Bicycle rollers are well known devices for supporting a bicycle and permitting a user to mount and ride the bicycle with the rear wheel rotatably supported by a pair of rear rollers and the front wheel rotatably supported by a single front roller. Motion permitting bicycle rollers include the above described device mounted on wheels or some other motion permitting assembly, so that the rollers and bicycle can move slightly forward and rearward during use, limited by a motion-resisting assembly. To provide a realistic riding sensation, the motion-resisting assembly must permit from 5 to 10 cm of forward and rearward movement, gently resisted and urged back to a center point. To achieve this goal, some currently available systems include an outer frame, which provides a stationary track for movement and an anchor point for one or more elastic members (“bungies”) which gently resist the movement. This produces a far more realistic sensation of bicycle riding. Also, however, it is virtually impossible to build an easily collapsible assembly, using this basic structure, because of the two frames.
Whether motion permitting or not, currently available bicycle rollers connect the front roller and rear rollers with a pair of structural rails running along the sides of the rollers about 15 cm off the ground, suspending the rollers above the ground and carrying the weight of the cyclist. Accordingly, these rails present a trip hazard to the user mounting or dismounting from a bicycle mounted on the rollers. When a rider loses his balance and must dismount very quickly, these rails present a particular hazard.
With respect to motion permitting rollers, the current designs tend to be somewhat heavier than would be ideally desirable, and are not collapsible, for easy transport.
The following embodiments and aspects thereof are described and illustrated in conjunction with systems, tools and methods which are meant to be exemplary and illustrative, not limiting in scope. In various embodiments, one or more of the above-described problems have been reduced or eliminated, while other embodiments are directed to other improvements.
In a first separate aspect, the present invention may take the form of a bicycle rollers device, having a frame that includes a rear mounting assembly for two rear rollers; a front mounting assembly for a front roller; support elements, for supporting the frame above a surface, upon which the support elements are set to rest; and a central bridge connecting the front drum assembly to the rear drum assembly. Also, two rear rollers are mounted in the rear mounting assembly and a front roller is mounted in the front mounting assembly and defines a roller width. Finally, the central bridge is more narrow than the roller width, thereby permitting a bicycle rider to mount and dismount a bicycle set on the rollers without encountering the central bridge.
In a second separate aspect, the present invention may take the form of a bicycle rollers device, having a frame that includes a rear roller mounting assembly for two rear rollers; a front roller mounting assembly for a front roller; and a central bridge assembly connecting the front mounting assembly to the rear mounting gear. Also, two rear rollers are mounted in the rear mounting assembly, and a front roller is mounted in the front mounting assembly, each of the rollers having an axis of rotation. Finally, a set of wheels, each rotatably mounted on the roller axles, so as to support the rollers above a surface upon which the wheels are set, the wheels permitting forward and rearward motion of the support assembly and all six of the wheels having an axis of rotation co-incident with the roller axes of rotation.
In a third separate aspect, the present invention may take the form of a bicycle rollers device, having a frame that includes a rear roller mounting assembly for two rear rollers; a front roller mounting assembly for a front roller; and a central bridge assembly connecting the front mounting assembly to the rear mounting gear. Also, two rear rollers are mounted in the rear mounting assembly, and a front roller is mounted in the front mounting assembly and a set of wheels are mounted on the roller axles so as to support the rollers above a surface upon which the wheels are set, the wheels permitting forward and rearward motion of the support assembly. Finally, a motion-resisting assembly, includes one of the set of wheels, which is a motion-resisting wheel, having a wheel attachment element displaced from the axis of rotation, a frame attachment element on the frame, and an elastic tension member, which is attached to the frame attachment element and the wheel attachment element, wherein the motion-resisting wheel has a centered position in which the elastic tension member is at its shortest and wherein when the motion-resisting wheel rotates from the centered position the elastic tension member urges it toward its centered position.
In addition to the exemplary aspects and embodiments described above, further aspects and embodiments will become apparent by reference to the drawings and by study of the following detailed descriptions.
Exemplary embodiments are illustrated in referenced drawings. It is intended that the embodiments and figures disclosed herein are to be considered illustrative rather than restrictive.
Referring to
Referring to
Referring to
The folding of device 10 from the configuration shown in
Central column 72 is made of rectangular polyvinyl tube 14 cm×3.8 cm in transverse dimension, having wall thickness of 2.3 mm. The remainder of the frame 11 is made of either aluminum or steel. In one embodiment the entire device 10 has a mass of less than 8 kg. In an alternative embodiment device 10 has a mass of less than 9 kg. And in yet another alternative, device 10 has a mass of less than 10 kg.
Referring to
Similar to the prior shown embodiment, device 110 includes a motion resisting assembly 160, comprising an elastomeric loop 164, looped around two posts 166 on the forward wheel of the forward pair of wheels 144, and two posts 168 on the rearward wheel of the rearward pair of wheels 142. Because posts 166 are placed in a rearward location on the more forward wheel 144, and posts 168 are placed in a forward location on the more rearward wheel 144, the effect of wheel rotation is opposite on posts 168, relative to posts 166. When device 110 moves forward, the topmost of posts 166 will move forward, whereas the topmost of posts 168 will move rearward, thereby stretching loop 164, which has the effect of urging device 110 to move in a rearward direction, and resisting further forward movement. When device 110 moves rearward, the reverse process occurs, and device 110 is urged forward, with further rearward motion resisted.
Belts 141 and 145 cause the wheels on both sides of device 110 to turn in greater unison than they otherwise would. This is particularly important for the rear belt 145 because the rear wheels 142 and 144 host the motion resisting assembly 160. Varying wheel rotation between the sides would have the potential to limit the effectiveness of assembly 160, thereby permitting device 110 to creep forward or rearward an unacceptable distance. Also, belts 141 and 145 have less of a tendency to be stopped by a small item, such as a grain of sand or a pebble, that might be on the floor of a garage, where device 110 might be used.
A flywheel 190 is operatively connected to rearmost roller 132 by means of a ¼ inch belt 192. This flywheel acts to mimic the effect of inertia and momentum for a rider having his bicycle on assembly 110.
In an embodiment, a bicycle rollers device has a front and a back and comprising: a frame including, a rear mounting assembly for two rear rollers, a front mounting assembly for a front roller, support elements, for supporting the frame above a surface, upon which the support elements are set to rest; and a central bridge connecting the front mounting assembly to the rear mounting assembly. Also, two rear rollers are mounted in the rear mounting assembly; a front roller is mounted in the front mounting assembly and defining a roller width; and the central bridge is more narrow than the roller width, thereby permitting a bicycle rider to mount and dismount a bicycle set on the rollers without encountering the central bridge. In this embodiment the support elements are wheels, permitting forward and rearward movement. Further, the device may be such that once placed on a surface it has a central position and further includes a motion resisting assembly that urges the device back to the central position. Also, the device may have a belt between one of the rear rollers and the front roller, on one side of said device, leaving the other side clear for mounting and dismounting. In addition, the central bridge may be made of two pieces that telescope together and include a mechanism for locking the two pieces into place. In addition, the central bridge may be made of polymeric tubing, which may be, more specifically, polyvinyl tubing.
In a further embodiment, a bicycle rollers device has a front and a back, a longitudinal dimension, and includes a frame including a rear roller mounting assembly for two rear rollers, a front roller mounting assembly for a front roller; and a central bridge assembly connecting the front mounting assembly to the rear mounting gear. Two rear rollers are mounted in the rear mounting assembly, and a front roller mounted in the front mounting assembly, each the roller having an axis of rotation. A first support assembly is co-located longitudinally with the rear roller mounting assembly and is able to support the rear roller mounting assembly above an upwardly facing surface. Further, a second support assembly is co-located longitudinally with the front roller mounting assembly and able to support the front roller mounting assembly above an upwardly facing surface. Finally, when the device is in use the first and second support assemblies support the roller mounting assemblies and the weight the roller mounting assemblies are supporting, above an upwardly facing surface, leaving the central bridge substantially free of vertical structural stress. In this embodiment, the second support assembly may comprise a single wheel mounted on an axle attached to the frame, and substantially vertically aligned to the axis of the front roller. Also, the second support assembly may comprise two wheels, mounted on axles supported by the frame, and wherein the two wheels are substantially centered about the axis of the front roller. Further, the axles may be mounted on the frame by being mounted on a support plate, which is mounted on the frame. In addition, the bridge may be made of light-weight polymeric material
In a yet further embodiment a bicycle rollers device, has a front and a back and comprises: a frame that includes a rear roller mounting assembly for two rear rollers, a front roller mounting assembly for a front roller; and a central bridge assembly connecting the front mounting assembly to the rear mounting gear. Also, two rear rollers are mounted in the rear roller mounting assembly, and a front roller is mounted in the front roller mounting assembly. A set of wheels are mounted on the frame so as to support the rollers above a surface upon which the wheels are set, the wheels permitting forward and rearward motion of the support assembly. Also included is a motion-resisting assembly, wherein a first one of the set of wheels is a motion-resisting wheel, having an axis of rotation and a first attachment element displaced from the axis of rotation; a second attachment element on the bicycle rollers device, longitudinally displaced from the first attachment element; and an elastic tension member, attached to the first attachment element and the second attachment element, wherein the motion-resisting wheel has a centered position in which the elastic tension member is at its shortest. Further, wherein when the motion-resisting wheel rotates from the centered position the elastic tension member urges it toward its centered position. In this embodiment, the first attachment element may be a post attached to the motion-resisting wheel, and the elastic tension member may be an elastic loop, that is looped over the post. Further, the post may terminate in a knob that retains the elastic member on the post.
Also, in the yet further embodiment, the motion-resisting wheel may have a circumference and the post may be attached to the wheel by way of a rigid element attached to the wheel, so that the post protrudes past the wheel circumference. In addition, the second attachment element may be a stationary axle for one of the wheels. In addition, the second attachment element may be on a second one of the set of wheels, and wherein the second attachment element is positioned so that as the first attachment element moves forward, with device movement and attendant wheel rotation, the second attachment element will move backward, thereby stretching the elastic tension member, which urges the first one and the second one of the set of wheels, to a centered position. In addition, the elements of the motion resisting assembly may be present on both sides of the device, for laterally balanced motion resistance. In addition, the device may further be divided into segments that are connected together by hinges, so that the device can be folded into a compact state, and wherein the motion-resisting assembly is positioned on a single one of the segments (which may be the rear roller mounting assembly), so that the device can be folded without releasing tension on the elastic tension member. In addition, the elastic tension member may be made of polyurethane. Finally, the elastic tension member may act as a damped spring.
While a number of exemplary aspects and embodiments have been discussed above, those possessed of skill in the art will recognize certain modifications, permutations, additions and sub-combinations thereof. It is therefore intended that the following appended claims and claims hereafter introduced are interpreted to include all such modifications, permutations, additions and sub-combinations as are within their true spirit and scope.
This application is a continuation of PCT international application serial number, PCT/US14/65370, filed Nov. 13, 2014, which is itself a continuation-in-part of U.S. patent application Ser. No. 14/080,016, filed on Nov. 14, 2013, now U.S. Pat. No. 9,295,894, issued on Mar. 29, 2016, which are incorporated by reference as if fully set forth herein.
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Number | Date | Country | |
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20160250541 A1 | Sep 2016 | US |
Number | Date | Country | |
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Parent | PCT/US2014/065370 | Nov 2014 | US |
Child | 15151770 | US |
Number | Date | Country | |
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Parent | 14080016 | Nov 2013 | US |
Child | PCT/US2014/065370 | US |