The present invention relates to suspension systems for vehicle seats.
In one embodiment, the invention provides a seat support assembly including a base, first, second, third, and fourth suspension arms. Each of the suspension arms is mounted at a first end to the base and moveable with respect to the base, and adapted for mounting to a seat at a second end opposite the first end, the arms being moveable with respect to the seat. A torsion spring has a first end defining a length, a second end defining a length, and a coil between the first and second ends, and the coil defines a torsion spring axis. A first bearing surface abuts the first end of the torsion spring at a first abutment point to define a first moment arm distance from the first abutment point to the torsion spring axis. A second bearing surface abuts the second end of the torsion spring at a second abutment point to define a second moment arm distance from second abutment point to the torsion spring axis. An adjustment mechanism simultaneously causes relative movement between the torsion spring and the first and second bearing surfaces to simultaneously move the first abutment point along the length of the first end of the torsion spring to change the first moment arm distance, and move the second abutment point along the length of the second end of the torsion spring to change the second moment arm distance.
In another embodiment the invention provides a seat support assembly including a base, a suspension including a plurality of suspension arms, each of the arm mounted at a first end to the base and moveable with respect to the base, and adapted for mounting to a seat at a second end opposite the first end, the arms being moveable with respect to the seat. A torsion spring has a first end defining a length, a second end defining a length, and a coil between the first and second ends; the coil defines a torsion spring axis. A first bearing surface abuts the first end of the torsion spring at a first abutment point to define a first moment arm distance from the first abutment point to the torsion spring axis. A second bearing surface abuts the second end of the torsion spring at a second abutment point to define a second moment arm distance from second abutment point to the torsion spring axis. An adjustment mechanism simultaneously causes relative movement between the torsion spring and the first and second bearing surfaces to simultaneously move the first abutment point along the length of the first end of the torsion spring, to change the first moment arm distance, and move the second abutment point along the length of the second end of the torsion spring, to change the second moment arm distance.
Other aspects of the invention will become apparent by consideration of the 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. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
In the illustrated embodiment, the engine 25 includes an ignition system 45 that provides a spark or other event that drives combustion within the internal combustion engine 25. Although the engine 25 in the illustrated embodiment is of the internal combustion variety, the invention is applicable to any type of engine, and the term “ignition system,” as applied to this invention, refers to the part of the engine that sustains its continued operation. In this regard, the ignition system 45 may be termed an ignition circuit that permits operation of the engine 25 when closed and disables operation of the engine 25 when open. Although the illustrated embodiment includes an internal combustion engine 25, the present invention may be applied to vehicles and systems having alternative prime movers, such as batteries or other energy storage devices, fuel cells, or gas/electric hybrid drive systems. In such other embodiments, the ignition system would include the electric circuit that enables and disables the prime mover to operate or that enables and disables the vehicle drive and implement systems to operate under the influence of the prime mover.
In the illustrated embodiment, the engine 25 drives rotation of at least one of the wheels 20 through a transmission (e.g., a hydraulic, electric, or mechanical transmission). The operator independently controls speed and direction of rotation of the left and right side wheels 20 via the control levers 40. The engine 25 also selectively drives rotation of one or more cutting blades 55 under a mower deck 60 to cut vegetation over which the vehicle 10 travels. The mower deck 60 is raised and lowered with respect to the chassis by operation of deck actuators 65 which may be controlled by switches on the control panel 35. The mower deck 60 may include wheels 70 or other mechanisms to facilitate the deck 60 moving smoothly over ground to maintain an even cutting height for the blades 55.
With reference to
The side portions 140, 145 include support brackets 150 to which are mounted a resilient web 180, such that the web 180 extends across the seat frame 120 between the left and right side portions 140, 145. The illustrated web 180 is made of a flexible, strong, resilient material. One suitable material for use in the web 180 is sold under the Dymetrol trademark of E. I. Du Pont De Nemours and Company. A top surface of the web 180 supports the bottom cushion 115 of the seat 30, and a bottom surface of the web 180 faces down away from the cushion 115.
Referring primarily to
With reference to
Referring now to
A shoulder bolt 330 extends through the bushing 325 and the aligned pair of mounting holes 320, 255, and is secured with washers 335 and a nut 340. Consequently, the first end 310 of the suspension arm 225a is pivotally mounted to ear 250, with the shoulder bolt 330 defining a pivot axis 343 for the first ends 310. The second end 315 of the suspension arm 225a is similarly mounted to bottom mounting brackets 345 (
The first suspension arm 225a also includes a mounting hole 365 to which a roller bearing 370 is mounted with a shoulder bolt 375 and nut 380 in the illustrated embodiment. The smooth shank of the shoulder bolt is sized such that roller bearing 370 rotates freely on the shoulder bolt 375, even when the nut is tightened onto the threaded end of the shoulder bolt 375. The mounting hole 365 is between the mounting holes 320 in the first and second ends 310, 315 and is generally in the middle of the first suspension arm 225a in the illustrated embodiment. The illustrated roller bearing 370 is on an inner side of the first suspension arm 225a. The “inner side” of each of the first and second suspension arm 225a, 225b is the side facing toward the other of the first and second suspension arm 225a, 225b. In other embodiments, the roller bearing 370 is positioned in one or more other locations, or other suitable bearings are used in place of or in addition to the illustrated roller bearing 370. For example, and without limitation, the roller bearings 370 or other bearings or bearing surfaces may be attached to or part of the seat frame 120, or the bottom mounting brackets 345 specifically.
With reference to
The suspension 215 is supported by a track system 405 that includes a pair of top U-shaped tracks 410 that have mounting apertures 415 that align with the front and rear mounting apertures 260 in the horizontal legs 240 of the side brackets 235. Each top U-shaped track 410 is mounted to the respective horizontal leg 240 by way of bolts, washers or spacers, and nuts, as illustrated. The track system also includes a pair of lower U-shaped tracks 420 that are mounted to the floor of the off-highway vehicle by way of bolts 425. The illustrated feet 430 are useful for protecting the threaded ends of bolts 425 during shipping, but are removed upon installation. At least one of the lower U-shaped tracks 420 includes locking apertures 435 at discrete intervals. The seat 30 and seat support assembly 210 are adjustable forward and rearward along the track system 405 to a desired position. Once at the desired position, a spring-biased locking lever 440 is released and engages one or more of the locking apertures 435 to retain the seat 30 and seat support assembly 210 in the desired position.
The suspension adjustment mechanism 220 includes a pair of torsion springs 510, a spring support 515, a support plate 520, an adjustment rod 525, and a handle 530. With reference to
The spring support 515 includes a base plate 565, a pair of vertical supports 570, a cross member 580 mounted to and extending to each side beyond the vertical supports 570, and a face plate 585. The base plate 565 includes a slot 590 between the vertical supports 570 (visible in
Referring to
Referring to
The handle 530 is generally T-shaped, with a cylindrical base 710 and a wide end 715. The cylindrical base 710 is integrally formed or permanently affixed to the wide end 715 at one end, and includes an opposite free end. A counter bore 720 having a shape that mates with the head 655 of the adjustment rod 525 extends through the wide end 715 and deeply into the cylindrical base 710. The free end of the cylindrical base 710 includes an end wall 725 through which is formed a circular hole 730 of size sufficient to accommodate the shaft 660 of the adjustment rod 525. The circular hole 730 is coaxial with the counter bore 720. A cover plate 735 with surface indicia to instruct a user how to turn the handle 530 is affixed over the wide end 715 of the handle 530, covering the counter bore 720.
The suspension adjustment mechanism 220 is assembled as follows. The torsion springs 510 are mounted on the cross member 580 of the spring support 515, and the spring support 515 is positioned on the support plate 520 with the stopper 630 received in the slot 590. The adjustment rod 525 is extended through the counter bore 720 and circular hole 730 in the handle 530, with the head 655 of the adjustment rod 525 bottoming out in the counter bore 720 against the end wall 725. The counter bore 720 and circular hole 730 are centered on the longitudinal axis 665 of the adjustment rod 525. The threaded end 650 of the adjustment rod 525 is then extended through the low-friction bushing 285 in the support hole 280 in the front support plate 275 of the suspension base 223, and is threaded into the threaded aperture 595 in the face plate 585 of the spring support 515. The adjustment rod longitudinal axis 665 extends perpendicular to the axes 560 of the torsion springs 510 and the cross member 580 of the spring support 515, and perpendicular to the pivot axes 343 of the suspension arms 225a, 225b, 225c, 225d. With the adjustment rod 525 properly installed, the pin hole 670 in the adjustment rod 525 is exposed behind the front support plate 275. A retaining pin 750 is inserted into the pin hole 670, such that the front support plate 275 and end wall 725 of the handle 530 are trapped between the head 655 of the adjustment rod and the retaining pin 750. Because the shape of the counter bore 720 mates with the head 655 of the adjustment rod 525, the handle 530 and adjustment rod 525 are coupled for rotation about the longitudinal axis 665 of the adjustment rod 525. The shape of the handle 530 facilitates grasping by the hand of a user, and rotating about the longitudinal axis 665. As will be discussed in more detail below, as the adjustment rod 525 is rotated about its longitudinal axis 665, the threaded interconnection between the threaded end 650 of the adjustment rod 525 and the threaded aperture 595 of the spring support 515 causes the spring support 515 to move linearly forward and rearward.
Operation of the suspension will be described with reference to
In
With reference to
A first point of contact 810 is the region at which each roller bearing 370 touches the first end 535 of the associated torsion spring 510. A second point of contact 820 is the region at which the second end 540 abuts and bears against the support plate 520, generally at or near the front edge 620. For the purposes of illustration in
The suspension adjustment mechanism 220 permits the operator to simultaneously change the length of the first moment arm 850 and the length of the second moment arm 860 for each torsion spring 510. This is accomplished by moving the spring support 515 forward and rearward within the range of motion permitted by the slot 590 and stopper 630. Moving the spring support 515 forward moves the first point of contact 810 and the second point of contact 820 along the length of the respective first end 535 and second end 540 of the torsion spring, toward the coil 545. Such forward movement decreases the moment arms and thereby increases the stiffness of the suspension, as shown in
In
The suspension adjustment mechanism 220 is infinitely adjustable between the positions illustrated in
The suspension adjustment mechanism 220 rapidly changes suspension stiffness because it simultaneously changes the length of the first and second moment arms 850, 860. A system which only changes the length of one of the moment arms by moving a single point of contact would have to move the point of contact twice as far as the present invention to achieve the same change in suspension stiffness.
It should be noted that in other embodiments the bearing surfaces 370 could be provided on parts of the system other than the suspension arms as illustrated. Regardless of the actual construction, the suspension adjustment mechanism 220 is movable between a first position in which the first and second moment arm distances are relatively short such that the torsion spring provides relatively stiff resistance to pivotal movement of the suspension arms (whether or not the bearing surfaces are on the suspension arms themselves), and a second position in which the first and second moment arm distances are relatively long such that the torsion spring provides relatively soft resistance to pivotal movement of the suspension arm (whether or not the bearing surfaces are on the suspension arms themselves).
Various features and advantages of the invention are set forth in the following claims.
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