The present invention relates, in general, to a support platform for body treatment and, more particularly, to such a support platform that has a moveable resilient cushion in an upper surface of the support platform that accommodates shapes, contours and protuberances of the human body.
Because the human body has many shapes, contours and protuberances, when an individual lies in a prone position, to rest, relax, sleep or receive treatment, localized discomfort, pain and even injury can result. This problem is exacerbated for the mature female because, while lying face down, the female cannot relax in a natural whole body extending position due to the breasts causing a distortion in body position that is both uncomfortable as well as stressful for various muscle groups and tissue.
The breast tissue is primarily composed of subcutaneous fat and is almost solely supported by suspensory ligaments connecting breast skin to the tissue that rests above the pectorals major. With traditional prior art flat treatment tables, the female patient, while lying prone, will experience uncomfortable and sometimes harmful pressure on all breast tissue, including stretching and tearing of the suspensory ligaments and compressing of the fat cells, often causing swelling to occur. Women with breast augmentations are faced with fear of possible ruptures and certainly severe discomfort.
Whether the individual is seeking a massage for relaxation or for therapeutic treatment, the body needs to be maintained in a relaxed position to achieve the highest degree of success. The thrust of the present invention is to provide a novel support apparatus that will achieve this result. More particularly, the present invention provides an adjustable personal treatment apparatus that is usable by persons of all sizes to enable them to enjoy, without harm, the full healthful benefits of proper and necessary massage and therapy.
Part of the reason that the problems described above have not been solved is that often the designers of traditional mattresses or, for instance, massage tables, keep them flat and ignore the problems described above. Also, the designers of tables or mattress materials have tried to address the issue of comfort, pain or injury, but; because of the degree of contour of the human body, changing the material of the mattress or the table, in and of itself, often is not alone enough to provide both the desired results when the present invention is used in body treatment practices.
While others have attempted to address some of the problems described above, there remains a need for an automated, adjustable body part and contour comfort system. The structures disclosed in the prior art suffer from one or more of the following shortcomings: (a) lack of adjustable recessed cup area; (b) requirement that the patient stand during treatment; (c) lack of portability; and (d) limited adjustability.
A support platform for body treatment, constructed in accordance with the present invention is provided and includes a supporting frame, a resilient pad, a guide passageway, a cushion and a control assembly. The resilient pad is secured to the supporting frame and includes an upper surface positioned opposite the supporting frame. The guide passageway extends from the upper surface and through the resilient pad toward the supporting frame. The cushion includes a lower surface side and is connected to control assembly so that it vertically positions the lower surface side along the guide passageway.
The present invention will be explained in greater detail in the following, with reference to the appended drawings, in which:
Hereinafter, embodiments of the invention will be described in detail with reference to the accompanying drawings. However, the invention is not limited to the embodiments described herein.
Referring first to
Forming an important aspect of the support platform 22 of the present invention is a control assembly 30 that has a breast support cushion 32 disposed within the receiving chamber 28. The control assembly 30 includes a breast cushion positioning mechanism 34 for moving the breast support cushion 32 within receiving chamber 28 from a first elevated position to a second lowered position. As shown in
The breast cushion positioning mechanism 34 includes a pair of linear motor assemblies 38 that include elongated tracks or slides 38a that, in the manner shown in
In using the invention shown in
Turning next to
The support platform 22 includes a supporting frame 24 that is substantially similar in construction and operation to the supporting frame previously described and functions to support a resilient body cushion 26 having opposing upper and lower surfaces 26a and 26b. As best seen in
As shown, another control assembly 230 according to the present invention is provided and is positioned within receiving chamber 28 of resilient body cushion 26. The control assembly 28 includes a breast cushion 32 and a breast cushion positioning mechanism 234 for maintaining the breast cushion 32 at an optimum position within receiving chamber 28.
As shown in
Next, with respect to
As shown, the support platform 50 includes a foldable support frame 54 that functions to support an elongated resilient body pad 56 that includes first and second sections 58 and 60. A first section 58 has a forward portion 58a having opposing upper and lower surfaces 62 and 64 and a guide passageway 66 that is generally oval shaped in
As indicated in
A patient support cushion assembly numeral 74 is connected to the forward portion 58a of first section 58 of the resilient body pad 56. The patient support cushion assembly 74 includes a housing 76 having an internal chamber 76a that is in communication with the guide passageway 66 and is positioned at the forward portion of the first section 58 of the resilient body pad 56. Also, an inflatable, deflatable airbag 78 is disposed within the internal chamber of the housing 76. The airbag 78 is movable relative to housing 76 between the first partially collapsed configurations shown in
A resiliently deformable patient support cushion 80 is provide with the patient support cushion assembly 74 and is generally oval shaped in cross-section in the shown embodiment. However, one skilled in the art should appreciate that other design and configurations are possible. The support cushion 80, which includes yieldably deformable side and top walls 80b (
A pump assembly 86 is connected to the airbag 78 for moving the airbag between the first partially collapsed configuration shown in
A vent line assembly 98 is also provided and is connected to airline 90 for controllably deflating the airbag 78. In the embodiment shown, the vent line assembly 98 includes a vent line 99 having a first end portion 99a that is connected to one leg of the “T” connector 92 and a second end portion 99b that is secured to the side of the resilient body pad 56 by means of a conventional line clamp 99c which can be used to control the flow of air through vent line 99 (see
The support platform 50 further includes a head support assembly 97 that is connected to the forward portion of the first section 58 of the resilient body pad 56 (
In using the present invention, the apparatus is first erected from the collapsed, folded configuration (not shown) into the operable configuration illustrated in
The height of the platform can be adjusted by appropriately manipulating the downwardly extending adjustable front leg assemblies 70 and the downwardly extending adjustable rear leg assemblies 72. This is accomplished by moving the second portions 70b and 72b of the front and rear leg assemblies 70, 72 upwardly or downwardly, relative to the first portions 70a and 72a of the leg assemblies (
As shown in
With a starting configuration shown in
Similarly, when the patient is in a supine position and with line clamp 99c closed, operation of the foot pump 88 by the foot of the caregiver will cause the support cushion 80 to move upwardly relative to the surface of the resilient body pad 56 in the manner illustrated in
When the massage is complete, the forward and rearward legs can be pivoted in a direction toward the lower surface of the resilient body pad 56 and the resilient body pad 56 can then be folded to form a compact unit that can be easily transported and stored.
Next, with respect to
The control assembly 100 includes a lower support structure 110, an upper support platform 120, a plurality of extension arms 140, a plurality of horizontal supports 160, a lifting mechanism 170, and a control mechanism 180.
As shown in
Each lower support arm 112 is an elongated rigid beam having a rectangular shape. However, one skilled in the art should appreciate other designs are possible, including but not limited to round, tubular, hexagonal, and triangular configurations. In the embodiment shown, each lower support arm 112 is made of metal, such as steel, aluminum, or other rigid strong material. However, one skilled in the art should appreciate that other materials could be used. Each lower support arm 112 includes a lower pivot receiving passageway 114, a lower slide receiving groove 116, and a plurality of lower fastener receiving passageways 117. In the embodiment shown, the lower pivot receiving passageway 114 is a hole that extends from an inner surface side 112a to an outer surface side 112b of the lower support arm 112. More particularly, the lower pivot receiving passageway 114 extends completely through the lower support arm 112. However, one skilled in the art should appreciate other designs are possible, including a blind pocket hole that does not extend there through. In the embodiment shown, the lower slide receiving groove 116 is an elongated groove extending along a length of the lower support arm 112. The lower slide receiving groove 116 extends from the inner surface side 112a to the outer surface side 112b of the lower support arm 112. More particularly, the lower slide receiving groove 116 extends completely there through the lower support arm 112. As shown, the pair of lower support arms 112 positioned parallel to each other. In the shown embodiment, a length of each lower support arm 112. Each lower fastener receiving passageways 117 is a hole that extends from an upper surface side 112c to a lower surface side 112d of the lower support arm 112. More particularly, the lower fastener receiving passageway 117 extends completely through the lower support arm 112. The lower fastener receiving passageway 117 is positioned at an end of each lower support arm 112 in the embodiment shown.
In the embodiment shown, each support fastener 118 is a screw that attaches to the support platform 50 through the lower fastener receiving passageway 117. However, one skilled in the art should appreciate that other fasteners or an adhesive could be used to attach the lower support arm 112 to the support platform 50, such as latches, nuts and bolts, Velcro, and removable adhesives.
As shown in
Each upper support arm 122 is an elongated rigid beam having a rectangular shape. In the embodiment shown, each upper support arm 122 is made of metal, such as steel, aluminum, or other rigid strong material. However, one skilled in the art should appreciate that other materials could be used. Each upper support arm 122 includes an upper pivot receiving passageway 124, an upper slide receiving groove 126, and a plurality of upper fastener receiving passageways 127. In the embodiment shown, the upper pivot receiving passageway 124 is a hole that extends from an inner surface side 122a to an outer surface side 122b of the upper support arm 122. More particularly, the upper pivot receiving passageway 124 extends completely there through the upper support arm 122. In the embodiment shown, the upper slide receiving groove 126 is an elongated groove extending along a length of the upper support arm 122. The upper slide receiving groove 126 extends from the inner surface side 122a to the outer surface side 122b of the upper support arm 122. More particularly, the upper slide receiving groove 126 extends completely there through the upper support arm 122. As shown, the pair of upper support arms 122 positioned parallel to each other and the pair of lower support arms 112. In the embodiment shown, a width W1 of the pair of upper support arms 122 (measured from the outer surface side 122b of both upper support arms 122) is smaller than a width W0 of the pair of lower support arms 112 (measured from the inner surface side 112a of both lower support arms 112). In the shown embodiment, a length Lu of the pair of upper support arms 122 is smaller than a length L1 of each lower support arm 112, as well as a length Lc of the deformable support cushion Each upper fastener receiving passageways 127 is a hole that extends from an upper surface side 122c to a lower surface side 122d of the upper support arm 122. More particularly, the upper fastener receiving passageway 127 extends completely there through the upper support arm 122. The upper fastener receiving passageways 127 are positioned at opposing ends of each upper support arm 122 in the embodiment shown.
In the embodiment shown, each support fasteners 128 is a screw that attaches to deformable support cushion 80 through the upper fastener receiving passageway 127. However, one skilled in the art should appreciate that other fasteners or adhesive could be used to attach the upper support arm 122 to deformable support cushion 80, such as latches, nuts and bolts, Velcro, and removable adhesives.
As shown in
Each outer extension arm 142 is an elongated rigid beam having a rectangular shape. In the embodiment shown, the outer extension arm 142 is made of metal, such as steel, aluminum, or other rigid strong material. However, one skilled in the art should appreciate that other materials could be used.
The outer extension arm 142 includes an end pivot receiving section 144, a middle pivot receiving section 146, and a slide receiving section 148. In the embodiment shown, the end pivot receiving section 144 is a hole that extends from an inner surface side 142a to an outer surface side 142b of the outer extension arm 142. More particularly, the end pivot receiving section 144 extends completely there through the outer extension arm 142. In the embodiment shown, the middle pivot receiving section 146 is a hole that extends from the inner surface side 142a to the outer surface side 142b and extends completely there through the outer extension arm 142. In the embodiment shown, the slide receiving section 148 is a hole that extends from the inner surface side 142a to the outer surface side 142b and extends completely there through the outer extension arm 142. In the embodiment shown, the end pivot receiving section 144 is positioned at a lower end of the outer extension arm 142, while the slide receiving section 148 at an upper end of the outer extension arm 142, opposite the end pivot receiving section 144. The middle pivot receiving section 146 is positioned between the end pivot receiving section 144 and the slide receiving section 148 and, more particularly, proximate to a middle portion of the outer extension arm 142. As shown, the outer extension arms 142 are positioned parallel to each other.
Each inner extension arm 152 is an elongated rigid beam having a rectangular shape. In the embodiment shown, the inner extension arm 152 is made of metal, such as steel, aluminum, or other rigid strong material. However, one skilled in the art should appreciate that other materials could be used.
The inner extension arm 152 includes an end pivot receiving section 154, a middle pivot receiving section 156, and a slide receiving section 158. In the embodiment shown, the end pivot receiving section 154 is a hole that extends from an inner surface side 152a to an outer surface side 152b of the inner extension arm 152. More particularly, the end pivot receiving section 154 extends completely there through the inner extension arm 152. In the embodiment shown, the middle pivot receiving section 156 is a hole that extends from the inner surface side 152a to the outer surface side 152b and extends completely there through the outer extension arm 142. In the embodiment shown, the slide receiving section 158 is a hole that extends from the inner surface side 152a to the outer surface side 152b and extends completely there through the inner extension arm 152. In the embodiment shown, the end pivot receiving section 154 is positioned at an upper end of the inner extension arm 152, while the slide receiving section 158 at a lower end of the inner extension arm 152, opposite the end pivot receiving section 154. The middle pivot receiving section 156 is positioned between the end pivot receiving section 154 and the slide receiving section 158 and, more particularly, proximate to a middle portion of the inner extension arm 152. As shown, the inner extension arms 152 are positioned parallel to each other.
In the embodiment shown, a width Wi of the pair of inner extension arms 152 (measured from the outer surface side 152b of both inner extension arms 152) is smaller than a width Wo of the pair of outer extension arms 142 (measured from the inner surface side 142a of both outer extension arms 142). As shown, the outer extension arms 142 and the inner extension arms 152 are positioned in a scissor-type manner, wherein the outer extension arms 142 and the inner extension arms 152 cross each other around a substantial middle section of the outer extension arms 142 and the inner extension arms 152. However, it is possible that the support arms 14 be positioned such that they may act as a cantilever lift (i.e. powered), in a way which makes it easy and fast to lift a collapsible massage table no matter the size.
Now with reference to
The upper rotation support 162 is an elongated rigid rod shaped support. In the embodiment shown, the upper rotation support 162 is made of metal, such as steel, aluminum, or other rigid strong material. However, one skilled in the art should appreciate that other materials could be used. The lower rotation support 163 is an elongated rigid rod shaped support. In the embodiment shown, the lower rotation support 163 is made of metal, such as steel, aluminum, or other rigid strong material. However, one skilled in the art should appreciate that other materials could be used. The upper rotation support 162, the lower rotation support 163, and the middle rotation support 164 include a fastener receiving mechanism (not shown), such as a threaded receiving wall for engagement with a fastener (i.e. screw or bolt), positioned at both ends thereof. In the shown embodiment, the upper rotation support 162 is shorter than the lower rotation support 163.
The middle rotation support 164 is an elongated rigid rod shaped tubular support. In the embodiment shown, the middle rotation support 164 is made of metal, such as steel, aluminum, or other rigid strong material. However, one skilled in the art should appreciate that other materials could be used.
The upper slide support 166 is an elongated rigid rod shaped support. In the embodiment shown, the upper slide support 166 is made of metal, such as steel, aluminum, or other rigid strong material. However, one skilled in the art should appreciate that other materials could be used. The lower slide support 168 is an elongated rigid rod shaped support. In the embodiment shown, the lower slide support 168 is made of metal, such as steel, aluminum, or other rigid strong material. However, one skilled in the art should appreciate that other materials could be used. Both the upper slide support 166 and the lower slide support 168 include a fastener receiving mechanism (not shown), such as a threaded receiving wall for engagement with a fastener (i.e. screw or bolt), positioned at both ends thereof. In the shown embodiment, a length L1 of the upper slide support 166 is shorter than a length L2 of lower slide support 168.
As shown in
With reference to
Now, with respect to
The lower support structure 110 is positioned below the upper support platform 120. The outer extension arms 142 and the inner extension arms 152 are positioned in a scissor-type manner.
The middle rotation support 164 is positioned between the inner extension arms 152 and the outer extension arms 142 and corresponds with the middle pivot receiving sections 146, 156. One outer extension arm 142 is rotatably connected to one inner extension arm 152 using a fastener 200 positioned through the middle pivot receiving section 146, 156, respectively. The other outer extension arm 142 is rotatably connected to the other inner extension arm 152 using another fastener 200 positioned through the middle pivot receiving section 146, 156, respectively.
The upper rotation support 162 is positioned between the inner extension arms 152 in order to correspond with the end pivot receiving sections 154 and the upper pivot receiving passageway 124. A fastener 200 rotatably connects the inner extension arms 152 and the upper rotation support 162 about the upper support arms 122.
The lower rotation support 163 is positioned between the outer extension arms 1422 in order to correspond with the end pivot receiving sections 146 and the lower pivot receiving passageway 114. A fastener 200 rotatably connects the outer extension arms 142 and the lower rotation support 163 about the lower support arms 112.
The upper slide support 166 is positioned between the outer extension arms 142 in order to correspond with the slide receiving sections 148 and the upper slide groove 126. A fastener 200 rotatably connects the outer extension arms 142 and the upper slide support 166 about the upper support arms 122 such that the upper slide support 166 moves linearly along the upper slide groove 126.
The slide receiving section 174b receives the lower slide support 168 about a middle portion thereof in the shown embodiment. Next, the lower slide support 168 is positioned between the inner extension arms 152 in order to correspond with the slide receiving sections 158 and the lower slide groove 116. A fastener 200 rotatably connects the inner extension arms 152 and the lower slide support 168 about the lower support arms 112 such that the lower slide support 168 moves linearly along the lower slide groove 116.
The upper support structure 120 is then connected to the cushion 80 using the support fasteners 128 that are positioned through the upper fastener receiving passageways 127 and secured to the cushion 80. The cushion 80 is then positioned within the guide passageway 66. Then, the lower support structure 110 is then connected to the body pad 56 using the support fasteners 118 that are positioned through the lower fastener receiving passageways 117 and secured to the body pad 56.
The motor 172 is connected to the actuator 174 and the attachment support 176 is rotatably connected to the motor 172 and/or the actuator 174 using a hinge joint (not shown). The bracket 178 is then secured to the body pad 56. The control mechanism 180 is positioned on the body 56 in the embodiment shown and electrically connects to the motor 172.
Now, with respect to
In order to adjust the height of the 80 cushion within the guide passageway 66, a user activates the motor 170 using the control mechanism 180. The motor 170 moves the actuator 174, which then moves the lower slide support 168 linearly along the lower slide receiving groove 116. As the lower slide support 168 moves linearly in the lower slide receiving groove 116, the outer inner extension arms 142 and inner extension arms 152 pivot about the middle pivot receiving sections 146, 156, and the upper slide support 166 moves linearly along the upper slide receiving groove 126. The upper support structure 120 moves horizontally toward and away the lower support structure 110. In accordance, an upper surface of the cushion 80 moves along the guide passageway 66, such that the cushion can be moved above or below an upper surface of the body pad 56.
The foregoing illustrates some of the possibilities for practicing the invention. Many other embodiments are possible within the scope and spirit of the invention. It is, therefore, intended that the foregoing description be regarded as illustrative rather than limiting, and that the scope of the invention is given by the appended claims together with their full range of equivalents.
This application is a continuation of co-pending application U.S. Ser. No. 15/888,523 filed on Feb. 5, 2018, which claims priority to U.S. Ser. No. 14/724,881 filed on May 29, 2015 that is now issued into U.S. Pat. No. 9,925,108 on Mar. 28, 2018.
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Number | Date | Country | |
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20220071829 A1 | Mar 2022 | US |
Number | Date | Country | |
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Parent | 15888523 | Feb 2018 | US |
Child | 17530678 | US | |
Parent | 14724881 | May 2015 | US |
Child | 15888523 | US |