The present disclosure relates to exercise equipment and, more particularly, to treadmill stepper exercise equipment that combines features of treadmills and stair climbing exercise machines.
Conventional treadmills provide a platform with a moving belt on which a user can walk or run in place. Most conventional treadmills have a motor that drives the belt over the platform. Some conventional treadmills are motorless, but have the platform set at a fixed angle or slope so that with each step the user's weight pushes the belt down along the platform. A flywheel may be coupled to the belt to maintain the belt motion that is generated by the user with each step.
Conventional stair climbing exercise machines (also called steppers) generally have two pedals that a user alternately steps against to simulate stair climbing. Devices that combine the stair climbing aspect of steppers with the moving belt of a treadmill have also been developed. For example, U.S. Pat. No. 7,097,593, assigned to Nautilus, Inc., discloses a combination treadmill/stepper. Like conventional treadmills, however, conventional combination treadmill/steppers, such as the device disclosed in U.S. Pat. No. 7,097,593, are motor-driven so that the speed of the moving belts and/or the stepping action can be more accurately controlled.
In one embodiment, an exercise device comprises a frame, first and second treadle assemblies, a drive shaft, and a rotational coupling between the drive shaft and the tread belts so that the rotational motion of the drive shaft provides rotational motion of the tread belts. The first and second treadle assemblies each include a deck and an endless tread belt rotatably mounted to pass over the deck. Each treadle assembly is pivotably mounted to the frame to pivot between upward and downward positions. The drive shaft is operably coupled to the first and second treadle assemblies by a one-way drive system through which pivotal motion of the first and second treadle assemblies provides rotational motion to the drive shaft.
In some embodiments, the one-way drive system includes a first drive member coupled to the first treadle assembly and positioned to contact a first one-way engagement member to rotate the drive shaft in a first direction when the first treadle assembly moves between the upward and downward positions, and a second drive member coupled to the second treadle assembly and positioned to contact a second one-way engagement member to rotate the drive shaft in the first direction when the second treadle assembly moves between the upward and downward positions.
In some embodiments, the first and second engagement members are configured to disengage from the drive shaft when the respective first and second treadle assemblies return from the movement that rotates the drive shaft in the first direction. The first drive member can include a first linkage arm and the first engagement member can include a first one-way clutch bearing coupled to the first linkage arm, and the second drive member can include a second linkage arm and the second engagement member can include a second one-way clutch bearing coupled to the second linkage arm. In other embodiments, the first drive member can include a first roller and the first engagement member can include a first cam that is driven by the first roller, and the second drive member can include a second roller and the second engagement member can include a second cam that is driven by the second roller. Both first and second cams can be mounted on respective one-way clutch bearings so that the movement of the first and second treadle assemblies from the downward position to the upward position causes the first and second cams to pivot back toward the respective first and second rollers. In some embodiments, the rotational coupling between the drive shaft and the tread belts includes a roller shaft extending across a back portion of the first and second treadle assemblies to drive rotational motion of the tread belt of the first and second treadle assemblies. In some embodiments, the rotational coupling can include a step-up gearing mechanism to provide stepped-up gearing between rotational motion of the drive shaft and the roller shaft.
In other embodiments, a return assembly can be provided. The return assembly can link the first and second treadle assemblies such that movement of either of the first and second treadle assemblies from the upward position to the downward position causes the other of the first and second treadle assemblies to move from the downward position to the upward position. In other embodiments, the decks of the first and second treadle assembles can each have a length and the first and second treadle assemblies can be pivotable between a maximum pivot angle and a minimum pivot angle. Movement of either treadle assembly between the maximum pivot angle and the minimum pivot angle can cause the tread belts of the first and second treadle assemblies to move a distance that is less than the length of the decks.
In another embodiment, an exercise device can comprise a frame, left and right treadle assemblies, a roller, and a motorless drive system. The left treadle assembly can have a left deck and an endless left tread belt rotatably mounted to pass over the left deck. The left treadle assembly can be pivotally mounted to the frame. The right treadle assembly can have a right deck and an endless right tread belt rotatably mounted to pass over the right deck. The right treadle assembly can also be pivotally mounted to the frame. The roller can extend across a rear portion of both the left and right treadle assemblies and within the left and right tread belts to rotate them. The motorless drive system is configured to drive the roller during pivotal motion of the left and right treadle assemblies.
In some embodiments, the left and right treadle assemblies are pivotable between an upward position and a downward position to provide a downward stroke, and the motorless drive system is powered by the downward movement of the left and right treadle assemblies during the downward stroke of the left and right treadle assemblies. In some embodiments, the roller can drive the right and left tread belts at the same speed. In some embodiments, a pair of external bearing members can be positioned on the roller between the left and right treadle assemblies. In other embodiments, a drive shaft can be positioned below the left and right treadle assemblies and a rotational coupling can be provided between the drive shaft and the roller. The motorless drive system can include a left drive member and a right drive member, with the left drive member being coupled to and extending below the left treadle assembly and the right drive member being coupled to and extending below the right treadle assembly. The left and right drive members can engage the drive shaft during pivotal motion of the left and right treadle assemblies to provide to the drive shaft rotational motion that is imparted to the roller via the rotational coupling.
In some embodiments, a return assembly can be provided that links the left and right treadle assemblies such that the left and right treadle assemblies move in opposite pivotal directions and the left and right drive members alternately engage the drive shaft. The left and right drive members can comprise linkage arms or rollers. In some embodiments, a left one-way clutch bearing and a right one-way clutch bearing can be provided, with the left drive member providing a downward force on the left one-way clutch bearing to engage the drive shaft during a downward stroke of the left treadle assembly and the right drive member providing a downward force on the right one-way clutch bearing to engage the drive shaft during a downward stroke of the right treadle assembly.
In another embodiment, an exercise device comprises a frame, first and second treadle assemblies, and a motorless drive system. First and second treadle assemblies can each include a deck and an endless tread belt extending around the treadle assembly and passing over the deck. Each treadle assembly can be pivotably mounted to the frame such that each treadle assembly can alternately pivot upwards and downwards. The motorless drive system can be driven by the respective downward movements of the first and second treadle assemblies from upward positions to downward positions to rotate the tread belts around the treadle assemblies.
In some embodiments, a return assembly can be provided. The return assembly can link the left and right treadle assemblies such the left and right treadle assemblies move in alternating directions. The motorless drive system can include a first one-way drive member associated with the first treadle assembly and a second one-way drive member associated with the second treadle assembly. The first and second one-way drive members can be configured to alternately engage to rotate the tread belts of the first and second treadle assemblies.
In some embodiments, a drive shaft and a rotational coupling between the drive shaft and the tread belts can be provided so that the rotational motion of the drive shaft provides rotational motion of the tread belts. The first and second one-way drive members can engage the drive shaft to rotate it and thereby to provide rotation to the tread belts via the rotational coupling.
In another embodiment, a method of exercising is provided. The method includes pivoting a first treadle assembly between an up position and a down position and pivoting a second treadle assembly between an up position and a down position. A tread belt rotatably coupled to a deck of each of the respective first and second treadle assemblies can be driven by exerting a user-directed force to the first and second treadle assemblies as each respective treadle assembly moves from the up position to the down position. The user-directed force comprises a first component that directly rotates the respective tread belts of the first and second treadle assemblies and a second, downwardly directed component that drives a one-way drive system that causes the tread belts to rotate about their respective decks.
In some embodiments, the first and second treadle assemblies can pivot in a reciprocating manner. In other embodiments, the driving of the one-way drive system can include moving a drive member to engage a one-way engagement member that transmits a rotational force to the tread belts. The tread belts of the first and second treadle assembly can be driven at the same speed.
The foregoing and other objects, features, and advantages of the invention will become more apparent from the following detailed description, which proceeds with reference to the accompanying figures.
The following description is exemplary in nature and is not intended to limit the scope, applicability, or configuration of the disclosed embodiment in any way. Various changes to the disclosed embodiments may be made in the function and arrangement of the elements described herein without departing from the scope of the invention.
As used in this application and in the claims, the singular forms “a,” “an,” and “the” include the plural forms unless the context clearly dictates otherwise. Additionally, the term “includes” means “comprises.” Further, the terms “coupled” and “associated” generally mean electrically, electromagnetically, and/or physically (e.g., mechanically or chemically) coupled or linked and does not exclude the presence of intermediate elements between the coupled or associated items absent specific contrary language.
Although the operations of exemplary embodiments of the disclosed method may be described in a particular, sequential order for convenient presentation, it should be understood that disclosed embodiments can encompass an order of operations other than the particular, sequential order disclosed. For example, operations described sequentially may in some cases be rearranged or performed concurrently. Further, descriptions and disclosures provided in association with one particular embodiment are not limited to that embodiment, and may be applied to any embodiment disclosed.
Moreover, for the sake of simplicity, the attached figures may not show the various ways (readily discernable, based on this disclosure, by one of ordinary skill in the art) in which the disclosed system, method, and apparatus can be used in combination with other systems, methods, and apparatuses. Additionally, the description sometimes uses terms such as “produce” and “provide” to describe the disclosed method. These terms are high-level abstractions of the actual operations that can be performed. The actual operations that correspond to these terms can vary depending on the particular implementation and are, based on this disclosure, readily discernible by one of ordinary skill in the art.
As used herein, the terms “front,” “rear,” “right,” and “left,” “upper,” and “lower” refer to relative directions from the perspective of a user standing on the exercise device in a forward facing manner as the device is typically used.
Each treadle assembly 14, 16 has a front portion 28 and a rear portion 30 and includes as a top surface a deck 32 that supports a tread belt 34. Tread belts 34 are continuous belts that each travel in a circuit around the length of its treadle assembly 14, 16 in an endless loop. In operation, the treadle assemblies 14, 16 pivot up and down in alternation while their respective tread belts 34 are rotated to pass over their decks 34 to provide a moving treadmill-type surface for each foot.
Treadle assemblies 14, 16 include respective front rollers 36, 38 and a common rear roller 40. Each tread belt 34 extends over its respective front roller 36, 38 and rear roller 40. As will be described in more detail below, rear roller 40 can be a single integrated roller, or otherwise two separate rollers that are fixed relative to one another, to provide a uniform speed for both tread belts 34. Exercise device 10 can have one or more panels 42 (
As shown in
A shaft extension 106 (
As described above and as shown in
A return assembly 50 (
Rocker member 60 includes a central pivot aperture 62, a first pivot aperture 64 on a first side of central pivot aperture 62, and a second pivot aperture 66 on a second, opposing side of central pivot aperture 62. A central pivot pin 68 extends through central pivot aperture 62 and frame aperture 63 to pivotably couple rocker member 60 to central frame member 61. A first pivot pin 70 extends through first pivot aperture 64 to couple the second end of first arm 52 to rocker member 60. A second pivot pin 72 extends through second pivot aperture 66 to couple the second end of second arm 54 to rocker member 60.
The return assembly 50 described above can also be referred to herein as interconnection assembly 50 since the rocker member 60 interconnects the left treadle assembly 14 with the right treadle assembly 16. For example, the downward stroke of one treadle assembly (e.g., left treadle assembly 14) pivots rocker member 50 about the central pivot pin 68 to induce an upward stroke in the other treadle assembly (e.g., right treadle assembly 16). Thus, the two treadle assemblies 14, 16 are interconnected in a manner to provide a stepping motion in which the downward movement of one treadle is accompanied by the upward movement of the other treadle, and vice versa, through the alternate pivoting or rocking of rocker member 60.
Thus, treadle assemblies 14, 16 reciprocate in an even manner with the alternating pivoting or rocking rocker member 60 of interconnection assembly 50 to provide a user with a consistent stepping action. However, it should be understood that other interconnection assemblies can be provided. For example, the two treadle assemblies can be linked in any manner that causes a generally reciprocating movement of the two treadle assemblies.
Alternatively, or in addition, the return assembly 50 can include independent (e.g., non-interconnected or non-linked) return members that function to assist the return of each treadle assembly in an upward stroke without regard for the downward stroke of the other treadle assembly. For example, a return spring could be coupled between each treadle assembly and the frame. When a user “steps” from the rear portion of one treadle assembly after its downward stroke, the user generally lifts his foot off of the tread belt and extends his foot forward toward the front portion of that treadle assembly. The return spring can provide an upward force to that treadle assembly during the forward extension of the foot so that the treadle assembly can return to the upward position.
As discussed above, exercise device 10 can be configured to use the force created by the downward motion of each treadle assembly 14, 16 to drive shaft extension 106 and simultaneously rotate tread belts 34 of the two treadle assemblies 14, 16.
As shown in
As shown in
Lower portions of drive members 76, 78 are coupled to one-way engagement member 84, 86, respectively. In the illustrated embodiment of
Both one-way engagement members 84, 86 successively engage and disengage drive shaft 74 to impart rotational force during one treadle stroke and to return without impeding drive shaft 74 during the opposing treadle stroke. In the illustrated embodiment, one-way engagement members 84, 86 engage and transmit a rotational force on drive shaft 74 to rotate it in a first direction 88 during downward treadle strokes. During upward pedal strokes, one-way engagement members 84, 86 disengage drive shaft 74 and allow it to continue rotating (e.g., freewheeling) in first direction 88 while one-way engagement members 84, 86 return to upward positions. Accordingly, when used in combination with return assembly 50 that links the left and right treadle assemblies 14, 16, drive members 76, 78 alternately engage and drive the drive shaft 74.
It will be appreciated that as an alternative to the illustrated embodiment drive members 76, 78 can alternately engage and drive the drive shaft 74 during upward strokes of treadle assemblies 14, 16. In one implementation of this alternative embodiment, drive shaft 74 could be repositioned so that linkage arms 83, 87 extend rearward and are coupled to respective drive members 76, 78 through rocker mechanisms so that one-way engagement members 84, 86 engage and transmit a rotational force on drive shaft 74 to rotate it in first direction 88 during returning upward treadle strokes.
As shown in
In operation, for each downward stroke of either treadle assembly 14, 16 (e.g., the drop from an upward position to a downward position), tread belts 34 both move along at least a portion of the length L (
A step-up gearing mechanism 91 steps-up rotation of drive shaft 74 to provide sufficient rotation of rear roller 40 to pass the tread belts 34 and a user's foot from a desired front portion to a desired rear portion of the treadle assemblies 14,16 during a downward treadle stroke. As illustrated in
It will be appreciated that the step-up gearing provided by step-up gearing mechanism 91 can be implemented in alternative ways. For example, cogs and endless chains can be substituted for pulleys and endless belts, and vice versa. Also, direct gear-to-gear engagement could be used as an alternative to any belts or chains.
As described above, each treadle assembly 14, 16 moves from an upward position to a downward position during a downward stroke. In a full downward treadle stroke a treadle assembly 14, 16 moves from a maximum height or pivot angle to a minimum height or pivot angle. For a user to maintain a foot on the tread belt 34 of each treadle assembly 14, 16 throughout the full downward treadle stroke, exercise device 10 can be configured such that tread belts 34 move less than an entire length L (
Of course, it should be understood that exercise device 10 can be operated with less than full upward or downward strokes. Another benefit of driving the tread belts 34 with the pivoting of the treadle assemblies 14, 16 is that a user may perform smaller, less-than-full-stroke pivoting (i.e., stepping) movements, and the tread belts 34 will move a correspondingly smaller distance. Thus, a user can adjust his or her stride on the exercise device 10 by adjusting the size of the downward strokes on treadle assemblies 14, 16. For example, the user may operate the exercise device 10 at 50% of the downward stroke and obtain movement of tread belts 34 of about 50% of the maximum tread belt travel distance. In one embodiment, each treadle assembly 14, 16 is configured to pivot a total of between about 6 and 20 degrees, and more preferably, a total of between about 10 and 14 degrees during each full treadle stroke. In addition, as noted above, the motion of the tread belts can directly correspond to an amount of drop of the downward stroke.
As shown in
Rearward roller 40 extends through a pair of external ring bearings 110 that are mounted to and extend back from the inner, facing rearward sides of treadle assemblies 14, 16, thereby to support the inner, facing rearward sides of treadle assemblies 14, 16 on roller 40 while allowing it to rotate freely. An annular spacer 112 is provided between external bearings 110 to maintain a desired separation between them and treadle assemblies 14, 16. The combination of external bearings 110 and spacer 112 can further improve the structural rigidity of the forward-cantilevered treadle assemblies 14, 16 by reducing relative movement of the treadle assemblies 14, 16 along the axis of roller 40.
Referring again to
As shown in
A lower portion of first drive member 120 is coupled to a first one-way engagement member 128 and a lower portion of second drive member 122 is coupled to a second one-way engagement member 130. In the illustrated embodiment of
Rotation of drive shaft 74 is converted into a rotational force that is applied to shaft extension 106 in the same general manner as described above with respect to
As described above with respect to
The use of a cam-follower system as described above can advantageously reduce stress on the system, relative to the linkage arm coupled to a pivoting one-way clutch bearing, by providing a more constant application of torque to drive shaft 74.
As discussed above, various return members can be provided. Also, if desired, one or more resistance elements can be provided to increase a resistance to the pivoting of the device. Such resistance elements can include any type of device, structure, member, assembly, and configuration that resists the pivotal movement of the treadle assemblies or the rotational movement of the tread belts. The resistance provided by the resistance element may be constant, variable, and/or adjustable. Moreover, the resistance may be a function of load, of time, of heat, or of other factors. Such a resistance element may provide other functions, such as dampening the downward, upward, or both movements of the treadle assemblies. The resistance element can also impart a return force on the treadles such that if the treadle is in a lower position, the resistance element will impart a return force to move the treadle upward, or if the treadle is in an upper position, the resistance element will impart a return force to move the treadle downward. The term “shock” or “dampening element” can be used to refer to a resistance element, or to a spring (return force) element, or a dampening element that may or may not include a spring (return) force.
In addition, various resistance members can be provided to increase the resistance of the rotation of the tread belts around their respective deck member. For example, a friction brake, such as a felt pad, can be provided to resist rotational movement of the tread belts. Alternatively, the resistance member can comprise an eddy current brake, which creates a magnetic field to increase a resistance to the rotational movement of tread belts over their respective decks.
In this manner, the gravity-driven, user-directed downward force F delivers energy to power the one-way drive system 212, which transfers at least a portion of that energy to drive the rotation of tread belts 208 of both treadle assemblies 202, 204. Thus, the potential energy associated with a user supported, at least in part, on a treadle assembly in an upward position can be transmitted into rotational energy sufficient to drive the tread belts of both treadle assemblies. Drive system 212 is operatively coupled (e.g., via a rotational coupling) to tread belts 208 to transmit the potential energy of the user into rotational energy sufficient to drive tread belts 208. The operative coupling of drive system 212 to tread belts 208 is illustrated schematically as a rotational coupling member 216 in
Since each tread belt 208 is rotatable about its respective deck 210, depending on the angle of each respective treadle assembly, a component C of the downward directed force F is also be directed towards a rear portion of each treadle assembly, further facilitating the rotation of tread belts 208 in the first direction D. Thus, in some embodiments, exercise device 200 is driven by both the drive system 212 as it converts potential energy from the user into rotational energy delivered to tread belts 208 and the component C of the downward directed force which also causes tread belts 208 to rotate about their respective decks 210.
In another embodiment, exercise device 200 includes a resistance member 218. Resistance member 218 can include a power generator that is configured to capture energy from the system and store and/or use the energy produced by operation of the exercise device. Alternatively, resistance member 218 may be a user-controlled braking system, as is known in the art, by which the user may control the rotational motion of tread belts 208 relative to pivotal motion of treadle assemblies 202, 204.
In view of the many possible embodiments to which the principles of the disclosed embodiments may be applied, it should be recognized that the illustrated embodiments are only preferred examples and should not be taken as limiting the scope of the invention. Rather, the scope of the invention is defined by the following claims. We therefore claim as our invention all that comes within the scope and spirit of these claims.
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