This application is not based upon any pending domestic or international patent applications.
This invention relates to dynamic bases for supporting the front and rear struts of an exercise bicycle that permit the exercise bicycle to sway from side to side when ridden vigorously to thereby replicate the feel of a regular bicycle when vigorously ridden on the open road.
Stationary exercise bicycles have been available for many years and offer a good alternative to bicycling outdoors. The standard stationary bicycle is arranged to support a bicycle in an upright position and typically includes front and rear end struts. The struts are configured to engage a support surface such as a floor, deck or concrete surface. Most stationary bicycles include a wheel, which may be in front of or behind the rider, that spins as the rider pedals. Further, most bicycles have facilities for varying the intensity of resistance applied to the wheel so that the amount of energy required to pedal the bicycle can be varied.
Most riders of a bicycle outdoors experience varying terrain including uphill and downhill situations. For this reason nearly all bicycle riders tend to stand with their weight supported on the pedals at least part of the time. Cyclists rise out of the saddle for several reasons including to stretch their legs, relieve discomfort of the buttocks, to change the emphasis on muscles and, most importantly, to provide power for acceleration or for hill climbing. When a cyclists stands on their feet, he or she can shift the body weight from one side to the other to apply greater force to rotation of the pedals.
It is estimated by some that professional bicycle riders may ride out of the saddle in the standing position, as much as 30 to 40% of the time over the course of a race. While most recreational bicyclists do not ride out of the saddle this much, nevertheless nearly all bicycle riders spend at least part of the time in the standing position. When in the standing position, a bicyclists tends to sway the bicycle back and forth as he or she pedals so that as force is applied by one leg to push the pedal downwardly the leg is extending substantially straight with the biker's weight over the straight leg and as the biker's weight is shifted as force is applied by the other leg. By swaying the bicycle back and forth less stress is placed on the bikers skeletal components and the muscles operate more effectively and efficiently. Most exercise or stationary bicycles in use today do not provide for replicating the swaying action that is encountered in riding a bicycle in the normal way. This lack of a swaying action that is characteristic of the typical stationary bicycle imposes additional stress on the legs of the user and does not afford opportunity for varying the combination of muscles employed while riding a bicycle in the normal way.
For these reasons, the invention herein provides a dynamic system for a stationary bicycle that permits the bicycle to sway from side to side when ridden vigorously by a rider while at the same time supporting the bicycle in the usual upright position when ridden less vigorously.
For background information relating to exercise type of bicycles, reference may be had to the following previously issued United States patents.
The invention herein relates to improvements in stationary exercise bicycles. While there are a large number of exercise bicycles in existence today, they universally are built to include front and rear support struts that rest on a support surface, such as the floor of a building, or a garage or patio surface. Thus the standard exercise bicycle remains rigidly upward regardless of how vigorously it is ridden by the user. This invention provides an inexpensive and easy to use way of improving the exercise experience of a typical user.
The dynamic system of this invention is adapted for use with an exercise bicycle having front and rear support struts. The system permits the bicycle to sway side to side when ridden vigorously.
The dynamic system of this invention consists of a first and second housing for resting on the support surface. A platform is retained by each housing. The platform of the first housing serves to receive thereon an exercise bicycle front strut and the platform of the second housing serves to receive thereon the exercise bicycle rear strut. Each platform is pivotal end to end.
At least one deflectable resilient member engages each platform and functions to normally retain the exercise bicycle uprightly. However, each platform tilts in response to action applied by a rider to the bicycle as the bicycle is ridden vigorously.
In this way, the rider experiences the normal attitude of a bicycle when ridden vigorously as well as when ridden leisurely.
A better understanding of the invention will be obtained from the following detailed description of the preferred embodiments and the claims taken in conjunction with the drawings.
Preferred embodiments of the invention will now be described in further detail. Other features, aspects, and advantages of the present invention will become better understood with regard to the following detailed description, appended claims, and accompanying drawings (which are not to scale) where:
It is to be understood that the invention that is now to be described is not limited in its application to the details of the construction and arrangement of the parts illustrated in the accompanying drawings. The invention is capable of other embodiments and of being practiced or carried out in a variety of ways. The phraseology and terminology employed herein are for purposes of description and not limitation.
Elements shown by the drawings are identified by the following numbers:
The invention herein is in components 40, a pair of which can be used to quickly adapt a typical stationary exercise bicycle so that a user thereof experiences the natural oscillations of a normal bicycle being ridden vigorously on the open road.
Each of the two assemblies 46 of this embodiment comprises a rectangular platform 44 having two integral axially-aligned collars 52A and 52B affixed to the underneath side 54. Two identical tension springs 56 and 58, best seen in
Once springs 56 and 58 are held in place by rod 60 secured in collars 52A and 52B, the platform 44 of each assembly 46 is attached to a cross-member 48 or 50 of exercise bicycle 38 by means of straps 42 (best seen in
The assembly 46 is contained in a housing 62. Tubular collars 52A and 52B rest in bearing pads 64A and 64B respectively (best seen in
The weight of exercise bicycle 38 is sufficient to flex the tension springs 56A and 56B and allow collars 52A and 52B to contact bearing pads 64A and 64B respectively. Identical resilient members 68R and 68L are also flexed by the weight of exercise bicycle 38 and provide further stability and additional recuperative forces outboard of springs 56 and 58.
As a seated rider pedals the exercise bicycle 38 the motion of platform 44 would be slight and gentle, not reaching the maximum positions shown in
An alternate embodiment of the invention is illustrated in
In addition, as with
It is to be understood, as stated with reference to
External spring guides 76A and 76B are secured to the underneath side 54 of platform 44. Spring guides 76A and 76B are short length tubular members of internal diameters greater than the external diameters of springs 74A and 74B and fit about the springs to ensure that they are retained in position. Short length internal spring guides 78A and 78B are secured to the interior surface of the bottom of housing 62. These internal spring guides are in the form of short upstanding posts which may typically be cylindrical and of external diameter less than the internal diameter of springs 74A and 74B. Springs 74A and 74B remain under compressive tension at all times. That is, in
Platform 44 pivots on a tubular rod 60 as described with the previous embodiments. The tubular rod 60 rests in a bearing pad which is not seen in
Resilient members 68R and 68L are positioned within the housing 62 and below platform 44 and function to assist in providing resilient forces to normally maintain platform 44 horizontally as described with reference to
As with the previous embodiments, in
As compared with the embodiments of
The largest diameter or lower ends of springs 90A and 90B are received in shallow cups 93A and 93B, the cups being affixed to base 84. The upper or smaller diameter ends of conical volute springs 90A and 90B are received by pins 92A and 92B that are secured to the bottom of platform 44.
In a manner similar to the embodiments of
Exercise bicycle 38 includes, as shown in dotted outline, a cross member 48 that forms a part of the strut which supports either the front end or rear end of the exercise bicycle. This cross member 48 is secured to platform 44 by means of straps 42 as seen in
Positioned within housing 62 are resilient members 68R and 68L. In this embodiment the resilient members are each formed of a stack of resilient pieces such as made of plastic foam or the like and in which the resiliency of each portion of the stack is different and showing higher density portions being on the bottom of the stack and lower density portions on the top of the stack. Pins 100 on the top of bearing pad 64A extend through openings 102 in platform 44, the pins serving to maintain platform 44 in position but allowing it to pivot on bearing block 64A.
Referring to
Positioned between the underneath bottom surface of platform 44 and the top surface of housing bottom 84 is a first bellows 106A and a second bellows 106B. The interior of bellows 106A and 106B are connected to each other through a first flexible tube 108A and a second flexible tube 108B. Tubes 108A and 108B are joined end-to-end by a manually controllable valve 110. Valve 110 is located convenient to the rider of the bicycle 38 so that the rider may adjust the resistance to fluid flow between bellows 106A and 106B. By tightening valve 110, the fluid flow in the bellows is restricted and therefore resistance to tilting of platform 44 is increased. When valve 110 is open to a greater degree fluid flows more readily between bellows 106A and 106B meaning that platform 44 can more easily tilt from side to side. When valve 110 is turned towards the closed position the resistance to pivotation of platform 44 will serve to accommodate a heavier rider or, for reduce the degree of tilt that a rider experiences as the bicycle sways during vigorous riding activity. By opening the valve and therefore increasing fluid flow between bellows 106A and 106B the rider decreases the resistance which serves to accommodate a smaller rider. If the valve 110 is fully closed then fluid flow between the bellows stops and the pivotation of platform 44 is effectively eliminated. Thus the rider can lock the attitude of bicycle 38 in place when mounting or dismounting by closing valve 110.
While not shown, the bellows system of
Bellows 106A and 106B are shown of the pleated type but other types such as a bladder-type may be employed. Further, instead of bellows, cylinders with pistons therein can take the place of the bellows and provide for moving fluid from one to the other to control the resistance to swaying of the bicycle.
Fluid used in bellows 106A and 106B can be either gas or liquid. Due to the compressibility of gas the use of liquid will provide for specific control of pivotation of platform 44. However, the use of gas as a fluid medium has the advantage of providing cushioning action as the bicycle resting on platform 44 is swayed during vigorous exercise.
While the invention has been described with a certain degree of particularity, it is manifest that many changes may be made in the details of construction and the arrangement of components without departing from the spirit and scope of this disclosure. It is understood that the invention is not limited to the embodiments set forth herein for purposes of exemplification, but is to be limited only by the scope of the attached claims, including the full range of equivalency to which each element thereof is entitled.
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