This document relates generally to the motor vehicle field and, more particularly, to an automatic sliding roof rail system.
Roof rail systems are often provided on motor vehicles to provide a convenient place for storing oversized or excess cargo that cannot be accommodated in other vehicle storage areas, such as the cabin or trunk. The roof rail is typically a fixed structure secured directly to the roof. This may create an obstruction in terms of the wind, which can lead to increased noise and reduced fuel efficiency, and may also have an undesirable impact on the aesthetics of the vehicle.
Accordingly, a need is identified for an improved automatic roof rail system that addresses the foregoing issues and perhaps others not yet contemplated.
According to one aspect of the disclosure, a system for providing storage on a vehicle roof. The system includes at least one partially hollow pillar for supporting the vehicle roof. A rail is provided for raising and lowering relative to the vehicle roof between a deployed position and a non-deployed position. An actuator is positioned at least partially along or within the at least one pillar for moving the rail relative to the roof.
In one embodiment, the actuator comprises a support for the rail positioned at least partially within the at least one pillar. The at least one pillar may comprise an A-pillar. A second rail may also be provided for being raised and lowered relative to the vehicle roof, along with a second actuator for moving the second rail.
A first support may be slidably connected to the rail. The first support may be positioned in a C-pillar. A second support for the rail may be positioned in a B-pillar, and may be fixed to the rail between the support forming part of the actuator and the support positioned in the C-pillar.
The actuator may comprise a pinion and the rail may be connected to a rack in engagement with the pinion and positioned at least partially within the at least one pillar. A latch may also be provided for latching the rail in a raised position. The latch may comprise a magnetic coupling formed between a support for supporting the rail and another pillar for supporting the vehicle roof.
According to a further aspect of the disclosure, a system for providing storage on a vehicle roof is provided. The system comprises at least one pillar for supporting the vehicle roof, and a rail adapted to being raised and lowered relative to the roof. A support for the rail is received within the at least one pillar.
An actuator may also be provided for moving the rail relative to the roof. The actuator may be positioned at least partially within the at least one pillar. The system may also be arranged to work in connection with a plurality of pillars, with support for the rail associated with each of the plurality of pillars. The support may also be slidably connected to the rail.
Still a further aspect of the disclosure pertains to a system for providing storage for cargo. The system comprises a vehicle including a roof, and a rail adapted to being raised and lowered relative to the roof. A support for supporting the rail is connected to the rail for sliding as the rail is raised and lowered.
An actuator may also be connected to the support for moving the rail. A second support may be provided for supporting the rail for sliding as the rail is raised and lowered. Likewise, a third support may be provided, and may be fixed to the rail between the first and second supports. The roof may be supported by at least one pillar and at least partially received therein.
In the following description, several embodiments of an automatic sliding roof rail system. As it should be realized, the arrangement is capable of other, different embodiments and its several details are capable of modification in various, obvious aspects all without departing from the system as set forth and described in the following claims. Accordingly, the drawings and descriptions should be regarded as illustrative in nature and not as restrictive.
The accompanying drawing figures incorporated herein and forming a part of the specification, illustrate several aspects of the disclosed automatic sliding roof rail system serve to explain certain principles thereof. In the drawing figures:
Reference will now be made in detail to the present preferred embodiments of the automatic sliding roof rail system, examples of which are illustrated in the accompanying drawing figures.
Reference is now made to
The vehicle 20 may be provided with a selectively actuatable roof rail system 40. In the illustrated embodiment, the system 40 includes a pair of spaced rails 42, 44 adapted for moving between a lowered or non-deployed position (
According to one aspect of the disclosure, the system 10 includes an actuator 46 that may be associated with one of the pillars 24, 26, 28, such as by being positioned along or within it. In the illustrated embodiment, the actuator 46 is positioned at least partially within a recess or cavity in the front or A-pillar 24, and includes an active support 42a for supporting the rail while moving it to and fro between the lowered/non-deployed and raised/deployed positions. The support 42a is at least partially received in a recess of the A-pillar. Actuation of the actuator 46 thus moves the support 42a and causes the rail 42 to move relative to the roof panel 22.
In the particular embodiment shown, and with reference to
Turning to
As also shown in
As indicated in
The actuator 46 is shown in the A-pillar 24, which advantageously is proximate to the vehicle battery at the typical location in an engine compartment of the vehicle 20, but it could be associated with the B-pillar 26 or the C-pillar 28 instead with suitable wiring to the battery (which can sometimes be located at the rear of the vehicle 20, such as in the trunk). The actuator 46 may also take different forms, such as a linear actuator, and/or may be pneumatic instead of mechanical. Multiple actuators may also be provided for each rail 42, 44.
While the foregoing discussion centered on one rail 42, it should be appreciated the same or a similar configuration could be used on the second rail 44, or perhaps even additional rails, as indicated by the depiction of actuator 46 of the left hand side of
The rails 42, 44 may also be recessed relative to the roof panel 22 in the non-deployed position. Specifically, with reference back to
Actuation of the system 10 to deploy the rail(s) 42, 44 may be achieved using a control (not shown) within the vehicle 20, such as on a control panel. Alternatively or additionally, the control may be achieved by a remote device, such as a portable or handheld mobile computer or a key fob (not shown). In any case, the system 10 may be selectively activated by the user when cargo storage on the vehicle roof is desired, and de-activated when this functionality is not needed.
In summary, an automatic sliding roof rail system 10 is provided that can be selectively deployed by a vehicle operator when it is desirable to store cargo on a vehicle roof. The system 10 includes an actuator 46 for moving a rail 42 (or rail 44) recessed in one (or more) of the pillars 24, 26, 28 for supporting the vehicle roof (panel 22), which creates a low profile arrangement. The rail 42 may also be slidably connected to one or more supports 42a, 42c to allow for regulation of the height as a function of the actuation. Latches 56 may also be provided for holding the rail 42 in the deployed or raised condition, such as along depending portions 42b, 42c of the rail that are not associated with actuator 46. A selectively actuatable system 10 thus results that is reliable and secure in operation.
The foregoing description of an automatic sliding roof rail system has been presented for purposes of illustration. It is not intended to be exhaustive or to limit the embodiments to the precise form disclosed. Obvious modifications and variations are possible in light of the above teachings. For instance, in a vehicle 20 without three pillars, as shown, one of the supports (such as support 42b if no B-pillar 26 is present) may be omitted. The supports or actuator may also extend along an outer surface of the pillar, such as adjacent to the vehicle cabin, with the pillars thus providing support and guidance in the same manner as if the support were recessed within a hollow portion of the pillar. All such modifications and variations are within the scope of the appended claims when interpreted in accordance with the breadth to which they are fairly, legally and equitably entitled.