MULTIMODAL FITNESS BAR

Abstract

A multimodal fitness bar with a bar assembly and resistance assembly is disclosed. Exemplary implementations may further include a hanging member, a weighting assembly, a toggle assembly, a furling member, and/or other components. The resistance assembly may include a flexible fabric sheet with an opening configured to receive a user's foot and the bar assembly may include handles configured to be gripped by a user.

Description

FIELD OF THE INVENTION

The field of the invention is a multimodal fitness bar.

BACKGROUND

Fitness bars are known. Resistance bands are known

SUMMARY OF THE INVENTION

One aspect of the disclosure relates to a multimodal fitness bar with a resistance assembly. In some implementations the multimodal fitness bar may include a bar assembly, which may further include a weighting assembly. The weighting assembly may allow a user to adjust the weight of the multimodal fitness bar. A resistance assembly may be attached to the bar assembly. The resistance assembly may be configured to furl about the bar assembly to reduce the footprint of the multimodal fitness bar when the resistance assembly is not in use.

In some implementations, the bar assembly may be configured to be held in the hands of a user. A distal portion of the resistance assembly may include a loop for receiving the user's foot. When in an unfurled configuration, the user may create resistance between the user's hands and the user's foot by pressing the user's foot away from the user's hands. Such resistance allows a user to perform a variety of exercises and stretches including, but not limited to: resistance squats, resistance lunges, resistance bicep curls, resistance rows, resistance shoulder press, resistance deadlifts, resistance rows, calf stretches, hamstring stretches, and gluteus stretches. When in a furled configuration, a user may perform a variety of exercises and stretches including, but not limited to: weighted squats, weighted lunges, weighted bicep curls, weighted deadlifts, weighted rows, weighted shoulder press, weighted one handed lateral raises, and overhead triceps extensions.

A multimodal fitness bar, in accordance with one or more implementations herein, presents advantages over the fitness bars and fitness bands known in the art including, but not limited to: allowing a user to perform myriad exercises and stretches with a single device; a relatively compact form factor, and a secured furled configuration that substantially reduces the form factor of the device.

These and other objects, features, and characteristics of the apparatus and/or method disclosed herein, as well as the methods of operation and functions of the related elements of structure and the combination of parts and economies of manufacture, will become more apparent upon consideration of the following description and the appended claims with reference to the accompanying drawings, all of which form a part of this specification, wherein like reference numerals designate corresponding parts in the various figures. It is to be expressly understood, however, that the drawings are for the purpose of illustration and description only and are not intended as a definition of the limits of the invention. As used in the specification in the claims, the singular form of “a”, “an”, and “the” include plural references unless the context clearly dictates otherwise.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 is a front perspective view of a multimodal fitness bar in an unfurled configuration, in accordance with one or more implementations.

FIG. 2 is a partial, front perspective view of a multimodal fitness bar in an unfurled configuration, in accordance with one or more implementations.

FIG. 3A is a bottom perspective view of a weighting assembly, in accordance with one or more implementations.

FIG. 3B is a bottom perspective view of a weighting assembly, in accordance with one or more implementations.

FIG. 4A is a partial, front perspective view of a multimodal fitness bar, in accordance with one or more implementations.

FIG. 4B is a partial, front perspective view of a multimodal fitness bar, in accordance with one or more implementations.

FIG. 5A is a front view of a multimodal fitness bar in an unfurled configuration, in accordance with one or more implementations.

FIG. 5B is a partial rear perspective view of a sheet assembly, in accordance with one or more implementations.

FIG. 6 is a front view of a front furling member, in accordance with one or more implementations.

FIG. 7 is a front perspective view of a multimodal fitness bar in a furled configuration, in accordance with one or more implementations.

FIG. 8 is a front perspective view of a bar assembly, in accordance with one or more implementations.

FIG. 9 is a side perspective view of a multimodal fitness bar being used by a user, in accordance with one or more implementations.

FIG. 10 is a side perspective view of a multimodal fitness bar being used by a user, in accordance with one or more implementations.

FIG. 11 is a front perspective view of a multimodal fitness bar, in accordance with one or more implementations.

FIG. 12 shows two multimodal fitness bars with electronic components for a heating element.

FIG. 13 shows a multimodal fitness bar having a charging port.

FIG. 14 shows a multimodal fitness bar having a heating element.

DETAILED DESCRIPTION

FIG. 1 shows a front perspective view of a multimodal fitness bar 10 (hereinafter multimodal fitness bar 10), in an unfurled configuration, in accordance with one or more implementations. Multimodal fitness bar 10 may include one or more of a bar assembly 11, a resistance assembly 12, and a hanging member 13.

FIG. 2 shows a partial, front perspective view of multimodal fitness bar 10, in an unfurled configuration, in accordance with one or more implementations. Bar assembly 11 may include one or more of a first handle 201, a bar 202, a second handle 203, and a weighting assembly 204. In some implementations, first handle 201 may be a generally cylindrical member with a proximal end 210, a distal end 211, a diameter 212, and a length 213. Proximal end 210 of first handle 201 may be attached to bar 202 and distal end 211 of first handle 201 may be attached to hanging member 13. In some implementations, length 213 of first handle 201 may be between 100 mm and 140 mm and diameter 212 of first handle 201 may be between 27 mm and 37 mm.

In some implementations, bar 202 may be a generally cylindrical member with a first end 220, a second end 221, a length 222, a diameter 223, a depression 224, a logo 225, and bar magnets 226. First end 220 of bar 202 may be attached to proximal end 210 of first handle 201. Second end 221 of bar 202 may be attached to proximal end 230 of second handle 203. In some implementations, bar 202 is constructed of aluminum. It should be appreciated that bar 202 may be constructed of various rigid, or semi-rigid materials. It should be further appreciated that bar 202 may be non-cylindrical. For example, bar 202 might be an octagonal prism, or bar 202 may have curves or kinks, or undulations, such as those known for barbells. In some implementations, length 222 of bar 202 may be between 225 mm and 275 mm and diameter 223 of bar 201 may be between 27 mm and 37 mm.

Depression 224 may be a depression in, indentation in, or carve out of the body of bar 202, with the length of depression 224 being generally parallel with the longitudinal axis of bar 202. One or more bar magnets 226 may be included at or near the surface of depression 224. For clarity, bar magnets 226 are referred to as bar magnets 226 due to their placement on or in bar 202, as opposed to due to the shape or type of magnet. It should be appreciated that bar magnets 226 may be of various sizes, shapes, and numerosity, including a single magnet such as a magnetic strip that spans the length of depression 224.

In some implementations, weighting assembly 204 may include one or more of a weight 240, a weighting strap 241, and weight magnets 242. Weight 240 may be a partially cylindrical member with a length 243, a diameter 244, a cylindrical surface 245, a planar surface 246, and a channel 247. For purposes of this specification, a partial cylinder is a shape formed when a cylinder is cut along a plane, which is perpendicular to the ends of the cylinder. Planar surface 246 may be the flat surface formed by such theoretical cut and cylindrical surface 245 may be the remaining cylindrical portion of the surface. Planar surface 246 may be curved at one or both ends, such that weight 240 may be tapered at one or both ends. Diameter 244 of weight 240 is the diameter of the theoretical cylinder from which the partially cylindrical shape is derived. In some implementations, diameter 244 of weight 240 may be 27 mm and 37 mm. In some implementations, diameter 244 of weight 240, is substantially similar to diameter 224 of bar 202 and the surface of depression 222 is substantially similar in shape to planar surface 246 of weight 240, such that when weight assembly 204 is coupled with bar 202, a substantially complete cylinder is formed. In some implementations, length 243 of weight 240 may be between 130 mm and 170 mm.

Channel 247 in weight 240 may be a cavity configured to receive weighting strap 241. For clarity, weight magnets 242 are referred to as weight magnets 242 due to their placement on or in weight 242, as opposed to due to the weight or type of said weight magnets 242. Weighting assembly 204 and bar 202 are in an uncoupled configuration in FIG. 2.

Second handle 203 may be a generally cylindrical member with a proximal end 230, distal end 231, diameter 232, and length 233. Proximal end 230 of second handle 201 may be attached to second end 221 of bar 202. In some implementations the longitudinal axis of first handle 201, second handle 203, and bar 202, are aligned such that first handle 201, second handle 203, and bar 202 form a continuous cylinder.

In some implementations, diameter 212 of first handle 201, diameter 223 of bar 202, and diameter 232 of second handle 203 may be substantially similar, such that the diameter of bar assembly 11 is consistent throughout its length, when weighting assembly 204 is in a coupled configuration. In some implementations, first handle 201 and second handle 203 are constructed from cork, to provide comfort and friction, when gripped by a user. It should be appreciated that first handle 201 and second handle 203 may be constructed from a variety of materials, which may provide more or less friction and comfort when gripped by a user. It should be further appreciated that first handle 201 and second handle 203 may be attached to bar 202 using a variety of coupling arrangements. For example, bar 202 may extend into first handle 201 and second handle 203, which may provide additional bending strength for first handle 201 and second handle 203. In some implementations, bar 202 may extend for the entire length of bar assembly 11 and first handle 201 and second handle 203 may be sleaves of rubber, fabric, or other material that surrounds the ends of bar assembly 11. In some implementations, first handle 201, second handle 203, and bar 202, may be constructed of a single material, such as aluminum, and may be an integral whole. In such implementations, gripping features may be etched on or near first handle 201 and second handle 203, to increase friction with the user's grip. In some implementations first handle 201 and second handle 203 may be constructed of heavy materials for the purpose of further weighting bar assembly 11. First handle 201 and second handle 203 may be removably coupled to bar 202, for example by screwing. First handle 201 and second handle 203 may be hollow, to allow for the insertion of interchangeable weights, such that the weight of bar assembly 11 may be adjusted.

In some implementations, hanging member 13 may be a loop with two ends that terminate at and are attached to distal end 211 of first handle 201. Hanging member 13 may be constructed of flexible cord, such as paracord, and may allow multimodal fitness bar 10 to be attached to hooks, carabiners, and the like. It should be appreciated that hanging member 13 may be attached to either end of bar assembly 11, and may be another means of hanging bar assembly 11, such as a hook or tie.

FIG. 3A shows a bottom perspective view of a weighting assembly 204, in accordance with one or more implementations. In some implementations, weighting strap 241 may be a sheet of material with a first end 301, a second end 302, and a length 303. First weighting coupling 304 may be attached to weighting strap 241 at or near first end 301. Second weighting coupling 305 may be attached to weighting strap 241 at or near second end 302. First weighting coupling 304 and second weighting coupling 305 may be Velcro, magnets, or other components that allow the two ends of weighting strap 241 to mechanically or magnetically couple with each other. Weighting strap 241 may also be secured with a cinching mechanism or the like. In some implementations length 303 of weighting strap 241 is sufficient to allow weighting strap 241 to pass through channel 247 and around the body of bar 202, at or near depression 222, such that first weighting coupling 304 and second weighting coupling 305 couple to secure weight 240 to bar 202.

It should be appreciated that weighting strap 241 may be replaced or supplemented with additional means of securing weighting assembly 204 to bar 202. For example, corresponding Velcro strips or magnets could be placed along planar surface 246 and depression 224. Additionally, weighting strap 241 may be two separate members affixed to cylindrical surface, as opposed to a single member which passes through channel 247. In such an implementation, channel 247 may be omitted. In some implementations, weighting strap 241 may be constructed of a fabric material similar to that of a fabric watch band, or another flexible and durable material. A user may also unfurl and pull on weighting strap 241 to remove weighting assembly 204 from bar 202, in implementations where Velcro strips or magnets tightly secure weighting assembly 204 to bar 202.

FIG. 3B shows a bottom perspective view of a weighting assembly 204, in accordance with one or more implementations. In this implementation, planar surface 246 is replaced by interior cylindrical surface 307. Interior cylindrical surface 307 defines a partially cylindrical cavity. Assuming that weight 240 were made of the same material implementations of weighting assembly 204 depicted in FIGS. 3A and 3B were made of the same material, the implementation depicted in FIG. 3A would weigh more than the implementation depicted in FIG. 3B. In some implementations, weight 240 may be constructed of aluminum. Weight 240 may also be constructed of heavier or lighter materials, to increase or decrease the weighting effect of weight 240. Weight 240 may weigh an amount that is considered useful or common for fitness purposes such as a 2 pounds, 5 pounds, or 1 kg.

FIG. 4A shows a partial, front perspective view of multimodal fitness bar 10 with weighting assembly 205 and bar 202 in a coupled configuration, in accordance with one or more implementations. Planar surface 246 of weight 240 is disposed against depression 224 of bar 202. First end 301 and second end 302 of strap 241 are wrapped around the body of bar 202 and first weighting couplings 304 is coupled with second weighting coupling 305, securing weight 240 to bar 202. Weight magnets 242 are aligned with and magnetically coupled with bar magnets 226, further securing weight 240 to bar 202.

FIG. 4B is a partial, front perspective view of multimodal fitness bar 10. In this alternative implementation, bar assembly 11 does not include a weighting assembly. In this implementation, bar 202 is a complete cylinder and lacks depression 224.

FIG. 5A is a front view of multimodal fitness bar 10 in an unfurled configuration, in accordance with one or more implementations. Resistance assembly 12 may include one or more of sheet a 501, a front furling member 502, an alignment stitch 503, and a toggle assembly 504. In some implementations, sheet 501 is a sheet of elastomeric fabric with a front surface 505, a rear surface 506, a proximal end 507, a distal end 508, and a length 509. Proximal end 507 may be attached to bar assembly 11. In some implementations, sheet 501 may include a first bar coupling 510, a second bar coupling 511, and a cutaway 512, each disposed near proximal end 507. As used in this specification with respect to sheet 501, proximal end 507 refers to the end of sheet 501 that is disposed near and/or attached to bar assembly 11, when resistance assembly 12 is in an unfurled configuration.

As used in this specification with respect to sheet 501, distal end 508 refers to the end of sheet 501 that is disposed farthest away from bar assembly 11, when resistance assembly 12 is in an unfurled configuration.

In some implementations, cutaway 512 may be disposed between first bar coupling 510 and second bar coupling 511. First bar coupling 510 and second bar coupling 511 may be attached to bar 202, securing sheet 501 to bar assembly 11. Cutaway 512 may be of sufficient width and depth to receive a user's hand in the channel defined by cutaway 512 and bar 202. In other implementations, cutaway 512 may not be present and the entire width of proximal end 507 of sheet 501 may be coupled to bar 202. First bar coupling 510 and second bar coupling 511 may be attached to bar 202 by a variety of means, including, but not limited to stitching and adhesives. It should be appreciated that sheet 501 may be attached to bar assembly 11 in a variety of manners with more or less points of coupling.

In some implementations sheet 501 may be constructed of a flexible fabric such as woven recycled polyethylene terephthalate (RPET). In some implementations, sheet 501 may have elastic qualities that may allow for variable tension during fitness activities. In other implementations, sheet 501 may not have elastic qualities. It should be appreciated that sheet 501 may be constructed of various materials, including but not limited to, woven polymers, rubbers, or traditional fabrics.

In some implementations sheet 501 may be generally tapered, with a proximal width 515 that is greater than a distal width 516. In other implementations, sheet 501 may be generally rectangular.

In some implementations, sheet 501 may include an opening 520, disposed near distal end 508. Thus, sheet 501 may form a loop 517 at distal end 508, with an exterior perimeter 518 and an interior perimeter 519, with the interior perimeter 519 defining opening 520 in sheet 501.

Opening 520 in sheet 501 may be configured to receive the foot of a user. In some implementations, a distal portion of loop 517 that is disposed closest to distal end 508 of sheet 501 may curl towards the user, such that such distal portion of loop 517 may hang in a relatively horizontal configuration, as opposed to the vertically hanging configuration of the remainder of sheet 501. Such distal portion of loop 517 of sheet 501 may allow for a greater area of interface between the bottom of the user's foot and sheet 501.

Opening 520 in sheet 501 may be configured to secure the heel of a user, such that the ball of the user's foot and the underside of the user's toes may press against front surface 505, as depicted in FIG. 10. In some implementations, a distal portion of loop 517 that is disposed closest to distal end 508 of sheet 501 may curl towards the user, such that such distal portion of loop 517 may hang in a relatively horizontal configuration, as opposed to the vertically hanging configuration of the remainder of sheet 501. Such distal portion of loop 517 of sheet 501 may allow for the securing of the user's heel. For the purposes of this specification, the term heel refers to the rear surface of the user's leg, beginning at the top of the Achilles tendon and extending downward to the point at which the rear of the user's foot interfaces with the ground when the user is standing, flat footed. One advantage of the present invention is that a stretch of the plantar fascia may be accomplished without any members that interface with the front of the user's leg or ankle. For example, no Velcro or elastic straps around the front of the user's shin or ankle are required to secure sheet 501.

In some implementations, sheet 501 may be an integral whole. In other implementations, one or more of loop 517 of sheet 501, first bar coupling 510, and second bar coupling 511, may be non-integral members that are attached to sheet 501. For example, loop 517 of sheet 501 may be replace with a fabric strap with two ends, each end being connected to sheet 501, such that sheet 501 and the fabric strap form a loop. Loop 517 of sheet 501 may also be configured to receive both of a user's feet simultaneously. In some implementations, length 509 of sheet 501 may be between 650 mm and 900 mm. In some implementations, opening 520, may have a diameter 524 between 5 mm and 12 mm. It should be appreciated that opening 520 need not be annular.

In some implementations, sheet 501 may be omitted and another means of securing a user's fore-foot and heel may be employed in order to achieve a stretch of the plantar fascia. For example, sheet 501 may be omitted and the user's fore-foot and heel may be secured inside of a pouch-like structure, that may resemble a loose-fitting moccasin. The toe-box area of such pouch-like structure may be attached to bar assembly 11, such that when a user extends their leg and bulls bar assembly 11 toward the user, the toes of the user are pulled back and a stretch of the plantar fascia is achieved, similar to the stretch demonstrated in FIG. 9.

In some implementations, toggle assembly 504 may include one or more of a loop 521 passed through two openings in toggle 522. Loop 521 may be a cord and may be attached to sheet 501 at or near distal end 508 of sheet 501. In some implementations, toggle 522 may be disposed between 35 mm and 45 mm from the distal end 508 of sheet 501. In some implementations, toggle 522 may be between 29 mm and 39 mm in length and between b6 mm and 10 mm in diameter.

Front furling member 502 may be attached to front surface 505 of sheet 501. In some implementations, front furling member 502 may be attached above loop 517 of sheet 501. Alignment stitch 503 may be a stitching or other visual identifier disposed near loop 517 of sheet 501. Alignment stich 503 may serve as a visual que that that may assist the user to properly align the user's foot in opening 520.

FIG. 5B is a partial, rear perspective view of sheet assembly 12, in accordance with one or more implementations. Sheet assembly 12 may include one or more of rear surface 506 and rear furling member 523. In some implementations rear furling member 523 may be attached to rear surface 506 of sheet 501. It should be appreciated that rear surface 506 of sheet 501 may be substantially similar to front surface 505 of sheet 501, in most respects. Notwithstanding the foregoing, in some implementations, alignment stitch 503 may be omitted from rear surface 506, insofar as multimodal fitness bar 10 may be more suited to receiving a user's foot through front surface 505, due to the direction of the curl of loop 517 of sheet 501. Still in other implementations, alignment stitch 503 may be included on both front surface 505 and rear surface 506.

FIG. 6 shows a front view of furling member 502, in accordance with one or more implementations. Furling member 502 may include one or more of a first end 601, a second end 602, a middle portion 603, a first coupling 604, and a second coupling 605. Front furling member 502 may be generally rectangular and constructed of a flexible fabric, such as woven RPET. In some implementations, first coupling 604 of front furling member 502 and second coupling 605 of front furling member 502 may be one or more box stitches, disposed at or near first end 601, and second end 602, respectively. It should be appreciated that first coupling 604 of front furling member 502 and second coupling 605 of front furling member 502 may be one or more box stitches may be other means of attaching furling member 502 to sheet 501, including but not limited to various types of stitching or adhesive.

In some implementations first coupling 604 and second coupling 605 of front furling member 502 may be attached to front surface 505 of sheet 501, while middle portion 603 of front furling member 502 may not be attached to sheet 501, thereby defining a channel between middle portion 603 and front surface 505 of sheet 501. In some implementations, said channel is of sufficient size to receive toggle 522 in a vertical position, but not so large as to allow toggle 522 to pass therethrough in a horizontal position. In some implementations front furling member 502 may be between 78 mm and 98 mm in length and between 9 mm and 15 mm in width, with the length of said channel being between 30 mm and 42 mm.

Rear furling member 523 may be substantially similar to front furling member 502 with respect to dimensions, components, materials, method of attachment, and location of attachment, except that rear furling member may be attached to rear surface 506 of sheet 501, as opposed to front surface 505 of sheet 501.

It should be appreciated that toggle assembly 502 and furling member 502 may be replaced with various means of securing sheet 501 in a furled position. Such means may include, but not be limited to, snap closures, Velcro, hooks, ties, cinches, and the like.

FIG. 7 shows a front perspective view of multimodal fitness bar 10, in a furled configuration, in accordance with one or more implementations. Insofar as sheet 501 may be constructed of flexible material, it may be furled about bar assembly 11. Once sheet 501 is furled, toggle assembly 504 may removably couple with front furling member 502 to secure sheet 501 in a furled configuration. It should be appreciated that sheet 501 may be furled in the reverse direction and toggle assembly 504 may be coupled with rear furling member 523 to secure sheet 501.

FIG. 8 shows a front perspective view of a multimodal fitness bar 10, in accordance with one or more implementations. In this implementation, resistance assembly 12 is omitted. The omission of resistance assembly 12 may reduce the cost to produce multimodal fitness bar 10 and reduce the overall size of multimodal fitness bar 10, while still allowing a user to perform a subset of the exercises that may be performed with other implementations, including but not limited to certain weight training exercises. Apart from the omission of resistance assembly 12, multimodal fitness bar 10 may be substantially the same as described above.

FIG. 9 shows a user 901 operating a multimodal fitness bar 10, in accordance with one or more implementations. User 901 is lying on her back with one of her feet 902 stretched above her. User's foot 902 is received through opening 520 in sheet 501 and the bottom of user's foot 902 rests on the distal portion of loop 517 of sheet 501. User's first hand 903 grips first handle 201 and user's second hand 904 grips second handle 203. User 901 applies downward force 905 with user's first hand 903 and second hand 904 to create tension in sheet 501, thereby stretching user's 901 calf and hamstring. Weight 240 creates additional downward force to stretch the user's 901 calf and hamstring. It should be appreciated that FIG. 9 demonstrates only one of many possible exercises that may be performed with multimodal fitness bar 10.

FIG. 10 shows a user 901 operating a multimodal fitness bar 10, in accordance with one or more implementations. User 901 is lying on her back with one of her feet 902 stretched above her. Distal portion of loop 517 of sheet 501 is wrapped behind user's heel 1001, and the ball of user's foot 902 and underside of the user's toes are pressed against front surface 505 of sheet 501. User's first hand 903 grips first handle 201 and user's second hand 904 grips second handle 203. User 901 applies downward force 905 with user's first hand 903 and second hand 904 to create tension in sheet 501, thereby flexing user's toes back towards user 901 and stretching the plantar fascia of user's foot 902, along with other soft tissues. Sheet 501 is secured from sliding off the user's foot by distal portion of loop 517 being wrapped behind user's heel 1001. Weight 240 creates additional downward force. It should be appreciated that FIG. 10 demonstrates only one of many possible exercises that may be performed with multimodal fitness bar 10.

FIG. 11 shows a front perspective view of a multimodal fitness bar 10 in an unfurled configuration, in accordance with one or more implementations. In these implementations, multimodal fitness bar 10 comprises a bar assembly 1101 and a sheet 1102. Bar assembly 1101 comprises a bar 1103 with a first handle 1104, a second handle 1105, and a middle portion 1106. Bar assembly 1101 may be of various shapes, including generally cylindrical, prismatic, or in such shapes as may be found in exercise barbels, such as curl bars or camber bars. The width of first handle 1104 and second handle 1105 may, but need not be, greater than the width of middle portion 1106. First handle 1104 and second handle 1105 may be attached to middle portion 1106, or first handle 1104, second handle 1105, and middle portion 1106 mayform an integral whole. Sheet 1102 comprises a front surface 1106, a rear surface 1107, a proximal end 1108, a distal end 1109, and a length 1110. Proximal end 1108 of sheet 1102 may be attached to bar assembly 1101. In some implementations, proximal end 1108 of sheet 1102 may be furled about bar assembly 1101 and affixed to the body of sheet 1102, for example by stitching or gluing, in order to attach sheet 1102 to bar assembly 1101. Alternatively, proximal end 1108 of sheet 1102 may be attached to bar assembly 1101 directly, for example, by stitching or gluing proximal end 1108 of sheet 1102 to middle portion 1106 of bar assembly 1101.

In some implementations sheet 1102 may be generally tapered, with a proximal width 1111 that is greater than a distal width 1112. In other implementations, sheet 1102 may be generally rectangular.

In some implementations, sheet 1102 may include an opening 1113, disposed near distal end 1109. Thus, sheet 1102 mayform a loop 1114 at distal end 1102, with an exterior perimeter 1115 and an interior perimeter 1116, with the interior perimeter 1116 defining opening 1113 in sheet 1102.

It should be appreciated that the implementation of the multimodal fitness bar 10 depicted in FIG. 11 may be operated by the user in many of the same manners as described with respect to FIGS. 5A, 9, and 10. It should be further appreciated that the multimodal fitness bar 10 depicted in FIG. 11 may be of similar dimensions and materials as the implementation depicted in to FIG. 5A.

In some implementations bar assembly 1102 may be replaced with another gripping member or gripping members by which a user can pull sheet 1106 towards the user, in order to flex the toes of the user and achieve a stretch of the plantar fascia. Some examples of gripping members include, but are not limited to: resistance exercise handles, ropes, ball and rope grips, rope loops, elastic loops, straps configured to be gripped by the user, or straps configured to secure the user's wrists.

In some embodiments, a multimodal fitness bar of the inventive subject matter can include a heating element. FIGS. 12-14 show multimodal fitness bar 1200 having a heating element 1202. FIG. 12 shows two example multimodal fitness bars

Heating element 1202 comprises at least one wire 1204 that is embedded within a fabric outer surface 1206. As shown in FIG. 14, Wire 1204 is configured into a repeating S-curve pattern, though other patterns can be implemented without deviating from the inventive subject matter. For example, wire 1204 could be configured in a woven pattern to distribute heat more uniformly. To create heat, current passes through wire 1204, which generates heat due to its electrical resistance. Heating element 1204 can extend around the hole portion of the device, such that, for example, heat can be applied to a user's foot when in use.

In some embodiments, instead of wire 1204, heating element 1202 can feature a resistive sheet. A resistive sheet has similar material qualities as a sheet of fabric (e.g., flexible and durable), and can result in more uniform heat distribution. Resistive sheets can also be, e.g., non-woven conductive fabrics that are incorporated into heating element 1202 of multimodal fitness bar 1200.

Power for heating element 1202 is stored in one or more batteries contained within handle 1206. Shown in FIG. 13, to charge the batteries, power cord 1208 can plug into an end of handle 1206. Power is then delivered to heating element 1202 via cable 1210, which passes through input 1212. Input 1212 can be used to toggle heating element 1202 on and off (e.g., by pressing down as with a button), and, in some embodiments, input 1212 can be used to adjust temperature (e.g., by twisting). In still further embodiments, input 1212 can be used to toggle between different modes, such as on, off, heating mode 1, heating mode 2, heating mode 3, etc. Each heating mode can comprise, for example, a set temperature or a temperature that changes over time (e.g., as a sine wave, as a step function, etc.).

Heating element 1202 can generate temperatures between 65° F. and 135° F. In some embodiments, that temperature can be adjusted using input 1212, and in some embodiments that temperature is fixed at a temperature within the disclosed range such that turning the device on causes it to reach the fixed temperature. Heating element 1202 can include a fabric that is designed to conduct heat, though insulating fabrics can also be implemented in some embodiments.

Although the present technology has been described in detail for the purpose of illustration based on what is currently considered to be the most practical and preferred implementations, it is to be understood that such detail is solely for that purpose and that the technology is not limited to the disclosed implementations that are within the spirit and scope of the appended claims. For example, it is to be understood that the present technology contemplates that, to the extent possible, one or more features of any implementation can be combined with one or more features of any other implementation.

Claims

1. A multimodal fitness bar, comprising: a handle comprising at least one battery and a charging port;a resistance assembly coupled with the handle;the resistance assembly comprising a heating element; andwherein the heating element is connected to the at least one battery.

2. The multimodal fitness bar of claim 1, further comprising a connecting wire disposed along an edge of the resistance assembly, wherein the connecting wire couples the heating element to the battery.

3. The multimodal fitness bar of claim 1, wherein the heating element is configured to generate a temperature from 65° F. to 135° F.

4. The multimodal fitness bar of claim 1, further comprising an input.

5. The multimodal fitness bar of claim 4, wherein the input is configured to toggle the heating element between on and off.

6. The multimodal fitness bar of claim 4, wherein the input is configured to adjust a temperature of the heating element.

7. A multimodal fitness bar, comprising: an elongated bara battery;a resistance assembly coupled with the elongated bar; andthe resistance assembly having a heating element.

8. The multimodal fitness bar of claim 6, wherein the heating element comprises at least one wire.

9. The multimodal fitness bar of claim 6, wherein the heating element comprises a resistive sheet.

10. The multimodal fitness bar of claim 6, further comprising an input.

11. The multimodal fitness bar of claim 9, wherein the input is configured to toggle the heating element on and off.

12. The multimodal fitness bar of claim 9, wherein the input is coupled with the heating element by a first connecting wire and with the battery by a second connecting wire.

13. A multimodal fitness bar, comprising: an elongated handle;the elongated handle having a flexible fabric sheet extending therefrom; andthe flexible fabric sheet comprising a heating element.

14. The multimodal fitness bar of claim 12, wherein the heating element comprises a wire.

15. The multimodal fitness bar of claim 12, wherein the heating element comprises a resistive sheet.

16. The multimodal fitness bar of claim 12, further comprising a user input configured to toggle the heating element.

17. The multimodal fitness bar of claim 12, further comprising a user input configured to adjust a temperature of the heating element.

18. The multimodal fitness bar of claim 12, wherein the heating element is configured to generate a temperature from 65° F. to 135° F.