The present invention relates to an automotive power partition, and more particularly to a power tailgate system for use in a pick-up truck.
Pick-up trucks commonly have a tailgate, which can be opened or closed by a user to access a box or bed of the pick-up truck. Such tailgates are manually operable and often can be heavy or difficult to safely open and close when the user is holding one or more objects. Some tailgates are removable to provide additional functionality to the truck in accordance with the user's needs. Removal of the tailgate from the truck, however, can be cumbersome and time consuming because one or more tools are required by the user to facilitate removal of the tailgate from the truck.
The present invention provides, in one aspect, a power tailgate system for a vehicle. The power tailgate system includes an actuator for moving a tailgate of the vehicle between an open position and a closed position, and a spring spaced apart from the actuator for counter-balancing a weight of the tailgate. The power tailgate system also includes a coupler assembly movable relative to the tailgate between a locked position and an unlocked position. In the locked position, the actuator is secured to the tailgate. In the unlocked position, the tailgate is removable from the vehicle and the actuator.
The power tailgate system may further include an actuator arm assembly having a pin defining an axis of rotation and an arm having a first end rotatable about the pin. The actuator may be configured to rotate the first end of the arm about the pin, thereby moving the tailgate of the vehicle between the open position and the closed position.
The actuator may have a proximal end fitting attached to the vehicle and a distal end fitting coupled to a second end of the arm of the actuator arm assembly. The second end of the arm of the actuator arm assembly may pivot towards the proximal end fitting of the actuator when the tailgate moves to the open position. The second end of the arm of the actuator arm assembly may pivot away from the proximal end fitting of the actuator when the tailgate moves to the closed position.
The coupler assembly may include a body fixed to the tailgate and having a slot for receiving the pin of the actuator arm assembly.
The coupler assembly may include a collar slidable between a first position and a second position and in a direction parallel to the rotational axis defined by the pin of the actuator arm assembly. The collar may have a slot. The coupler assembly may further include a lever engagable with the slot of the collar. In the first position, the lever may engage the slot of the collar, thereby permitting removal of the tailgate from the vehicle.
The first end of the arm may include teeth. The teeth may be engagable with notches of the collar when the collar is in the second position, thereby preventing removal of the tailgate from the vehicle.
The power tailgate system may further include an electronic controller in electrical communication with the actuator and configured to receive a signal for opening the tailgate or a signal for closing the tailgate. The electronic controller may receive the signals for opening and closing the tailgate from a fob. The electronic controller may be configured to detect if the tailgate is coupled to the power tailgate system.
The present invention provides, in another aspect, a coupler assembly for removably attaching a tailgate to a vehicle. The coupler assembly includes a body fixed to the tailgate and having a slot for receiving a portion of the vehicle. The coupler assembly also includes a collar positioned about the body. The collar is movable between a first position permitting removal of the tailgate from the vehicle and a second position preventing removal of the tailgate from the vehicle.
The coupler assembly may further include a lever. The collar may include a slot engagable with the lever when the collar is located in the first position.
The lever may be movable, thereby allowing the collar to move between the first position and the second position. The lever may be movable by a spring.
The slot of the body may receive the portion of the vehicle when the collar is located in the second position. The collar may include notches for receiving a second portion of the vehicle when the collar is located in the second position.
Other features and aspects of the invention will become apparent by consideration of the following detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.
In the illustrated construction, the strut 12 has clevis endfittings 24, 28, in which the endfitting 24 proximal to the top side 16 of the box 8 is fastened or attached to the vehicle 1. In particular, the proximal endfitting 24 is fastened or attached to a rail 32 of the box 8 via a plate 36 of the strut 12 and fasteners 40 (
With continued reference to
As illustrated in
Additionally, the first end 80 of the drive arm 76 includes teeth 88 engageable with a coupler assembly 92 of the power tailgate system (
In some embodiments, a single coupler assembly 92 may be used for the quick disconnection or connection of the tailgate 4 to the box 8 of the truck 1. Such a single coupler assembly 92, when in the locked position, may be coupled or secured to the strut 12 via the actuator arm assembly 68 as described below in more detail. If a single coupler assembly 92 is used, then the vehicle 1 may include a slot for receiving a pin fixed or attached to the tailgate 4. Alternatively, the vehicle 1 may include the pin and the tailgate 4 may include the slot. This combination of the slot and pin may be located or positioned opposite of the coupler assembly 92 (i.e., such that the coupler assembly 92 and the combination of the slot and pin are located or positioned on opposite sides or ends of the tailgate 4). In still other alternative embodiments, another form of mechanically coupling or securing the tailgate 4 and the vehicle 1 may be used in place of the combination of the pin and slot.
In other embodiments, two coupler assemblies 92 may be used for the quick disconnection or connection of the tailgate 4 to the box 8 of the truck 1. The two coupler assemblies 92 may be located opposite one another, for example, on opposite sides of the box 8 of the truck 1 or on opposite ends or sides of the tailgate 4. The two coupler assemblies 92, when in the locked position, may be coupled or secured to respective struts 12 (via respective actuator arm assemblies 68) if the power tailgate system includes two struts 12. Alternatively, if the power tailgate system includes a single strut 12, one coupler assembly 92, when in the locked position, may be coupled or secured to the strut 12 while the other coupler assembly 92, when in the locked position, may be coupled or secured to a portion of the vehicle.
With reference to
The coupler assembly 92 also includes a collar 120 positioned about or encircling the cylinder 96, and having notches 124 located on an interior surface 128 thereof for receiving the teeth 88, 108 of the cylinder 96 and drive arm 76. The collar 120 is slidable or movable in a direction parallel to the rotational axis defined by the stationary pin 72. In other words, the collar 120 is slidable or movable between the tailgate 4 and the actuator arm assembly 68.
The collar 120 has slots 132, 133 on an exterior surface 136 thereof engagable with the lever 116 (
In an alternative embodiment, the collar 120 may include a single slot or notch and the lever 116 may extend from the cylinder 96 in the direction transverse to the rotational axis defined by the stationary pin 72. In this alternative embodiment, the slot of the collar 120 may engage the lever 116 when the collar 120 is in the first position (i.e., not engaging both teeth 88 and teeth 108), but upon removal of the lever 116 from the slot, the collar 120 may be slid to the second position and engage teeth 88, 108. In this alternative embodiment, the collar 120 is prevented from sliding back towards the tailgate 4 by the lever 116 extending from the cylinder 96 because the collar 120 abuts or backs into the lever 116.
In some embodiments of the coupler assembly 92, the lever 116 of the cylinder 96 can be actuated or moved by a spring such that applying a force against the spring bias allows the collar 120 to slide between the first position (i.e., the lever 116 is located within the distal slot 133 in the collar 120) and the second position (i.e., the lever 116 is located within the proximal slot 132 in the collar 120). In other embodiments, threads may replace the teeth 88, 108 on both the cylinder 96 and the drive arm 76 such that the collar 120 can be threaded or rotated between the first and second positions.
With reference to
The electronic controller 140 can be operable with a fob (e.g., remote keyless entry), and therefore, the electronic controller 140 can verify an identity of the fob and execute instructions provided by the fob, for example, opening or closing the tailgate 4 of the truck 1. In other embodiments, the electronic controller 140 can be operable with a switch to facilitate opening and closing of the tailgate 4. In still other alternative embodiments, two or more electronic controllers may be in electrical communication with each other and/or the strut 12 to facilitate opening and closing of the tailgate 4.
In some embodiments, the electronic controller 140 can include a latching routine that powers unlatching of the tailgate 4 from the box 8 of the truck 1 before powering the tailgate 4 open. Conversely, the latching routine can power the tailgate 4 closed before powering latching of the tailgate 4 to the box 8 of the truck 1. In other embodiments, the electronic controller 140 can include a falling tailgate routine that controls descent and/or ascent of the tailgate 4 when the tailgate 4 is powered open and closed, respectively. The falling tailgate routine can also control or cushion descent of the tailgate 4 when the tailgate 4 is manually opened by the user, thereby preventing the tailgate 4 from falling freely.
In still other embodiments, the electronic controller 140 can be configured to detect if the tailgate 4 is coupled or secured to the power tailgate system and/or the vehicle 1. In particular, the electronic controller 140 can include a tailgate detection routine that identifies whether the tailgate 4 is coupled or attached to the box 8 of the truck 1. When the tailgate 4 is removed from the box 8 of the truck 1, the tailgate detection routine powers down or shuts off the power tailgate system such that the strut 12 and actuator arm assembly 68 are maintained in the open position of the tailgate 4. Accordingly, when the tailgate 4 is reinstalled in the box 8 of the truck 1, the strut 12 and actuator arm assembly 68 are ready to power the tailgate 4 closed.
In operation of the powered tailgate system, the tailgate 4 is moved from the closed position to the open position when the electronic controller 140 receives the open tailgate signal. Particularly, the electronic controller 140 electrically communicates with the strut 12 to cause actuation of the strut 12, which in turn, causes the drive arm 76, including the second end 84 of the drive arm 76, to pivot towards the proximal endfitting 24 of the strut 12 (
When the electronic controller 140 receives the close tailgate signal, the electronic controller 140 electrically communicates with the strut 12 to cause actuation of the strut 12, which in turn, causes the drive arm 76, including the second end 84 of the drive arm 76, to pivot away from the proximal endfitting 24 of the strut 12, thereby powering the tailgate 4 closed (
In other embodiments, the electronic controller 140 can use the latching routine to determine if the tailgate 4 is latched and if so, powers unlatching of the tailgate 4 from the box 8 of the truck 1 before powering the tailgate 4 open. The electronic controller 140 can also use the latching routine to determine if the tailgate 4 is latched after the tailgate 4 is powered close, and if not, power latching of the tailgate 4 to the box 8 of the truck 1. The electronic controller 140 may further use the latching routine to determine if the tailgate 4 is latched after the tailgate 4 is manually closed, and if not, power latching of the tailgate 4 to the box 8 of the truck 1.
In still other embodiments, the electronic controller 140 can employ the tailgate detection routine to determine if the tailgate 4 is coupled to the box 8 of the truck 1, and if not, the tailgate detection routine shuts off the power tailgate system. When the tailgate 4 is attached to the box 8 of the truck 1, the tailgate detection routine detects the presence of the tailgate 4, and then activates the power tailgate system, allowing the tailgate 4 to be powered between the open and closed positions.
Although the invention has been described in detail with reference to certain preferred embodiments, variations and modifications exist within the scope and spirit of one or more independent aspects of the invention as described.
This application claims priority to U.S. Provisional Patent Application No. 61/817,723, filed Apr. 30, 2013, the entire content of which is incorporated herein by reference.
Number | Date | Country | |
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61817723 | Apr 2013 | US |