cart enclosure is disclosed. The golf cart enclosure is movable from a stored position to a deployed position which covers the golf bag storage area of the golf cart. The enclosure includes a plurality of struts which are substantially the same size. The enclosure is mounted to the golf cart rear roof supports via a pair of mounting wings or brackets. The mounting wings include a cam member rotatably mounted to a lower end of the mounting wing. The cam member includes a slot which allows at least one strut to move within the slot as the cam member is rotated to store or deploy the enclosure. The enclosure is mounted to an underside of the golf cart roof such that in the stored position, the enclosure fits underneath the golf cart roof and is protected from the elements or sun by a rear end of the golf cart roof. A metallic member provided on the mounting wing is magnetically coupled to a magnet mounted in the enclosure cover to releasably secure the enclosure in the stored position.

A smart tonneau cover for a pickup truck includes an input system that receives information concerning a route and the weather forecast for the route to a destination, the height of a cargo, a precipitation sensor, a wind sensor, and to determine the limits to the height, position, and orientation of the portions of a tonneau cover, which can include solar panels that can be moved to optimize power generation and minimize power consumption while protecting the cargo. The solar panels can be positioned when stationary, such as while parked, and repositioned as needed during transit to maintain an optimal power efficiency.

A tonneau cover lift; the tonneau cover lift includes a height-adjustable, lightweight tonneau cover assembly including a cover member and a rectangular frame supported by four telescoping, hydraulic support posts including a first-telescopic-leg, a second-telescopic-leg, a third-telescopic-leg, and a fourth-telescopic-leg. The cover member is sized and configured to cover a bed of a truck and may be remotely controlled using a remote activation unit. The tonneau cover lift expands a protected cargo capacity of a truck.

Disclosed herein are embodiments of a folding top assembly for use with a vehicle and methods for using a folding top assembly on a vehicle. The folding top assembly can be used to create openings on the top of the vehicle by folding a rear panel segment of the folding top assembly forward to expose a space over a rear seating area of the vehicle and/or folding a front panel segment of the folding top assembly rearward to expose a space over a front seating area of the vehicle. The assembly can be designed and shaped to improve the ability to store the folding top assembly on the vehicle and/or to improve aerodynamics when the vehicle is moving.

A rolling tarp deployment system includes a trailer, a bulkhead fixed to the trailer, first and second bows movable along the trailer, first and second tensioning assemblies, and a cover. The first tensioning assembly has a first member secured to the first bow, a second member secured to the bulkhead, and a first actuator configured to engage the first and second members to restrain the first bow to the bulkhead. The second tensioning assembly has a third member secured to the second bow, a fourth member fixed to the trailer, and a second actuator configured to engage the third and fourth members and move the second bow away from the bulkhead. The cover is tensioned when both the first and second members and the third and fourth members are engaged.

A lift assist lock-down assembly for a soft top assembly, the lock-down assembly operably coupled to first and second bows selectively rotatable between an open/sunroof position and an open/downward position. A handle member is rotatable between unlocked and locked positions. A cam and a cam lockout selectively prevent the bows from rotating. When locked in a first position, the bows are prevented from rotating generally rearward/downward, thereby preventing the soft top assembly from moving into the open/downward position. When locked in a second position, the bows are prevented from rotating generally forward/upward, thereby generally preventing the soft top from bouncing or from moving into the open/sunroof position.