This invention relates to a stirrup with an automatic binding, designed to facilitate horseback riding and make it safe by securing the rider's foot in the stirrup using two associated retaining mechanisms that mate with elastic return force to allow the binding to engage and disengage.
Traditionally, a horseback riding stirrup is composed of a loop, two branches, and a bottom.
The use of two branches allows the rider to more easily remain in the stirrups, since the foot is only able to exit through a rearward motion, and it is not possible to lose the stirrup through a lateral movement. The drawback of using two branches is the danger of a foot becoming blocked in the stirrup if it is inserted too far. The use of a heeled boot arises from the need to protect the rider from that risk of becoming blocked. It is effective without being perfect or helping the rider to remain in the stirrups in all situations.
The device according to the invention is a stirrup with a single branch whose bottom, affixed to a pin through the intermediary of a hub, is able to rotate forward and rearward. The bottom comprises a female binding mechanism. This binding mechanism is composed of two bars parallel to the axis of rotation. These bars may be separated parallel to the pin and are maintained in position by elastic return forces.
The ends of the bars, wound in spirals around two pins integral with the bottom, constitute the elastic return forces.
The female binding mechanism is designed to mate with a male binding mechanism affixed to the sole of the rider's shoe. The rider engages the automatic binding by inserting the male binding mechanism on his shoe between the two bars of the female binding when, once in the saddle, he puts his feet in the stirrups.
Once engaged, the automatic binding eliminates all risk of inadvertently losing the stirrups. Regardless of the rider's leg movements or movements by the horse, the rider remains in the stirrups, which provides better balance for beginning riders and better control of the horse for experienced riders.
The pin, which is integral with the branch of the stirrup, comprises a projection topped with a stop that disengages by means a hub with a hollow center.
This projection attached to the disengagement stop prevents the bottom from completely rotating around the pin. When the bottom rotates forward or rearward beyond a predefined angle, the disengagement stop of the pin exerts pressure on the bars of the female binding of the bottom. This pressure is an antagonistic force to the elastic return force, which disengages the male binding from the shoe. This disengagement mechanism makes it possible to remove the stirrups and ensures the safety of the rider in the event of a fall. This disengagement may be adjustable according to the weight of the rider.
An adjustment mechanism on the male binding on the sole of the shoe allows the rider to adjust the binding point from the front to the rear of the sole. This adjustment mechanism makes it possible to exert pressure on the stirrup at the location on his foot that suits him perfectly.
The lower part of the single branch of the automatic stirrup contains a shock absorber. This shock absorber absorbs the variations in pressure exerted on the stirrup and, therefore, absorbs any untimely forces exerted on the disengagement mechanism of the binding. This shock absorber provides greater comfort to both rider and horse, and is particularly useful when jumping.
The embodiment, provided as a non-limiting example, refers to the attached figures.
Above the fixation of the bottom, the branch 1 of the stirrup, made of aluminum, may comprise a shock absorber system 2 composed of a spring 3 and an elastomer 4.
A steel pin A is affixed perpendicularly to the branch 1 at its base.
A bottom 5, made of a composite material, is rotationally affixed to the pin A through the intermediary of a steel hub B.
A hollow 6 in the center of the hub B allows a projection 7 to be affixed to the pin A.
This projection 7 on the pin A is topped with a flat rectangular piece 8 that plays the role of a disengagement stop.
The hollow 6 in the hub B allows the bottom to pivot around the pin A, despite the projection, within the limits of the hollow.
Two pins C and D are affixed to the right and left walls of the bottom 5 parallel to the pin A on each side of the hub B.
Two steel wires each for an inverted U in a vertical plane from pins C and D. The U is obtained by piercing holes in the bottom 5, allowing the steel wire and two elbows 10 to pass through it. These inverted U shapes form two bars 9 above the bottom 5, parallel to the pin A, in front and behind it. These two bars 9 play the role of the female binding mechanism for the male binding mechanism 12 on the shoe.
The ends of these U-shaped steel wires are wound in a spiral around pins C and D, creating torsion springs 11.
The torsion springs 11 of each steel wire allow the bars 9 to be separated when the male binding mechanism 12 of the shoe is being engaged, while exerting return force that returns the two bars 9 to their initial positions once the male binding mechanism 12 is in the engaged position.
The purpose of the part 8 mounted on the projection of the pin A is to disengage the male binding mechanism 12 of the shoe when the bottom pivots forward or rearward.
Integral with the bottom mounted rotationally on the pin A via the two pins C and D, the two vertical branches 13 of each U-shaped steel wire abut against the part 8 when the bottom rotates.
The pressure exerted by the part 8 on the vertical branches 13 allows the bars 9 to be separated in order disengage the male binding mechanism of the shoe. When the bottom 5 rotates forward, the branches 13 of the steel wire placed behind the pin A abut against the rear part of the part 8 and cause the rear bar 9 to separate rearward. This separation releases the male binding mechanism 12 of the rider's shoe. The effect is inversely identical for rearward rotation.
The width of the part 8 and the force of the torsion springs 11 determine the front and rear disengagement thresholds.
Loop 14 of branch 1 is created in an extension of the stirrup leather, such that the stirrup remains naturally perpendicular to the direction of the horse when it is at rest.
Using the automatic stirrup allows the rider to remain in his stirrups in all circumstances. Useful during abrupt, uncontrolled movements, the automatic stirrup allows the rider to retain his balance. This is a comfort and safety feature for the experienced rider as well as for the beginning rider.
The automatic stirrup is also particularly effective when the rider is riding seated in the saddle.
In effect, when he is seated in the saddle, the rider has to exert effort to maintain sufficient pressure not to lose his stirrups. The binding allows him to ride in a much more relaxed sitting position and his support is always available, adjusted exactly as he desires, using the adjustment mechanism on the male binding of the shoe.
The binding prevents the foot from having to constantly find the ideal pressure point that he is used to, and the leg is more steady.
The use of a single branch, attached to lateral break-away mechanism, provides maximum stirrup use safety. The foot can no longer become blocked in the stirrup in the event of a fall.
The suspension integrated into the branch of the stirrup absorbs shock, relieving the rider's knees, which usually play this shock absorber role, and the back of the horse.
Number | Date | Country | Kind |
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02/02311 | Feb 2002 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR03/00604 | 2/24/2003 | WO | 5/4/2005 |