The present invention is directed to an athletic training apparatus, specifically a pole vault swing-up rack. The swing-up rack helps train athletes in the mechanics of raising one's body vertically during a pole vault.
Prior art athletic training devices for the pole vault typically try to simulate the act of actually pushing one's body up while holding onto the pole. Such devices suffer from the disadvantage of involving multiple movements and positions in training, i.e., pushing, balancing, lifting, etc., while the athlete must also maintain his/her shoulders forward of the vertical line of the hands as would be in an actual pole vault action. Such multiple movement training more closely simulates the total movement of a pole vault. However, the inventor has found that breaking the mechanics of the pole vault action down into simpler movements improves training efficiency and overall results.
Accordingly, there is a need for a pole vault training apparatus that simplifies the training mechanics and improves efficiency and results. The present invention fulfills these needs and provides other related advantages.
The present invention is directed to a pole vault swing-up rack. The swing-up rack includes a generally rectangular frame body having a long dimension with a pair of vertical uprights oriented in and co-extensive with the long dimension. The frame body also has an upper crossbar and a lower crossbar, both oriented perpendicular to the long dimension. A pair of hooks is attached to the frame body proximate to the upper crossbar. The pair of hooks preferably extend from a back side of the frame body. A push bracket is attached to the frame body proximate to the lower crossbar, with that push bracket extending from the back side of the frame body.
The push bracket is preferably oriented generally perpendicular to the frame body and may further include angle braces attaching the push bracket to the frame body at a point a fixed distance above the lower crossbar. The pair of hooks are each preferably configured to fit over a horizontal bar such that the pole vault swing-up rack hangs vertically downward from the horizontal bar.
The swing-up rack may also include a pair of foam pads, one encircling each of the pair of vertical uprights. The pair of foam pads preferably extends from proximate to the lower crossbar to at least half of the long dimension. The pair of foam pads are each preferably made from high-density, polyethylene foam for durability, but may be low-density. A rubber coating may surround each of the pair of foam pads. The rubber coating may be a vinyl rubber tape.
The rack may also include a lower foam pad on the lower crossbar, which lower foam pad is also polyethylene foam, either high-density or low-density. The lower foam pad is also preferably surrounded by a rubber coating such as vinyl rubber tape. Similarly, an upper foam pad may be included on the upper crossbar—also made from polyethylene foam, either high-density or low-density. The upper foam pad preferably includes a horizontal bar cut-out proximate to the pair of hooks on the back side of the frame body. The upper foam pad may also include a rubber coating, such as vinyl rubber tape.
A process for training an athlete in a pole vault movement using the pole vault swing-up rack described above begins with hanging the swing-up rack on an upper horizontal bar by the pair of hooks. The swing-up rack preferably hangs from the upper horizontal bar in a generally vertical orientation. The athlete is then positioned on a front side of the swing-up rack and the upper horizontal bar. The athlete grips the upper horizontal bar using his/her hands, one hand on each side the swing-up rack. The athlete then places his/her shoulders against the pair of vertical uprights while hanging from the upper horizontal bar straight-armed in an upright vertical position with his/her legs and torso adjacent to the lower crossbar. The athlete then kicks his/her legs and torso upward and away from the lower crossbar such that the athlete moves from the upright vertical position to an inverted vertical position with the athlete's legs and torso adjacent to the upper crossbar.
The athlete may then lower his/her legs and torso downward and away from the upper crossbar so as to move from the inverted vertical position to the upright vertical position with the athlete's legs and torso adjacent to the lower crossbar. The kicking and repeating steps can be repeated as many times as necessary to train the athlete in the pole vault movement. This resembles repetitions as are performed in any number of physical training exercises. The lower push bracket may be secured against a lower horizontal bar to assist the athlete in performing these steps on his/her own.
Alternatively, a trainer or coach may push the lower push bracket simultaneously with the athlete performing the kicking step. The pushing action causes the swing-up rack to move from the generally vertical orientation toward an approximately horizontal position. The simultaneous kicking and pushing action allows the trainer or coach to assist the athlete in performing the transition from upright vertical orientation to inverted vertical orientation. After the kicking step, the swing-up rack is returned to the generally vertical orientation.
When gripping the upper horizontal bar, the athlete may use an opposite hand grip meaning that one hand is facing the front side of the swing-up rack and the other hand is facing the back side of the swing-up rack.
Other features and advantages of the present invention will become apparent from the following more detailed description, taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention.
The accompanying drawings illustrate the invention. In such drawings:
In the following detailed description, the pole vault swing-up rack of the present invention is generally referred to by reference numeral 10 in
The frame body 12 has a generally rectangular shape with extended vertical uprights 18a, 18b, an upper crossbar 20, and a lower crossbar 22. The uprights, 18a, 18b, upper crossbar 20 and lower crossbar 22 are made from steel or other material of similar strength such that when joined together form a rigid, inflexible shape. These components preferably have a square cross-section, but may also be round or any other polygon shape provided it still has the requisite rigidity and inflexibility to support the weight of a human body as described below.
As shown in close-up view in
As shown in close-up view in
A pushing crossbar 26 spans the distance between and is attached to an opposite second end of each extending arm 24a, 24b. The extending arms 24a, 24b and the pushing crossbar 26 are preferably permanently attached, as by welding, or integrally form with each other. A pair of angle braces 28a, 28b may support the joint between the frame body 12 and the extending arms 24a, 24b as shown. All of the components of the lower push bracket 16, including the extending arms 24a, 24b, the pushing crossbar 26 and the angle brace 28 are preferably made from steel or other material of similar strength so as to be sufficient to support the weight of a human body as described below.
Each of the vertical uprights 18a, 18b are preferably surrounded by or enclosed in a padding 30 sufficient to provide comfort for a user of the rack 10 when a part of a user's body, i.e., shoulder, comes into contact with the same as described below. The padding 30 preferably comprises high-density polyethylene foam or similar material to provide comfort and durability over repeated use. The padding 30 may also be surrounded by a rubber coating 31 (see
As shown in environmental view in
For individual use without a trainer, the lower end of the rack 10 may rest against a lower horizontal bar 38b. The lower horizontal bar 38b may be fixed in a vertical plane with the upper horizontal bar 38a. Alternatively, the lower horizontal bar 38b may consist of a removable dowel or similar bar that rests against the frame body 12 proximate to the lower push bracket 16, as by passing through the opening between the frame body 12 and the angle braces 28a, 28b. In the case of a removable dowel or bar, the lower horizontal bar 38b preferably rests against the same vertical supports 39 that support the upper horizontal bar 38a.
The lower end of the rack 10 may also hang free without a lower horizontal bar 38b. In this case, the rack 10 may be used individually without a trainer where the upper horizontal bar 38a is a configured as a pull-up bar spaced a fixed distance from a vertical wall. In this base, the lower push bracket 16 is preferably configured to rest against the wall beneath the upper horizontal bar 38a so as to maintain the rack 10 in a generally vertical orientation. The rack 10 may also be used individually with a trainer with the lower end of the rack 10 hanging free. In this instance, the trainer would grip the lower push bracket 16 and push the rack 10 through a range of pivoting motion around the upper horizontal bar 38a as described below.
An individual person 40 using the rack 10 preferably positions themselves in front of the rack 10 and horizontal bar 38 in an upright vertical position. The person preferably grips the horizontal bar 28 using an opposite grip, e.g., one hand 41a facing the front side and the other hand 41b facing the back side as shown, similar to how a pole is gripped in a pole vault. However, the person 40 may grip the bar 38a in any comfortable manner. The person 40 rests his/her shoulders 42 against the vertical uprights 18a, 18b with their arms at full extension from the upper horizontal bar 38a. In an exercise movement, the person 40 swings their legs 44 and torso 46 upwards to an inverted vertical position, e.g., upside down, as in a pole vault action. The person's head 48 moves in the space between the vertical uprights 18a, 18b during this exercise movement.
The rack 10 is designed to hold the shoulders 42 of person 40 in front of a vertical line 50 passing through the horizontal bar 38a, in line with the hands, while the person 40 is moving from the upright vertical position to the inverted vertical position.
Use of the inventive rack 10 by a person creates movement and resistance that very closely mimics the actual movement involved in performing a pole vault. The rack 10 allows a person to focus on and correct mechanical flaws in the swing-up motion of the pole vault. It helps the coach or trainer isolate any flaws in the movement, correct the flaws, and quickly and efficiently practice the swing-up motion in a repetitive manner with the same body positions found in the pole vault. The rack 10 allows the coach or trainer to provide the person with additional momentum in the swing and/or decrease the angle at the start to make the movement easier. This type of training allows the person to retain muscle memory of the movement when performing an actual pole vault. The rack 10 helps avoid neck strain and holds the person's shoulders in front of the hand grip just as in an actual pole vault movement. The same repetitive movement cannot be achieved with as much speed or efficiency simply by hanging on a high bar or rope.
Although several embodiments have been described in detail for purposes of illustration, various modifications may be made without departing from the scope and spirit of the invention. Accordingly, the invention is not to be limited, except as by the appended claims.
This application claims the benefit of U.S. Provisional Application No. 62/178,674, filed on Apr. 17, 2015.
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