Patent Grant
11585137
The present disclosure relates to a motorized vehicle for transporting one or more passengers, and more particularly to a motorized vehicle which is retrofitted for transporting one or more physically limited passengers seated in a wheelchair.
Automobile manufacturers do not currently mass-produce passenger vehicles specifically designed to transport passengers having physical limitations, either as a driver or as a non-driving passenger. Consequently, mass-produced passenger vehicles are modified, or retrofitted, by a number of aftermarket companies dedicated to supplying vehicles to physically limited passengers. Such vehicles can be modified by removing certain parts or structures within a vehicle and replacing those parts with parts specifically designed to accommodate the physically limited passenger. For example in one configuration, a van may be retrofitted with a ramp to enable a physically limited individual using a wheelchair to enter the vehicle without the assistance of another individual.
Other known level change devices for retrofitting a vehicle, such as a van, include wheelchair lifts, lift platforms, and lowered floor surfaces. In some instances, a door of an original equipment manufacturer (OEM) van is enlarged or otherwise modified to permit entry of the physically limited individual through what is known as the assisted entrance. Once inside the vehicle, individuals who use the assisted entrance are often located in a rear passenger compartment of the vehicle adjacent to or behind the assisted entrance.
Many motorized vehicles modified to include a ramp or lift for transporting physically limited passengers are passenger vans or buses. Minivans, or passenger vans, are often referred to as multi-purpose vehicles (HPVs), people movers, or multi-utility vehicles. At least in the United States, minivans are classified as light trucks or MPVs. In many instances, these vans have rear access doors on each side thereof that, when opened, define a door opening that can provide easy ingress and egress of a wheelchair.
Crossover and sport-utility vehicles have become popular due to their style and driving performance. Sport-utility vehicles are built off a light-truck chassis similar to passenger vans, whereas crossover or crossover utility vehicles are built from a passenger car chassis. Due to their build, crossover vehicles are often more fuel efficient than heavier, sport-utility vehicles and include other advantages over minivans and sport-utility vehicles.
In a first embodiment of the present disclosure, a door opening assembly is provided for moving a vehicle door of a motorized vehicle between an open position and a closed position. The assembly includes a frame member configured to be coupled to a body of the vehicle; a link operably coupled to the frame member; a link arm comprising a pin, the link arm pivotally coupled to the link; a pivot arm pivotally coupled to the frame member; a pivot bracket pivotally coupled to the door and the pivot arm, the pivot bracket further defining a slot having a first end and a second end; a gear rack comprising a plurality of teeth, the gear rack including a first end and a second end; a gear operably coupled to the gear rack, the gear operably driven between the first and second ends of the gear rack as the door moves between its open and closed positions; a guide track configured to be coupled to the body of the vehicle; and a plurality of rollers rotatably driven along the guide track as the door moves between its open and closed positions; wherein, as the door moves between its open and closed positions, the pin moves within the slot between the first end and the second end.
In a first example of this embodiment, the pivot arm is pivotally coupled to the frame member about a first pivot axis; and the pivot bracket is pivotally coupled to the pivot arm about a second pivot axis, wherein the first pivot axis is parallel to but spaced from the second pivot axis. In a second example, the pivot bracket is pivotally coupled to a mounting bracket about a third pivot axis, the third pivot axis being parallel but offset from the first and second pivot axes. In a third example, the gear rack comprises a substantially S-shaped curvature.
In a fourth example, the gear rack comprises a length defined between its first end and its second end, the gear rack comprising a first arc portion, a second arc portion, and a substantially linear portion. In a fifth example, the gear rack comprises a first vertex, a second vertex, and an inflection point located therebetween; wherein the first arc portion is defined between the first end of the gear rack and the inflection point; the second arc portion is defined between the inflection point and the substantially linear portion; the substantially linear portion defined between the second end of the gear rack and the second arc portion.
In a sixth example of this embodiment, the guide track comprises a shape substantially the same as the gear rack. In a seventh example, the plurality of rollers comprises a first roller and a pair of second rollers, the first roller having a larger diameter than each of the pair of second rollers. In an eighth example, the first roller is rotatable about a first rotation axis; a first of the pair of second rollers is rotatable about a second rotation axis; a second of the pair of second rollers is rotatable about a third rotation axis; the first rotation axis being oriented substantially perpendicular to the second and third rotation axes.
In another example of this embodiment, in the closed position, the pin is located at the first end of the slot and the gear is located at the first end of the gear rack; in the open position, the pin is located at the second end of the slot and the gear is located at the second end of the gear rack. In yet another example, during movement of the door from its closed position to its open position, the gear moves from the first end of the gear rack to an intermediate position; wherein, in the closed position, the door is positioned along a door frame axis; wherein, in the intermediate position, the door is positioned at an angle relative to the door frame axis; wherein, in the open position, the door is positioned substantially parallel to but offset from the door frame axis. In a further example, a first distance defined between the first end and the intermediate position of the gear rack is shorter than a second distance defined between the intermediate position and the second end of the gear rack.
In another embodiment of the present disclosure, a door opening assembly is provided for moving a vehicle door of a motorized vehicle between an open position and a closed position. The assembly includes a first assembly comprising a frame member configured to be coupled to a body of the vehicle; a link operably coupled to the frame member; a link arm comprising a pin, the link arm pivotally coupled to the link; a pivot arm pivotally coupled to the frame member; and a pivot bracket pivotally coupled to the door and the pivot arm, the pivot bracket further defining a slot having a first end and a second end; wherein, as the door moves between its open and closed positions, the pin moves within the slot between the first end and the second end; a second assembly comprising a gear rack comprising a plurality of teeth, the gear rack including a first end and a second end; a gear operably coupled to the gear rack, the gear operably driven by a motor between the first and second ends of the gear rack as the door moves between its open and closed positions; a guide track configured to be coupled to the body of the vehicle; and a plurality of rollers rotatably driven along the guide track as the door moves between its open and closed positions; and a control system for operably controlling the motor, the control system including a controller; wherein, the controller is configured to receive a communication from a user control to operably drive the motor to move the door from its open and closed positions.
In one example of this embodiment, a second motor operably controls pivotal movement of the pivot arm or pivot bracket, the second motor operably driven by the controller. In a second example, a sensor is in communication with the controller, the sensor configured to detect a location of the pin relative to the first and second ends of the slot. In a third example, a sensor is in communication with the controller, the sensor configured to detect a location of the gear relative to the first and second ends of the gear rack. In a fourth example, a sensor is in communication with the controller, the sensor being configured to detect a location of at least one of the plurality of rollers relative to the guide track.
In a fifth example, a ramp assembly is operably coupled to the body of the vehicle; a sensor in communication with the controller, the sensor configured to detect a position of the ramp assembly relative to the body of the vehicle. In a sixth example, the controller operably disables the motor when the sensor communicates to the controller that the ramp assembly is in a deployed position.
In a further embodiment of the present disclosure, a method is provided of controlling movement of a vehicle door from a closed position to an open position such that the vehicle door is operably coupled to a body of a motorized vehicle. The method includes providing the vehicle door with a door opening assembly comprising a frame member coupled to the body of the vehicle, a link, a link arm including a pin, a pivot arm, a pivot bracket having a slot, a gear rack, a gear, a motor, a guide track, a plurality of rollers, and a controller; in the closed position, positioning the pin at a first end of the slot, the gear at a first end of the gear rack, and the plurality of rollers at a first end of the guide track; releasing a latch of the door from the body of the motorized vehicle; driving the motor by the controller to pivot the door from the closed position to a partially open position, where in the partially open position the gear is at an intermediate position and the pin is located between the first end and a second end of the slot; and driving the motor by the controller from the partially open position to the open position, where in the open position the gear is at a second end of the gear rack, the pin is at the second end of the slot, and the plurality of rollers are located at a second end of the guide track.
The above-mentioned aspects of the present disclosure and the manner of obtaining them will become more apparent and the disclosure itself will be better understood by reference to the following description of the embodiments of the disclosure, taken in conjunction with the accompanying drawings, wherein:
Corresponding reference numerals are used to indicate corresponding parts throughout the several views.
The embodiments of the present disclosure described below are not intended to be exhaustive or to limit the disclosure to the precise forms disclosed in the following detailed description. Rather, the embodiments are chosen and described so that others skilled in the art may appreciate and understand the principles and practices of the present disclosure.
As shown in
As shown, a first or front passenger side door 108 is located between the front wheels 104 and rear wheels 106 and provides access to a passenger for sitting in a front seat of the vehicle 100 adjacent to the driver. In this position, the passenger has a clearer forward view of the road when compared to sitting in a middle row or back row of seats of the vehicle 100. Moreover, when seated, the passenger may be facing in a forward direction of travel 122.
In its conventional arrangement, the vehicle 100 of
These conventional hinge-style doors are inconvenient, however, when the passenger entering or exiting the vehicle is physically limited and/or in a wheelchair. The door opening is often not wide enough, or if it is, the door does not open wide enough to accommodate a ramp for a wheelchair. For this reason, many vehicles that can accommodate a wheelchair ramp are built on a larger vehicle chassis such as a bus or van. Vehicles such as sport-utility vehicles and the like are often unable to accommodate a ramp or wheelchair from a side door. Thus, there is a need for a modified vehicle, and in particular a modified door, to accommodate a wheelchair ramp and physically limited passenger. To do so, the rear door 110 of the vehicle 100 may be modified according to the principles and teachings of the present disclosure such that the door 110 moves in a generally forward and rearward direction indicated by arrow 120.
Referring to
The front side 202 may include a first latch 238 and a second latch 240. The first latch 238 may engage a first striker (not shown) on the door frame (not shown) of the vehicle 100 in a closed position, and the second latch 240 may engage a second striker (not shown) in the closed position. The first and second strikers may take many forms, but for sake of this disclosure, each striker is configured to engage the first and second latches on the door to couple the door to the frame in the closed position. It is noted that the conventional door hinges are removed from the door 110 during the modification process and replaced by the first latch 238 and second latch 240. Moreover, the strikers may be mounted to the door frame in any conventional manner.
While the present disclosure describes the use of latches in the form of the first latch 238 and second latch 240, other embodiments may utilize a hook or guide in place of either or both latches. The hook or guide may further assist with guiding the door 110 along its intended motion or profile when moving into a closed position. Moreover, these may provide a pivot point to complete the door closing process. Other similar coupling devices may be used besides a latch, hook, or guide when coupling the door to the vehicle or door frame in the closed position.
The door 110 may be further modified by providing a frame member 206 that may include a base 406 (
The door opening assembly may further include a link 210 coupled to the frame member 206. The link 210 includes a first end coupled to the frame member 206 and a second end to a link arm 418 (see
The frame member 206 is designed to be coupled to a pivot arm 212 about the pivot axis A-A. The pivot arm 212 may include an upper arm and a lower arm spaced vertically from one another. Each of the upper arm and lower arm is coupled to a vertical portion that is coupled to the frame member 206 and aligned along the pivot axis A-A. As shown in
The pivot bracket 216 may also define a slot 218 in a portion thereof. The slot 218 is arcuate in shape and is configured to receive a pin 220 that is coupled to or integrally formed with the link arm 418. The pin 220 is configured to travel through the slot 218 as the door 110 moves between its open and closed positions. As shown in
A second portion of the door opening assembly is also shown in
The gear 228 may be driven by a motor 222 or actuator. The motor 222 may be an electrical, mechanical, hydraulic, or a combination thereof. Alternatively, the motor 222 may be another type of conventional motor for operably driving the gear 228. The motor 222 may include an output coupled to a cable 224 or link for operably rotating the gear 228 and driving it to move along the gear rack 230 between the first and second ends. The motor 222 may be coupled to the inner surface 200 of the door 110, and the cable 224 and gear 228 may be coupled to a bracket 226 as shown in
Referring to
As shown in
The guide track and roller assembly 900 may also include a plurality of rollers that slidingly engage and move about the guide track 902. The plurality of rollers may include a first roller 920 and a pair of second rollers 922. The first roller 920 may include a larger diameter than the pair of second rollers. Moreover, the first roller 920 may rotate about a first rotation axis 1010 (
The guide track and roller assembly 900 may further include an arm assembly 912. The arm assembly 912 may include a support member 926 coupled thereto via one or more fasteners 1008. The cable 924 and gear 928 may also be coupled to the arm assembly 912, and in particular to an arm portion 1006 as shown in
The plurality of rollers may be operably coupled to the arm assembly 912 via a bracket 914. The bracket 914 may include a first finger 1000 spaced from a second finger 1002, as shown in
The bracket 914 may include a flange 918 that depends vertically downwardly as shown in
In use, the first roller 920 may rotate along the lower surface 904 of the guide track 902. The pair of second rollers 922 may rotate along the first side surface 908 and the second side surface 910. As the door 110 moves between its open and closed positions, the pair of second rollers 922 roll or rotate along the first and second side surfaces as the first roller 920 rolls or rotates along the lower surface 904.
As described above, the guide track 902 may include a substantially identical curvature as the gear rack 230 to allow the gear 228 to move about the gear rack 230 as the rollers 920, 922 move about the guide track 902.
The gear rack 230 is designed in a circuitous manner as shown in
The door opening assembly of
In the closed position, the ramp assembly 300 is in its stowed position. The door 110 may block or at least partially obstruct movement of the ramp assembly 300 in either the deploying or stowing direction 304. The ramp assembly 300 may be located within a cavity or opening below a floor of the vehicle. Alternatively, the ramp assembly 300 may be removable from the vehicle 100, stowed in any location within the vehicle, and then manually coupled to the vehicle to facilitate the movement of a wheelchair into and out of the vehicle.
While
In
In the closed position, the pin 220 may be disposed at or near the second end 422 of the slot 218. This is best shown in
In
As shown, the distance between the first end 232 of the gear rack 230 to the intermediate position 606 may be referred to as a first distance, and the distance between the intermediate position 606 and the second end 234 may be referred to as a second distance. In one example, the second distance is at least twice the first distance. In another example, the second distance is at least three times the first distance. In a further example, the second distance is at least four times the first distance. In yet a further example, the second distance is at least five times the first distance. In yet another example, the second distance may be at least 5-10 times the first distance.
In any event, in the partially open position 600, the gear 228 may be located at or near the first vertex 402 as shown in
As shown in
Thus, when opening the door 110 from its closed position 500, the first step in the door opening process is to pivot the door 110 outwardly by an angle Θ relative to the door frame (not shown). To achieve the pivoting action of the door 110, the pin 220 may move within the slot 218 from the second end 422 to an intermediate location 608 between the first end 420 and the second end 422. To achieve this movement of the pin 220 within the slot 218, the pivot arm 212 may pivot relative to the first pivot axis 408 and the pivot bracket 216 may pivot relative to the second pivot axis 410 and the third pivot axis 412.
As the door 110 moves from its closed position 500 to the partially open position 600, the gear 228 travels along the gear rack from the first end 232 to the intermediate position 606 and the pin 220 travels through the slot 218 from the second end 422 to the intermediate location 608. The distance from the first end 232 of the gear rack 230 to the second end 234 is greater than the distance from the second end 422 of the slot 218 to the first end 420.
For purposes of characterizing the travel of the gear 228 relative to the pin 220, a first ratio of travel of the gear 228 may be defined as the travel of the gear 228 from the first end 232 to the intermediate position 606 relative to the overall gear rack distance from the first end 232 to the second end 234 and a second ratio of travel of the pin 228 may be defined as the ratio of travel of the pin 220 from the second end 422 to the intermediate location 608 relative to the overall slot length from the second end 422 to the first end 420. In one example, the first ratio is substantially equivalent to the second ratio. In another example, the first ratio may be greater than the second ratio. In yet another example, the first ratio may be less than the second ratio.
As the door opening assembly further assists with moving the door 110 from its partially open position 600 to its open position 700, the door 110 may further move in an opening direction 704. As the door 110 moves in the opening direction 704, a door opening 706 may be formed in the area of the door frame vacated by the door 110. In particular, the door 110 may move along a door axis 702 as it moves to the open position 700.
In the open position, the gear 228 may move to the second end 634 of the gear rack 630 and the pin 220 moves to the first end 420 of the slot 218. The link 210 pivots about its pivot connection 414 and relative to the frame member 206. Moreover, the pivot arm 212 continues to pivot about the first pivot axis 408 relative to the frame member 206, and the pivot bracket 216 pivots about the second pivot axis 410 relative to the pivot arm 212 and the third pivot axis 412 relative to the mounting bracket 214.
In
The length of the gear rack 230, and in particular the length of the substantially linear portion 708, may allow the door 110 to travel an additional rearward distance thereby allowing the door opening 706 to be wide enough to accommodate the ingress and egress of a wheelchair. Moreover, the wider door opening 706 may allow for the ramp assembly 300 to move between its stowed and deployed positions.
In one example, the door 110 may move between 1-12 inches further rearward due to the shape and design of the gear rack 230. In another example, the door 110 may move between 1-8 inches further rearward. In yet another example, the door 110 may move between 1-6 inches further rearward. In a further example, the door 110 may move approximately 4 inches further rearward as a result of the door opening assembly and the path of travel of the gear 228 along the gear rack 230.
Referring to
The controller 1102 may be in communication with a user control 1106. The user control 1106 may be located on the door 110, door frame or other location in the vehicle 100. Alternatively, the user control 1106 may be located on a key fob. The user control 1106 may be actuated or triggered by a user to automatically open or close the door 110. Upon triggering the user control 1106, the controller 1102 may operably drive the motor 222 and any other motor or actuator which operably drives the door opening assembly.
In
There may also be a third sensor 1112 located at or near the first end 420 and a fourth sensor 1114 located at or near the second end 422 of the slot 218. The third and fourth position sensors may communicate to the controller 1102 the location of the pin 220 relative to both ends of the slot 218. Thus, each of the aforementioned sensors may be in communication with the controller 1102 to communicate the position of the gear 228 or pin 220. As such, the controller may receive communications about where the door 110 is located relative to the door frame.
Similarly, a fifth sensor 1116 may be provided for detecting a position of the ramp assembly 300 relative to the vehicle. In one example, if the ramp assembly 300 is deployed, the controller 1102 may prevent the door 110 from being closed until the ramp assembly 300 returns to its stowed position (or is decoupled from the vehicle floor). The sensor 1116 may alert the controller 1102 once the ramp 300 returns to its stowed position. Likewise, the sensor 1116 may communicate to the controller 1102 when the ramp 300 is in its fully deployed position.
While the control system 1100 has been described in detail, it is to be understood that the control system 1100 may be capable of performing additional functions. For example, the control system 1100 may be capable of performing an algorithm, control function, software and the like for controlling the opening and closing of the door. The control system 1100 may control the door 110 electrically, mechanically, hydraulically, pneumatically, or a combination thereof. For example, the motor 222 may be an electro-hydraulic motor. Other arrangements are possible for controlling the door movement.
In a further embodiment of the present disclosure, a method is further contemplated of converting a convention, hinge-style door from a motorized vehicle into a sliding door according to the principles and teachings above. In particular, the method may include removing the conventional door and modifying it such that the modified door includes either or both latches 238, 240. The door may further be modified by coupling the base 406 of the frame member 206 to the vehicle (e.g., vehicle floor) and the mounting bracket 214 to an inner surface of the door. The link 210 may be coupled to the frame member 206 via the pivot connection 414. The pivot arm 212 may be coupled to the frame member 206. The pivot bracket 216 may be pivotally coupled to the mounting bracket 214 about the third pivot axis 412, and the link arm 418 may be coupled to the to the pivot bracket 216 and the link 210. The pin 220 on the link arm 418 may be disposed within the slot 218 in the pivot bracket.
The method may also include coupling the drive track 902 to the vehicle, such as the vehicle floor. The gear rack 230 may also be coupled to the vehicle. The bracket 226 may be mounted to the inner surface of the door 110, and the arm 912 may be coupled to the bracket 226. The plurality of rollers may be coupled to the bracket 914 as described above. Each of the plurality of rollers may be positioned within the drive track 902 to engage the surfaces of the drive track 902 to allow for rotation therealong. The motor 222 may be coupled to the interior of the door or another location on the vehicle. The cable 224 may be coupled from an output of the motor 222 to the gear 228. The gear 228 may be positioned at the first end 232 of the gear rack 230 when the door is in its closed position.
While exemplary embodiments incorporating the principles of the present disclosure have been disclosed hereinabove, the present disclosure is not limited to the disclosed embodiments. Instead, this application is intended to cover any variations, uses, or adaptations of the disclosure using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this disclosure pertains and which fall within the limits of the appended claims.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 62/869,632, filed Jul. 2, 2019 and entitled “MODIFIED DOOR OPERATION FOR A MOTORIZED VEHICLE,” the disclosure of which is hereby incorporated by reference in its entirety.
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