This invention relates to a traction assembly for a vehicle. More particularly, the present invention relates to traction assemblies with lower and longitudinally displaced pivoting points.
The type of surfaces over which a vehicle is ridden significantly affects its capacity and efficiency.
While the riding behavior is one of the most important aspects involved in the concept of a vehicle, the ability to allow interchangeability of parts or to retrofit new components on existing vehicles greatly satisfies the owner of vehicles and represents an interesting market source for vendors of specialized parts destined to vehicles such as snowmobiles, motorcycles, all terrain vehicles (ATVs), tractors, trucks, etc.
Specialized parts for those vehicles include kits which may develop the vehicle's capacity to accomplish other functions, to extend its duration of use throughout the seasons or to allow the use of the vehicle under different riding conditions.
For instance, different riding kits are sometimes installed to replace the wheels of existing vehicles. In principle, the kits should minimize the need to change existing components, must be able to fit on the vehicle without interference and should try to minimize any negative change to the overall riding behavior of the vehicle and comfort of the driver.
However, since most vehicles are initially designed for a typical use on a specific ground surface, some vehicle parameters like steering, weight distribution or general stability may be affected by different vehicle uses combined with other components such as different riding kits. For example, a better riding behavior on snow usually requires less weight applied to ski assemblies (usually located at the forward portion of the vehicle) than for a regular vehicle riding on another ground surface.
Numerous traction kits have been proposed throughout the years. In “Wheel Mount Track Conversion Assembly” (U.S. Pat. No. 5,607,210 issued on Mar. 4, 1997), Brazier proposes a traction kits to replace the wheels of wheeled vehicles. His system further comprises an anti-torque system that prevents the kit from contacting the vehicle. Though it can be easily mounted on a wheeled vehicle, the system of Brazier does not include particular means to allow a better weight distribution or a better maneuverability of the kit equipped vehicle. Moreover, the traction kit of Brazier can only pivot around the axle axis.
In “Conversion System for All Terrain Vehicles” (U.S. Pat. No. 6,095,275 issued on Aug. 1, 2000), Shaw proposes an ATV equipped with conversion kits such as ski assemblies and traction assemblies to replace existing wheels. Although adapting to the existing power system, the conversion system does not provide adjustability means for the weight distribution of the vehicle, such that the ATV's weight is dispersed to the ground surface through the traction and ski assemblies. Also, as for Brazier, the traction kit of Shaw can only pivot around the axis of the axle.
The problem with these particular arrangements is that in order to follow the bumps and depressions of the terrain over which the vehicle is ridden, the traction kit needs to pivot around the axis of the axle, which implies unnecessary large movements of the traction kit. These large movements are translated into an uncomfortable ride for the user. Furthermore, these traction kits generally need means to prevent any contact between the traction assembly and the body of the vehicle. These means generally add to the weight and cost of the assembly.
There is therefore a need for a traction assembly which improves riding condition when traction assemblies are used to replace existing wheels on vehicles.
Accordingly, an object of the present invention is to provide a traction assembly for a vehicle which uses an endless traction band.
Another object of the present invention is to provide a traction assembly which is compact and easily retrofitted on a vehicle.
Another object of the present invention is to provide a traction assembly which can be easily installed either in the front or in the back of a vehicle or both.
Other and further objects and advantages of the present invention will be obvious upon an understanding of the illustrative embodiments about to be described or will be indicated in the appended claims, and various advantages not referred to herein will occur to one skilled in the art upon employment of the invention in practice.
To attain these and other objects which will become more apparent as the description proceeds according to one aspect of the present invention, there is provided a traction assembly.
The object of the present invention involves a traction assembly that can preferably replace a wheel on vehicle. The traction assembly thus involves a vehicle with a frame and at least one traction axle. Preferably, the traction assembly can replace wheels on either side of the front portion and/or the rear portion of the vehicle.
More particularly, the traction assembly includes a sprocket wheel and a longitudinally extending traction band cooperating with such sprocket wheel. The sprocket wheel is preferably fixedly attached by means known in the art to the traction axle (or the wheel hub) of the vehicle. The traction assembly also comprises a support structure, sometimes in the form of a slider bar, on which at least one but preferably two idler wheels are pivotally mounted. These idlers wheels are preferably mounted at the extremities of the support structure. A plurality of road wheels can also be pivotally mounted on either side the support structure to increase the stability of the traction band.
In a first embodiment, the support structure (or slider bar) is connected to the vehicle via a member which is non-drivingly mounted on the axle (or an extension thereof). More precisely, the first end of the member is non-drivingly attached to the traction axle or to a laterally extending structure axially extending from the traction axle. This first end is preferably attached to the axle or to the laterally extending support with rollers or ball-bearings. The second end is attached to a pivot point located under the traction axle, on the support structure (or slider bar) and preferably longitudinally displaced in relation to such traction axle. A supplementary road wheel support, onto which a supplementary road wheel can be pivotally mounted, can also upwardly extend from the first end of the member. This supplementary road wheel and its corresponding support increases the stability of the traction band. The member is preferably rigid and can be adjustable.
To increase the adjustability of the pivot point, protuberances extending toward or in vicinity of the sprocket wheel can be fixedly attached to the support structure with mounting means known in the art. These protuberances are also preferably longitudinally adjustable with respect to the support structure. These protuberances include at least one and preferably a plurality of pivot points to which the member can be pivotally attached.
To prevent any interference between the support structure and the vehicle and to support the traction kit, a preferably rigid link connects the member to the vehicle frame. The connections of this link to the member and the frame are done preferably with ball-joint, bushing or rubber joint type connections. These connections allow for a tri-dimensional adjustment. Using a shock absorber in place of the rigid link could also be envisaged.
In another embodiment of the present invention, the support structure (or slider bar) is connected to the vehicle via a member which is fixedly mounted onto the suspension leg connected to the traction axle. As for the first embodiment, the second end of the member is pivotally connected to the support structure via a first pivot means located on the support structure. This first pivot means is also located under the axis of the sprocket wheel and axle. In this embodiment, there is no need for another link connecting the member to the vehicle frame. Nevertheless, a shock absorber can preferably be pivotally connected between the member and the support structure (or slider bar). This shock absorber improves the riding quality of the vehicle.
Other aspects and many of the attendant advantages will be more readily appreciated as the same becomes better understood by reference to the following detailed description and considered in connection with the accompanying drawings in which like reference symbols designated like elements throughout the figures.
The features of the present invention which are believed to be novel are set forth with particularity in the appended claims.
The present invention relates to a traction assembly for a vehicle using an endless traction band and a plurality of wheels for propulsion on irregular terrains.
The following description will be made according to embodiments of the present invention designed to be installed on ATVs and other similar vehicles. However, it is to be understood by the skilled addressee that the present invention can be adapted for any wheeled vehicles. Therefore, variants of the present invention adapted to be used on trucks, tractors and other similar vehicles fall inside the scope of the present invention.
As seen in
A first preferred embodiment of the traction assembly 20 is shown in more details in
A lateral support 52 extends from the sprocket 48 preferably along the center of rotation of the rotating components. The lateral support 52 pivotally holds a member 54 which radially connects the sprocket 40 to idler 42, 44 and road wheels 22 (not shown) via a support structure or slider 56. The member 54 is connected to the slider 56 via a pivot 58 and also includes a connection 57 where a link 60 connects the member 54 to the chassis 62 or structure 46 of the vehicle 24. The pivot 58 is located under the lateral support 52 and is preferably longitudinally displaced in relation with the lateral pivot 52 in order to change the caster angle.
The link 60 is preferably a rod-like bar with roller ball joints, bushings or rubber joints 64 providing tri-dimensional adjustability while keeping the same predetermined length during the operation of the vehicle 24. However, the link 60 may include lengthwise adjustability means to suit the dimensions of different types of vehicles 24.
The slider 56 and the member 54 are pivotally connected by the pivot 58 such that any significant relative motion between the two takes place as a rotation around the pivot 58. However, the rotation of the slider 56 around pivot 58 can be limited by rubber stoppers 59 (shown in
Since the member 54 is free to rotate around the pivot 58, the predetermined length of the link 60 restrains the relative movement between the axle 48 (and thus sprocket 40) (to which the link 60 is connected via the member 54 and the lateral support 52) and the slider 56 (to which the link 60 is connected via the member 54 and pivot point 58). Therefore, the interference risks between the sprocket 40 and the slider 56 are minimized.
The support structure or slider 56 consists of a structure which supports idler wheels 42 and 44 and a plurality of road wheels 22 and cooperates with the traction band 28. The slider 56 longitudinally or circumferentially extends in such a way as to give form to the traction band 28. The design of the slider 56 depends on the desired overall riding characteristics.
In the variant shown in
However, the positioning of the protuberances 66 with respect to the slider 56 may also be longitudinally adjustable while the vehicle 24 is not in operation. Also, the mounting means (not shown) of the protuberances 66 may consist of a series of holes or slots for positioning the pivot 58. This adjustable feature allows the traction assembly 20 to fit the dimensional configuration of a plurality of vehicles 24 and to fit the desired driving conditions.
Depending on the number of idler wheels 42, 44 and road wheels 22 being supported by the slider 56, side wheel supports 68, 70 (shown in
Therefore, the traction assembly 20 comprises the traction band 28, the sprocket wheel 40, the laterally extending support 52, the member 54, the pivot 58, the protuberances 66, the link 60, the slider bar 56, preferably at least idler wheels 42 and 44 and preferably a plurality of road wheels 22. The interaction between those various components while the vehicle 24 is in operation are illustrated in more details in
A second preferred embodiment is shown in
The sprocket wheel 140 is fixedly attached to the axle (not shown) or the wheel hub (not shown) of the vehicle 24.
In this second embodiment, the support structure 156 is not connected to the axle (not shown) or an extension thereof. Support structure 156 is interconnected to the suspension leg 149 which is generally connected to the axle in a known manner, with the help of member 154. The first end of member 154 is fixedly attached to the lower portion of the suspension leg 149 using a bracket assembly 150. The second end of member 154 is pivotally mounted to the support structure 156 via pivot point 158. The particular configuration of bracket assembly 150 depends on the particular configuration of the suspension leg lower portion. Therefore, different bracket assembly 150 should be necessary according to the design and shape of the suspension leg 149 used on different vehicles.
The skilled addressee will readily understand that the support structure 156 is not directly connected to the sprocket wheel 140 as in the prior art. Thus, support structure 156 can only pivot around pivot point 158. If the vehicle 24 equipped with traction assemblies 120 is ridden over uneven terrain, the amplitude of the movements of the traction assemblies 120 will be smaller, thus improving the riding quality if the vehicle.
To further improve the riding quality of vehicle 24 equipped with traction assemblies 120, the traction assembly 120 can further comprise a second pivot point 164, located on support structure 156 and longitudinally displaced in relation to the first pivot point 158. In the embodiment shown in
When the vehicle is ridden and the traction assemblies 120 face a bump, the front portion of the traction assembly 120 facing the bump will rise, by pivoting around pivot point 158, in order to follow curvature of the terrain. However, if the bump is abrupt, the rising movement of the traction assembly 120 can be sharp and thus uncomfortable for the rider. The presence of the shock absorber 160 prevents sharp movements by partially absorbing and dampening the movement.
The same principles apply when the front portion of the traction assembly 120 faces a depression. The shock absorber 160 will prevent any sharp descending movements.
To improve the adjustability of the traction assembly 120, the support structure 156 could comprise a plurality of pivot points 158 longitudinally displaced in relation to each other.
Also, with the use of an adjustable shock absorber 160, it would be possible to artificially rise or lower the front portion of the traction assembly 120 should it be needed.
Obviously, the skilled addressee will understand that a traction band (not shown), known in the art, is tensioned around the sprocket wheel 140, the idlers wheels 142 and 144, the road wheels 122.
Although preferred embodiments of the invention have been described in detail herein and illustrated in the accompanying figures, it is to be understood that the invention is not limited to these precise embodiments and that various changes and modifications may be effected therein without departing from the scope or spirit of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
2,495,642 | Jan 2005 | CA | national |
2,533,517 | Jan 2006 | CA | national |