This invention relates to pedals, and more particularly to an adjustable pedal assembly for a vehicle.
Vehicles, such as motor vehicles, typically contain foot-actuated devices or pedals for controlling various functions of the vehicle. These functions are known to include: acceleration, controlled by an accelerator pedal; braking, controlled by a brake pedal; and shifting, controlled by a clutch pedal. In addition, the vehicle may include a non-functional pedal that serves as a footrest for the driver. The pedals are aligned in a predetermined dimensional relationship relative to each other and fixed portions of the vehicle, including the vehicle dash panel, floor, seat and instrument panel. The pedal pad portion of the pedal assembly travels in a predetermined path. In the past, the path was typically an arc. Thus, to move the pedal pad closer to the driver, the pedal pad typically moves along the path into the vehicle, closer to the driver. The pedal pad is moved away from the driver by moving the pedal pad along the path away from the driver.
The pedals are positioned in the vehicle so that they are accessible by the driver. However, drivers come in a wide variety of shapes and sizes, and a pedal positioned to accommodate a large driver with a large foot will generally be unreachable by a small driver with a small foot. In the past, the pedals were fixedly positioned so that the majority of drivers were accommodated, from a functional and ergonomic aspect. An example of a functional aspect of the pedal is the ability of the driver to reach and actuate the pedal. An example of an ergonomic aspect of the pedal is the driver's comfort while actuating the pedal, as measured by a parameter such as foot angle.
More recently, adjustable pedals have been used in vehicles to accommodate a greater number of drivers from a functional and ergonomic perspective. With an adjustable pedal, the driver can modify the position of the pedal so that it is either closer to the driver or away from the driver. However, moving the pedal closer to the driver raises the height of the pedal pad with respect to the floor of the vehicle. As a result, the driver's heel may not rest on the floor of the vehicle. One consequence of not resting the driver's foot on the floor is the potential for foot fatigue during driving. In the past, the length of the accelerator pedal pad was increased to overcome this concern. However, there are limitations as to how much the pedal pad can increase in length. At the same time, it is essential that the relative dimensional relationships between the pedals are maintained during adjustment, such as the height relationship between each of the pedals.
An example of such an adjustable pedal is disclosed in commonly assigned U.S. Pat. No. 6,151,986 to KSR International, Inc. entitled “Adjustable Vehicle Control Pedals,” the disclosure of which is incorporated herein by reference. This type of adjustable pedal works well, and includes an adjustment mechanism comprising a motor, a drive mechanism operatively connected to the motor and a screw mechanism operatively connected to the pedal.
Another example of an adjustable control vehicle pedal is disclosed in U.S. Pat. No. 6,389,927. The patent discloses a control pedal arrangement including a base member having an integral support arm for supporting a pedal arm. The base also has a guide device and control mechanism for adjusting the position of the pedal arm. The control mechanism includes a motor with a gear for driving a screw rod. The screw rod extends between the base and the pedal arm and pivotally adjusts the position of the pedal arm with respect to the operator. In operation, as the pedal arm is pivoted about a pivot axis, the pedal pad moves through an arc which raises the pedal pad as it moves into the vehicle. At the same time the pedal pad is angled upwardly. While this adjustment method works, the modified angle of the pedal pad may not be ergonomically desirable.
Thus, there is a need in the art for an ergonomically beneficial adjustable pedal assembly that controls the rise, run and angle of the pedal pad with respect to the driver during adjustment of the pedal assembly.
Accordingly, the present invention is an adjustable pedal assembly. The adjustable pedal includes a mounting bracket and guide housing having a gear sector formed therein. The gear sector pivots about a fixed pivot during adjustment, and the mounting bracket upper arm includes an arcuate slot having a radius of curvature centered at the fixed pivot. A swing plate is slidingly supported within the arcuate slot in the mounting bracket upper arm at a second non-fixed pivot point located radially inboard from the first pivot point. The swing plate includes a gear sector that cooperates with the guide housing gear sector. A pedal arm with pedal pad is attached to the swing plate. An adjustment mechanism adjusts the pedal pad position. The guide housing gear sector pivots about the fixed pivot, engaging the swing plate gear sector and varying the position of the non-fixed pivot within the slot in the mounting bracket arm, constraining travel of the pedal pad.
One advantage of the present invention is that an adjustable pedal assembly is provided with a pedal pad that can be ergonomically positioned to accommodate a variety of drivers while retaining the functional features of the pedal assembly. Another advantage of the present invention is that an adjustable pedal assembly is provided whereby the rise and angle of the pedal pad is constrained as the pedal position is adjusted closer to or farther away from the driver. A further advantage of the present invention is that an adjustable pedal assembly is provided that allows the driver to maintain their heel on the floor of the vehicle while actuating the pedal, in all pedal adjustment positions. Still a further advantage of the present invention is that the motion of the pedal pad is linear during adjustment of the pedal position.
Other features and advantages of the present invention will be readily understood as the same becomes better understood after reading the subsequent description when considered in connection with the accompanying drawings.
Referring to
The mounting bracket 12 also includes a pair of upper arms 14 extending radially from an upper end of the mounting face 13, such that the arms oppose each other. The mounting bracket upper arms 14 pivotally support a lever arm extending therebetween the arms, in a manner to be described. The mounting bracket 12 has a generally inverted “L” shape.
The pedal assembly 10 also includes a first lever arm 16 disposed between the mounting bracket upper arms 14. In this example, the first lever arm includes a disc-shaped member 16a, although other shapes are contemplated. The first lever arm 16 also includes a pivot pin 16b for pivotally supporting the first lever arm 16 between the mounting bracket upper arms 14 at a first fixed pivot point. In this example, the first fixed pivot point pivots about an axis labeled “A”.
The pedal assembly 10 also includes a swing plate 18 that is pivotally supported by the first lever arm 16 at a second non-fixed second pivot point which is located radially outward from the fixed first pivot point “A”. The second non-fixed pivot point pivots about an axis labeled “B”. The swing plate 18 is attached to the first lever arm 16 at the second non-fixed pivot point “B” using a conventionally known attaching means, such as pin and clip or the like.
The swing plate includes a generally planar mounting face 18a, and a pair of arms 18b extending radially from an upper edge of the swing plate mounting face 18a. The swing plate 18 is pivotally attached to the first lever arm 16 at the second non-fixed attachment point “B”, which is located at an outer end of the arm 18b. It should be appreciated that in this example the second pivot axis “B” is positioned radially outward from the first pivot axis “A” of the first lever arm, and about 10 degrees above a horizontal line through point “A” in a non-adjusted position, and about 8.4 degrees below the horizontal line shown at an adjusted position. In addition, the upper arm 18b may include a notched portion for clearance purposes as shown at 18c. The swing plate 18 further includes a lower arm 18f extending radially from an edge of one of the upper arms that is substantially vertically oriented. The function of the lower arm 18f will be described in detail below.
The swing plate 18 also includes a pedal support arm 18d extending radially from an outer edge of the mounting face 18a. The pedal support arm 18d includes a slot 18e having a generally vertical orientation for a purpose to be described. It should be appreciated that the pedal support arm 18d, mounting face 18a, upper arm 18b and lower arm 18f are integral and formed as one using a rigid material such as steel or plastic or the like.
The pedal assembly 10 further includes a second lever arm 22. Preferably, the second lever arm 22 is a generally planar member. An upper end of the second lever arm 22 is pivotally attached to the swing plate lower arm 18f at a third, non-fixed, pivot point as shown at “C”. In this example, the angular relationship between the swing plate lower arm 18f and the second adjustment lever arm 22 is about 166.7 degrees in a non-adjusted pedal position, and 142.9 degrees in a fully adjusted position. A lower end of the second lever arm 22 is pivotally attached to the mounting bracket 12 at a fourth, fixed, pivot point, as shown at “D”.
Preferably, the swing plate mounting face 18a provides a support surface for a conventional pedal arm 20. In this example, the pedal arm is an elongated member having a front face portion, and side portions extending from an edge of the face portion. An upper end of the pedal arm includes an aperture for securing the pedal arm 20 to the swing plate mounting face, such as by bolting or the like. A pedal pad 26 is secured to a lower end of the pedal arm. In this example, the pedal pad is a rectangular member made from an isomeric material, such as rubber. The pedal arm 20 is fixedly attached to the swing plate 18. This allows for integral movement of the swing plate 18 and pedal arm 20 about the pedal arm pivot axis “B”.
Also in this example, the pedal assembly 10 is an electronically controlled throttle assembly, as is known in the art, and includes an electronic position sensing device. An example of an electronic sensing device is a position sensor, potentiometer, inductive sensor, hall sensor or the like. Movement of the pedal arm relative to the pedal arm pivot point produces an electronic control signal proportional to the position of the pedal arm, to operate the corresponding control, such as the brake, transmission or engine control.
The pedal assembly 10 further includes an adjustment mechanism 24 for adjusting the position of the pedal pad 26. The adjustment mechanism 24 includes a drive motor (not shown) preferably mounted to the mounting bracket 12 to adjust the position of the swing plate 18 and pedal arm 28. The adjustment mechanism 24 also includes a screw rod 30, wherein one end of the screw rod 30 is operatively attached to the drive motor, and the other end of the screw rod 30 is operatively attached to the swing plate 18. In this example, the screw rod 30 includes a radially extending pin 32 that is slidingly disposed in a guide slot 18e in the swing plate pedal support arm 18d. The drive unit has a drive shaft with a worm gear portion, which engages a gear wheel with a threaded aperture to move the screw rod 30. The drive motor is preferably connected to the drive shaft by a cable to drive the shaft.
In operation, activation of the motor worm gear rotates the screw rod 30 to move the lower end of the swing plate 18 and the pedal arm 20 in a predetermined direction, such as forwardly or rearwardly, depending upon the direction of rotation of the screw rod 30. In a non-adjusted position as shown in
Concurrently, the upper end of the swing plate 18 begins to rotate about the mounting axis “B” at the second pivot point, while the first lever arm 16 pivots about the fixed pivot point at axis “A”, so that the upper arm 18b of the swing plate and fixed support arm 18f moves downwardly and forwardly as the bottom of the swing plate moves rearwardly into the vehicle. It should be appreciated that the pivot point “B” is initially oriented about 10 degrees above a horizontal line through the pivot point prior to adjustment, and about 8 degrees below the horizontal line after adjustment. In addition, as the swing plate 18 rotates about the second non-fixed pivot point “B”, the second lever arm 22 begins to rotate about the third, non-fixed pivot point “C”, and the fourth fixed pivot point “D”. It should be appreciated that an angle formed between the swing plate and adjustment lever decreases as the pedal pad portion is adjusted. As the swing plate 18 and first lever arm 16 rotate, the pivot link rotates about the first, fixed pivot link point “A”.
Advantageously, the position of the pedal pad moves along a predetermined path towards the driver, while a predetermined vertical height between the floor and a point on the pedal pad is maintained. Similarly, an angular relationship between the pedal pad and the floor of the vehicle is maintained as the pedal pad moves closer to the driver. It should be appreciated that the non-fixed pivot points “B” and “C” constrain the motion of the swing plate 18, to maintain the predetermined distance between the pedal pad 26 and the floor of the vehicle.
For example, a radius may be drawn between a fixed point on the pedal pad 50 and each of the pivot points “A”, “B”, “C” and “D” for the pedal in the non-adjusted position. These radiuses are labeled rA, rB, rC and rD respectively. A similar radius may be drawn between a corresponding point on the pedal pad 50′ and each of the pivot points “A”, “B”, “C” and “D” for the pedal in the fully adjusted position. These radiuses are labeled RA, RB, RC and RD respectively. The ratios
may be computed. For the fixed pivot points “A” and “D”, the ratios
vary throughout the adjustment motion. For the non-fixed pivot points “B” and “C”, the ratios
are 1, indicating that the radius stays the same throughout the adjustment motion. This unique combination of fixed and non-fixed pivot points constrains the motion of the pedal pad along the predetermined linear path. This is distinguishable from the motion of the pedal pad along a radial path using one pivot point, as described by the prior art.
Thus, the non-fixed pivot points constrain the movement of the pedal pad, so that the pedal pad does not follow the radial curve through the first pivot point, but retains the substantially same relationship between the pedal pad and the floor of the vehicle. The addition of the movable pivot points causes the pedal pad position to move towards the driver during adjustment without rising off the floor. The orientation of the pedal pad is also substantially the same after adjustment as before adjustment.
As shown in
For example, in
In
In
Referring to
The upper arm 414 includes a cut-away portion 415 to accommodate the motion of the swing plate 418, as shown in
The swing plate 418 is pivotally attached to the mounting bracket 412 via a sector pin 423 that extends through the slots 419 of the guide housing and a throughbore 429 in the top of the swing plate, so that the swing plate 418 pivots at a non-fixed attachment pivot point “B”. The throughbore is coaxial with the center of curvature of the gear sector 421.
The pedal assembly also has a pedal arm 428 pivotally attached to the swing plate at a pivot point “E”. It should be appreciated that an electronic position sensing device, not shown but known in the art, may be located at pivot point “E” for sensing the angular pedal arm rotation about pivot point “E”. The pedal assembly further includes an adjustment mechanism as previously described. A lower portion of the swing plate 418 has a slot 418e to receive a pin 432 attached at the end of a screw rod 430, as previously described. The slot 418e is angled slightly from a vertical line. In operation, the screw rod 430 is driven by the motor, as previously discussed, and the pin 432 rides within the slot 418e in the swing plate 418. As the screw rod 430 is moved outwardly from the mounting bracket 412, the sector pin 423 is guided through an arcuate path formed by the slot 419 in the guide housing of the upper arm 414 to keep the gear sectors 421, 417 in mesh as the swing plate 418 is pivoted about the point “B” within the slot 419 in the upper arm 414. Thus, the upper end of the swing plate 418 moves downwardly and rearwardly through the path formed by the slot 419 in the guide housing upper arm 414.
As the lower portion of the swing plate 418 moves outwardly, the bottom portion of the swing plate 418 is guided by the pin 432 at the end of the screw rod 430 to move outwardly and somewhat downwardly as the screw rod 430 is extended. Advantageously, in this example the position of the pedal is maintained a generally uniform distance from the floor of the vehicle throughout the adjustment range, as previously described.
Referring to
The pedal assembly 510 includes a mounting bracket (not shown), as previously described, for attaching the pedal assembly 510 to a portion of the vehicle, such as the dash panel. The pedal assembly 510 also includes a swing plate 518 that is pivotally supported by the mounting bracket at a fixed first pivot point and corresponding pivot axis shown at “A”. The swing plate 518 is attached to the mounting bracket using a conventionally known attaching means, such as a pin or the like.
The swing plate 518 includes a mounting face 518a, and a support arm 518b extending radially from an upper portion of the mounting face 518a. A pedal arm assembly 520 is pivotally attached to the support arm 518b in a manner to be described, for relative movement about a non-fixed pedal arm pivot point shown at “B”. The pedal arm pivot axis “B” extends parallel to and outboard of the pivot axis “A”. In
The support arm 518b includes a guide channel 519 positioned near an outer end of the support arm 518b. The support arm guide channel 519 is a longitudinally extending bore having a predetermined cross-sectional shape. In this example, the predetermined shape is generally a V-shape with rounded edges.
The pedal assembly also includes a pedal arm 520. In this example, the pedal arm is an elongated member having a front wall 520a, and side walls 520b extending from an edge of the front wall 520a. The upper end of each pedal arm sidewall 520b includes a longitudinally extending guide channel 520c having a predetermined shape for receiving a pin. For example, the pedal arm guide channel 520c generally has a V cross-sectional shape. A pedal pad 526 is attached to an other end of the pedal arm 520. In this example, the pedal pad 526 is fixedly attached to the pedal arm, as is known in the art. The side wall 520b of the pedal arm 520 includes an elongated slot 520d. An adjustment mechanism (not shown) is slidingly disposed within the slot 520d, for adjustment of the position of the pedal arm 520, as previously described.
The pedal arm 520 is connected to the swing plate 518 by a pivot pin 534 extending there through the support arm guide channel 519. As illustrated in
In operation, as the pedal pad position is adjusted, the pivot pin 534 rotates about a non-fixed pivot point and corresponding pivot axis, shown at “B”. The non-fixed pivot point “B” is defined by a point of contact between an outer surface 534a of the pivot pin 534 and an inner surface 519a of the guide channel 519. The position of the pivot point “B” varies along an arc 539 whose length is defined by the moving points of contact between the pin and the guide channel 519 as the pivot pin 534 rotates eccentrically about the guide channel 519, as shown in
The movement of the pivot pin 534 within the guide channel 519 is limited by the contact points between the pivot pin 534 and the guide channel 519, which in this example is four, although greater or fewer contact points are contemplated. The eccentric movement of the pivot pin 534 within the guide channel 519 constrains the rise of the pedal pad 526 as the pedal pad position is adjusted relative to the driver of the vehicle, so that the travel is substantially linear.
The present invention has been described in an illustrative manner. It is to be understood that the terminology which has been used is intended to be in the nature of words of description rather than of limitation. Many modifications and variations of the present invention are possible in light of the above teachings. Therefore, within the scope of the appended claims, the present invention may be practiced other than as specifically described.
This Application is a Division of application Ser. No. 11/567,051 filed on Dec. 5, 2006. Ser. No. 11/567,051 is a Division of application Ser. No. 10/608,484 filed on Jun. 27, 2003. Ser. No. 10/608,484 is a Non-Prov of Prov (35 USC 119(e)) application 60/392,325 filed on Jun. 28, 2002.
Number | Date | Country | |
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60392325 | Jun 2002 | US |
Number | Date | Country | |
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Parent | 11567051 | Dec 2006 | US |
Child | 12099958 | US | |
Parent | 10608484 | Jun 2003 | US |
Child | 11567051 | US |