Exemplary embodiments of the present invention are generally related to closure manipulating systems. More particularly, in some exemplary embodiments, the present invention provides a power closure system for use on a tailgate.
During use, an owner of a pickup truck is required to repeatedly open and close the tailgate of his or her pickup truck to provide selective access to the cargo area of the truck. In particular instances, the user may be required to remove the tailgate from the truck so as to provide the necessary accommodations for larger loads. In modern truck designs, compromises must be struck to permit the installation of ever-greater number and types of features in the truck while still maintaining the ease of use the earlier designs contained.
In one embodiment, the present invention provides a tailgate drive for use with a tailgate in a cargo bed of a pickup truck, the cargo bed having a first hinge bracket and a second hinge bracket, and the tailgate defining a volume therein. The tailgate drive includes a counterbalance assembly positioned within the volume of the tailgate and removably coupled to one of the first hinge bracket and the second hinge bracket, and a motor assembly positioned within the volume of the tailgate and removably coupled to one of the first hinge bracket and the second hinge bracket, the motor assembly operable to rotate the tailgate with respect to the cargo bed between an opened position and a closed position.
In another embodiment, the present invention provides a tailgate drive for use with a tailgate positioned in a cargo bed of a motor vehicle, the cargo bed having a first hinge bracket and a second hinge bracket coupled thereto, and the tailgate is rotatable about an axis with respect to the cargo bed between an open position and a closed position, where the axis is at least partially defined by the first hinge bracket and the second hinge bracket, and the tailgate defines a volume therein. The tailgate drive includes a motor assembly positioned within the volume of the tailgate and operatively coupled to one of the first hinge bracket and the second hinge bracket, the motor assembly operable to rotate the tailgate about the axis between the opened position and the closed position.
In another embodiment, the present invention provides a tailgate drive for use with a tailgate positioned in a cargo bed of a motor vehicle, the cargo bed having a first hinge bracket and a second hinge bracket coupled thereto, the tailgate defining a volume therein and being rotatable with respect to the cargo bed between an opened position and a closed position. The tailgate drive includes a motor assembly in operable communication with the tailgate and adjustable between a manual mode of operation and an automatic mode of operation, where the motor assembly permits free rotation of the tailgate between the open and closed positions during manual mode of operation and wherein the motor assembly drives the tailgate body between the open and closed position during the automatic mode of operation.
Other objects, features, advantages and details appear, by way of example only, in the following detailed description of embodiments, the detailed description referring to the drawings in which:
Illustrated in
The cargo bed 10 also includes a second hinge bracket 62 coupled to the second side wall 38, opposite the first hinge bracket 46, and positioned proximate the closure frame 22. The second hinge bracket 62 includes a mounting plate 66 secured to the second side wall 38 by one or more fasteners 55, and a hinge cup 70 (
The second hinge bracket 62 of the present invention may also include a bell crank assembly 82 rotatable with respect to the second hinge bracket 62 and in operable communication with a damper (not shown) for example a spring, a gas strut, a fluid strut, a reverse driver, and the like. In the illustrated embodiment, the bell crank assembly 82 includes a rotatable shaft 86 passing perpendicularly through the second hinge bracket 62, and a crank arm 90 extending radially from a distal end 94 of the shaft 86. In the illustrated embodiment, the damper is coupled to a distal end 98 of the crank arm 90 (see
When the tailgate 26 is installed in the cargo bed 10, the shaft 86 of the bell crank assembly 82 is configured to engage and rotate with the tailgate 26 such that the shaft 86 and crank arm 90 transmit the rotation of the tailgate 22 to the damper. As such, the damper limits the rotational speed of the tailgate 26 with respect to the closure frame 22 by providing dampening forces in response to tailgate 26 movements.
Illustrated in
Illustrated in
The tailgate 26 also includes a first corner bracket 138 coupled to the tailgate 26 proximate the lower-right corner. The first corner bracket 138 is substantially L-shaped having a first leg 142 in contact with the bottom wall 118 of the tailgate 26 and a second leg 146 in contact with the right wall 122 of the tailgate 26. In the illustrated embodiment, the first corner bracket 138 is coupled to the tailgate 26 with one or more fasteners 55. The corner bracket 138 is configured to provide additional rigidity and strength to the tailgate 26 while also providing a foundation for additional mounting elements.
The first corner bracket 138 also includes a hinge member 150 coupled to the second leg 146 of the first corner bracket 138 and extending outwardly therefrom. The hinge member 150 is substantially annular in shape having a first open end 154 sized to receive at least a portion of a coupler 158 therein (described below), and a second open end 162 extending opposite the first open end 154. In the illustrated embodiment, the first open end 154 forms an inner diameter that is larger than the inner diameter of the second open end 162. When the tailgate 26 is assembled, a coupler 158 is positioned within and able to rotate with respect to both the first corner bracket 138 and the hinge member 150. Although not shown, the hinge member 150 also defines an aperture formed in the wall of the first open end 154 to permit the introduction and removal of the hinge lug 58 into the coupler 158.
The tailgate 26 also includes a second corner bracket 166 positioned proximate the lower, left-hand corner of the tailgate 26 opposite the first corner bracket 138. Similar to the first corner bracket 138, the second corner bracket 166 is substantially L-shaped having a first leg 170 in contact with the bottom wall 118 of the tailgate 26 and a second leg 174 in contact with a left-side wall 126 of the tailgate 26.
The second corner bracket 166 also includes a substantially cylindrical hinge lug 178 extending outwardly from the second leg 174 of the bracket. When the tailgate 26 is installed in the cargo bed 10, the hinge lug 178 is at least partially received within the hinge cup 70 of the second hinge bracket 62 (described above).
Together, the hinge member 150 of the first corner bracket 138 and the hinge lug 178 of the second corner bracket 166 define an axis of rotation 182 extending substantially lengthwise along the tailgate 26 proximate the bottom wall 118. During use, the tailgate 26 pivots about this axis 182 between the open and closed positions.
The tailgate 26 also includes a latch mechanism (not shown) to secure the tailgate 26 in the closed position. During use, the latch mechanism may be released both manually, via the use of a handle (not shown), or automatically, by receiving a signal from a control unit (described below).
The tailgate 26 also includes a torque bar system 190 configured to act as a counterbalance for the weight of the tailgate 26 as it moves between the open and closed positions. The torque bar system 190 includes a torque bar 194 having a first end 198 and a second end 202 opposite the first end 198, a coupler 158 fixedly coupled to the first end 198 of the torque bar 194, and an anchor block 206 fixedly coupled to the second end 202 of the torque bar 194. During use, the rotational motion of the tailgate 26 with respect to the closure frame 22 is transmitted to the torque bar 194 which, through torsion, creates torque acting about the axis of rotation 182 opposite the moment created about the axis 182 by the weight of the tailgate 26. As such, the two forces at least partially cancel each other out, reducing the amount of force that is required to rotate the tailgate 26 between the opened position and the closed position.
The torque bar 194 of the torque bar system 190 includes a substantially elongated metallic bar having a first end 198 and a second end 202 opposite the first end 198. During use, the torque bar 194 produces torque by way of torsion when the first end 198 of the bar is rotated with respect to the second end 202 of the bar. For example, as the first end 198 of the torque bar 194 is rotated in a clockwise direction with respect to the second end 202, the bar 194 produces a torque in the counter-clockwise direction resisting the twisting motion. The further the first end 198 of the torque bar 194 is rotated with respect to the second end 202, the greater the magnitude of the torque produced. In the illustrated embodiment, both the first end 198 and the second end 202 of the torque bar 194 include a key surface 210. When assembled, the keyed surfaces 210 are configured to engage with and rotationally lock the first end 198 and the second end 202 of the torque bar 194 with the coupler 158 and anchor block 206, respectively. While the illustrated construction includes a flattened surface on an otherwise cylindrical bar, additional shapes of key surfaces may be used such as splines, keyways, locking pins, and the like.
The coupler 158 of the torque bar system 190 is configured to fix the first end 198 of the torque bar 194 with respect to the cargo bed 10 via the first hinge bracket 46. The coupler 158 is substantially cylindrical in shape having a first portion 214 defining a first outer diameter and a second portion 218 extending axially from the first portion 214 to define a second outer diameter smaller than the first outer diameter. More specifically, the first outer diameter is configured to substantially correspond to the inner diameter of the first open end 154 of the hinge member 150 and the second outer diameter is configured to substantially correspond to the inner diameter of the second open end 162 of the hinge member 150. The size and shape of the coupler 158 allows the hinge member 150 to rotate with respect to the coupler 158 while providing the necessary support for the tailgate 26 within the closure frame 22 of the cargo bed 10.
Best illustrated in
The second portion 218 of the coupler 158 also includes a plurality of exterior splines 226 sized and shaped to be at least partially received within and mesh with the interior splines 230 of the collar 234 (described below). When assembled, the splines 230 cause the coupler 158 and the collar 234 to rotate together as a unit. Although splines are provided, alternative embodiments may utilize other ways of rotationally keying the coupler 158 and the collar 234.
Also illustrated in
The slot 238 may also include an open end (not shown) to allow the hinge lug 58 to slide radially into and out of the slot 238. More specifically, the coupler 158 is configured such that, when no load is being placed on the torque bar 194, the open end of the slot 238 and the aperture of the hinge member 150 align allowing the hinge lug 58 to be radially introduced into and removed out of the slot 238.
Illustrated in
To install the tailgate 26 on the cargo bed 10, the user axially introduces the hinge lug 178 of the tailgate 26 into the hinge member 70 of the second hinge bracket 62. Once the hinge lug 178 is partially received therein, the user begins to pivot the tailgate body 26 until the hinge lug 58 of the first hinge bracket 46 aligns with the aperture of the hinge member 150 and the open end 242 of the slot 238. The user then radially introduces the lug 58 into the slot 238.
Once the lug 58 is positioned within the slot 238, the user is free to rotate the tailgate 26 about the axis 182 between the open and closed positions. If present, the user may also attach support straps (not shown) to help limit the extent of rotation allowed.
To remove the tailgate 26 from the cargo bed 10, the user rotates the tailgate 26 until the open end 242 of the slot 238 aligns with the aperture of the hinge member 150. The user then manipulates the body of the tailgate 26 until the lug 58 is radially removed from the slot 238. Once the lug 58 is removed from the slot 238, the user may axially remove the hinge lug 178 from the hinge cup 70.
In particular, the tailgate 26 of the present invention may be installed and removed without tools as is typically done in the art. As such, the present invention permits the tailgate to be removed and installed as is typically done in the art—while providing powered lift assist—without any major modifications or the need for tools and the like.
Illustrated in
The powered closure system 14 of the present invention includes a motor assembly 250, a collar 234 driven by the motor assembly 250, and an electric control module (ECM) 254 operable to control the operation of the motor assembly 250. The ECM 254 is positioned within the volume 110 of the tailgate 26 and is coupled to the vehicle's electrical system through a detachable cable junction or umbilical (not shown). During use, the motor assembly 250 drives an output pinion 258 which in turn drives the collar 234 causing the tailgate 26 to rotate about the axis 182. The powered closure system 14 of the present invention automatically rotates the tailgate 26 between the opened position and the closed position and is operable in both a manual and automatic mode.
Illustrated in
The motor assembly 250 also includes an electromagnetic clutch 274 positioned between the output pinion 258 and the motor 262 and operatively connecting the two elements. Specifically, the clutch 274 is operable in an engaged configuration, where torque is transmitted between the motor 262 and the output pinion 258, and a disengaged configuration, where torque is not transmitted between the motor 262 and the output pinion 258. During use, the clutch 274 defaults to the disengaged configuration (e.g., when the clutch 274 is not energized) allowing the user to manually open and close the tailgate 26 without the added forces involved in backdriving the motor 262 and planetary gears 270. Similar to the motor 262, the clutch 274 is in electrical communication with the ECM 254 which in turn provides the necessary signals to determine when the clutch 274 is in the engaged and disengaged configurations.
The motor assembly 262 also includes a position sensor 278 operable to record the position of the tailgate 26 with respect to the closure frame 22. In the illustrated embodiment, the position sensor 278 is a Hall Effect sensor; however, in alternative embodiments other types of position sensors may be used. The position sensor 278 is positioned between the clutch 274 and the output pinion 258 so that the position sensor 278 will not lose its position when the clutch disengages from the motor 262. As such, the position sensor 278 is able to record the location of the tailgate 26 regardless of whether the system 14 is operating in a manual mode or an automatic mode and regardless of whether the clutch 274 is in the engaged configuration or disengaged configuration. The position sensor 278 is in electrical communication with the ECM 254.
The motor assembly 262 also includes an abusive slip device 282 positioned between the motor 262 and the output pinion 258 and configured to disengage when an abusive or excessively large force propagates through the assembly 14. The slip device 282 operates separately from the clutch 274 being configured to release (e.g., stop the transmission of torque) based on the forces within the system rather than the mode of operation. During use, the slip device 282 is configured to protect the clutch 274, motor 262, and gear sets 270 from potential damage by disengaging the torque transfer between the output pinion 258 and those elements when the forces exceed a predetermined limit.
The motor assembly 250 also includes an output pinion 258 selectively driven by the motor 262 and meshingly engaging a section gear 286 coupled to the collar 234 (described below). During use, the output pinion 258 transmits the torque provided by the motor 262 and transmitted by the clutch 274 to the section gear 286 which ultimately causes the tailgate 26 to rotate about the axis 182. In the illustrated embodiment, the output pinion 258 is a spur gear; however, in alternative embodiments the torque may be transmitted in alternative forms, such as by belt, helical gears, and the like.
Illustrated in
The collar 234 also includes a section gear 298 rotationally fixed thereto. When assembled, the section gear 298 is configured to meshingly engage with the output pinion 258 of the motor assembly 250 allowing the transfer of torque therebetween. In the illustrated embodiment, the section gear 298 only extends over a 90 degree arc to conserve space within the volume 110 of the tailgate 26; however, in alternative embodiments an entire gear may be used.
During normal operation, the closure system 14 will default in the manual mode of operation. In the manual mode of operation, the clutch 274 is in the disengaged configuration isolating the motor 262 and planetary gears 270 from the output pinion 258. As such, the user may operate the tailgate 26 in the typical fashion, manually pivoting the tailgate between the open and closed positions, about the axis 182, without the added burden of backdriving the motor 262 and gears 279. Furthermore, given the location of the clutch 274, the position sensor 278 remains engaged with the output pinion 258 and continues to track the location of the tailgate 26 with respect to the closure opening 22. Further still, the counterbalance forces provided by the torque bar system 190 and the bell crank assembly 82 will continue to operate normally while the closure system 14 is in the manual mode of operation.
To operate the closure system 14 in the automatic mode of operation, the user first provides an input, such as pressing a button on a key FOB, lifting the tailgate handle (not shown), and the like. The input is received by the ECM 254 which in turn sends a signal to the motor 262 causing it to begin rotating the drive spindle 266 in a second direction. At the same time, the ECM 254 instructs the clutch 274 to switch from the disengaged configuration to the engaged configuration, allowing the transmission of torque between the motor 262 and the output pinion 258. The output pinion 258 transmits the torque through the section gear 298 to the collar 234, which in turn transmits the torque to the cargo bed 10 via the first hinge bracket 46. As such, the tailgate 26 begins to rotate about the axis 182 toward the closed position as the motor 262 turns in the second direction.
As the tailgate 26 rotates, the ECM continues to receive position information regarding the location of the tailgate 26 from the position sensor 278. The ECM continues to instruct the motor 262 to rotate until the tailgate 26 reaches the closed position. With the tailgate 26 in the closed position, the ECM shuts off the motor 262, and instructs the clutch 274 to return to the disengaged (e.g., manual mode) configuration. From the closed position, the user may return the tailgate 26 to the opened position by providing another input to the ECM 254. By doing so, the above steps will be repeated only with the motor 262 rotating in the first direction, causing the tailgate 26 to pivot in the opposite direction toward the opened position.
With reference to FIGS. 14 and 17-23, the tailgate 318 includes a first corner bracket 322 coupled to the tailgate 318 proximate a lower-right corner of the tailgate 318. The first corner bracket 322 is substantially L-shaped having a first leg 326 in contact with a bottom wall 330 of the tailgate 318 and a second leg 334 in contact with a right wall 338 of the tailgate 318. In the illustrated construction, the first corner bracket 322 is coupled to the tailgate 318 with one or more fasteners 342. The corner bracket 322 is configured to provide additional rigidity and strength to the tailgate 318 while also providing a foundation for additional mounting elements.
With reference to
With reference to
With reference to
The tailgate 318 further includes a second corner bracket (not shown) positioned proximate a lower, left-hand corner of the tailgate 318 opposite the first corner bracket 322. Similar to the first corner bracket 322, the second corner bracket is substantially L-shaped having a first leg in contact with the bottom wall 330 of the tailgate 318 and a second leg in contact with a left-side wall of the tailgate 318.
As with the embodiment illustrated in
Together, the opening 346 of the first corner bracket 322 and the hinge lug of the second corner bracket define an axis of rotation 378 (see
Similar to the tailgate 26, the tailgate 318 also includes a latch mechanism (not shown) to secure the tailgate 318 in the closed position. During use, the latch mechanism may be released both manually, via the use of a handle (not shown), or automatically, by receiving a signal from a control unit.
With reference to
The torque bar system 382 further includes an anchor block (not shown) fixedly coupled to the second end of the torque bar 386 (e.g. via keyed surfaces), similar to the anchor block 206 in
During use, the torque bar 386 produces torque by way of torsion when the first end 390 is rotated with respect to the second end. For example, as the first end 390 of the torque bar 386 is rotated in a clockwise direction with respect to the second end, the torque bar 386 produces a torque in a direction resisting the twisting motion. The further the first end 390 of the torque bar 386 is rotated with respect to the second end, the greater the magnitude of the torque produced.
With reference to
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With reference to FIGS. 15 and 18-21, the powered closure system 314 includes a motor assembly 434 (e.g., the same motor assembly as motor assembly 250 in
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The torque bar 620 of the torque bar system 618 includes a substantially elongated metallic bar having a first end 624 and a second end 628 opposite the first end 624. As described above, the torque bar 620 produces torque by way of torsion when the first end 624 of the bar is rotated with respect to the second end 628 of the bar. In the illustrated embodiment, both the first end 624 and the second end 628 of the torque bar 620 include a key surface 640. When assembled, the keyed surfaces 640 are configured to engage with and rotationally lock the first end 624 and the second end 628 of the torque bar with the coupler 632 and the anchor block 636, respectively.
With reference to
The first portion 644 of the coupler 632 is disposed outside the first corner bracket 138′ and configured to engage the first hinge bracket 46′ of the cargo bed 10′. In the illustrated construction, the first portion 644 of the coupler 632 defines a recess 652 shaped such that the first hinge bracket 46′ may be axially inserted therein. Once inserted, the corresponding shapes of the recess 652 and bracket 46′ cause the first hinge bracket 46′ and the coupler 632 to be rotationally fixed.
Best illustrated in
Illustrated in
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Illustrated in
Similar to the motor 676, the first clutch 680 is in electrical communication with an ECM which in turn provides the necessary signals to determine when the first clutch 680 is in the engaged and disengaged configurations. As discussed previously, the engaged and disengaged configurations of the first clutch 680 corresponds to the manual and automatic modes of operation—which operate the same as described above.
The second clutch 688 of the motor housing 668 includes an abusive slip device positioned between the first clutch 680 and the output shaft 696. During use, the second clutch 688 is configured to disengage when an abusive or excessively large force propagates through the motor assembly. The second clutch 688 operates separately from the first clutch 680, being configured to release based on the forces within the system (i.e., at a set torque amount) rather than the mode of operation. In the illustrated construction, the second clutch 688 is set to a torque load release point slightly above the maximum torque needed to open and close the tailgate during normal operation.
The motor housing 668 also includes a rotary hydraulic damper 700 that is operably to the output shaft 696. During use, the rotary hydraulic damper 700 applies dampening forces to the output shaft 696 to help regulate the movement of the tailgate 26′ with respect to the cargo bed 10′. In some constructions, the damper 700 may be used in lieu of an external damper (described above). In other embodiments, the damper 700 may be combination with an external damper. In the illustrated construction, the damper 700 is operatively coupled to the output shaft 696 such that regardless of whether the first or second clutches 680, 688 disengage, the fluid damper 700 will always be able to provide a dampening effect to the motion of the tailgate 26′. This is particularly useful in loss of power or manual opening situations.
In the illustrated construction, the fluid damper 700 provides a dampening force over the entire travel arc of the tailgate 26′ (i.e., from open to close). However, in alternative embodiments, the fluid damper 700 may be configured such that it only provides a dampening force over a portion of the overall travel arc of the liftgate 26′. For example, in some embodiments, the damper 700 may only provide dampening forces over the final 5 to 15 degrees of travel before the tailgate 26′ reaches the end of it's travel arc. In another embodiment, the damper 700 may only provide dampening forces over the final 15 to 20 degrees of travel. In such embodiments, the damper 700 may provide reduced or no dampening forces over the remainder of the travel arc. In still other embodiments, the damper 700 may provide dampening forces at one or both extents of travel (i.e., near full open and/or near full close). In still other embodiments, the damper 700 may only provide dampening forces when the tailgate 26 is traveling in a particular direction (i.e., when the tailgate 26 is being opened, but not when being closed).
The motor housing 668 also includes position sensor 704 to record the position of the tailgate 26 with respect to the closure frame 22.
The powered closure system also includes a drive shaft 672 operatively coupling the motor housing 668 and the second hinge bracket 62′ to transmit torque therebetween. In the illustrated construction, the drive shaft 672 extends through the second corner bracket 166′ and includes a first end 708, positioned outside the volume 110′ of the tailgate 26′, and a second end 712 positioned inside the volume 110′ of the tailgate 26′.
In the illustrated construction, the first end 708 of the drive shaft 672 forms a lug that is sized and shaped to be at least partially received within the second hinge bracket 62′ of the cargo bed 10′. The first end 708 is substantially rectangular in shape such that the drive shaft 672 is rotationally fixed with respect to the second hinge bracket 62′ and the cargo bed 10′. During use, the first end 708 of the drive shaft 672 may be radially inserted into and removed from the second hinge bracket 62′.
With reference to
While exemplary embodiments have been described and shown, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed as the best mode contemplated for carrying out this invention.
This application claims priority to co-pending U.S. Provisional Patent Application Nos. 62/012,881 filed on Jun. 16, 2014; 62/089,915 filed on Dec. 10, 2014; and 62/121,270 filed on Feb. 26, 2015. The entire contents of each application is hereby incorporated by reference.
Number | Date | Country | |
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62012881 | Jun 2014 | US | |
62089915 | Dec 2014 | US | |
62121270 | Feb 2015 | US |