FIELD OF THE INVENTION
This document concerns an invention relating to exercise devices incorporating elastic members.
BACKGROUND OF THE INVENTION
Exercise devices are known which use one or more hand grips, each bearing at least one elastic cord engaged to an anchor point. By varying the elasticity of the elastic cords, the devices can be configured to provide different resistances to stretching. Resistance is experienced by a user when one end of an elastic cord is fixed to an anchor point while the hand grip at the other end is pulled away from the fixed end. The elastic cord may be anchored to an immobilized object such as a wall, floor, or door frame, or the elastic cord may be anchored to a part of the user's body. Elastic cords that provide such resistance can substitute for weights, and in general the greater the resistance of an elastic cord, the greater the maximum weight that can be simulated.
Elastic cords may, over time, wear and break. Elastic cords become particularly vulnerable to wear and breakage at their points of attachment to exercise components because of the greater strain at this area. As such, what is needed is a way of attaching elastic cords to exercise devices that imposes less strain on the elastic cords, making them less susceptible to wear and breakage.
Separately, an exercise hand grip incorporating a particular elastic cord is limited to providing the stretch resistance resulting from its particular elastic cord. If an operator would like to simulate three different weights, for example, the operator traditionally must obtain three different exercise devices that incorporate three different elastic cords, each elastic cord having a different elasticity. Replacing exercise hand grips each time a different resistance is desired is costly. What is needed is an exercise hand grip that permits the operator to conveniently replace the elastic cord to be used without replacing the whole device.
SUMMARY OF THE INVENTION
The invention, which is defined by the claims set forth at the end of this document, is generally directed, among other things, to exercise devices with flexibly pivotal points of attachment for their elastic cords that relieve strain and make the elastic cords less susceptible to breakage. The invention also relates generally to exercise hand grips with handles that permit convenient installation and replacement of elastic cords. The features of this invention can be incorporated into exercise devices individually or in combination. Although some of the figures and diagrams may depict a device that incorporates, for example, both a flexibly pivotal point of attachment as well as a hand grip that permits convenient replacement of elastic cords, these features are independent and thus they need not be combined to provide their respective benefits and advantages.
Referring initially to FIG. 1, an exemplary exercise device 10 includes a foot cuff 20 and a hand grip 30, with an elongated elastic member 40 extending between the two. The elastic member 40 has an elastic member first end 42 removably secured to the foot cuff 20, and an elastic member second end 44 removably secured to the hand grip 30. A user 50 may insert a foot 52 through a foot passage 215 and grip the hand grip 30 with a hand 54, stretching the elastic member 40 between the foot 52 and the hand 54 while walking, jogging, running, performing calisthenics, or other exercises. As shown in FIG. 2A, the foot cuff 20 includes a foot cuff body 200 with a rigid foot cuff section 205 and a flexible foot cuff section 210, the rigid and flexible foot cuff sections 205, 210 defining the foot passage 215 sized to receive the foot 52 (or a shoe) therethrough. Referring to FIG. 4, the hand grip 30 may be elongated to allow for easier gripping with the hand 54, extending from a hand grip top side 305 to an opposing hand grip bottom side 310. The hand grip 30 includes a hand grip channel 315 formed therein, the hand grip channel 315 extending the length of the hand grip 30 and able to receive the elastic member 40 therethrough.
Referring to FIGS. 2A and 2B, a foot cuff body passage 220 is defined in the rigid foot cuff section 205, the foot cuff body passage 220 extending from a foot cuff body inner side 225 to a foot cuff body outer side 230. A foot cuff pivot 235 is pivotally fit in the foot cuff body passage 220, the foot cuff pivot 235 sized such that it cannot pass through the foot cuff body passage 220 at the foot cuff body outer side 230. The foot cuff pivot 235 includes a pivot enlarged portion 240 partly situated within the foot cuff body passage 220, and a pivot plug 245 extending from the pivot enlarged portion 240 away from the foot cuff body inner side 225. The elastic member first end 42, which includes an elastic member socket 46 defined therein, is secured to the foot cuff pivot 235 by inserting the pivot plug 245 into the elastic member socket 46.
Referring to FIG. 5, the hand grip 30 may include a chamber 320 sized to stow at least a portion of the elastic member 40 at the hand grip top side 305. The chamber 320 is preferably situated to receive the elastic member 40 extending from the hand grip channel 315. A closable lid 325 covering the chamber 320 may be situated over the hand grip top side 305, the lid 325 being movable to open and close the chamber 320. The stowed portion of the elastic member 40 is preferably secured within the chamber 320 when the lid 325 is closed. The hand grip 30 may include an impinger 330 secured thereto (e.g., within the chamber 320), the impinger 330 configured to impinge on the elastic member 40 extending through the hand grip channel 315 to secure the elastic member 40 to the hand grip 30. The impinger 330 may be configured to hinge between an engaged position (as shown in FIG. 5) in which the impinger 330 at least partially enters the hand grip channel 315 to impinge on the elastic member 40 extending through the hand grip channel 315, and a disengaged position (not pictured) in which the impinger 330 does not enter the hand grip channel 315.
As an aid to performing push-up or other exercises with the hand grip 30, a bottom side protrusion 340 may extend outward from the hand grip bottom side 310 in a direction that is perpendicular to the long axis of the hand grip 30. With the protrusion 340 pressed against a floor, the user's 50 fingers and knuckles can be distanced from the floor when the user 50 grips the length of the hand grip 30 and performs pushups.
Alternatively or additionally, the hand grip 30 may include an upper flange 605, and a lower flange 610 spaced therefrom, the upper and lower flanges 605, 610 radially extending outward from the hand grip 30 and circumferentially orbiting the hand grip channel 615, as shown in FIG. 6A. The upper and lower flanges 605, 610 are substantially parallel to each other, and situated near the top of the hand grip 30. A hand grip valley 620, also circumferentially orbiting the hand grip 30, is formed in the space between the upper and lower flanges 605, 610. The upper flange 605 has an upper flange inner surface 606 facing the hand grip valley 620, and an opposing upper flange outer surface 607 facing upwards. The lower flange 610 has a lower flange inner surface 611 facing the hand grip valley 620, and an opposing lower flange outer surface 612 facing downwards. As shown in FIG. 6B, the hand grip valley 620, which is sized such that at least a portion of the elastic member 40 fits therein, allows the user 50 to feed the elastic member 40 through the channel 615 wrap an unused portion of the elastic member 40 around the hand grip 30. To help secure the elastic member 40 to the hand grip 30, the hand grip 30 includes a groove 630 that is sized to receive the elastic member 40 and restrict its movement therethrough. The groove 630 may be in the upper flange 605 (as shown), extending between the upper flange outer surface 607 and the upper flange inner surface 606, and/or the lower flange 610 (not pictured), extending between the lower flange inner surface 611 and the lower flange outer surface 612. The groove 630 opens onto the hand grip valley 620 so that the elastic member 40 can extend from the hand grip valley 620 and into the groove 630.
An exemplary method of using the exercise device 10 may include feeding the elastic member through the hand grip channel 315, 615 and adjusting the position of the elastic member 40 to a desired position (i.e., to a desired unstretched separation between the foot cuff 20 and the hand grip 30). A first portion of the elastic member 40 may be wrapped around the hand grip channel 315 within the hand grip valley 620, and the elastic member 40 may be locked in the desired position by installing the elastic member 40 within the groove 630 (see FIGS. 6A and 6B) or by engaging the impinger 330 (see FIG. 5). With a foot 52 inserted in the foot passage 215, and a hand 54 holding the hand grip 30, the user 50 can expend energy to stretch the elastic member 40 between the foot 52 and the hand 54 as the user 50 walks, jogs, or performs other exercises.
The exercise device 10 is highly portable and easy to use, allowing the user 50 to enhance workout routines. The user 50 works his or her muscles by repeatedly stretching the elastic member 40 between the foot 52 and the hand 54. The foot cuff pivot 235 allows the elastic member 40 to rotate and easily change position relative to the hand grip 30, decreasing wear-and-tear and strain on the elastic member 40 and thus extending its life. The foot passage 215 lets the user 50 quickly insert and remove his or her foot 52. Elastic members 40 are easily replaceable by removing the pivot plug 245 from the elastic member socket 46 and inserting the pivot plug 245 into another elastic member 40 (which may have a different resistance and/or length). The hand grip 30 allows easy adjustment and storage of portions of the elastic member 40, letting users 50 of differing height, arm swing, gait, etc., incorporate elastic members 40 of varying length and resistance into the exercise device 10.
Further advantages and features of the invention will be apparent from the remainder of this document in conjunction with the associated drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows a pair of an exemplary exercise device 10, with a stretching elastic member 40 separating a hand grip 30 and a foot cuff 20, being used by a user 50 while walking;
FIG. 2A shows an exemplary foot cuff 20 with a foot passage 215 sized to fit a user's foot 52, and a foot cuff pivot 235 extending from a foot cuff body passage 220 (see FIG. 2B) formed in a rigid foot cuff section 205. FIG. 2B shows a cross-section of the foot cuff 20 of FIG. 2A, with the elastic member 40 extending from a pivot plug 245 of the foot cuff pivot 235, and with the pivot plug 245 installed in an elastic member socket 46 of the elastic member 40. Only a portion of the elastic member 40 is shown, with the remainder that would be extending upwards not shown in this drawing.
FIG. 3 shows an exploded view of the hand grip 30 of FIG. 1 with an optional hanging lever 306.
FIG. 4 shows a cutting-plane cross-section of the hand grip 30 of FIG. 1.
FIG. 5 shows the hand grip 30 of FIG. 1, with a lid 325 in an open position, the elastic member 40 stowed in a hand grip chamber 320, and an impinger 330 in an engaged position. The hand grip 30 of FIG. 5 does not include the hanging lever 306 of FIG. 3.
FIG. 6A shows an alternative hand grip 30 having upper and lower flanges 605, 610 extending radially around the circumference of the hand grip 30, with an elastic member 40 extending through a hand grip channel 615. FIG. 6B shows the hand grip 30 of FIG. 6A with an elastic member 40 installed in a hand grip valley 620 defined between the upper and lower flanges 605, 610.
DETAILED DESCRIPTION OF PREFERRED VERSIONS OF THE INVENTION
Returning to FIG. 1, the exercise device 10 allows the user 50 to enhance his or her workout routine while walking or jogging using the resistance provided by the elastic member 40 and the additional weight of the hand grip 30 and the foot cuff 20. Specifically, because the elastic member 40 resists being stretched, the user 50 expends additional energy stretching the elastic member 40 between the hand grip 30 and the foot cuff 20 with each step. A lanyard 70 is secured to the hand grip bottom side 310, as further discussed below, and the user's wrist or arm 56 can be inserted through the loop of the lanyard 70 (and/or the lanyard 70 may be wrapped around the user's wrist or arm 56) so that the hand grip 30 does not drop to the floor if the user 50 releases his or her grip of the hand grip 30.
Referring to FIG. 2A, the foot cuff 20 includes the bowed rigid foot cuff section 205, and a strap forming the flexible foot cuff section 210. The rigid foot cuff section 205 is curved so that the foot cuff body inner side 225 better conforms to the shape of the user's foot 52. The foot cuff 20 includes two foot cuff slots 250 on opposing sides of the rigid foot cuff section 205. Opposing ends of the strap 210 are looped through the foot cuff slots 250 and can be sewn onto the strap 210 to secure the strap 210 to the rigid foot cuff section 205. The strap preferably has a length that allows the foot cuff 20 to define a foot cuff body passage 220 (see FIG. 2B) sized to receive the user's foot 52 (or shoe 52) therethrough. The foot cuff body passage 220 extends through a tapered cylinder 255 extending upwards from the rigid foot cuff section 205. The pivot plug 245 of the foot cuff pivot 235 (and a portion of the pivot enlarged portion 240) is able to enter the foot cuff body passage 220 from below and pass through the foot cuff body passage 220, but the pivot enlarged portion 240 is not able to pass through the foot cuff body passage 220 due to the tapering of the tapered cylinder 255.
Although the pivot plug 245 is shown to extend perpendicularly from the rigid foot cuff section 205 in FIGS. 2A and 2B, the foot cuff pivot 235 is able to rotate and pivot with respect to the foot cuff 20, allowing the pivot plug 245 to point in different directions (see, e.g., FIG. 1). The foot cuff pivot 235 can be pivoted so that the pivot plug 245 points in any direction (i.e., until the pivot plug 245 makes contact with the tapered cylinder 255). In FIG. 2B, the pivot plug 245 is inserted in the elastic member socket 46 at the elastic member first end 42 by radially stretching the elastic member 40 outward. A pair of pivot plug bulges 246 help resist unwanted withdrawal of the pivot plug 245 from the elastic member socket 46. The ability of the pivot plug 245 to pivot as the elastic member 40 is being pulled in different directions helps minimize the stresses imposed on the elastic member 40 by the pivot plug 245 in the elastic member socket 46, helping extend the life of the elastic member 40. If the pivot enlarged portion 240 were not able to pivot, and the pivot plug 245 thus pointed in only one direction, the elastic member 40 being pulled in a different direction would press the pivot plug 245 against the inside edge of the elastic member socket 46, substantially increasing wear and tear.
Referring to FIG. 3, the hand grip 30 can be disassembled into the lid 325, the impinger 330, a chamber well 350, a hand grip body 360, and an end cap 370370. These components are assembled into the hand grip 30 shown in FIGS. 4 and 5. It is noted that the hand grip 30 of FIG. 3 also includes an optional hanging lever 306 (see discussion below) not included in the hand grip of FIG. 5. Starting at the top, the lid 325 covers the chamber 320 when closed, and allows access to the chamber 320, the impinger 330, and the elastic member 40 when open. The lid 325 is domed to provide additional space in the chamber 320. The lid 325 includes a pair of lid legs 326, each with a lid tab 327 extending therefrom. To install the lid 325 on the hand grip top side 305 of the hand grip body 360, the lid tabs 327 are inserted into a pair of lid sockets 364 in the hand grip top side 305 of the hand grip body 360. Once installed, the lid 325 is able to swing open and reclose as desired. The lid 325 also includes a lid lip 328, which is able to engage the chamber 320 lip to reversibly lock the lid 325 in the closed position.
The impinger 330 includes an impinger head 332 and an impinger torso 336 separated by an impinger neck 334. The impinger head 332 has a spherical shape, and a bend in the impinger neck 334 provides the impinger 330 with a roughly parabolic shape. The impinger torso 336 includes a pair of flexible impinger legs 338, each terminating in an impinger knob 339 that is sized to be received in a well socket 358. To install the impinger 330 in the chamber well 350, the impinger 330 legs are squeezed together slightly to fit between a pair of forward wings 353 in the well (see below), the impinger knobs 339 positioned at the well socket 358, and the impinger 330 legs released to permit the impinger knobs 339 to enter the well socket 358. Once installed, the impinger 330 is able to swing with respect to the impinger knobs 339, allowing the impinger head 332 to enter and exit the chamber well 350. To disengage the impinger 330, the user 50 can pull on the impinger 330 (such as the impinger neck 334) and swing the impinger 330 in an upwardly direction. To engage the impinger 330 (the impinger 330 is shown in the engaged position in FIGS. 4 and 5), the user 50 can press down on the impinger 330 (such as the impinger neck 334 or the impinger head 332) to insert the impinger head 332 into a well passage 351 (see FIG. 4) and press against any elastic member 40 extending from the hand grip channel 315 into the chamber 320. To enhance the hold of the impinger 330 on the elastic member 40 (and to minimize slippage of the elastic member back through the channel 315), the user 50 preferably holds the elastic member second end 44 with one hand, pulls down on a portion of the elastic member 44 entering the channel 315 from below the hand grip bottom side 310, and lowers the impinger 330 as the elastic member 40 is stretched. It is noted that the chamber 320 is formed in part in the hand grip top side 305, and the channel 315 extends through a handle 361 (see below) and the well passage 351, opening into the chamber 320.
The tapered well passage 351 is inserted into the hand grip channel 315, providing a continuous hand grip channel 315 extending from the hand grip top side 305 to the hand grip bottom side 310. A set of fins 316 (see FIGS. 4 and 5) extends radially into the channel 315 of the hand grip body 360. The fins 316 help center the chamber well 350 when the well passage 351 is inserted into the hand grip channel 315. The pair of forward wings 353 and a pair of rear wings 352, the rear and forward wings 352, 353 separated by a well neck 356, help secure an elastic member 40 wrapped around the well in the chamber 320 (see FIG. 4). The elastic member 40 extending up from the well passage 351 can wrap around the well by continuing beneath one of the rear wings 352 via one of a pair of semi-circular well depressions 357 (see FIG. 5, in which one of the well depressions 357 is viewable, and the other well depression 357 is covered by the elastic member 40). The well depressions 357 help better accommodate the elastic member 40 as the elastic member 40 snakes around the chamber well 350 for stowing in the chamber 320. The chamber well 350 includes a pair of flexible well prongs 354, each well prong 354 having a prong tab 355. The prong tabs 355 are sized to snap into a pair of stem windows 376 formed in a stem 372 of the end cap 370, helping secure the chamber well 350 and the end cap stem 372 together when the hand grip 30 is assembled. As can be seen in FIGS. 3 and 4, the inside of the stem 372 includes a pair of stem grooves 379. The stem grooves 379 are depressions sized to receive the well prongs 354 therein (that is, the thickness of the well prongs 354 are substantially equal to the depth of the grooves 372). As shown in FIG. 4, stem grooves 379 allow the diameter of the hand grip channel 315 to remain substantially constant through the stem 372 without narrowing even with the well prongs 354 inserted into the stem 372.
The hand grip body 360 includes the hand grip top side 305 and a hand grip body base 367 separated by the handle 361. The hand grip top side 305 has a top body depression 366, and the hand grip body base 367 and an end cap base 374 have hand grip body depression 368 and end cap base depression 375, respectively. The depressions 366, 368, 375 help accommodate the elastic member 40 as the exercise device 10 is moved about (letting the elastic member 40 nest within the depressions 366, 368, 375 as, e.g., the user 50 swings his or arm backwards). In FIG. 1, for example, the hand grip 30 in the user's left hand 54 is turned around such that the hand grip top side 305 is approximately pointed in the direction of the foot cuff 20. Here, the elastic member 40 fits in depressions 368, 375 in the hand grip bottom side 310, allowing the user 50 to move more freely by reducing interference resulting from the hand grip 30 itself.
Returning to FIG. 3, the hanging lever 306 includes a hanging lever 306 pin 307 extending perpendicularly from a lever body 309. The hanging lever 306 can be hingedly secured to the hand grip top side 305 by inserting the lever pin 307 into a lever socket 308. The hanging lever 306 is in a stowed position when it is substantially parallel to primary axis of the hand grip top side 305. To engage the hanging lever 306, the hanging lever 306 can be swung down such that it makes, e.g., about a ninety-degree angle with the primary axis of the hand grip top side 305. The hanging lever 306 can help secure or otherwise stow the hang grip when not being used by, for example, inserting the hanging lever 306 into a pocket in the user's 50 clothing to free-up the user's hands 54.
The end cap 370 includes the stem 372 extending from the end cap base 374. To assemble the hand grip 30, the end cap stem 372 is inserted through the channel 315 of the hand grip body 360 and engaged with the well prongs 354 of the chamber well 350. The end cap base 374 includes the end cap base depression 375 corresponding with the hand grip body base depression 368 for accommodating an elastic member 40. The end cap base 374 also helps provide strength to the hand grip body base 367 when the hand grip 30 is used to support the user's 50 weight while performing push-up exercises. As can be seen in FIGS. 3-5, a lanyard aperture 381A in the hand grip body base 367, and a lanyard depression 381B in the end cap base 374, together define a lanyard valley 380. A lanyard pin 382 formed in the hand grip body base 367 extends across the lanyard valley 380, permitting a lanyard 70, for example, to be secured to the hand grip 30 by looping about the lanyard pin 382.
In the alternative exemplary version shown in FIGS. 6A and 6B, the elastic member 40 is inserted through a channel 615 formed through a handle 661. The hand grip base 367 includes an analogous base depression 667 for accommodating the elastic member 40 as the hand grip 30 is used. Rather than stowing an unused portion of an elastic member 40 in a chamber 320, the elastic member 40 extending through the channel 615 enters the valley 620, which is defined between the upper and lower flanges 605, 610, via a groove 630 in the upper flange 605. Once the elastic member 40 has been wrapped around hand grip 30 within the valley 620, the end of the elastic member 40 is again extended into the groove 630 and held in place by being pressed between a portion of the elastic member 40 and the upper flange 605. The elastic member 40 being held in place can be unsecured by pulling the elastic member second end 44 out of the groove 630 and unwrapping the elastic member 40. This hand grip 30, and the one in FIG. 5, both allow for convenient stowing and easy replacement as elastic member 40 of varying resistances and lengths are desired.
It should also be understood that various terms referring to orientation and position are used throughout this document—e.g., “top” (as in “hand grip top side 305”) and “bottom” (as in “hand grip bottom side 310”)—are relative terms rather than absolute ones. In other words, it should be understood (for example) that the hand grip bottom side 310 being referred to may in fact be located at the top of the apparatus depending on the overall orientation of the apparatus. Thus, such terms should be regarded as words of convenience, rather than limiting terms. Also, it is to be understood that such terms as “forward,” “rear,” “upward,” “down,” and the like are words of convenience and are not to be construed as limiting terms.
Various preferred versions of the invention are shown and described above to illustrate different possible features of the invention and the varying ways in which these features may be combined. Apart from combining the different features of the foregoing versions in varying ways, other modifications are also considered to be within the scope of the invention. Following is an exemplary list of such modifications.
Although in FIG. 1, the elastic member second end 44 is secured to a hand grip 30, the elastic member second end 44 may instead be secured to the user's hand, wrist, arm, or upper body in any manner deemed suitable. For example, the pair of hand grips 30 can be replaced by a second pair of foot cuffs 20, and the user 50 may insert a hand 54 or wrist 56 through the foot passage 215 or otherwise grip the foot cuff 20 to stretch the elastic member 40.
Although in FIGS. 2A and 2B the foot cuff body 200 is shown with the rigid body section and the separate flexible foot cuff section 210, the foot cuff body 200 may be reconfigured, for example, to have only an extended rigid section defining the foot passage 215 without the flexible foot cuff section 210. Analogously, the rigid foot cuff section 205 (save a structure defining the foot cuff body passage 220) can be reconfigured to be flexible (e.g., made with fabric, elastic webbing incorporating rubber, etc.). Moreover, the tapered cylinder 255 may be shortened or eliminated, with the rigid foot cuff section 205 having an aperture sized to restrict passage by the pivot enlarged portion 240 while allowing the pivot plug 245 to pivot and point in various directions. Additionally, the pivot plug bulges 246 are not necessarily required for the pivot plug 245 to resist withdrawal from the elastic member socket 46. Enough resistance to withdrawal may be provided by the radial stretching of the elastic member 40 and the friction between the pivot plug 245 and the inside surface of the elastic member socket 46.
Referring to FIGS. 3-5, although the impinger head 332 is shown with an approximately spherical shape, the impinger head 332 pressing against the elastic member 40 to help secure the elastic member 40 to the hand grip 30 can have any shape or structure suited to restricting the movement of the elastic member 40. For example, the head may be cubical, pyramidal (preferably with the base of the pyramid pressing against the elastic member 40), or otherwise, and it may have an irregular outer surface to increase the friction with the elastic member 40. A spherical shape helps increase the surface area over which the impinger head 332 makes contact with the elastic member 40, pinching the elastic member evenly and helping minimize wear and tear on the elastic member 40. The diameter of the spherical impinger head 332 approaches the inner diameter of the chamber well 350 when the impinger head 332 is seated in the well 350.
The impinger 330 is shown to be secured to the hand grip 30 via the chamber well 350, but the impinger 330 may instead be secured directly to the hand grip 30. Moreover, features of the end cap 370 may be incorporated in the hand grip body 360, allowing the well prongs 354 to engage the hand grip body 360 directly rather than the end cap stem 372. Instead of, or in addition to, the rear and forward wings 352, 353, the hand grip top side 305 can include, for example, hooks in the chamber 320 to help keep the elastic member 40 within the chamber 320. Further, the chamber 320 may include a pair of flanges, with a valley sized to receive the elastic member 40 formed therebetween.
Although the hand grip bottom side 310 of the alternative version shown in FIGS. 6A and 6B is intended to help keep the elastic member 40 out of the user's way while the hand grip 30 is moved about, the bottom of the hand grip 30 (where the base depression 667 is located) may be strengthened to allow it to be used in push-up exercises as well, analogous to the version in FIGS. 3-5. Further, the protrusion 340 (see FIG. 5) and/or the protrusion in which base depression 667 is defined (see FIGS. 6A and 6B) at the bottom of the hand grip 30 can be eliminated. For example, the hand grip body base 367 and the end cap base 374 can be removed (see FIG. 3) from hand grip 30, such that the hand grip 30 terminates with handle 361.
It is noted that the exemplary exercise device and/or its parts discussed above, as well as variations thereof, may utilize features of, and/or be used with exercise devices and exercises discussed or referenced in, for example, the following references (among others): U.S. Pat. No. 7,044,896 to Hetrick: “Exercise device including adjustable, inelastic straps”; U.S. Pat. No. 7,090,622 to Hetrick: “Exercise device grips and accessories for exercise devices”; U.S. Pat. No. 7,651,448 to Hetrick: “Method of using an adjustable exercise device”; U.S. Pat. No. 7,722,508 to Hetrick: “Combination grip for an exercise device”; U.S. Patent Appln. Publication 2007/0027005 to Hetrick: “Exercise device grips and accessories for exercise devices”; U.S. Patent Appln. Publication 2007/0066450 to Hetrick: “Combination grip for an exercise device”; U.S. Patent Appln. Publication 2009/0075787 to Hetrick: “Exercise device having a door anchor”; U.S. Patent Appln. Publication 2009/0075788 to Hetrick: “Inelastic exercise device having a limited range”; U.S. Patent Appln. Publication 2009/0075789 to Hetrick: “Exercise device having inelastic straps and interchangeable parts”; U.S. Patent Appln. Publication 2009/0075790 to Hetrick: “Combination anchor for an exercise device”; U.S. Patent Appln. Publication 2009/0075794 to Hetrick: “Combination grip for an exercise device”; and U.S. Patent Appln. Publication 2009/0105053 to Hetrick: “Combination grip for an exercise device”.
The invention is not intended to be limited to the preferred versions of the invention described above, but rather is intended to be limited only by the claims set out below. Thus, the invention encompasses all different versions that fall literally or equivalently within the scope of these claims.
Patent Grant
8075462
