In recent decades, inversion therapy has become a popular and well-researched method for achieving musculoskeletal decompression. Using the lower-leg as the point of suspension enables nearly every joint in the human body to be in a state of traction. Devices for achieving this physical posture have been available for several decades, marketed under the popular name of “gravity boots”. These conventional designs use rigid metal or plastic shells which clamp or cinch around the user's shins, and a hook which is secured to the front of the shell allows for attachment to a horizontal supporting bar structure.
The device described in this document provides an alternative method for performing this exercise, with design advantages resulting in improved safety and comfort.
The device described in this document tightens and secures around the user's lower leg in direct proportion to the magnitude of applied tension. In practice, this means that the device is in a state of maximum closure when the user is fully inverted. It is therefore impossible to slip out of the device while using it.
The materials used to construct the device are soft and flexible and conform to the shape of the user's leg to distribute pressure as evenly as possible and therefor minimize discomfort. Traditional rigid-shell designs place concentrated pressure on the front of the user's lower shin region during use, and other pressure points can exist due to the metal hooks or buckles required by conventional designs.
The design shown in this document is collapsible for storage and transport and can easily fit into a small gym bag. Traditional gravity boots can be oversized and heavy and are less portable.
The additional weight attached to the ankles when using conventional gravity boots creates a significant burden when raising the feet to the bar elevation to attach the hooks. This burden is caused by the natural moment which occurs when the feet are extended outward in front of the body and pivoted about the axis of the hips and lower abdomen. The gravitational loading which is caused by the weight of the attached conventional gravity boots is multiplied by the length of the entire leg, resulting in an additional force which must be overcome by muscular effort. The design of the device described in this document eliminates this unnecessary burden, as no extra weight is attached to the ankles when entering or exiting the inverted posture.
While the device described enables decompression of the spine and joints, said device can also be used as a fitness tool. Exercises which can be performed while in the inverted posture include:
The device disclosed herein is a minimum embodiment required for performing all possible exercises enabled by its structure. Alternative embodiments may incorporate obvious modifications to suit user preferences, such as: padding around the ankle region, fabric sheaths over material surfaces, and other embellishments commonly used in the art field of the present invention.
The primary loop is shown with 1, the retainer loop is shown with 2 (and, by implication, the pair of retainer loops is thus identified), the release loop is shown with 3, the material linkage between the release loop bottom and the bottom location on the primary loop is shown with 4, the optional ankle enclosure grip surface is shown with 5, the connector loop is shown with 6, the mounting loop is shown with 7, and the optional release loop grip surface is shown with 8.
Safe Method of Operation:
Entry:
The distance between the attachment points of the retainer loops (2) on the primary loop (1) determines the minimum circumference of the ankle enclosure formed by the primary loop (1), as the fixed locations of the retainer loops (2) create static physical limits on the contraction of (1). The distance from the retainer loops (2) to the ends of the primary loop (1) at the top location on the device (6) determines the maximum circumference of the ankle enclosure formed by the primary loop (1), as said distance comprises the range of the slack-adjusting extensions of the primary loop (1).
The release loop (3) enables force application to the top location on the device (6), where load tension is transferred from the device to the mounting structure via the mounting loop (7). Enveloping the release loop (3) within the retainer loops (2) provides leverage for expanding the ankle enclosure of the primary loop (1) through an upward force application to the ankle-enclosure of (1) and a simultaneous counter-tension application to the bottom of the release loop (3). The material linkage (4) ensures a smooth expansion action of the ankle enclosure of the primary loop (1) during this process.
A pair of loops can be formed at and from the open ends of the slack-adjusting extensions of the primary loop (1). This is depicted in
The device can be assembled, based on the figures and claims provided, using standard best practices when sewing webbing for load-bearing applications.
Number | Name | Date | Kind |
---|---|---|---|
4565370 | Christianson | Jan 1986 | A |
5279386 | Cearley | Jan 1994 | A |
8007413 | Wu | Aug 2011 | B1 |
8038584 | Pruessner | Oct 2011 | B1 |
8845568 | Clark | Sep 2014 | B2 |
8858408 | DeMeo | Oct 2014 | B2 |
8979716 | Rawlins | Mar 2015 | B1 |
9259605 | Puig | Feb 2016 | B1 |
9854898 | Whitley | Jan 2018 | B2 |
9895566 | Zbinden | Feb 2018 | B2 |
20140073496 | Bannerman | Mar 2014 | A1 |
20140155233 | Latronica | Jun 2014 | A1 |
20160023051 | Lauener | Jan 2016 | A1 |
Number | Date | Country | |
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20180055710 A1 | Mar 2018 | US |