Exercise apparatuses commonly employ a weight stack actuated by a cable which is pulled by users of the apparatus. Recently, resistive elastic members, such as bands or plates, have been incorporated into exercise equipment to provide motion resistance. Specifically, resistive elastic members have gained increased popularity due to their ability to provide substantially consistent tension throughout the desired range of motion and generate an increased use of stabilizer muscles to oppose the substantially consistent tension while providing resistance in a large number of directions and ranges of motion.
While the use of resistive elastic members provides many benefits, a number of the traditional apparatus configurations can present limitations affecting the usefulness of the exercise apparatus. For example, the range of exercises which may be performed with certain cable actuated apparatuses is sometimes limited by the position and orientation of the apparatus itself. Particularly, with the added range of motion and resistance offered by the use of resistive elastic members, such as bands and plates, consumer needs and considerations are often at odds. Particularly, the safety considerations of providing a stable apparatus are constantly at odds with the desire for a system that is relatively compact while providing the ability to perform full body exercises and allow the user to take advantage of a full range of motion.
One type of resistance band apparatus is disclosed in U.S. Pat. No. 6,626,801 issued to Jean Pierre Marques. In this patent, an exercise system includes a pair of elongate side members, a plurality of bar members extending between the side members, a plurality of eyelets attached to a front edge of the side members, and a mat member pivotally attached to a lower portion of the side members. A plurality of attachments can be attached to the bar members and the eyelets to allow the performance of various exercises. An alternative resistance based apparatus is also disclosed in U.S. Pat. App. No. 20080020912 assigned to ICON IP, INC. In this patent, an exercise machine has resilient elongate members for providing balanced resistance in the form of elongate resilient members oriented horizontally such that the intermediate portion of the elongate members contact a fulcrum of the exercise machine.
In one aspect of the disclosure, an exercise apparatus includes a base, a first vertical support member coupled to the base, a second vertical support member coupled to the base, and at least one resistance assembly coupled to the first vertical support member and the second vertical support member. According to this aspect of the disclosure, the first and second vertical support members converge relative to one another to form a first vertex and a second vertex. Furthermore, the first support member and the second support member diverge relative to one another above the first and second vertex.
Another aspect of the disclosure may include any combination of the above-mentioned features and may further include a first resistance assembly disposed on the first vertical support member and a second resistance assembly disposed on the second vertical support member.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include at least one resistance assembly having at least one elastic resistance member, the at least one elastic resistance member having a first end and a second end. A first coupling feature may be connected to the first end of the at least one elastic resistance member and a second coupling feature may be connected to the second end of the at least one elastic resistance member. Furthermore, a guide system may be included corresponding to the at least one elastic resistance member, the guide system may couple the resistance assembly to one of the vertical support structures using at least three guides, a first guide coupled to a top portion of the vertical support member above the vertex, a bottom guide coupled to a bottom portion of the vertical support member below the vertex, and an intermediate guide corresponding coupled to the vertex of the vertical support member.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include an opening defined in the top guide and the bottom guide, the opening being configured to facilitate passage of the at least one elastic resistance member. According to this embodiment, the first coupling feature and the second coupling feature connected to the ends of the elastic resistance member each have a maximum width that is greater than the opening defined by the top guide and the bottom guide such that they act as anchors when the opposing feature is actuated.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include a vertically oriented base extension member having a first end and a second end, wherein the first end of the vertically oriented base extension member is coupled to a back portion of the base, and a back pad coupled to the second end of the vertically oriented base extension member. According to this embodiment, the back pad is disposed at the vertex of the first vertical support member and at the vertex of the second vertical support member.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include a support bar coupled to the second end of the vertically oriented base extension member, wherein the support bar is configured to project parallel to the base around the vertex of the first vertical support member and the vertex of the second vertical support member in a first position.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include a pivot assembly coupling the support bar to the second end of the vertically oriented base extension member, wherein the pivot assembly is configured to selectively position the support bar in the first position and a second position. According to this embodiment, the second position includes the support bar oriented substantially perpendicular to the base.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include a substantially horizontal protrusion disposed on top of each of the first and second support member.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include a horizontally oriented pull-up bar traversing the substantially horizontal protrusion disposed on top of each of the first and second support member substantially above a median plane of the base.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include the base having a front surface, a back surface, a first side surface, and a second side surface. According to this embodiment, the first vertical support member is coupled to the base near a midpoint of the first side surface, the second vertical support member is coupled to the base near a midpoint of the second side surface, the first and second vertical support member below the first and second vertex is oriented toward the back surface of the base, and the first and second vertical support member above the first and second vertex is oriented toward the front surface of the base.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include the first vertex and the second vertex being coincident.
Yet another aspect of the disclosure may include any combination of the above-mentioned features and may further include the first vertical support member and the second vertical support member coupled near the vertex.
The accompanying drawings illustrate various embodiments of the present method and system and are a part of the specification. The illustrated embodiments are merely examples of the present system and method and do not limit the scope thereof.
a is a bottom view of a selectively rotational coupler on the resistance based exercise apparatus, according to one exemplary embodiment.
b is a top view of a selectively rotational coupler on the resistance based exercise apparatus, according to one exemplary embodiment.
Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements.
A stable apparatus configured to take up a relatively small amount of floor space while providing for numerous resistance based exercises and substantially unobstructed movement is provided herein. Specifically, the present exemplary system provides a compact exercise system that enables the performance of multiple exercises. Additionally, as will be described below with reference to the Figures, the present exemplary system may also assume a number of different stable configurations to facilitate the performance of various exercises while maximizing the freedom of motion for the user. All of these previously contradictory interests are simultaneously satisfied by the present exemplary system. A number of exemplary structures and methods of the present resistance based exercise system are described in detail below.
Exemplary Structure
With reference to
As noted, the present exemplary resistance based exercise system 100 includes a base 110. The base 110 serves as the support structure for the remaining system 100 and engages the floor or other surface upon which the system is positioned and upon which the desired exercises will take place. Consequently, as illustrated, the base 110 includes a platform 112 that provides a substantially flat surface for performing a plurality of exercises while enlarging the stabilizing footprint of the base. According to this exemplary embodiment, during use, the weight of the user is applied to the platform 112 and distributed across the platform and base support 114 to enhance the effective footprint of the base 110, thereby stabilizing the system 100 during operation. The platform 112 may include any number of non-slip surfaces or friction enhancing materials to aid in the stabilization of the user and prevent unintentional motion while exercising. Furthermore, the platform 112 may be made of any number of durable materials including, but in no way limited to, a plastic, a metal, a composite, and the like. According to one exemplary embodiment, the base 110 is formed of a structural plastic in a substantially triangular shape to facilitate placement of the system 100 in a corner of a room while establishing at least three points of contact with the floor or other surface. Alternatively, the base 110 may assume any number of desired configurations aimed at balancing weight, stability, storability, and/or room placement.
Additionally, as illustrated in
Continuing with the base structure 110, a base extension 116 is fixedly coupled to the base support 114 and protrudes in a vertical direction. According to the illustrated embodiment, the base structure 110 may be coupled to the base support via any number of joining techniques including, but in no way limited to a weld, fasteners, and the like. According to the illustrated embodiment, the base extension 116 protrudes vertically to provide a mounting location for a back pad 138 that defines a user location during operation. As shown in the exemplary figures, one or more mounting members 240 may be coupled to both the base extension 116 and the back pad 138 to define the positional height of the back pad 138. The coupling of the back pad 138 to the one or more mounting members 240 may be fixed or, alternatively, may be adjustable to vary the back pad position according to the user's height and preferences. Additionally, as illustrated, the vertically oriented base extension 116 defines the back plane of the base 110 and functions as a mounting point for a collapsible support bar pivot assembly 200, as will be discussed in further detail below, with reference to
Continuing with the exemplary embodiment illustrated in
According to one exemplary embodiment, the convergence and subsequent divergence of the first and second vertical support structures 118 relative to one another provides a number of advantages to the present exemplary system 100. Specifically, the convergence and subsequent divergence of the first and second vertical support structures 118 relative to one another provides for the maximum range of motion to be available for a user when performing exercises in the arm/shoulder actuation zone. That is, if the first and second vertical support structures 118 did not assume a converging and diverging orientation, but rather had a linear configuration (e.g., substantially maintaining their distance from one another as they extend vertically from the base support 114 to their upper most extents), the areas directly proximal or distal to a user's elbows, depending on their orientation, would be occupied by the vertical support structures 118 and would thereby limit the user's ability to have a full range of movement of his/her arms. However, as illustrated in
Additionally, the convergence and divergence of the vertical support structures 118 enhance the stability of the structure 100. Particularly, according to one exemplary embodiment, when viewed from the extreme points of the vertical support structures 118, when a user actuates the resistance assembly 120, a force, equal and opposite to the force exerted by the user, is applied to the system. Due to the “X” shape assumed by the vertical support structures 118, the opposing or reactive force inserted into the system at the extreme points of the vertical support structures 118 is directed toward the center of the vertical support structures, rather than toward the edge of the base 110, thereby maintaining the stability of the system 100.
Additionally, as illustrated in
According to the present exemplary embodiment, the vertical support structures 118 are fabricated of hollow tubing to balance both strength and weight considerations. While the present exemplary system is illustrated with the vertical support structures 118 being formed of steel tubing having a substantially circular cross-section, the vertical support structures 118 may assume any number of cross-sectional configurations configured to provide the desired structural strength including, but in no way limited to, oval, box, rectangular, I-beam, and the like. Additionally, according to one exemplary embodiment, the vertical support structures 118 are formed of a metal such as, but in no way limited to, steel, aluminum, and the like. Alternatively, any sufficiently stable material, or combination of materials may be used to form the present exemplary vertical support structure including, but in no way limited to, composites, polymers, etc.
Continuing with
As shown, each of the plurality of elastic members 122 includes a coupling feature 125 on each end of the elastic member that is configured to be coupled, either independently or with additional coupling features 125, via a carabineer or other coupling device (510,
While the present exemplary system 100 is illustrated and described, for ease of explanation, as incorporating a resistance assembly utilizing elastic members such as bands, plates, and the like, any number of resistance systems may be incorporated by the present system including, but in no way limited to a cable system including an actuated weight stack.
As noted above, the resistance assembly 120 including the elastic members 122 may, according to one exemplary embodiment, be coupled to the vertical support structures 118 via a plurality of guides. According to one exemplary embodiment, the guides include a number of grooved rollers. As shown in
According to the present exemplary embodiment, the top 126, bottom 124, and intermediate rollers 128 are pivotably coupled to the vertical support structure to add an increased freedom of motion. Specifically, according to one exemplary embodiment, the top rollers 126 and bottom rollers 124 are configured to independently pivot, relative to the other rollers, according to the directional actuation of the elastic member(s) 122. According to one exemplary embodiment, the lateral pivoting of the top rollers 126 and bottom rollers 124 ensures that the actuation of the elastic member(s) 122 from various angles can be performed smoothly and without abrupt movements or binding that may otherwise inhibit a full range of motion by the user and could cause joint stress and injury.
As illustrated in
While the present exemplary embodiment is described in the context of using a plurality of rollers as guides to channel and direct the elastic members 122 through a change in direction, any number of guides may be used to channel the elastic members 122 including, but in no way limited to, low friction cylinders, bearings, and the like.
As noted previously, and as illustrated in
As noted previously, the collapsible support bar 130 is rotatably coupled to the top portion of the base extension 116, according to one exemplary embodiment, by a collapsible support bar pivot assembly 200.
As illustrated in
When a user then desires to perform a desired exercise where arm clearance is desired, the collapsible support bar 130 may be rotated to a second stable position. According to one exemplary embodiment, the collapsible support bar 130 is rotated to a second position by removing the pin 410 from the pin receiving collar 420 and the orifices defined in the plurality of tabs 405. According to this exemplary embodiment, the previously established two points of contact are reduced to one and the collapsible support bar 130 is free to rotate about the hinged member 430. According to one exemplary embodiment illustrated in
According to one alternative embodiment illustrated in
In general, the structure of the present exemplary disclosure provides an apparatus having a relatively small footprint while enabling the performance of numerous full range motion exercises. More specifically, the present exemplary apparatus includes a frame made of a number of vertically oriented support members that converge relative to one another from the base they are coupled to until they each form a vertex, upon which the support members then diverge. This configuration minimizes the size of the system's stabilizing footprint by allowing space for the user's arms to operate around the vertically oriented structure. That is, the combined distance between the outer surfaces of the vertical support members is minimized where the vertices meet. This area is, according to one exemplary embodiment, designed to coincide with the area a typical user would desire space to perform various full range arm exercises. By positioning the vertices according to the present disclosure, a user's arms may actually employ a range of motion that includes areas behind the support members. Furthermore, the range of motion is accomplished while maintaining stability of the system. Particularly, the converging and subsequently diverging nature of the vertical support members minimizes the likely generation of a tipping force on the apparatus as reactionary forces caused by actuation of the system are transferred to stable portions of the base.
In some configurations, at least one resistance assembly including at least one elastic member is coupled to the vertical support members to allow for the performance of resistance based exercises. In this embodiment, the resistance members are coupled to the vertical support frame by a system of at least three guides, such as rollers. Placement of the guides at the upper and lower extremes of each vertical support frame as well as at or near the vertex of each vertical support frame results in the resistance members generally following the orientation of the vertical support frames and preserving the area surrounding the arms of a user free from system elements.
Furthermore, according to one configuration, the vertical support members of the frame are oriented such that they both initially angle from the base toward the back of the system. The backward directed angle of the vertical support members terminates at the vertices and the support members are then directed forward. This configuration also increases the space available for movement of the user's arms while maximizing stability. The initial angle of the vertical support members may originate near the median plane of the base to further add to the stability of the apparatus.
Optionally, a selectively collapsible support bar may also be rotatably coupled to the system via a vertically oriented base extension disposed on the rear portion of the base. The inclusion of the selectively collapsible support bar allows for the performance of a number of body-weight based exercises. Additionally, as disclosed above, the selectively collapsible support bar is sized such that with the actuation of a pivot assembly, the collapsible support bar is rotated to a vertical position behind the vertical support structures. When in this position, the arm motion of the user remains uninhibited.
In conclusion, the present system and method provides a compact exercise system that enables the performance of multiple exercises by maximizing the user's freedom of motion without compromising the stability of the resulting system. More specifically, the present exemplary system assumes a plurality of different stable configurations to facilitate the performance of various exercises while maximizing the freedom of motion for the user.
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