Multi-Axis Massage Gun

Abstract

A handheld motorized massage gun is disclosed that combines the percussive action of conventional percussive-type massage guns with muscle stretching action of rolling element massage devices. The self-powered, self-standing device orbits a massage roller along a circular path about a virtual axis which induces both percussive forces and stretching forces along the axis of the target muscle fibers. The roller suspension of the device facilitates two operating modes that allow the device to be operated in a stationary position or with traversing motion for the purpose of treating cellulite and/or providing muscle rehabilitation.

Claims

1. A handheld self-powered percussive massage gun for utilization by a user upon a muscle comprising: a main body defining a cavity and a single handle portion extending therefrom, the single handle portion configured to be graspable by the user for operating the percussive massage gun with one hand; a piston orbitally reciprocating while driven by a single motor-driven gear set and having a first distal end received within the cavity of the main body and a second distal end for mounting a percussive massage roller therefrom; a focusing rest rigidly adjoined at a proximal end of the main body and possessing a first axle fixedly adjoined to the focusing rest at a distal end, the focusing rest having an axis noncoincident with the axis of the motor-driven piston and an axis parallel to the handle portion; a first roller mounted upon the first axle and freely rotatable thereon for creating non-vibratory contact with a fascia surface; a second roller mounted upon the first axle and freely rotatable thereon for creating non-vibratory contact with a fascia surface; a second axle rigidly adjoined to the motor-driven piston having an axis that is parallel to the first axle and perpendicular to the axis of the motor-driven piston; and a third roller mounted upon the second axle and freely rotatable thereon for creating percussive contact with the fascia surface; wherein spacing amongst the first roller, the second roller and the third roller is proportioned to provide a self-standing tripod suspension which maintains the axis of the main body substantially perpendicular to a fascia surface of the muscle absent a grasp of the user; the third roller continuously driven along a circular path by the motor while the first and second rollers are held stationary upon the fascia surface in a first operating mode; and wherein the circular path comprises an orbit about a virtual axis, the virtual axis being oriented substantially parallel to the fascia surface.

2. The percussive massage gun of claim 1 wherein each of the first roller, the second roller and the third roller are self-supporting and each configured to maintain rolling contact upon the fascia surface of the muscle as the third roller orbits about the virtual axis and the user traverses the percussive massage gun along the fascia surface of the muscle with the one hand in a second operating mode.

3. The percussive massage gun of claim 1 wherein the first distal end of the piston is rotatably and eccentrically attached to a continuously rotating gear of the single gear set.

4. The percussive massage gun of claim 1 wherein the piston is constrained to both slide and rotate within a piston rocker while orbitally reciprocating.

5. The percussive massage gun of claim 1, wherein the roller surfaces possess stimulating projections.

6. The percussive massage gun of claim 1, wherein the first roller is adjoined to the second roller.

7. The percussive massage gun of claim 1, wherein the single handle portion is a removable battery housing.

8. A handheld self-powered percussive massage gun for utilization by a user on a muscle comprising: a main body defining a cavity and a handle portion extending therefrom, the handle portion configured to be graspable by the user for operating the percussive massage gun with one hand; a piston orbitally reciprocating while driven by a single motor-driven gear set and having a first distal end received within the cavity of the main body and a second distal end for mounting a percussive massage roller therefrom; a focusing rest rigidly adjoined at a proximal end of the main body and possessing a first axle fixedly adjoined to the focusing rest at a distal end, the focusing rest having an axis noncoincident with the axis of the motor-driven piston; a first roller mounted upon the first axle and freely rotatable thereon for creating non-vibratory contact with a fascia surface; a second roller mounted upon the first axle and freely rotatable thereon for creating non-vibratory contact with a fascia surface; a second axle rigidly adjoined to the motor-driven piston having an axis that is parallel to the first axle and perpendicular to the axis of the motor-driven piston; a third roller mounted upon the second axle and freely rotatable thereon for creating percussive contact with the fascia surface; a fourth roller mounted upon the second axle and freely rotatable thereon for creating percussive contact with the fascia; wherein spacing amongst the first roller, the second roller, the third roller and the fourth roller is proportioned to provide a self-standing suspension which maintains the axis of the main body substantially perpendicular to a fascia surface of the muscle absent a grasp of the user; the third roller and the fourth roller synchronously and continuously driven along a circular path by the motor while the first and second rollers are held stationary upon the fascia surface in a first operating mode; wherein the circular path comprises an orbit about a virtual axis, the virtual axis being oriented substantially parallel to the fasci surface.

9. The percussive massage gun of claim 8 wherein each of the first roller, the second roller, the third roller and the fourth roller are self-supporting and each configured to maintain rolling contact upon the fascia surface of the muscle as the third and fourth rollers orbit about the virtual axis and the user traverses the percussive massage gun along the fascia surface of the muscle with the one hand in a second operating mode.

10. The percussive massage gun of claim 8 wherein the first distal end of the piston is rotatably and eccentrically attached to a continuously rotating gear of the single gear set.

11. The percussive massage gun of claim 8 wherein the piston is constrained to both slide and rotate within a piston rocker while orbitally reciprocating.

12. The percussive massage gun of claim 8, wherein the roller surfaces possess stimulating projections.

13. The percussive massage gun of claim 8, wherein the first roller is adjoined to the second roller.

14. The percussive massage gun of claim 8, wherein the handle portion is a removable battery housing.

15. A method of applying percussive massage to a fascia surface using a self-standing massage gun comprising a motor-driven orbitally reciprocating piston, the method comprising the steps of a user: resting non-vibratory rollers and at least one motor-driven roller of the massage gun upon a fascia surface in its self-standing position, wherein the self-standing position is maintained with the rollers contacting the fascia surface; grasping a handle of the self-standing roller supported massage gun with a single hand; activating the motor-driven orbitally reciprocating piston; applying pressure toward the fascia surface; and rolling the massage gun along the fascia surface in reciprocating strokes while maintaining the self-standing position with the single hand.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0022] FIG. 1 is an illustration of the hand movement utilized by a massage therapist while implementing the Myofascial Release technique.

[0023] FIG. 2 is an illustration of a prior art device which is utilized to implement the Myofascial Release technique.

[0024] FIG. 3 is an illustration of the operation of the massage device described in FIG. 2

[0025] FIG. 4 is an isometric view of another prior art massage device which is utilized to implement the Myofascial Release technique.

[0026] FIG. 5 is an illustration of a hand movement utilized by a massage therapist while implementing the Tapotement (percussive massage) technique.

[0027] FIG. 6 is an illustration of a prior art percussive massage gun which is utilized to implement percussive massage.

[0028] FIG. 7 is an isometric view of another prior art massage device that utilizes two handles to steady the massage gun while applying percussive massage.

[0029] FIG. 8 is an illustration of an exemplary application of the prior art massage device of FIG. 7.

[0030] FIG. 9 is an isometric view of another prior art massage device that is utilized for stabilizing a percussive massage gun while applying percussive massage.

[0031] FIG. 10 is an isometric view of another prior art massage device that is utilized for stabilizing a percussive massage gun while applying percussive massage in a traversing mode.

[0032] FIG. 11 is an isometric view of the massage device being described as the preferred embodiment of the current invention.

[0033] FIG. 12 is a cut away view of the massage device of FIG. 11 showing the internal piston drive mechanism.

[0034] FIGS. 13A, 13B and 13C are explanatory views of the piston drive mechanism when isolated from the massage device housing.

[0035] FIGS. 14A and 14B are views which show the compressive fascia wave that is formed in each direction along the fascia surface at two extreme positions of the massage roller.

[0036] FIGS. 15A and 15B are views which show the extreme positions of the massage roller in the percussive direction which is perpendicular to the fascia surface.

[0037] FIGS. 16A and 16B illustrate the piston drive mechanism in two successive positions while diagrammatically explaining the orbitally reciprocating piston motion.

[0038] FIG. 17 is an isometric view that explains the orbit of the massage roller about a virtual axis.

[0039] FIG. 18 is an isometric view of an alternate embodiment when adopting grooves to the roller surfaces for fascia stimulation.

[0040] FIG. 19 is an isometric view of an alternate embodiment when adopting pyramidal projections to the roller surfaces for fascia stimulation.

[0041] FIG. 20 is an isometric view of an alternate embodiment when the first and second roller are adjoined.

[0042] FIG. 21 is an isometric view of an alternate embodiment which utilizes two massage rollers mounted upon the second axle.

[0043] FIG. 22 is a side elevation view of an alternate embodiment where the handle is adjoined to the focusing rest.

[0044] FIG. 23 is an isometric view of the device shown in FIG. 22.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0045] FIG. 11 illustrates an isometric view of the massage device being described as the preferred embodiment of the invention herein. The device 100 comprises a main body 110 having a series of appendages serving the functions of supporting the device and housing the functional components. The device is supported in a self-standing orientation while resting upon a roller suspension comprising three freely rotatable rollers 120, 130 and 140 which are arranged in a tripod-like configuration. The spacing amongst the first roller, the second roller and the third roller is proportioned to provide a self-standing tripod suspension which maintains the axis 112 of the main body substantially perpendicular to a fascia surface of a target muscle absent a grasp of the user.

[0046] A first roller 120 and a second roller 130 are freely rotatable upon a first axle 132 which is located at the distal end of the focusing rest 143 that is adjoined to the main body 110 at its proximal end. The focusing rest 143 has an axis that is non-coincident with the axis of the motor-driven piston and an axis that is parallel to the handle portion. A third roller 140 is attached to a piston which orbitally reciprocates within the piston housing 180 while inducing the roller 140 to orbit upon a circular path. Roller 140 freely rotates upon axle 142 which is attached to the distal end of the piston, the roller 140 defining a percussive massage roller which creates percussive contact upon the fascia surface without imposing any frictional drag. The non-vibratory rollers 120 and 130 are not powered and maintain non-vibratory contact with the fascia surface. The non-vibratory rollers rest upon the fascia surface in first operating mode, or roll along the fascia surface in a second operating mode.

[0047] The device 100 may be operated in two modes including a first stationary mode and a second traversing mode. The device may be held in a stationary position upon a fascia surface while supported by roller suspension when targeting one specific fascia region. In this mode, the massage roller 140 induces motion upon the fascia in directions both vertical and parallel to the fascia surface while the first and second rollers remain stationary upon the fascia surface.

[0048] The second operating mode allows the user to reciprocate the roller-supported, self-standing device while applying sweeping massage action along the fascia surface. The user may rest the rollers upon a fascia surface in the self-standing position, grasp the handle with a single hand, activate the motor-driven orbitally reciprocating piston, and roll the device along the fascia surface in reciprocating strokes while maintaining slight downward pressure with the single hand.

[0049] The two operating modes are made possible by the focusing rest 143 where the term focusing rest was explained in copending patent application Ser. No. 17/488,831 filed Sep. 29 2021 (Publication No. US 2022/0354735A). The term describes an appendage that allows the massage gun to be stabilized by resting a non-vibratory surface upon the fascia while focusing the reciprocating portion upon a particular muscle or fascia region. The adoption of non-vibratory rollers 120 and 130 on the distal end of the focusing rest 143 allows the roller supported massage gun to be easily traversed along the fascia surface in sweeping frictionless reciprocating strokes by the user (second operating mode). The non-vibratory rollers maintain rolling contact with the fascia surface while the massage roller 140 maintains percussive contact with the fascia.

[0050] The main body 110 has an axis 112 oriented substantially perpendicular to the surface upon which the three rollers 120, 130 and 140 rest. A cylindrical projection 190 projects perpendicular to axis 112 and has the function of housing the motor which reciprocates the piston. Another cylindrical projection 190 extends oppositely of the motor housing 190 and has the function of providing a single handle 160 which is designed to allow the user to grasp the device 100 with one hand. In some embodiments the handle 160 contains a cavity which houses removeable and/or rechargeable batteries for powering the device motor. In other embodiments, the handle 160 is removeable and contains a battery pack capable of remote charging. The device motor is powered on and off by the pushbutton 112 which is accessible to the user's thumb while grasping the handle 160.

[0051] A focusing rest 143 projects from the main body and supports non-vibratory rollers 120 and 130 which are freely rotating about axle 132 which is fixedly attached to the focusing rest 143. The proximal end of the focusing rest 143 is fixedly attached to the piston housing portion 180 of the main body 110.

[0052] The piston drive mechanism is especially simple when compared to many prior art massage guns. FIG. 12 is a side elevation view of the device 100 with the main body 110 shown in cut away fashion to expose the piston drive mechanism which resides within the main body 110. The device utilizes a single gear set comprising a worm screw and a worm gear to both rotate and translate the upper end of the piston 320. A worm screw 310 is coupled to the shaft of the drive motor 194 and in mesh with the worm gear 312. An eccentric crank 314 is attached to the worm gear 312 and is rotationally driven by the worm drive.

[0053] The piston 320 possesses a ball bearing 316 which is rotationally attached to the eccentric at one distal end of the piston. The piston is attached to the second axle 142 of the third roller at its opposite distal end. The piston is supported and guided by the piston rocker 322 which possess a circular bore 325 which slidably constrains the circular portion of the piston 320. The piston rocker 322 thus forms a rotational joint which allows the piston to both translate and rotate. Two ball bearings 324 are fixedly attached to the main body 110 and rotationally support the piston rocker 322. As the eccentric 312 rotates, the piston 320 slides within the bore of the piston rocker 322 and also rotates about the center of bearings 324. The resulting piston movement is described as orbitally reciprocating. The orbitally reciprocating piston motion distinguishes device 100 from conventional massage guns whose pistons move only with straight line oscillation.

[0054] FIGS. 13A, 13B and 13C illustrate views of the orbitally reciprocating piston drive mechanism when isolated from the device 100. FIG. 13A is a side elevation view and FIG. 13B is an analogous isometric view of the simple mechanism which utilizes only one gear set to implement multi-axis massage forces. A single gear set comprising a worm screw 310 and a worm gear 312 is driven by a DC motor and rotates continuously when the device 100 is actuated. A connecting crank 314 is fixedly attached to the worm gear 312 and provides a journal for attaching the piston 320 to the rotating worm gear 312. Ball bearing 316 is attached to the piston 320 at its upper distal end and the massage roller 140 is rotatably attached to the piston at its lower distal end. The single motor-driven gear set (310 and 312) is responsible for the multi-axis motion of the percussive massage roller 140.

[0055] Referring to FIG. 13C, the piston 320 derives its guidance from a piston rocker 322 which rotates within ball bearings 324, where the ball bearings 324 are fixedly attached within the housing 180. The circular portion of piston 320 is captured within the bore 325 of the piston rocker 322 which constrains the piston to reciprocate within the bore, whose axis rotates about the axis of ball bearings 324. The arrows in FIG. 13A and FIG. 13B explain that the piston 320 both rotates and translates as the worm gear 312 continuously rotates. As will be explained more fully below, the combined rotation and translation of the piston 320 induces the massage roller 140 to orbit along a circular path.

[0056] FIG. 14A and FIG. 14B illustrate the range of movement of the massage roller 140 as it moves relative to the generalized plane of the fascia surface 410. This Myofascial Release motion is illustrated by the directional arrows which indicate the relative motion of the massage roller 140 as it creates the travelling compressive waves in both directions along the fascia surface in the same manner as shown in FIG. 3. Referring to FIG. 14A, the gear 312 is rotating CW, inducing piston 320 to rotate CW about ball bearing 324 while moving the massage roller 140 in the direction of arrow 420. Referring to FIG. 14B, the gear 312 is rotating CW, inducing piston 320 to rotate CCW about ball bearing 324 while moving the massage roller 140 in the direction of arrow 422. This range of motion of roller 140 exists regardless of whether the device 100 is held stationary upon the fascia surface (first operating mode) or whether the device 100 is being traversed along the fascia surface with reciprocating strokes by the user (second operating mode). In either operating mode, the free rotation of the roller 140 allows the compressive wave to be created without uncomfortable frictional drag along the fascia surface.

[0057] FIG. 15A and FIG. 15B demonstrate the range of motion of the massage roller 140 as it moves in the direction substantially perpendicular to the fascia surface. This motion illustrates the Tapotement (percussive) action of the device 100 which is superimposed upon the Myofascial Release motion during each rotational cycle of the eccentric 314. As is the case with the Myofascial Release motion illustrated in FIGS. 14A and 14B, the percussive motion shown in FIGS. 15A and 15B continues while the device is stationary (first operating mode) or whether the device 100 is being traversed along the fascia surface by the user (second operating mode).

[0058] FIG. 16A and FIG. 16B illustrate the combined rotating and reciprocating motion of the piston movement which explains the term orbitally reciprocating. The worm gear 312 is rotating CW in FIG. 16A where the piston bearing 316 is shown at about the two o'clock position on gear 312. The worm gear 312 continues to move CW in FIG. 16B and has advanced to the 5 o'clock position. During this movement, the piston 320 translates (slides) within the bore 325 of piston rocker 322 (see FIG. 13C) which increases the distance X1 from 8.6 mm to 16.8 mm.

[0059] During this translation of the piston 320 from 8.6 mm to 16.8 mm, the piston rocker 322 rotates within the ball bearing 324 which if fixedly attached the main body of the device 100. That rotation changes the indicated angle T1 from 9.3 degrees to 3.5 degrees as the piston 320 is configured to both slide and rotate within the piston rocker 322.

[0060] During an entire rotation cycle (360 degrees) of worm gear 312, the dimension X1 achieves a maximum and a minimum dimension as the piston reciprocates within the bore 325 of the piston rocker 322. The angle T1 is also constantly changing while the worm gear 312 rotates. The piston 320 is simultaneously orbiting angularly about the rotation center of ball bearing 324 as indicated by the everchanging angle T1. As the piston 320 both slides and rotates within the piston rocker 322, the resulting motion of the piston 320 is summarily described as orbitally reciprocating.

[0061] A unique characteristic of the device 100 is the resulting orbital motion of the massage roller 140 (third roller) which orbits about a virtual axis, where the term virtual axis is construed to mean an axis in space having no physical axle or no physical bearing. FIG. 17 illustrates an isometric view of the device 100 showing the massage roller axle 142 (second axle) located at multiple extreme positions. The massage roller 140 is continuously driven along a circular path by the motor as the worm gear 312 rotates. However, the massage roller 140 is omitted in the view of FIG. 17 for the purpose of observing the circular path of the axle 142. It can be observed that the roller axle 142 orbits circularly about a virtual axis as the worm gear 312 completes each 360 degree cycle. The virtual axis is labeled as axis 370 where the axis 370 is parallel to the axis 372 of the first axle 132. The extreme positions of the second axle 142 are labeled 142N, 142S, 142E and 142W to symbolically signify north, south, east and west positions of the axle 142 as it orbits about virtual axis 370. The virtual axis 370 is parallel to the axis 372 of the first and second rollers, and virtual axis 370 also resides within a plane that is substantially parallel to the fascia surface.

[0062] The device may include rollers with various fascia-stimulating surface projections upon its roller surfaces in other embodiments. FIG. 18 illustrates the device utilizing rollers with shallow grooves patterned upon the spherical surfaces of its rollers. FIG. 19 illustrates the device utilizing small pyramidal projections patterned upon the spherical surfaces of its rollers.

[0063] In other embodiments, the first roller and the second roller may be adjoined to each other and rotate upon the first axle. FIG. 20 illustrates an embodiment where the first roller 120S and the second roller 130S are adjoined together to form a unitary roller 144.

[0064] In other embodiments, the device 100 may be modified to increase the size of the fascia region being treated. That objective can be achieved by adding an additional roller to the distal end of the orbitally reciprocating piston 320. FIG. 21 illustrates an alternate embodiment illustrated by the device 500 which has been modified to mount two massage rollers 510 and 512 upon the axle 552 (second axle) of the orbitally reciprocating piston. The internal piston drive mechanism of device 500 is the same as that of device 100. A first roller 520 and a second roller 530 are mounted upon a first axle 532. A third roller 540 and a fourth roller 550 are mounted on a second axle 552. The two rollers 540 and 550 orbit synchronously with each other about the same virtual axis 370 as illustrated in FIG. 17.

[0065] The handle portion is adjoined to the distal end of the focusing rest in another alternate embodiment. This configuration as shown in FIG. 22 creates an overall structure that is more rigid and somewhat more compact while orienting the handle at an advantageous angle. Referring to FIG. 22, the handle portion 660 of device 600 is adjoined to the distal end of the focusing rest 643. The power button 616 is conveniently arranged such that it may be actuated by the user's thumb while grasping the handle 660 with one hand. FIG. 23 is an isometric view of the integrated handle configuration shown in FIG. 22 when adapted to the tripod suspension configuration that is taught by device 100. A first roller 620 and a second roller 630 freely rotate upon a first axle 632 while a third percussive massage roller 650 freely rotates upon the second axle 652.