The present invention relates to the field of exercise devices. More particularly, the present invention relates to a controlled pressure resistance unit engagement system that, when used, applies a consistent, correct pressure of a resistance unit on the wheel of a bicycle.
A number of resistance-type bicycle training devices have been developed that allow a person to train on a bicycle while maintaining a stationary position. Such bicycle training devices are commonly used indoors when it is not possible or convenient to ride outdoors. Such bicycle training devices normally include a collapsible frame that may be positioned on the floor and releasably attachable to the rear wheel of the bicycle. The frame supports a resistance unit, which is known to include a mounting member, a roller rotatably secured to the mounting member, and a knob for tightening the roller. The resistance unit releasably engages the bicycle tire by application of pressure against the rear wheel, via the roller, to provide resistance to the rotation of the wheel. Therefore, as the person moves the pedals and, consequently, the rear wheel of the bicycle, the rotation of the wheel is opposed by the resistance provided by the resistance unit.
Previous resistance unit engagement mechanisms, which typically utilize a screw-type knob for resistance unit engagement, have not provided feedback on how tight to turn the knob to provide a desired degree of pressure. The result is the inability to apply consistent, correct pressure of the resistance unit against the wheel of the bicycle. For example, some users may not tighten the roller of the resistance unit against the tire enough (under tighten), which can cause slippage between the tire and the resistance unit. On the other hand, some users may tighten the roller of the resistance unit against the tire too much (over tighten), which can cause a significant increase in resistance. In either event, variance in resistance unit pressure and resultant resistance to wheel rotation may lead to an undesirable user experience, and over tightening can cause premature tire wear and/or damage to the roller.
Also, because consistency in pressure with previous knobs was only achievable through user feel, design efforts directed toward refining a specific power curve are typically ineffective or inaccurate due to the significant variance in the amount of torque that users may apply to the knob. The difference is especially noticeable with smaller diameter rollers in which one knob rotation could result in a significant difference in power attained by the resistance unit (e.g., one knob rotation could equal as much as 50 watts at 20 mph).
Needless to say, it is desirable to apply consistent, correct pressure of the resistance unit against the wheel of the bicycle during such training.
In accordance with an aspect of the present invention, a bicycle trainer is provided that includes a clutched adjuster arranged with respect to a resistance unit so that actuation of the clutched adjuster moves the resistance unit against a tire of a bicycle in the bicycle trainer so as to achieve an appropriate amount of tire-to-resistance unit engagement force and thus a correct amount of resistance. In this way, the bicycle can be mounted in the bicycle trainer multiple times for multiple training sessions and during each time the same amount of tire-to-resistance unit engagement force will be provided without requiring any tools or measurement instruments for setup comparisons. This may define a use-ready position of the resistance unit which provides a correct tire-to-resistance unit engagement force that can be consistently repeated in a tool-less manner.
In accordance with another aspect of the present invention, the clutched adjuster may be a rotatable member such as a knob or a pivoting member such as a lever. A clutch arrangement may be arranged at least partially within the knob or lever so that the knob or lever can be manipulated to a maximum tightened position, after which further manipulation results in the clutch arrangement slipping to prevent over tightening. This may allow for consistent set-up(s) of the bicycle trainer by tightening the clutched adjuster until the clutch slips at the maximum tightened position, which provides the correct tire-to-resistance unit engagement force.
According to another aspect of the present invention, a clutch arrangement is used to limit the maximum torque applied to the knob, and by doing so, also applies consistent pressure to the tire through the resistance unit. By providing users with a clutched knob, each user can apply consistent, correct torque. This will prevent a user from under tightening or over tightening the resistance unit, thereby avoiding tire or resistance unit damage. Also, by applying consistent pressure, a more consistent resistance unit power curve can be achieved.
According to yet another aspect of the present invention, a clutch arrangement is used in a clutch lever arrangement for a bicycle trainer to limit the maximum torque for a predetermined pressure of a movable resistance unit of the bicycle trainer on a bicycle tire. The resistance unit may include a roller for engaging the bicycle tire. The roller may be supported by a body having an opening or cavity with a boundary defined by an interior ribbed surface of a portion of the resistance unit body. A ribbed cam may be arranged within the cavity and have an exterior ribbed surface operable to engage the interior ribbed surface of the resistance unit body. The ribbed cam may include a detent that operably engages a cantilevered finger of the pivoting member so that a clutch arrangement is defined at least in part by the cantilevered finger and the detent. Pivoting of the pivoting member in a first direction provides movement of the ribbed cam and the engaged resistance unit toward a bicycle tire for tightening the resistance unit against the bicycle tire until the clutch arrangement enables the cantilevered finger to move past the detent at a maximum torque for a predetermined pressure of the resistance unit on the bicycle tire. At this point, the pivoting member is cam-locked into a locked position at which the resistance unit is maintained in the use-ready position for applying a correct pressure of engagement of the resistance unit with the tire. Pivoting of the pivoting member in a second direction provides movement of the ribbed cam and the engaged resistance unit away from the bicycle tire. By providing users with a clutched lever, each user can apply consistent, correct torque. This will prevent users from under tightening or over tightening their resistance units, thereby avoiding tire or resistance unit damage. Also, by applying consistent pressure, a more consistent resistance unit power curve can be achieved.
These and other aspects and objects of the present invention will be better appreciated and understood when considered in conjunction with the following description and the accompanying drawings. It should be understood, however, that the following description, while indicating preferred embodiments of the present invention, is given by way of illustration and not by way of limitation. Many changes and modifications may be made within the scope of the present invention without departing from the spirit thereof, and the invention includes all such modifications.
The drawings illustrate the best mode presently contemplated of carrying out the invention.
In the Drawings:
In describing the illustrated embodiment of the invention as shown in the drawings, specific terminology will be resorted to for the sake of clarity. However, it is not intended that the invention be limited to the specific terms so selected, and it is to be understood that each specific term includes all technical equivalents which operate in a similar manner to accomplish a similar purpose. For example, the word coupled, connected, attached, or terms similar thereto are often used. They are not limited to direct connection but include connection through other elements where such connection is recognized as being equivalent by those skilled in the art.
The present invention and the various features and advantageous details thereof are explained more fully with reference to the non-limiting embodiments described in detail in the following description. Referring now to
The frame 11 has a pair of generally forwardly extending legs 26 attached to opposite ends of a generally U-shaped support member 28. The legs 26 also extend slightly outwardly with respect to the support member 28 to enhance the stability of the device 10. The legs 26 and support member 28 are formed of a generally rigid material, such as a metal tubing, which may have a circular or any other desired cross section. Each of the legs 26 is connected to the support member 28 by a brace 30 that is secured to support member 28. A bolt 32 extends through the leg 26 and brace 30, and a nut 34 is engaged with the threads of bolt 32 such that leg 26 is pivotable about bolt 32 between an extended position as shown and a folded position for storage. Opposite the brace 30, each leg 26 also includes a foot 36 formed of a resilient high friction material, such as rubber, that serves to prevent the leg 26 from slipping with respect to the surface 13 on which the frame 11 is positioned. The support member 28 also includes a pair of feet 36 attached to opposite ends of a horizontal cross member 38 secured to the support member 28 opposite the legs 26. The cross member 38 serves to assist the legs 26 in holding the device 10 stable and stationary on the horizontal surface 13.
Training device 10 includes a releasable engagement mechanism 40 having a stationary first portion 42 located on one side of frame 11, and a movable second portion 44 having a manual release lever 46 located on the other side of frame 11. In a known manner, one end of the axle of hub 19 is engaged with stationary first portion 42, and lever 46 is operated to engage second portion 44 with the opposite end of the axle. In this manner, the rear of bicycle 12 is engaged with and supported by frame 11 such that rear wheel 18 is above the supporting surface 13, and can thus be rotated by operation of the pedals of bicycle 12.
A resistance unit 48 is movably mounted to frame 11 adjacent cross member 38. A clutched adjuster 49 in accordance with the present invention defines a driving engagement with the resistance unit 48 for moving the resistance unit 48 with respect to the wheel 18. The clutched adjuster 49 can be manipulated by a user to a maximum tightened position of the clutched adjuster 49 that corresponds to a maximum pressure between the resistance unit 48 and the wheel 18 which defines a use-ready position of the resistance unit 48. Manipulation beyond the maximum tightened position releases the driving engagement of the clutched adjuster 49 with the resistance unit 48 such that the clutched adjuster 49 cannot deliver more than a predetermined maximum torque, which prevents over tightening of the resistance unit 48 against the wheel 18. The clutched adjuster 49 may provide an indication, such as a tactile and/or audible indication, that the maximum tightened position has been achieved, as described in greater detail elsewhere herein.
A support yoke or arm 50 supports the resistance unit 48 and is pivotally attached to the support member 28 between a pair of mounting members 52. Each mounting member 52 is fixed to the support member 28, and functions to hold the resistance unit 48 on the support member 28. Each mounting member 52 includes an opening 60, and a pivot plate 66 extends between mounting members 52. The pivot plate 66 includes an upwardly curved section 68 that extends outwardly and defines a sleeve 70, which pivotally retains one end of an adjustment rod 72 that is used to adjust the position of the support arm 50 with respect to the support member 28.
Referring now to
The generally rectangular intermediate section 77 increases in width as it extends from the first end to the second end, but can also have a consistent width along its length. The intermediate section 77 includes a central slot extending through the central section perpendicularly to the channel in the first end. A threaded end (not shown) of the adjustment rod 72 opposite the sleeve 70 on plate 66 is inserted through the slot and, in this embodiment, is threadedly engaged with the clutched adjuster 49 that includes a rotatable member, shown here as knob 86. The knob 86 includes a lower assembly 88 with which the adjustment rod 72 is threadedly engaged with a nut 90 that is captured against rotation within a stem 92 that extends from an intermediate portion of a plate 95 (FIG. 4)., The lower assembly 88 may rest against a pair of curved surfaces 96 extending outwardly from the intermediate section 77 on opposite sides of the slot in order to limit the pivoting of the support arm 50 away from the support member 28 (
An upper assembly 98 of the knob 86 engages and selectively transmits torque to the lower assembly 88 through a clutch arrangement 100 for moving the resistance unit 48, as long as a user-applied input torque does not exceed a maximum torque value, as explained in greater detail elsewhere herein. In this way, during a tightening procedure by rotating knob 86, the position of lower assembly 88 on adjustment rod 72 or the rod 72 with respect to other components of the resistance unit 48 can be adjusted to selectively adjust the angle of support arm 50 with respect to the support member 28. This allows the resistance unit 48 to be adjusted with respect to the support member 28 in order to accommodate wheels 18 having different diameters and to tighten the resistance unit 48 against the wheel 18.
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In the complete assemblage of the knob 86, the engaged angled surfaces 124, 126 define a friction-based driving interface between the upper and lower assemblies 98, 88 that at least partially defines a clutch arrangement 100. When a user inputs a torque to the knob 86 by rotating the cap 102, if the input torque is at or less than a maximum torque value, then rotation of the cap 102 is translated through the frictional engagement of the angled surfaces 124, 126 of the upper and lower assembly ramps 116, 118, respectively, into rotation of the lower assembly 88. This correspondingly rotates the rod 72 which moves the resistance unit 48 closer to the wheel 18 so as to tighten the resistance unit 48 against the wheel 18 (
Referring now to
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In operation, as the upper assembly 300 is turned in a tightening direction, torque is applied from the teeth 320 to spring arms 420, which in turn transfers torque from spring arms 420 to the lower assembly 400 and threaded rod 410, which in turn rotates the lower assembly 400 and threaded rod 410 to increasingly tighten the resistance unit against the bicycle tire. Once the roller of the resistance unit 48 engages the bicycle tire, continued rotation of knob 200 causes advancement of the roller a limited amount until a certain maximum torque is reached. When this occurs, the spring arms 420 flex and can no longer transfer torque to the lower assembly 400 and threaded rod 410. This causes the lower assembly 400 and threaded rod 410 to cease rotating, despite continued turning of the upper assembly 300 in a tightening direction. In other words, if the upper assembly 300 continues to turn in a tightening direction after a certain maximum torque is reached, the clutch arrangement functions as a ratchet mechanism that makes the upper assembly 300 slip past the lower assembly 400 without any further transfer of torque to the lower assembly 400, and thus no further tightening of the resistance unit 48 against the tire, whereby the resistance unit is maintained in the use-ready position without being over tightened. This occurs when the resistance unit 48 has attained an optimal desired position in engagement with the tire, and the slipping of the upper assembly 300 past the lower assembly 400 may provide an audible and/or tactile indication that the optimal desired position has been attained. It should be noted that the maximum amount of torque desired can be set, for example, according to the manufacture and the configuration of the spring arms. The user is now prevented from over tightening the resistance unit, thereby providing consistent resistance and avoiding tire damage.
When upper assembly 300 is turned in a loosening direction, torque is applied in the reverse direction from the teeth 320 to spring arms 420, which in turn causes spring arms 420 to flex in the opposite direction and engage stops 430. Once this occurs, rotation of upper assembly 300 is transferred to lower assembly 400 through engagement of spring arms 420 with stops 430, to thereby transfer torque in the reverse direction to threaded rod 410. Rotation of threaded rod 410, in turn, moves the resistance unit 48 away from the bicycle tire. The upper assembly 300 may be turned in a loosening direction to loosen the resistance unit clamp from the bicycle tire at any time, whether or not the maximum amount of torque has been reached and the clutch arrangement engaged.
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To loosen the clutch lever resistance unit 500, the lever 580 is again rotated downward, and, as a result, the cantilevered finger 582 moves past the detent 564 to return to the “open” position. Continuing to rotate the lever 580 downward then causes the ribbed cam 560, coupled to the lever 580 and with the cantilevered finger 582 below the detent 564 (“open”), to rotate downward, and the resistance unit 500 to move away from the bicycle tire 520.
Although the best modes contemplated by the inventor of carrying out the present invention are disclosed above, practice of the present invention is not limited thereto. It will be manifest that various additions, modifications and rearrangements of the features of the present invention may be made without deviating from the spirit and scope of the underlying inventive concept. For example, a controlled pressure resistance unit could be enhanced by providing a cam lever used in conjunction with the clutch arrangement to provide faster tightening and loosening of the resistance unit. In addition, a spring could be used in conjunction with the clutch arrangement to provide a more consistent force to the resistance unit when the maximum torque has been applied. Also, a spring could be used without the clutch arrangement to apply a consistent force within a wider range of knob torques.
Furthermore, all of the disclosed features of each disclosed embodiment can be combined with, or substituted for, the disclosed features of every other disclosed embodiment except where such features are mutually exclusive. All of these variations achieve the objectives described herein, which include applying consistent, correct pressure of the resistance unit against the wheel of a bicycle.
This application claims priority to U.S. Provisional Patent Application Nos. 61/608,749 filed on Mar. 9, 2012 and 61/650,203 filed on May 22, 2012 each entitled Controlled Pressure Resistance Unit Engagement System, the entireties of which are expressly incorporated by reference herein.
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