ES2621223T3 - Operating system of vertebral insole / template in particular for ballet pointe shoes - Google Patents

Abstract

Insole device for footwear, in particular for ballet pointe shoes, comprising a vertebral insole provided with vertebral bodies, in whose intermediate spaces intervertebral discs are arranged for the definable flexibility of the insole, as well as a rubber layer arranged in the lower side of the template, characterized in that the vertebral bodies (V) of the vertebral template (B) have recesses arranged centrally for a rubber layer (R), which weaken the material of the lateral vertebral bodies (V), and on the rubber layer (R), ribs (F) are formed on both sides that protrude slightly, which are received in the recesses of the vertebral bodies (V), fitting the lateral projections of the ribs (F) precisely in the weakening of the recesses, and because the intervertebral discs are rods (S) that can be inserted or removed with recesses (RS) arranged centrally for the rubber layer (R), in which the rubber layer (R) fits, preventing lateral sliding of the rods (S).

Description

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DESCRIPTION

Operating system of vertebral insole / template in particular for ballet pointe shoes Introduction

In classical ballet, in most cases a dancer needs for the dance of tips only in a single case the relative stiffness of her pointed shoe (figure 1 - c), which is the time to stand On the tips. However, for all other dance steps and movements, in particular for the demi-pointe (figure 1 - b), stand on half a point, and not last for the maintenance of health or the healthy development of the foot under the stress of a dancer, this rigidity of the template is precisely the problem. All manufacturers of pointed shoes face a basic problem: How can I make a relatively flexible toe shoe template that offers enough support to stand on the tips? Therefore, solutions to date are often a compromise.

State of the art

Traditionally the toe slippers insoles are made up of several layers of different materials, such as cardboard, vulcanized fiber and leather, that stick together, nail or sew together in different lengths. The German utility model (No. 20 2011 004 126 - Wirbelsaulensohle (Spine Template)) already describes a vertebral construction of the template, making it possible to individually control important functional areas (figure of the state of the art). In the upper part, the vertebral insole is defined by a resistant but non-elastic material (U), with which the conically developed vertebral bodies (V) are firmly joined. The insertion or removal of intervertebral discs (S) defines the flexion behavior of the template. The lower material (L) is in turn resistant but elastic (eg rubber). The template thus becomes flexible upwards, but downwards its flexibility will be defined by the vertebrae (V) and intervertebral discs (S).

issue

However, the fixation of the intervertebral discs in front of the lateral sliding remains unresolved, as well as the way of joining the components together in a safe and environmentally friendly way. Thus, the glued joints between the rigid template and the elastic rubber layer can barely be guaranteed in a lasting and effective manner. The effective assembly in the finished toe shoe is not clear and it is not possible to individually vary the resistance behavior of the template, which is defined primarily by the Shore hardness of the lower rubber layer. In order to guarantee in a lasting manner the individual control behavior of the template for the end user, it must be possible at all times that each individual component can be easily removed or changed.

Solution

Often, the toe shoe template is also called the spine of the toe shoe. This idea was consequently perfected to take advantage from the technological point of view of what nature has optimized over millions of years of evolution. The structures developed to date have been optimized to achieve a revolutionary improvement in the functioning of the toe shoe and its medical objections. The result of this work is an intelligent backbone insole operating system attached with drag that is easy to assemble as a template, in particular for pointed shoes with the characteristics of claim 1 (Figure 1).

Embodiment of the invention

The intelligent vertebral template operating system (figure 2) is made up of at least two, in the optimal case however three functional basic components, which, in a union with pure drag, are joined together without means of union or adhesives and can be assembled or changed correspondingly easily. The basic element is the vertebral template (B), the rods (S) act as intervertebral discs and the rubber layer (R) as the system muscle.

1.) Vertebral template

The vertebral template (figure 3) mainly characterizes a juxtaposition of vertebral bodies (V), which can be configured both straight and conically with a defined angle. The intermediate spaces (I) of the vertebral bodies allow the vertebral template to have a free upward bending capacity. The downward bending capacity is limited in the first place by the straight or conical shape of the vertebral bodies, whose sides collide with each other in the case of a maximum definable flexion and do not allow additional flexion (Figure 4-a-A). The vertebral template is defined at the top by a very resistant, flexible but non-elastic material (Figure 4-a-U), with which the vertebral bodies, according to the production procedure, are firmly joined or molded directly. The most effective seems to be in this case to use a procedure of

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injection molding, in which the vertebral template with all vertebral bodies and the upper layer that acts as a joint (Figure 4 - a-U) are produced in a wash. The corresponding conformation and recesses of the vertebral template (figure 2 and figure3) now allow, among other things, the union with pure drag of all the components to each other without having to use adhesives. The vertebral insole hardly experiences fatigue compared to the conventional insoles of pointed shoes. So to speak it does not become soft, and offers the foot of the dancer throughout the life cycle of the outside of the shoe full mobility and a stable stable support in the position on the tips. The terminology often used by the dancers: softness or stiffness no longer plays any role in the vertebral template, because it is already flexible in all the desired directions and in the necessary final position on the tips is then firm in a lasting way (Figure 1 - a, b, c).

2.) Rods

The rods (Figure 5 - S) act as an intervertebral disc in the vertebral template. A rod between two vertebrae means that although the vertebral template at this point can still flex upwards, it can no longer do it down (Figure 4 - a). It is now very easily possible to insert or remove a random number of rods (S) in the heel area (Figure 2 - S). At points that can be freely defined, the vertebral template now follows the individually flexed anatomy of the sole of the foot and remains straight at other points, for example under the forefoot or behind the heel (Figure 1 - c). The following sentence is irrelevant and is deleted. The elastic rods in the forefoot area produce a noise and shock reduction effect for the position on the tips or in the case of a jump. The elastic rods can now also make the angular turns of the vertebral bodies to each other be tolerated. Instead of completely removing a rod in the heel area, an elastic rod can also be inserted, thus generating a variable back pressure under the heel curve that also absorbs shock. The rods are now thinner in this embodiment in the central zone, so that the rubber layer (figure 6-R) fits into these recesses (figure 5-RS) and prevents lateral sliding of the rods.

3.) Rubber layer

The bottom material, the rubber layer (Figure 6 - R) is strong but elastic, unlike the top layer (Figure 4 - U). It is fixed at defined points of the vertebral template. In the present embodiment, a purely dragged connection of the rubber layer with the vertebral template is shown (Figure 2). The integrated rubber layer is hooked in this case with corresponding ribs (Figure 2-F) as a muscle in each of the individual vertebral bodies, which are provided with corresponding housing recesses. Now, the rubber layer can synchronize with its elastic control the individual vertebral bodies with each other. If the vertebral insole is now flexed upwards when walking or in demi-pointe, a flexion that runs uniformly throughout the template is achieved through the traction on the rubber layer (Figure 1 - b). The union with drag of form of the layer of rubber with the vertebral template, without glue or mechanical elements of screwed, nailed, or other elements of union, allows a dancer to introduce herself with few maneuvers rubber layers with alternative Shore hardnesses in its staff, which represents in particular for professional dancers a relief not yet achieved. In the case of an extension, the integrated rubber layer, with respect to the lower glued or screwed flat rubber layers, also absorbs even more dynamic force, which returns during a jump or in the transition to the position on the tips so perceptible to the foot (kangaroo effect). In addition, the integrated rubber layer also acts as a mechanical and safe lock against the lateral sliding of the rods, which are provided with corresponding recesses for the rubber layer (Figure 5 - RS). The rubber layer is introduced in the extended state in the vertebral template and allows a pretension of the template. In this way, the vertebral template is previously flexed slightly in the areas without rods and adapts to the natural arch of the sole. This is for example especially useful when freely stretching the foot.

Without rods and rubber layer

The vertebral insole also achieves limited functionality without the rubber layer and rods, predefining the angles of the vertebral bodies and the possible flexion behavior, however excluding the possibility that the client can subsequently adjust the template to the shape of his foot and the necessary flexural strength (Figure 4 - c). In production, the material thickness of the vertebral template is selected in such a way that the template presents a relative stiffness, that is to say that in the case of forces defined by the body weight the template remains practically inflexible in both directions. If the material of the vertebral template is now cracked or meshed with intervertebral zones, the material is now relatively flexible in these vertebral zones in the opposite direction to the cracks and is not limited in the other direction until the vertebral bodies converge (figure 4 - c). However, by means of rods (S) in this case the individual bending behavior of the template without rubber layer can also be controlled. However, the realization of the intelligent vertebral template operating system with its three basic functional components (figure 2) promises a flexion behavior of the template that can be controlled more accurately and more effectively.

Mounting template with click fit rail

The intelligent spine insole operating system also offers innovative solutions for simple assembly with the full toe shoe. The outside of the pointed shoe is attached to the last with

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all layers and all cover structures in a thin and flexible mounting template (figure 7 - a). This internal mounting template is equipped, for example, with a click adjustment rail (Figure 7 - c). The outside of the template fits in the known procedure on the mounting template and finally presses all layers firmly between the mounting template and the outside of the template. The last is removed. A corresponding guide in the vertebral insole (Figure 2 - C) now allows the vertebral insole system to be fully assembled into the finished toe shoe and slide through the adjustment rail by click. When the vertebral template is audibly interlocked in the snap-fit closure, it is firmly attached to the outside of the pointed shoe. The concrete technical realization of this interlocking system may vary.

Other apps

The vertebral insole as a functional intelligent template system is conceivable for some applications in the field of general, orthopedic or sports shoes. Whenever comfortable flexibility is needed in relation to clearly definable flexibility endpoints, the modified vertebral template system will be an obvious solution. Also the kangaroo effect mentioned above is conceivable in relation to the structure of layers of a vertebral insole for example also for sports shoes and for running.

List of reference symbols

B = vertebral template (backbone shank)

V = vertebral body

I = intervertebral zones (inter vertebral space)

C = guide for adjustment rail per click (click bar)

S = rods / inter-vertebral discs (intervertebral discs)

R = rubber layer

U = upper layer

L = lower layer

RS = rubber space in the middle of the sticks

F = nerves of the rubber layer (fins of the rubber strap)

A = angle of the vertebral bodies

Claims (3)

1. Insole device for footwear, in particular for ballet pointe shoes, comprising a vertebral insole with vertebral bodies, in whose intermediate spaces intervertebral discs 5 are arranged for the definable flexibility of the insole, as well as a rubber layer arranged in the lower side of the template, characterized in that the vertebral bodies (V) of the vertebral template (B) have recesses arranged centrally for a rubber layer (R), which weaken the material of the lateral vertebral bodies (V), and on the rubber layer (R) are configured on both sides ribs (F) that protrude slightly, which are received in the recesses of the vertebral bodies (V), 10 fitting the lateral rib projections (F) precisely in the weakening of the recesses, and because the intervertebral discs are rods (S) that can be inserted or removed with recesses (RS) arranged centrally for the rubber layer (R), into which the rubber layer (R) fits preventing the lateral sliding of the rods (S). 15 2. Template device according to claim 1, characterized in that the rods (S) are elastic and They have different Shore hardnesses. 3. Template device according to claim 1 or 2, characterized in that a mounting template is arranged inside the tip shoe, which is provided with a click adjustment rail, and the template (B) 20 vertebral is interlocked in the click fit rail with the guide (C) for the click fit rail during the introduction inside the shoe of tips. 4. Use of the insole system according to one of the preceding claims in a shoe article, selected from the group consisting of a ballet shoe, an orthopedic shoe, a 25 sneaker and a running shoe.