The term “exercise” refers to a physical activity performed by a human to improve his/her health. Exercise may be performed in an attempt to increase muscle size, to improve balance or coordination, to reduce weight, and to improve cardiovascular endurance. Different exercises or different techniques may be performed in order to work different muscles or different muscle sets.
By way of example, compound lifting movements are designed to improve how muscles perform work. Compound exercises engage multiple different sets of muscles when performing a single movement. To illustrate, the so-called “deadlift” is often considered the most intensive compound weightlifting movement because the movement works a person's gluteus maximus, quadriceps femoris, hamstrings, trapezius, latissimus dorsi, and erector spinae. Other compound exercises work other muscle sets.
Exercise equipment is often used to help build muscle or to help with recovery and therapy.
Often, the exercise machine 100 includes a sufficient number of weights 100 to provide different levels of resistance. For instance, the weights 100 may include multiple 10 pound weights and multiple 20 pound weights. Typically, the exercise machine 100 will include a selection mechanism to enable different combinations of weights to be grouped together to thereby increase the amount of resistance. For example, three 10 pound weights may be grouped together to form a 30 pound resistance.
As one can imagine, the combination of the weights 105 results in a system that is very heavy and difficult to move. The weights 105 also have a large footprint due to their large mass and size. Furthermore, the exercise machine 100 is often quite expensive simply due to the large number or amount of materials needed for its manufacture. Additionally, to prevent the exercise machine 100 from tipping over, it is often the case that the exercise machine 100 is mounted to the ground in some manner. Accordingly, traditional exercise machines are large, expensive, heavy, difficult to maneuver, and require floor mounts. What is needed, therefore, is an improved design for an exercise machine, especially for a pulley-based exercise machine.
The subject matter claimed herein is not limited to embodiments that solve any disadvantages or that operate only in environments such as those described above. Rather, this background is only provided to illustrate one exemplary technology area where some embodiments described herein may be practiced.
Embodiments disclosed herein relate to improved designs for exercise machines that facilitate muscle development and other therapeutics or therapy. Notably, the embodiments provide a selectorized system in which different resistances can be selected to complete an exercise.
In some embodiments, the machine includes a frame and a pulley assembly supported by the frame. The machine further includes a cable extending through the pulley assembly. The cable has attachments at its opposite ends, including an attachment for connecting to a pull handle, and the cable is also connected (either directly or indirectly) to a selectively variable moveable resistance unit. The selectively variable moveable resistance unit is structured to provide an elastic resistance when a pulling force is applied to the connected pull handle. Additionally, the unit is connected to the cable and includes an elastomeric body that provides the elastic resistance and an arc plate that provides a curved support member on which a portion of the elastomeric body at least partially wraps around. Movement of the arc plate, which movement is caused by the pulling force applied to the pull handle, causes the elastomeric body to stretch and to provide the elastic resistance.
In some embodiments, an exercise machine includes a frame, a pulley assembly supported by the frame, and a cable extending through the pulley assembly. The cable has attachments at its opposite ends, including an attachment for connecting to a pull handle, and the cable is also connected (either directly or indirectly) to a selectively variable moveable resistance unit. In this implementation, the selectively variable moveable resistance unit, which is structured to provide a selectively variable elastic resistance when a pulling force is applied to the connected pull handle and which is connected to the cable, comprises a first elastomeric body. The unit also includes a first arc plate that provides a first curved support member on which a portion of the first elastomeric body at least partially wraps around. The unit further includes a second elastomeric body and a second arc plate that provides a second curved support member on which a portion of the second elastomeric body at least partially wraps around. The unit further includes a selection unit for enabling different selection settings of the selectively variable moveable resistance unit. The different selection settings cause the first elastomeric body or a combination of at least the first elastomeric body and the second elastomeric body to provide the selectively variable elastic resistance. Movement of the first arc plate or the first and second arc plates, which movement is caused by the pulling force applied to the pull handle, causes the first elastomeric body or the first and second elastomeric bodies to stretch and to provide the elastic resistance.
In some embodiments, the exercise machine includes a frame, one or more guide rails that are connected to the frame and that are structured to guide connected members along a movement direction, and a height adjustment rail that is connected to the frame and that runs parallel to the one or more guide rails. The machine also includes a pulley assembly that is supported by the frame and that includes at least one pulley. This pulley is connected to the height adjustment rail and is moveable along the height adjustment rail to accommodate different heights of different exercise movements. The machine also includes a cable extending through the pulley assembly. Here, the cable has attachments at its opposite ends, including an attachment for connecting to a pull handle, and the cable is also connected (either directly or indirectly) to a selectively variable moveable resistance unit. The selectively variable moveable resistance unit is operatively connected with the one or more guide rails and is guided in the movement direction by the one or more guide rails when operated. The selectively variable moveable resistance unit is structured to provide a selectively variable elastic resistance when a pulling force is applied to the connected pull handle and is connected to the cable. The selectively variable moveable resistance unit comprises multiple elastomeric bodies that provide the selectively variable elastic resistance when the pulling force is applied to the pull handle. Different selection settings of the selectively variable moveable resistance unit causes one or a combination of multiple elastomeric bodies to be engaged to provide the selectively variable elastic resistance. The unit also includes multiple nested arc plates (e.g., the second arc plate is nested within the first arc plate, the third arc plate is nested within the second arc plate, the fourth arc plate is nested within the third arc plate, and the fifth arc plate is nested within the fourth arc plate). Each nested arc plate provides a curved support member on which a portion of a corresponding elastomeric body at least partially wraps around. The different selection settings of the selectively variable moveable resistance unit causes one or a combination of multiple nested arc plates to be engaged. Movement of whichever ones of the nested arc plates are engaged causes corresponding elastomeric bodies of whichever ones of the nested arc plates that are engaged to stretch and to provide the selectively variable elastic resistance.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
Additional features and advantages will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the teachings herein. Features and advantages of the invention may be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. Features of the present invention will become more fully apparent from the following description and appended claims or may be learned by the practice of the invention as set forth hereinafter.
In order to describe the manner in which the above-recited and other advantages and features can be obtained, a more particular description of the subject matter briefly described above will be rendered by reference to specific embodiments which are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments and are not therefore to be considered to be limiting in scope, embodiments will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
Embodiments disclosed herein relate to improved designs for exercise machines that facilitate muscle development and other therapeutics or therapy. Notably, the embodiments provide a selectorized system in which different resistances can be selected to complete an exercise.
In some embodiments, the machine includes a frame, a pulley assembly, and cable extending through the pulley assembly. The cable has attachments, including an attachment for connecting to a pull handle, and the cable is also connected (either directly or indirectly) to a selectively variable moveable resistance unit (or “unit” for brevity). This unit is structured to provide an elastic resistance when a pulling force is applied to the pull handle. The unit is connected to the cable and includes an elastomeric body that provides the elastic resistance and also includes an arc plate that provides a curved support member on which a portion of the elastomeric body at least partially wraps around. Movement of the arc plate causes the elastomeric body to stretch and to provide the elastic resistance.
In some embodiments, the selectively variable elastic resistance unit (or “unit” for brevity) comprises a first elastomeric body and a first arc plate that provides a first curved support member on which a portion of the first elastomeric body at least partially wraps around. The unit further includes a second elastomeric body and a second arc plate that provides a second curved support member on which a portion of the second elastomeric body at least partially wraps around. The unit further includes a selection unit for enabling different selection settings of the selectively variable moveable resistance unit. The different selection settings cause the first elastomeric body or a combination of at least the first elastomeric body and the second elastomeric body to provide the selectively variable elastic resistance. Movement of the first arc plate or the first and second arc plates causes the first elastomeric body or the first and second elastomeric bodies to stretch and to provide the elastic resistance.
In some embodiments, the exercise machine includes one or more guide rails (e.g., 1, 2, 3, 4, or more than 4 guide rails) that are structured to guide connected members along a movement direction and a height adjustment rail that is connected to the frame and that runs parallel to the one or more guide rails. The machine also includes a pulley assembly that is supported by the frame and that includes at least one pulley. This pulley is connected to the height adjustment rail and is moveable along the height adjustment rail to accommodate different heights of different exercise movements. The selectively variable moveable resistance unit is operatively connected with the one or more guide rails and is guided in the movement direction by the one or more guide rails when operated. The selectively variable moveable resistance unit is structured to provide a selectively variable elastic resistance. The unit includes multiple elastomeric bodies that provide the selectively variable elastic resistance when the pulling force is applied to the pull handle. Different selection settings of the selectively variable moveable resistance unit causes one or a combination of multiple elastomeric bodies to be engaged to provide the selectively variable elastic resistance. The unit also includes multiple nested arc plates. Each nested arc plate provides a curved support member on which a portion of a corresponding elastomeric body at least partially wraps around. The different selection settings of the selectively variable moveable resistance unit causes one or a combination of multiple nested arc plates to be engaged. Movement of whichever ones of the nested arc plates are engaged causes corresponding elastomeric bodies of whichever ones of the nested arc plates that are engaged to stretch and to provide the selectively variable elastic resistance.
As used herein, the term “body” can refer to a band, a tube, or any other type of member. Therefore, the term “body” should be interpretated broadly. Additionally, the terms “connected” and “coupled” (as well as their variants) should be interpretated broadly and should not necessarily mean a rigid or even permanent connection or even a direct linkage. For example, a pulley may be attached to a weight, and a cable can run through the pulley and be attached to a handle. In this sense, the handle is coupled or connected to the weight even though they are not directly linked or attached one to another. Instead, the handle and the weight are connected indirectly via the cable. Furthermore, the cable is “connected” to the pulley even though the cable is not rigidly linked with the pulley and instead is free to move using the pulley. Manipulation of the handle results in manipulation of the weight, thereby leading the handle and the weight to be connected or coupled. As such, terms such as “connected” or “coupled” may refer to direct or even indirect linkages between different components.
As introduced above, instead of using heavy metal weights to provide a resistive force for the exercise machine, the disclosed embodiments utilize elastomeric bodies, which provide an elastic resistance.
Elastic resistive bodies (e.g., the elastomeric body 200) are able to provide resistance in any direction that the body is stretched or elongated. Heavy metal weights, on the other hand, have to be moved or lifted against the gravity vector in order to produce resistance. Elastic resistance is generated in a linear manner by stretching the body. The elastic resistance is dependent on the characteristics of the body, including the body's stiffness, length, width, and thickness. Elastic resistance is dynamic in that the more the elastic body is stretched, the more force will be needed to overcome the elastic resistance.
The resistance that is provided by the disclosed elastomeric bodies is dependent on the respective K constants of the elastic material, where F=k*x, and where “F” is the force of the body, “k” is the (spring/material) constant, and “x” is the (spring/material) stretch or compression. Different body types, widths, thicknesses, and configurations result in different K constants. The different K constants cause the bodies to provide different levels of resistance. As will be seen from this disclosure, the embodiments are highly versatile and customizable because different elastomeric bodies can be used and swapped out one with another to provide a fully customizable resistance-based workout routine. In some embodiments, the elastomeric body 300 is a tube between 1.5 inches and 2.5 inches in width. Of course, different sized bodies may be used.
Having just discussed the properties of elastic resistance, attention will now be directed to
The exercise machine 400 also includes a guide rail 410 and a guide rail 415. Notice, the guide rails 410 and 415 run parallel to a length of the frame 405. The guide rails 410 and 415 guide any members connected thereto along a defined movement direction. In this case, the movement direction is parallel to the length of the frame 405 and the length of the guide rails 410 and 415. Depending on the orientation of the exercise machine 400, the guide rails 410 and 415 may guide the connected members along the gravity vector. The guide rails 410 and 415 are often between ⅜ inch and ½ inch in thickness, though other thicknesses may be used.
The shape of the guide rails 410, 415 can also vary. For instance, the shape may be circular or tube-like. In some cases, the shape may be triangular, square-like, or even rectangular. Other shapes may also be used. As will be described later, the guide rails fit through corresponding guide through-holes located in so-called “arc plates.” One will appreciate how the shape of the guide through-holes will match the shape of the guide rails.
The exercise machine 400 also includes a height adjuster rail 420, which also runs parallel to the length of the frame 405 and the guide rails 410, 415. The height adjuster rail 420 is coupled to a height adjuster 425, which is a unit that allows a height of a frontend pulley to be modified to accommodate different exercise heights or levels. For example, the height adjuster rail 420 includes any number of height adjuster holes, such as height adjust hole 430. The height adjuster 425 can be moved along the height adjuster rail 420 and can be secured in place via use of a pin pushed through the height adjuster 425 into any one of the height adjuster holes, thereby securing the height adjuster 425 in place. In some cases, the various height adjuster holes are spaced apart one from another by about 100 mm, or anywhere between about 50 mm and 200 mm. The width of the height adjuster rail 420 is often between about 20 mm and 60 mm, and is often about 39 mm.
In this example scenario, the height adjuster 425 includes a pulley 435 which is connected to a cable 440. The cable 440 is connected to a handle 445, which is used by a person exercising on the exercise machine 400. The cable 440 is designed to support weight reaching up to even 900 pounds.
By adjusting the height of the height adjuster 425, the height or elevation of the handle 445 can be set to different levels to facilitate different exercises or movements. By way of example, setting the height of the height adjuster 425 to an upper position results in the handle 445 being relatively high. In this position, a person can perform exercises such as a lat pulldown, a close grip front lat pulldown, or a face pull. Manipulating the height adjuster 425 to a middle position along the height adjuster rail 420 can enable a person to perform exercises such as a wrap around row, a cable seated row, and so forth. Manipulating the height adjuster 425 to a lower position along the height adjuster rail 420 can enable a person to perform exercises such as should shrugs, front deltoid raises, lateral deltoid raises, and so forth.
The exercise machine 400 also includes a selectively variable moveable resistance unit 450 (or simply unit 450). As will be discussed in more detail later, the unit 450 may be made from any type of material, including metal, hard plastic, and so on. Consequently, the unit 450 has a non-negligible weight that provides at least some gravimetric resistance. In addition to the base or default gravimetric resistance, the unit 450 also provide an elastic resistance because it incorporates the use of elastomeric bodies. The unit 450 also includes a selection unit 455 that allows an operator (i.e. a person using the exercise machine 400) to engage different ones or combinations of elastomeric bodies so as to provide variable resistance. The machine 400 also includes a body connector base 460, which provides a secure platform or base to connect the elastomeric bodies to. Further details on these features will be provided later.
The selectively variable moveable resistance unit 450 is comprised of a number of components, including (but not limited to) a number of arc plates and a corresponding number of elastomeric bodies.
In some implementations, the so-called “arc” region may be less than a half circle or more than a half circle. In some embodiments, the arc region has a uniform radius. That is, the curved support member can have a uniform curvature radius for areas where the elastomeric body is wrapped around such that the curved support member forms a half circle having a uniform curvature radius. In some embodiments, the arc region is an ellipse having two different radii (e.g., a semimajor axis and a semiminor axis). Accordingly, the term “arc” should be interpreted broadly as including a surface that is curved in any manner. For non-circular arcs, a peak or a cone may be provided and may result in additional stress on the elastomeric body. Consequently, it may be the case that low resistance elastomeric bodies (e.g., bodies that provide less than 10 or 20 pounds of resistive force) are used for arcs that have peaks and high resistance elastomeric bodies are refrained from being used at those arc plates.
The arc plates 500 include a 1st arc plate 505, a 2nd arc plate 510, a 3rd arc plate 515, a 4th arc plate 520, and a 5th arc plate 525. Although only five arc plates are illustrated, one will appreciate how the unit 450 may include more or less arc plates. For example, the unit 450 may include 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or perhaps even more than 10 arc plates. In the configuration shown in
Each arc plate is provided with a first guide through-hole and a second guide through-hole through which one of the guide rails 410, 415 fits through. For example,
In order to engage different ones of the arc plates, each of the arc plates is equipped with a corresponding selector pin hole. To illustrate, the 1st arc plate 505 includes a selector pin hole 540; the 2nd arc plate 510 includes a selector pin hole 545; the 3rd arc plate 515 includes a selector pin 550; the 4th arc plate 520 includes a selector pin hole 555; and the 5th arc plate 525 includes a selector pin hole 560. Notice, the selector pin holes are in-line with one another and are arranged in a manner so as to be parallel to the guide rails. The selection unit 455 from
In accordance with the disclosed principles, an operator can use a selector pin 610 to engage one or a combination of multiple arc plates in order to set a desired elastic resistance. Notice, the arc plates are currently in a nested configuration 615, meaning that one arc plate is nested within another arc plate, and so on and so forth. Further details on this nested configuration will be provided momentarily.
The arc plates also include a number of connector holes, including connector hole 620 and connector hole 625. These holes are provided to secure or fasten a front end of the arc plate to a backend of the arc plate. Further details will be provided later. Bolts, screws, dowels, or any other connection mechanism may be used for such connections.
Each arc plate is comprised of a frontend and a backend portion.
In some embodiments, each arc plate may support or accommodate 2 separate elastomeric bodies. For instance, it may be the case that the curved support member 1000 supports not only the elastomeric body 1005 but also supports a second elastomeric body. More than two bodies may also be used for each arc plate. Furthermore, the body connector base can also support more than one elastomeric body per corresponding connection hole, as will be discussed in more detail later.
Typically, the 1st arc plate (or rather, the elastomeric body associated with the 1st arc plate) provides a lighter resistance than the 2nd arc plate (or rather, the elastomeric body associated with the 2nd arc plate). The 2nd arc plate typically provides a lighter resistance than the 3rd arc plate. The 3rd arc plate typically provides a lighter resistance than the 4th arc plate. The 4th arc plate typically provides a lighter resistance than the 5th arc plate. That being said, the bodies are fully customizable and swappable to accommodate any desired arrangement, even one that is opposite of the above description. In some cases, the resistance provided by the 1st arc plate (and coupled elastomeric body) can have a maximum elastic resistance equivalent to about 8 pounds, 9 pounds, 10 pounds, or more or less. Indeed, use of different types of elastomeric bodies results in different resistance amounts. The machine is fully customizable and the arc plates can support different types of elastomeric bodies and resistances.
The disclosed elastomeric bodies provide a resistance that dynamically changes/increases based on the degree or amount by which the body is stretched. The more the body is stretched, the more resistance is provided. In some cases, the stretch amount of the body can reach even beyond three times the body's original length before that body begins to strain. For every amount the body stretches, the resistive force grows exponentially.
Using the selector pin (e.g., selector pin 610 from
Notice, the guide rail 1215 is provided to guide a movement of the engaged arc plates along a movement direction 1220. As a result of the selector pin being inserted into the selector pin hole of the 3rd arc plate, three elastomeric bodies are engaged and will provide elastic resistance. To illustrate, the elastomeric bodies 1225, 1230, and 1235 are currently being stretched and are currently and simultaneously provided an elastic resistance. The elastomeric body 1225 is the body associated with the 1st arc plate (i.e. arc plate 1200); the elastomeric body 1230 is the body associated with the 2nd arc plate (i.e. arc plate 1205); and the elastomeric body 1235 is the body associated with the 3rd arc plate (i.e. arc plate 1210). Not shown are the elastomeric bodies associated with the 4th and 5th arc plates. Those bodies are currently hidden from view because those arc plates are not being raised. Accordingly, the elastomeric bodies 1225, 1230, and 1235 are currently providing an elastic resistance 1240.
The arc plates 1245 and 1250 are not engaged and thus their respective elastomeric bodies are not contributing to the elastic resistance 1240. In some embodiments (though not all), terminal ends of the elastomeric bodies (e.g., elastomeric bodies 1225, 1230, and 1235) are secured or fixed to a body connector base 1255 to secure those bodies to a fixed position so that they can flex and stretch freely.
On the contrary, the resistance provided by heavy metal weights remains constant throughout the pulling motion of the user. Another significant difference is that the entire weight of the exercise machine is significantly lighter as compared to machines that rely on heavy metal weights to provide their resistances.
Having introduced how the selectively variable moveable resistance unit operates, attention will now be turned to dimensions of the arc plates.
Turning now to the front view, the dimension “A” is shown as being formed from the dimensions “D,” “E,” “J,” “K,” and “I.” The dimension “D” is the dimension for the area that supports the guide through-hole. The dimension “E” is the dimension between the outermost circumference of the 1st arc plate 1500 and the curved support member. The dimension “J” is the dimension or thickness of the curved support member. The dimension “K” is the dimension spanning the region from the innermost circumference of the 1st arc plate to the point where the curved support member begins. The dimension “I” is the dimension of the half circle formed by the curved support member.
As will be seen in later Figures, the dimensions “D,” “J,” and “K” are uniform even between the different arc plates. In this figure, the dimension “L” is formed from the dimensions “E,” “J,” and “K” while the dimension “M” is formed from “L” plus the dimension “D.”
The height of the section supporting the guide through-hole is labeled as having a height “N.”
The connector holes also are shown as having dimensions. Specifically, the outer diameter (OD) of the connector hole is “Q” while the inner diameter (ID) is shown as being “R.”
The dimension “A” is often (though not necessarily) between about 310 mm and about 320 mm, and is often about 313.5 mm or about 343.5 mm. The dimension “B” is often between about 31 mm and 40 mm, and is often about 31.75 mm. The dimension “C” is between about 260 mm and 270 mm, and is often about 261.3 mm. The dimension “D” is often between about 20 mm and 30 mm, and is often about 23.4 mm. The dimension “E” is often between about 2 mm and 5 mm, and is often about 2.7 mm. In some instances, the dimension “E” is less than 2 mm, such as between 0.5 mm and 2.0 mm. The dimension “F” is often between about 15 mm and 25 mm, and is often about 19.05 mm. The dimension “G” is often between about 10 mm and 20 mm, and is often about 12.7 mm. The dimension “H” is often between about 10 mm and 20 mm, and is often about 14.7 mm. The dimension “I” is often between about 220 mm and 230 mm, and is often about 228.6 mm. The dimension “J” is often between about 1 mm and 10 mm, and is often about 6.35 mm. The dimension “K” is often between about 5 mm and 15 mm, and is often about 10 mm. The dimension “L” is often between about 15 mm and 25 mm, and is often about 19.05 mm. The dimension “M” is often between about 40 mm and 50 mm, and is often about 42.45 mm. The dimension “N” is often between about 35 mm and 45 mm, and is often about 40.64 mm. The dimension “O” is often between about 120 mm and 130 mm, and is often about 124.3 mm. The dimension “P” is often between about 110 mm and 120 mm, and is often about 114.3 mm. The dimension “Q” is often between about 5 mm and 15 mm, and is often about 10 mm. The dimension “R” is often between about 5 mm and 15 mm, and is often about 7 mm. Of course, these dimensions are for example purposes only and should not be construed as being binding. Even the ranges are for example purposes only and should not be construed as binding.
The length of the 2nd arc plate 1600 is shown as having a section “D” for the guide through-holes. A new dimension is introduced, as shown by new dimension “T.” Dimension “T” shows how the gap through which the elastomeric body fits is now larger than the gap shown in
Turning now to the front view, the dimension “A” is shown as being formed from the dimensions “D,” “T,” “E′,” “J,” “K,” and “I′.” The dimension “D” is the dimension for the area that supports the guide through-hole. The dimension “T” represents the increase in size for the gap mentioned earlier. The dimension “E′” is the dimension between the outermost circumference of the 2nd arc plate 1600 and the curved support member. The dimension “J” is the dimension or thickness of the curved support member. The dimension “K” is the dimension spanning the region from the innermost circumference of the 2nd arc plate to the point where the curved support member begins. The dimension “I′” is the diameter of the half circle formed by the curved support member. The dimension “I′” is smaller than the dimension “I.”
In this figure, the dimension “L′” is formed from the dimensions “T,” “E′,” “J,” and “K” while the dimension “M′” is formed from “L′” plus the dimension “D.”
The height of the section supporting the guide through-hole is labeled as having a height “N.” A new dimension “S” is also now introduced. The dimension “S” shows how an additional length has been added between the area where the half circle terminates and where the section supporting the guide through-hole begins.
The connector holes also are shown as having dimensions. Specifically, the outer diameter (OD) of the connector hole is “Q” while the inner diameter (ID) is shown as being “R.”
The new dimension “C′” is often between about 205 mm and 215 mm, and is often about 210.5 mm. The dimension “E′” is often between about 5 mm and 15 mm, and is often about 9.05 mm, which is larger than the previous dimension “E.” The dimension “I′” is often between about 175 mm and 185 mm, and is often about 177.8 mm. The dimension “L′” is often between about 40 mm and 50 mm, and is often about 44.45 mm. The dimension “M′” is often between about 60 mm and 70 mm, and is often about 67.85 mm. The dimension “O′” is often between about 90 mm and 100 mm, and is often about 98.9 mm. The dimension “P′” is often between about 80 mm and 90 mm, and is often about 88.9 mm. The dimension “S” is often between about 35 mm and 45 mm, and is often about 40.64 mm. The dimension “T” is often between about 15 mm and 25 mm, and is often about 19.05 mm.
In some embodiments, the dimension “N” for the 1st arc plate is two the dimension “N” for the other arc plates. Such is the case in order to provide additional reinforcement for that arc plate.
Accordingly, in some embodiments, the exercise machine includes a left guide rail and a right guide rail. The arc plate(s) may include a left guide through-hole and a right guide through-hole. The left guide rail extends through the left guide through-hole of the arc plate, and the right guide rail extends through the right guide through-hole. Consequently, the arc plate is free to move in a movement direction, which is defined by the left guide rail and the right guide rail.
In this example scenario, each of the elastomeric bodies includes two terminating ends. Other embodiments, however, may not have terminating ends for the elastomeric bodies. Such embodiments will be discussed in more detail later. In any event, the two terminating ends of each elastomeric body are shown as being connected or coupled to the body connector base 2060. For example, the elastomeric body 2040 includes a body end 2065 and a body end 2070. Both of those body ends are secure in place using the body connector base 2060.
Regarding the top view, the body connector base 2100 includes multiple body holes, such as body hole 2105. An elastomeric body, such as elastomeric body 2110, is configured to fit within the body hole 2105. In some implementations, more than one elastomeric body can fit within the body hole 2106 such that each body hole can accommodate multiple (e.g., 2, 3, 4, 5, 6, or more) elastomeric bodies. In order to lock or secure the elastomeric body 2110 in place, some embodiments use a locking mechanism to prevent the elastomeric body 2110 from slipping or dislodging from the body hole. For example, in this scenario, the elastomeric body 2110 may be configured as a tube body, and a lock ball 2115 (e.g., a 10 mm BB ball or some other sized ball or plastic ball) can be inserted into the terminal end of the elastomeric body 2110. The lock ball 2115 prevents the elastomeric body 2110 from being released from the body hole. A pinching device or clamp or any type of tie-down may also be used to lock the body in place.
The number of body holes corresponds to the number of elastomeric bodies and the number of arc plates that are incorporated into the exercise machine. For example, if the exercise machine includes only a single arc plate and elastomeric body combination, then it may be the case that only a single body hole is provided. If 2, 3, 4, 5, or more than 5 arc plate/elastomeric bodies are used, then a corresponding 2, 3, 4, 5, or more than 5 body holes may be provided. In some cases, 2 or more bodies may use the same body hole, such as when a single arc plate supports multiple bodies.
Optionally, the location of the body hole is horizontally in-line with the terminal end portion of the curved support member. For instance, with reference to
Returning to
Referring to the top view, the length of the body connector base 2100 is often between about 300 and 330 mm, and is often about 313.5 mm or about 343.5 mm. The width is often between about 20 mm and 50 mm, and is often about 38.1 mm. The spacing between one body hole and another is often between about 5 mm and 20 mm, and is often around 12.7 mm. The width of a body hole is often between about 1 mm and 10 mm, and is often about 3.18 mm.
The exercise machine also includes a cable 2235 extending through the pulley assembly 2210. The cable 2235 has attachments at its opposite ends, including a first attachment 2240 and a second attachment 2245. The first attachment 2240 is structured to connect to a pull handle 2250, and the second attachment 2245 is potentially structured to connect to the selectively variable moveable resistance unit 2255. In some cases, the second attachment 2245 is connected to the height adjuster mentioned earlier. In any event, the cable 2235 is either directly or indirectly connected to the selectively variable moveable resistance unit 2255. For instance, the cable 2235 may be directly connected to the selectively variable moveable resistance unit 2255 when the second attachment 2245 is coupled to the selectively variable moveable resistance unit 225, such as in the case of a single handle configuration. The cable 2235 may be indirectly connected to the selectively variable moveable resistance unit 2255 when the cable extends through a pulley connected to the selectively variable moveable resistance unit 2255, such as in the case of a dual handle configuration.
The selectively variable moveable resistance unit 2255 is structured to provide an elastic resistance when a pulling force is applied to the connected pull handle 2250. Additionally, the unit 2255 is connected to the cable 2235.
As discussed previously, the unit 2255 comprises an elastomeric body (or multiple bodies) that provides the elastic resistance and an arc plate (or multiple arc plates). The arc plate provides a curved support member on which a portion of the elastomeric body at least partially wraps around. Movement of the arc plate, which movement is caused by the pulling force applied to the pull handle 2250, causes the elastomeric body to stretch and to provide the elastic resistance.
In some embodiments, the unit 2255 includes multiple elastomeric bodies and multiple arc plates. By way of example, the unit 2255 may include a first elastomeric body (e.g., perhaps elastomeric body 2035 from
The unit 2255 may include a second elastomeric body (e.g., elastomeric body 2040 from
The unit 2255 may further include a selection unit (e.g., selection unit 600 from
Optionally, the exercise machine may include one or more guide rails (e.g., guide rails 410, 415) that are connected to the frame (2200) and that are structured to guide connected members (e.g., the unit 2255) along a movement direction (e.g., movement direction 1220). As will be discussed in more detail later, the guide rails 410, 415 also help ensure that various so-called “arc plates” (to be discussed later) are moved in a manner to ensure proper nesting between the different plates. In this regard, misalignments between the plates is prevented.
The machine can include a height adjustment rail 2205 that is connected to the frame 2200 and that runs parallel to the one or more guide rails. The pulley assembly 2210 is supported by the frame 2200 and includes at least one pulley (e.g., pulley 2225). This pulley 2225 is connected to the height adjustment rail 2205 and is moveable along the height adjustment rail 2205 to accommodate different heights of different exercise movements. One or more of the pulleys may be mounted to the frame.
The selectively variable moveable resistance unit 2255 is operatively connected with the guide rails and is guided in the movement direction by the guide rails when operated. That is, the exercise machine includes one or more guide rails that guide the movement of the arc plate(s) in the movement direction.
The unit 2255 is structured to provide a selectively variable elastic resistance when a pulling force is applied to the connected pull handle 2250. The unit 2255 is connected to the cable 2235. Furthermore, the unit 2255 includes a number of components, such as a plurality of elastomeric bodies that provide the selectively variable elastic resistance when the pulling force is applied to the pull handle. Different selection settings of the selectively variable moveable resistance unit 2255 (e.g., using the selection unit 600 of
The unit 2255 also includes a plurality of nested arc plates, as described previously. Each nested arc plate provides a curved support member on which a portion of a corresponding elastomeric body at least partially wraps around. The different selection settings of the selectively variable moveable resistance unit causes one or a combination of multiple nested arc plates to be engaged. Movement of whichever ones of the nested arc plates are engaged causes corresponding elastomeric bodies of whichever ones of the nested arc plates that are engaged to stretch and to provide the selectively variable elastic resistance.
Because the unit 2255 itself has a non-negligible weight to it, the unit 255 further provides a gravimetric resistance. Consequently, both the gravimetric resistance and the elastic resistance are simultaneously provided during the movement of the arc plate(s).
Up to this point, the disclosure has described embodiments where the elastomeric bodies have terminating ends that are secured in place. Some embodiments may use elastomeric bodies that do not have terminating ends but that are loops, such as the one shown in
Due to their high weight and large footprint, traditional exercise machines are normally secured in place using ground connection mechanisms, such as floor bolts. Because the disclosed embodiments have a much smaller footprint and a much lighter weight, the disclosed exercise machines can actually be mounted to a wall as opposed to only the floor. That is, in addition to the ability to be mounted to the floor, the disclosed exercise machines also have the option of being wall mounted.
In some instances, the wall mount 2910, as shown, has a protruding arm that extends outwardly from the wall. The arm includes a recessed or dipped portion, which is designed to accommodate the wall mount connection 2905. When the wall mount connection 2905 is disposed within the recessed portion of the arm, the exercise machine is secured in place.
Optionally, other connection techniques may be used. Examples include, but are not limited to, bolts, screws, clasps, latches, and so forth. Indeed, any type of connection mechanism may be used to secure the frame 2900 to the wall mount 2910.
In the illustration shown in
The wall mount connection 2905 may also be located on the top portion of the frame 2900 and/or on the bottom portion of the frame 2900. Any number of wall mount connections may be used.
Some embodiments use a U-bracket to mount the exercise machine to the wall. The U-bracket may be as wide as the machine and can be used to support the machine against the wall. The U-bracket can be on the bottom of the machine or some other location. Some embodiments mount wheels on the bottom of the machine to help the machine be easily moveable. Typically, the machine is lifted about 3 inches off of the ground because, in some embodiments, pulleys are provided on the bottom portion of the machine.
Because the disclosed embodiments refrain from using heavy metal weights to provide resistance, the weight of the entire unit is orders of magnitude lighter than the weight of traditional exercise machines. For example, in some cases, the weight of the entire unit is 20 pounds, 25 pounds, 30 pounds, 35 pounds, 40 pounds, 45 pounds, 50 pounds, 55 pounds, 60 pounds, 65 pounds, 70 pounds, 75 pounds, 80 pounds, 85 pounds, 90 pounds, 95 pounds, or less than 100 pounds. The weight may be anywhere in between 20 pounds and 100 pounds.
Despite the weight being between only 20 to 100 pounds, the exercise machine is able to provide resistive force spanning between 1 pound and over 200 pounds. In some cases, the provided resistive force may be between 1 pound and 300 pounds. Using the selection unit as well as the ability to swap out different types of elastomeric bodies, the unit is also highly customizable and can provide drastically varying levels of resistance, which customizability is not achievable using traditional systems. Accordingly, in some embodiments, the frame includes connections for mounting the exercise machine to a wall, and a weight of the exercise machine is less than 60 pounds. In some implementations, the selectively variable elastic resistance is equivalent to more than a 250 pound gravimetric weight. Due to the use of elastomeric bodies, as the pulling force applied to the connected handle increases, the selectively variable elastic resistance increases such that the selectively variable elastic resistance does not remain constant during movement of the arc plates.
The present invention may be embodied in other specific forms without departing from its characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
This application claims the benefit of and priority to U.S. Provisional Patent Application Ser. No. 63/091,591 filed on Oct. 14, 2020 and entitled “STRENGTH/FITNESS MACHINE WITH ARC PLATES,” which application is expressly incorporated herein by reference in its entirety. This application also claims the benefit of and priority to U.S. Provisional Patent Application Ser. No. 62/991,949 filed on Mar. 19, 2020 and entitled “EXP STRENGTH ARC PLATE,” which application is expressly incorporated herein by reference in its entirety.
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