The present invention relates generally to exercise equipment or exercise machines. More particularly, the present invention relates to elliptical or elliptical-type exercise machines and a method and system for varying or adjusting the stride of the reciprocating foot supports supported on an elliptical exercise machine for one or more purposes, and namely to accommodate different exercise routines and different users.
Exercise machines having alternating reciprocating foot supports configured to traverse or travel about a closed path to simulate a striding, running, walking, and/or a climbing motion for the individual using the machine are well known in the art, and are commonly referred to as elliptical exercise machines or elliptical cross-trainers. In general, an elliptical or elliptical-type exercise machine comprises a pair of reciprocating foot supports designed to receive and support the feet of a user. Each reciprocating foot support has at least one end supported for rotational motion about a pivot point or pivot axis, with the other end supported in a manner configured to cause the reciprocating foot support to travel or traverse a closed path, such as a reciprocating elliptical or oblong path or other similar geometric outline. Therefore, upon operation of the exercise machine to rotate the proximal end, each reciprocating foot support is caused to travel or traverse the closed path. The reciprocating foot supports are configured to be out of phase with one another by 180° in order to simulate a proper and natural alternating stride motion.
An individual may utilize an elliptical or elliptical-type exercise machine by placing his or her feet onto the reciprocating foot supports. The individual may then actuate the exercise machine for any desired length of time to cause the reciprocating foot supports to repeatedly travel their respective closed paths, which action effectively results in a series of strides achieved by the individual to obtain exercise, with a low-impact advantage. An elliptical or elliptical-type machine may further comprise mechanisms or systems for increasing the resistance of the motion, and/or for varying the vertical elevation or height of the closed path. In addition, the reciprocating motion of the feet to achieve a series of strides may be complemented by a reciprocating movement of the arms, whether assisted by the exercise machine via a suitably configured mechanism or system, or unassisted.
A typical closed path may comprise a generally horizontal outline having a longitudinal axis therethrough. Depending upon the exercise machine, a closed path may be many different sizes. As such, a particular measurement of interest to individuals with respect to an elliptical or elliptical-type exercise machine is “stride length.” A stride length is essentially a measurement of the distance separating the two furthest points along the longitudinal axis of the closed path. Therefore, upon actuation of the exercise machine, a single stride may be referred to as travel by the reciprocating foot support, and therefore the foot of a user, along the closed path from a first endpoint on the along the longitudinal axis of the closed path to the a distal endpoint, also on the longitudinal axis. The stride and resulting stride length provided by an exercise machine, although simulated and possibly modified, is comparable to a single stride achieved during natural and/or modified gait of an individual.
Obviously, the strides, and particularly the stride lengths, between different individuals may vary, perhaps considerably. Indeed, a person of small stature will most likely have a much shorter stride length than a person of large stature, and thus will be more comfortable on an exercise machine configured to accommodate his or her particular size and resulting stride length. As such, it is important that the exercise machine function with a stride that corresponds to the stride of the user. The challenge arises when the exercise machine is intended for use by many individuals that may or may not have the same stride length. Moreover, it may be desirable within an exercise routine to vary the speed or frequency of strides along the closed path, the resistance felt, and/or the vertical height of the closed path, wherein some or all of these variable elements may require the user to adapt his or her stride to the changing routine to realize a more natural motion.
Despite their many advantages, and despite recent efforts to attain such, elliptical or elliptical-type exercise machines are devoid of a simple and efficient way to vary their stride length for the purpose of accommodating the stride lengths of individuals of different size and of providing a more natural stride motion. Many prior related exercise machines exist in the art that comprise complex or intricate solutions. However, many of these are difficult to operate at best, and are also expensive to manufacture and cumbersome to assemble as many of them comprise several components or linkages to ultimately achieve a variable stride length.
Another inherent deficiency with the many prior related exercise machines comprising a mechanism or system for varying the stride length of the machine is that they are so complex in design that it would be difficult to utilize the system or mechanism technology on different machines without requiring significant modifications to the machine, if possible at all.
In light of the problems and deficiencies inherent in the prior art, the present invention seeks to overcome these by providing an exercise machine having the ability to be selectively adjusted to vary the stride of alternating reciprocating foot supports supported, and therefore the stride or stride length of a user.
As broadly embodied and described herein, the present invention features an exercise machine comprising: (a) a support structure; (b) a drive component pivotally coupled to the support structure and configured to rotate about a first pivot axis; (c) a reciprocating foot support configured to travel about a closed path having a stride length upon rotation of the drive component; (d) a coupling configuration configured to support the reciprocating foot support about the drive component at a position radially offset from the first pivot axis, the coupling configuration pivotally coupled to the drive component about a second pivot axis; and (e) an adjustment mechanism configured to enable the coupling configuration to pivot about the second pivot axis between at least two adjustment positions to vary the radial offset of the reciprocating foot support with respect to the first pivot axis.
In some embodiments, the reciprocating foot supports are further supported at a position offset from a longitudinal axis of the drive component. In other embodiments, the reciprocating foot supports are further supported at a position along the longitudinal axis of the drive component.
Moreover, in some embodiments, the reciprocating foot support comprises an axis of rotation that allows the reciprocating foot support to properly orbit the drive component during its rotation.
The drive component may comprise a crank, a wheel, or any other structure configured to rotate about a pivot point in a concentric or eccentric manner.
In one exemplary embodiment, the coupling configuration comprises a link having a proximal end pivotally coupled to the drive component, the link being configured to rotate about a second pivot axis positioned offset from the first pivot axis; and a strut extending from a distal end of the link and configured to couple the reciprocating foot support, the strut being radially offset from the first pivot axis and providing an axis of rotation for the reciprocating foot support.
In an exemplary embodiment, the adjustment mechanism comprises a plurality of adjustment apertures formed within the drive component, each of the adjustment apertures being configured to vary the stride length of the reciprocating foot support; a pin contained within the strut and configured to releasably and selectively engage the adjustment apertures upon rotation of the link about the second pivot axis to vary the stride length of the reciprocating foot support; and biasing means configured to bias the pin within the strut.
The present invention also features an exercise machine comprising: (a) a support structure; (b) a drive component pivotally coupled to the support structure and configured to rotate about a first pivot axis; (c) a reciprocating foot support configured to travel about a closed path having a stride length upon rotation of the drive component; and (d) a rotatable engagement member supported within the reciprocating foot support and configured to couple the reciprocating foot support to the drive component at a position radially offset from the first pivot axis, the rotatable engagement member configured to adjust between at least two adjustment positions with respect to the first pivot axis to vary the radial offset of the reciprocating foot support with respect to the first pivot axis to vary the stride length.
The present invention further features an exercise machine comprising: (a) a support structure; (b) a crank having a proximal end pivotally coupled to the support structure and configured to rotate about a first pivot axis; (c) a strut pivotally coupled to the crank at a position radially offset from the first pivot axis, the strut configured to define and travel about a radial path upon rotation of the crank; (d) a reciprocating foot support having a proximal end coupled to the strut and a supported distal end, the reciprocating foot support configured to rotate about the strut and to traverse a closed path having a stride length upon rotation of the crank; and (e) an adjustment mechanism configured to selectively position the strut between at least two adjustment positions to vary the radial offset position of the strut and the reciprocating foot support with respect to the first pivot axis to vary the stride length.
In still another broad sense, the present invention still further features an exercise machine comprising: (a) means for supporting a drive component about a surface, the drive component configured to rotate about a first pivot axis; (b) means for coupling a reciprocating foot support to the drive component at a position radially offset from the first pivot axis, the reciprocating foot support traversing a closed path having a stride length defined by a relative distance between the reciprocating foot support and the first pivot axis; and (c) means for pivoting the means for coupling between at least two adjustment positions to vary the offset position of the reciprocating foot support with respect to the first pivot axis to vary the stride length.
In a more specific description, the present invention features an elliptical exercise machine comprising: (a) a support structure; (b) a crank having a proximal end pivotally coupled to the support structure and configured to rotate about a first pivot axis, the crank comprising a plurality of adjustment apertures formed therein, each being radially offset from the first pivot axis and each defining an adjustment position; (c) a link having a proximal end pivotally coupled to a distal end of the crank, the link configured to rotate about a second pivot axis positioned offset from the first pivot axis; (d) a strut extending from a distal end of the link and configured to provide an axis of rotation radially offset from the first pivot axis, the strut configured to define and travel about a radial path upon rotation of the crank; (e) a reciprocating foot support having a proximal end coupled to the strut and a supported distal end, the reciprocating foot support configured to traverse a closed path having a stride length defined by the radial path; and (f) a pin contained within the strut and configured to selectively engage the adjustment apertures upon rotation of the link to vary the radial offset position of the axis of rotation to vary the stride length of the reciprocating foot support.
Finally, the present invention still further features a method for varying the stride of an exercise machine comprising: (a) providing a coupling configuration configured to couple a reciprocating foot support to a crank at a position radially offset from a first pivot axis; (b) operating the exercise machine to cause the reciprocating foot support to define a radial path about the first pivot axis upon rotation of the crank, and to cause the reciprocating foot support to traverse a closed path having a stride length; (c) causing the coupling configuration to pivot between at least two adjustment positions to adjust the radial offset of the reciprocating foot support with respect to the first pivot axis for the purpose of varying the stride length of the reciprocating foot support.
The present invention will become more fully apparent from the following description and appended claims, taken in conjunction with the accompanying drawings. Understanding that these drawings merely depict exemplary embodiments of the present invention they are, therefore, not to be considered limiting of its scope. It will be readily appreciated that the components of the present invention, as generally described and illustrated in the figures herein, could be arranged and designed in a wide variety of different configurations. Nonetheless, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
The following detailed description of exemplary embodiments of the invention makes reference to the accompanying drawings, which form a part hereof and in which are shown, by way of illustration, exemplary embodiments in which the invention may be practiced. While these exemplary embodiments are described in sufficient detail to enable those skilled in the art practice the invention, it should be understood that other embodiments may be realized and that various changes to the invention may be made without departing from the spirit and scope of the present invention. Thus, the following more detailed description of the embodiments of the present invention, as represented in
The following detailed description and exemplary embodiments of the invention will be best understood by reference to the accompanying drawings, wherein the elements and features of the invention are designated by numerals throughout.
The present invention describes a method and system for varying the stride length of an exercise machine whose components are configured to travel about a closed path, such as an elliptical or elliptical-type exercise machine. Generally, the present invention describes a simple and efficient way to vary the stride length of the exercise machine to accommodate the different strides and resulting stride lengths of different users, as well as to improve the natural motion of the desired type of stride, whether that be walking, running, climbing, or any combination of these.
At the outset, although many of the principles, exercise machines, systems, devices, assemblies, mechanisms, and methods described herein are discussed primarily in terms of their use with those types of elliptical exercise machines having a rear mount drive component or crank that utilizes swing arms, one ordinarily skilled in the art will understand that such principles, exercise machines, systems, devices, assemblies, mechanisms, and methods are adaptable, without undue experimentation, to be useable on an elliptical exercise machine or other similar type of exercise machine having a front mount configuration, wherein the closed path is generated by a front mount drive component, such as on a front mechanical-type exercise machine, or through any other manner, and are similarly adaptable for use on those types of exercise machines having stationary or fixed hand grips or handlebars.
The present invention provides several significant advantages over many prior related exercise machines comprising a system or mechanism for varying stride length within a closed path. First, an adjustment mechanism or system that adjusts the relative position of the reciprocating foot support with respect to the pivot point of the drive component provides a simple and effective solution to stride length variability that may be easily incorporated into several exercise machine designs. Second, by providing an adjustment mechanism configured to pivot about a central axle or pivot point located on the drive component or the crank and to engage one of a plurality of adjustment apertures formed in the drive component or crank, the ease and efficiency of adjustment of the stride length is improved because there are no parts that are releasable from the crank. In other words, everything is contained within the mechanism. Third, the support structure, such as a base or frame support, can be configured to comprise a much smaller foot print, thus changing the foot pad location along the reciprocating foot support. Fourth, the adjustment system or mechanism can be incorporated into a front mount (front mechanical-type) or rear mount (rear mechanical-type) exercise machine, as commonly known in the art. Fourth, different individuals with different strides or stride lengths can use the same machine at the same level of comfort, meaning the same natural simulated stride may be achieved for different individuals.
Each of the above-recited advantages will be apparent in light of the detailed description set forth below, with reference to the accompanying drawings. These advantages are not meant to be limiting in any way. Indeed, one skilled in the art will appreciate that other advantages may be realized, other than those specifically recited herein, upon practicing the present invention.
With reference to
The reciprocating foot supports 14 and 44, as well as the other components of the exercise machine, are supported by a support structure 70. The support structure 70 is configured to provide both structural and translational support to the components of the exercise machine 10, and also to interface with the ground. The support structure 70 generally defines the size of the foot print of the exercise machine 10. The support structure 70 may be any suitable frame-like structure or other configuration. In addition, the support structure 70 may comprise a unitary structure, or a plurality of components all coupled together or in groups. Essentially, the support structure 70 may comprise any suitable design and is not limited in any way herein. In the embodiment shown, the support structure 70 comprises an I-beam base configuration having a longitudinal support beam 74 functioning as the primary support member, and first and second lateral cross beams 78 and 82 located about and extending in opposing directions from each end of the longitudinal support beam 74. Rubber or plastic caps 98 may be situated on the ends of the cross beams 78 and 82. Extending upward from the longitudinal support beam 74 is a vertical or upright support 86 that functions to assist in the support of first and second swing arms 102 and 122. The vertical support 86 may comprise or support various known items or assemblies, such as a user interface, fixed handle bars, cup holders, magazine or book racks, etc. In the embodiment shown, first and second fixed handle bars 90 and 94 are supported atop the vertical support 86.
Each of the second ends 22 and 52 of the first and second reciprocating foot supports 14 and 44 may be supported in any way commonly known in the art to enable the operation of the exercise machine 10, and particularly the reciprocating motion of the reciprocating foot supports 14 and 44. In one exemplary embodiment, the first and second ends 22 and 52 of the first and second reciprocating foot supports 14 and 44 may be pivotally coupled to first and second swing arms, respectively, such as illustrated in
As shown in
The exercise machine 10 further comprises first and second drive components, shown as first and second cranks or crank arms 140 and 160 rotatably supported about the support structure 70 using any known means for supporting. It is contemplated that the present invention may be incorporated into any type of drive component capable of rotating about a pivot point in either a concentric or eccentric manner. However, for the purposes of discussion, the drive component will be described as a crank. The cranks 140 and 160 are preferably in a fixed relationship with respect to one another and are configured to travel along identical repeating circular paths about respective pivot points (see
The present invention exercise machine 10 further comprises means for coupling the reciprocating foot supports to the drive components, respectively. The means for coupling is intended to couple each of the reciprocating foot supports to the respective drive components at a position that is radially offset from the pivot points of the drive components, thus allowing each of the reciprocating foot supports to traverse or travel about a closed path, wherein the closed path comprises a stride length. The stride length is dictated, at least in part, by the relative distance between the reciprocating foot supports and the pivot points of the cranks. The first ends 18 and 48 of the first and second reciprocating foot supports 14 and 44 are rotatably supported about a distal or free end of the corresponding cranks 140 and 160 by a suitable coupling configuration. As so supported, the reciprocating foot supports 14 and 44 are allowed to move rearward and forward along a closed path during operation of the exercise machine 10.
Means for coupling the reciprocating foot supports to the respective drive components may comprise a number of different coupling configurations, several of which are illustrated in the drawings and described herein. Generally, as shown in
Each of the first and second struts 194 and 206 further comprise rotating collars 198 and 210, respectively, configured to rotatably receive and couple the first ends 18 and 48 of the first and second reciprocating foot supports 14 and 44, respectively. The rotatable collars 198 and 210 allow the first and second reciprocating foot supports 14 and 44 to rotate about an axis of rotation as coupled to the struts 194 and 206, wherein the axis of rotation is offset from the pivot points of the cranks 140 and 160. Thus, as the exercise machine 10 is operated and the first and second cranks 140 and 160 rotated along their respective circular paths, the offset position of the axes of rotation of the reciprocating foot supports 14 and 44, as provided by the struts 190 and 206, with respect to the pivot point of the cranks 14 and 44, as well as the suitably supported second ends 22 and 52 of the reciprocating foot supports 14 and 44, causes the reciprocating foot supports 14 and 44 to traverse an elliptical closed path.
The exercise machine 10 may be operated by placing the feet of the user in the respective foot pads 30 and 60 about the respective reciprocating foot supports 14 and 44. The rotational position of the cranks 140 and 160, and the resulting position of the reciprocating foot supports 14 and 44 about the reciprocating foot path are not important as the exercise machine may be started with these components in any position. To perform an exercising motion and to cause the reciprocating foot supports 14 and 44 to traverse the closed path, the user initiates a striding action, which functions to induce a force upon the reciprocating foot supports 14 and 44 to move them in a forward or backward direction, depending upon their initial starting position. Once a single stride has been completed, each reciprocating foot support changes direction to complete a stride in the opposite direction. Essentially, as one reciprocating foot support is moved forward, the other reciprocating foot support is moved backward under a combination of forces resulting from the fixed coupled relationship of the first and second cranks 140 and 160, which causes a force to be applied to each reciprocating foot support from the opposite reciprocating foot support, from the swing arms 102 and 122 tending to apply a compression or tensile force to each of the reciprocating foot supports 14 and 22, respectively, and from the feet of the user applying a force on the reciprocating foot supports 14 and 18. For example, with the exercise machine 10 in the position illustrated in
With reference to
The adjustment mechanisms for adjusting the stride length of the first and second reciprocating foot support 14 and 44 will most likely be the same. In the embodiment shown in
The pin 270 may be slidably coupled within the strut 194 using any known means (see
The second reciprocating foot support 44 comprises a similar coupling configuration and adjustment mechanism as just described, with a pin (not shown) being slidably contained within the strut 206 and configured to selectively engage one of a plurality of adjustment apertures, shown as adjustment apertures 176-a, 176-b, and 176-c, formed in the crank 160 upon rotating the link 240 about its pivot point 254 to reposition the strut 206 and align the pin with the desired adjustment aperture. The adjustment apertures function to define the several available adjustment positions. It is noted herein that the adjustment apertures formed in the cranks need not be throughholes. In addition, any number of adjustment apertures is intended and contemplated herein, as is their radial location with respect to the first pivot axis. As such, those embodiments shown in the drawings and discussed herein are not meant to be limiting in any way.
With reference to
The crank 160 comprises a plurality of adjustment apertures, namely adjustment apertures 176-a, 176-b, and 176-c formed therein. The adjustment apertures are each located at a different radial offset position so as to be able to adjust the relative offset position of the reciprocating foot support with respect to the first pivot axis when attached to the strut 206. The adjustment apertures 176 may further be located along the longitudinal axis of the crank, or offset some length from the longitudinal axis of the crank. In this embodiment, the adjustment apertures are formed along a curve with the adjustment aperture 176-a being located in a radial offset position furthest from the first pivot axis 172 and in an offset position furthest from a longitudinal axis of the crank 160. The longitudinal axis of the crank 160 (or drive component as referred to herein) may be referenced as running lengthwise along the crank 160, through or intersecting the first pivot axis to symmetrically divide the crank 160, as commonly known in the art. In this configuration, as the link 240 is caused to rotate about the pivot point 254 formed in its proximal end 244, the pin contained within the strut 206 may be properly and selectively aligned with any one of the adjustment apertures 176 simply by manipulating the link 240 into a position where the pin is capable of engaging the selected adjustment aperture. In other words, the relative distance of a center axis of the pin from the second pivot axis 254 corresponds to a relative distance of the center axis of each of the adjustment apertures from the second pivot axis 254. Although the link 240, as shown, traces a circular path, it may also be configured to trace an eccentric path, thus providing eccentric formation and location of adjustment apertures about the crank 160. In addition, the adjustment apertures 176 may be oriented about a common linear axis, such as the longitudinal axis, depending upon the type of coupling configuration and adjustment assembly employed.
With reference to
The exercise machine 10-b further comprises means for coupling the reciprocating foot supports 14 and 44 to the cranks 140 and 160, which means may comprise several different types of coupling configurations. In addition, the exercise machine 10-b comprises means for varying its stride length, which means may comprise any number of adjustment systems or mechanisms.
The compact design of the exercise machine 10-b of
With reference to
With reference to
The strut 194 further comprises a pin 270 supported within the strut 194. The pin 270 is slidably supported. The pin 270 comprises a first end 274 extending from the strut 194 a suitable distance so as to engage a selected adjustment aperture 156. The opposing second end 278 of the pin 270 is secured to a handle 286. The handle is configured to be pulled by a user to retract the first end 274 of the pin 270 from the adjustment aperture 156 and to facilitate the repositioning of the pin 270 to engage a different adjustment aperture, such as adjustment aperture 156-b. The pin 270 comprises a ledge 280 configured to engage a similar ledge 282 formed in the support structure of the strut 194, thus preventing the pin 270 from being removed from the strut 194. However, the ledges are spaced apart a sufficient distance to allow the pin 270 to extend and retract as intended. The strut 194 may further comprise biasing means, such as a spring 330, configured to bias the pin 270 to its fully extended position, such as when inserted into an adjustment aperture. The biasing means functions to prevent inadvertent disengagement of the pin 270 from the selected adjustment aperture.
With reference to
The crank 140 comprises a plurality of adjustment apertures, shown as adjustment apertures 156-a and 156-b, formed therein as discussed above. These adjustment apertures are located at a radial offset position from the pivot point 152. The reciprocating foot support 14 may selectively attach to either of these adjustment apertures depending upon the desired stride length.
When attached to the adjustment aperture 156-a, the reciprocating foot support comprises an axis of rotation 202-a radially offset from the pivot point 152, which radial offset is labeled as 1. As the crank 140 is caused to rotate about the pivot point 152, the axis of rotation 202-a at the radial offset 1 traverses about a radial path, which is depicted directly below the crank 140, and labeled as first radial path 204-a. This first radial path 204-a comprises a radial offset from the pivot point 152, which radial offset comprises a distance r1.
Concurrent with the rotation of the crank 140, the reciprocating foot support 14 traverses about a closed path, shown as closed path 36-a. Radial path 1 traversed by the axis of rotation 202-a corresponds to closed path 1 traversed by the reciprocating foot support 14. The closed path 36-a comprises a stride length having a distance L1, as measured from the two furthest opposing points situated about the closed path 36-a and intersecting a longitudinal axis of the closed path 36-a. This distance L1 is commonly referred to as stride length and is the length intended to be adjustable according to the teachings herein.
When attached to the adjustment aperture 156-b, the reciprocating foot support comprises an axis of rotation 202-b radially offset from the pivot point 152, which radial offset is labeled as 2. As the crank 140 is caused to rotate about the pivot point 152, the axis of rotation 202-b at the radial offset 2 traverses about a radial path, which is depicted directly below the crank 140, and labeled as second radial path 204-b. This second radial path 204-b comprises a radial offset from the pivot point 152, which radial offset comprises a distance r2.
Concurrent with the rotation of the crank 140, the reciprocating foot support 14 traverses about a closed path, shown as closed path 36-b. Radial path 2 traversed by the axis of rotation 202-b corresponds to closed path 2 traversed by the reciprocating foot support 14. The closed path 36-b comprises a stride length having a distance L2, as measured from the two furthest opposing points situated about the closed path 36-b and intersecting a longitudinal axis of the closed path 36-b.
Reference letters A1-A4 represent the relative positions of the axis of rotation 202 and the reciprocating foot support 14 about their respective paths during operation of the exercise machine with the axis of rotation 202 set at the radial offset 1. Likewise, reference letters B1-B4 represent the relative positions of the axis of rotation 202 and the reciprocating foot support 14 about their respective paths during operation of the exercise machine with the axis of rotation 202 set at the radial offset 2.
As can be seen, the stride length L1 resulting from the axis of rotation 202 being set at the radial offset 1 is shorter than the stride length L2 resulting from the axis of rotation being set at the radial offset 2. The difference between these distances or stride lengths may be pre-determined and dependent upon the location of the various available radial offsets of the axis of rotation with respect to the pivot point 152 of the crank 140. Nonetheless, utilizing the adjustment mechanisms described herein, the stride length is easily adjusted or varied simply by relocating or adjusting the radial offset of the axis of rotation of the reciprocating foot support with respect to the pivot point of the crank.
It will be obvious to one skilled in the art that the second reciprocating foot support (not shown) functions in the same way, even though such is out of phase 180° and is not specifically set forth herein.
With reference to FIGS. 10-A and 10-B, illustrated is a coupling configuration according to another exemplary embodiment. In this particular embodiment, the reciprocating foot support 414 comprises in one end an engagement member 440 configured to be supported by the reciprocating foot support 414 and to releasably engage one or more corresponding receivers, such as a plurality of apertures or slots, formed within the drive component or crank 540 (see
In another aspect, the drive component itself comprises the necessary rotation components. For example, the receivers formed within the drive component and comprising the at least two adjustment positions may be configured with the rotation components needed for facilitating the rotation of the reciprocating foot support, and particularly the engagement member contained therein, about the crank at the various adjustment positions.
It is also contemplated that, with respect to this embodiment, the exercise machine will comprise a sufficient and capable coupling configuration configured to adequately support the reciprocating foot supports and their adjustability during use of the exercise machine. The types of coupling configurations that may be used for these purposes are not specifically set forth herein, but are well known in the art.
It is noted herein that the struts, as described above, may be utilized with or without a linking configuration. In other words, it is contemplated that the struts discussed above may be coupled directly to the drive components or cranks without the need for a connecting link. The struts in this configuration may still be adjustable by providing an adjustment mechanism or means for adjusting the struts between at least two adjustment positions with respect to the first or crank pivot axis. For example, the struts may be coupled directly to any one the adjustment apertures formed in the drive component shown in
As generally noted above, the above-described present invention methods and systems may also be incorporated into a front mount or front mechanical-type exercise machine, wherein the drive component and/or crank assembly is supported about a front portion of the exercise machine, as commonly known in the art. With reference to
The foregoing detailed description describes the invention with reference to specific exemplary embodiments. However, it will be appreciated that various modifications and changes can be made without departing from the scope of the present invention as set forth in the appended claims. The detailed description and accompanying drawings are to be regarded as merely illustrative, rather than as restrictive, and all such modifications or changes, if any, are intended to fall within the scope of the present invention as described and set forth herein.
More specifically, while illustrative exemplary embodiments of the invention have been described herein, the present invention is not limited to these embodiments, but includes any and all embodiments having modifications, omissions, combinations (e.g., of aspects across various embodiments), adaptations and/or alterations as would be appreciated by those in the art based on the foregoing detailed description. The limitations in the claims are to be interpreted broadly based the language employed in the claims and not limited to examples described in the foregoing detailed description or during the prosecution of the application, which examples are to be construed as non-exclusive. For example, in the present disclosure, the term “preferably” is non-exclusive where it is intended to mean “preferably, but not limited to.” Any steps recited in any method or process claims may be executed in any order and are not limited to the order presented in the claims. Means-plus-function or step-plus-function limitations will only be employed where for a specific claim limitation all of the following conditions are present in that limitation: a) “means for” or “step for” is expressly recited; b) a corresponding function is expressly recited; and c) structure, material or acts that support that structure are expressly recited. Accordingly, the scope of the invention should be determined solely by the appended claims and their legal equivalents, rather than by the descriptions and examples given above.