WO2014090413A1 - Intelligent backbone shank functional system/insole, in particular for pointe ballet shoes (intelligent vertebral insole - backbone shank) - Google Patents

Abstract

The invention relates to the "backbone shank functional system" which is a pure molding composite of basic components that are functional and can be produced efficiently. The complete system replaces the conventional insole of the pointe shoe. The backbone shank functional system guarantees long durability, combined with the permanent possibility of easily re-optimizing the flexural behavior and the flexural characteristics of a ballet pointe shoe again and again under changing conditions and demands.

Description

 INTELLIGENT SWIVEL SOLE FUNCTIONAL SYSTEM Insole, especially for ballet pointe shoes

as well as for other applications - intelligent vertebral insole - backbone shank

INTRODUCTION

 In classical ballet, a dancer for top dance usually only needs the relative stiffness of the insole of her pointe shoe in a single case - (Fig.1 - c) that is the moment of standing on top! For all other steps and movements in dance, especially for the demi-point (Fig.1 - b), standing at half-peak, and not least for the health and healthy development of the stressed foot of a ballerina, but this stiffness the sole is exactly the problem. All lace shoe manufacturers face a fundamental problem: How can I be a relatively flexible

Produce a pointe shoe sole that provides sufficient support for standing on top? So previous solutions are often a compromise!

STATE OF THE ART

Traditionally, insoles of lace shoes consist of several layers

different materials, such as cardboard, volcanic fever and leather, which are glued together in different lengths, nailed or sewn. Our German

 Utility model (No. 20 201 1 004 126.3 - spine sole) already describes a vertebral structure of the insole, whereby it is possible to control important functional areas individually. (Prior Art) At the top, the spine is defined by a tough but inelastic material (U) with which the conical

elaborated vertebral body (V) are firmly connected. The insertion or removal of discs (S) defines the bending behavior of the sole. The lower material (L), in turn, is tough but elastic (e.g., rubber). The sole becomes bendable upwards, but downwards its flexibility becomes definable by the vertebrae (V) and intervertebral discs (S).

PROBLEM

 However, the fixation of the "intervertebral discs" against the lateral ones remains unsolved

Slipping. Likewise the way of the safe and environment-friendly union of the components together. Thus, adhesive bonds between rigid insole and elastic outer layer are difficult to ensure durable and efficient. The efficient assembly in the finished pointe shoe is unclear and it is not possible to vary the resistance behavior of the insole, which is mainly defined by the Shore hardness of the lower "rubber layer", individually. In order to permanently guarantee the individual control behavior of the insole for the end user, it must always be possible for each individual component to be easily removed or replaced. SOLUTION

 Often the insole of pointe shoes is also called the "backbone" of the pointe shoe. This idea has been consistently pursued by us in order to make what can be used in nature over millions of years of evolution technologically usable. Finally, we have optimized the structures we have developed so far that a revolutionary improvement in the tip shoe function and its medical concerns is achieved. Result of our work is an easy-to-install form-linked "intelligent spine functional system" as an insole, especially for pointe shoes! (Fig.1)

EMBODIMENT OF THE INVENTION

The "intelligent spine functional system" (Figure 2) consists of at least two, but in the best case of three basic functional components that are "married" together in a pure mold compound without bonding agents or adhesives and accordingly easy to assemble or change. The basic element "spine" (B), the "sticks" (S) as intervertebral discs and the "rubber layer" (R) as the muscle of the system.

1.) spine

 The "spine" (Figure 3) mainly characterizes a juxtaposition of vertebral bodies (V), which may be conical both straight and at a defined angle. The interstices (I) of the vertebral bodies allow the spine a free

Bendability upwards. The bendability downwards is limited only by the straight or conical shape of the vertebral bodies whose legs abut against each other at a definable maximum bending and allow no further bending (Figure 4 - a - A). The "spine" is defined above by a very resistant, flexible but inelastic material (Figure 4 - a-U), with which the vertebral bodies, depending on the production process, are firmly connected or directly potted. Most efficient seems to be the use of injection molding in which the spine with all the vertebral bodies and the upper hinge (Fig.4 - a-U) are made in one piece. Corresponding design and bulges of the spine (Fig.2 & Figure 3) now allow, among other things, the pure mold composite of all components together without having to use adhesives. The "spine" hardly tires compared to conventional insoles of lace shoes! It does not "soften", so to speak, and provides the dancer's foot with full agility over the entire life cycle of the outer shoe and lasting, stable support at the top! Often used by dancers

Terminology: "Softness" or "firmness" is no longer important in the "spine"! Because it is already flexible in all desired directions and then permanently "stuck" in the required end position on the tip (Figs.1 - a, b, c). 2.) Sticks

 The "Sticks" (Fig.5 - S) act like an intervertebral disc in the "spine"! A stick between two vertebrae causes the "spine" to bend upwards at this point but not further down (Fig. 4 - a). Now it is very easy to insert or remove any "sticks" (S) in the heel area (Fig.2 - S). At freely definable points, the "spine" now follows the individually curved anatomy of the sole of the foot and remains in other places, e.g. under the forefoot or behind the heel (Fig.1 - c)! For each gap, the "spine", depending on the defined conical shape of the vertebral bodies, reaches a flexibility e.g. around 18 degrees. If now a total of five "sticks" are removed between the vertebrae, the additional total bending achieved is 90 degrees. Elastic "sticks" in the forefoot area provide a noise and impact reducing effect for standing on top or jumping. Elastic "sticks" can now also tolerate the angular rotations of the vertebral bodies. Instead of completely removing a "stick" in the heel area, an elastic "stick" can also be used to create a variable and also shock-absorbing under the heel bend

To generate back pressure. The "sticks" in our version are now thinned in the middle area, so that the "rubber layer" (Fig.6 - R) reaches into these bays (Fig.5 - RS) and prevents lateral slippage of the "sticks". 3.) rubber layer

 The lower material, the "rubber layer" (Fig.6 - R) is resistant and opposite the top layer (Fig.4 - U) but elastic. It is fixed at defined points of the "spine". In our version we show a pure composite of the "rubber layer" with the "spine" (Fig.2). The integrated "rubber layer" engages here with corresponding ribs (Fig.2 - F) like a muscle in every single vertebral body, with corresponding

Recording bays are provided. Now the "rubber layer" with its elastic

Control the individual vertebrae synchronize with each other. If the "spine" is now bent upwards while walking or in the Demi Pointe, the train on the rubber layer results in a uniform bending of the entire sole (Fig.1 - b). The molded compound of the rubber layer with the "spine", without gluing or mechanical screw, nail or other fasteners, allow a dancer with a few simple steps "rubber layers" with alternative Shore hardness in their sole themselves contribute, which is especially unprecedented for professional dancers Relief represents. When stretched, the integrated "rubber layer", in contrast to flat glued or screwed rubber underlay, also absorbs even more dynamic force, which noticeably returns to the foot during the jump or when moving to the peak position (kangaroo effect). In addition, the integrated "rubber layer" also acts as a mechanical and safe Lock against lateral slippage of the "Sticks", which are provided with corresponding bays for the "rubber layer" (Figure 5 - RS). The "rubber layer" is introduced in the stretched state in the "spine" and allows a bias of the sole. As a result, the "spine" in the areas without "sticks" already slightly bent and nestles to the natural curvature of the sole. This is especially helpful when free stretching the foot!

Without sticks and rubber layer

The "spine" obtains even without "rubber layer" and "sticks" a limited

 Functionality by predefining the angles of the vertebral bodies and the possible bending behavior, but excluding the possibility that the customer can later adjust the sole to its foot shape and bending resistance (Figs.4 - c). In production, the material thickness of the "spine" is chosen so that the sole has a relative stiffness, i. that, when the forces are defined by the body weight, the insole is practically inflexible in both directions. If the material of the "spine" is now slotted or toothed with intervertebral disk regions, the material in these swirl regions in the opposite direction of the slits is now relatively flexible and is limited to the other direction only by the meeting of the vertebral bodies (FIGS. 4 c). By means of "sticks" (S), however, the individual bending behavior of the sole without a rubber layer can also be controlled here. The execution of the "intelligent spine soles

Functional system "with its three functional basic components (Fig.2) promises, however, a finer to be controlled and more effective bending behavior of the insole!

Mounting sole with click rail

The "intelligent spine functional system" also offers innovative solutions for easy installation with the complete pointe shoe. The outer pointe shoe is attached to the last with all the layers and cap assemblies on a thin and flexible mounting sole (Fig.7 - a). This inner mounting sole is z. B. with a click rail (Fig.7 - c) provided. The outsole is glued in the known method on the mounting base and finally presses all layers firmly between the mounting sole and outsole. The last is removed. A corresponding guide in the "spine" (Fig.2 - C) now allows to bring the fully assembled "spine system" in the finished tip shoe and push over the click rail. When the "spine" audibly snaps into the click fastener, it is firmly connected to the outer pointe shoe. The specific technical design of this system for locking can vary. Other applications

The "spine" as a functional intelligent system of insoles is conceivable for a number of applications in general, orthopedic or in the sports shoe sector. Whenever comfortable flexibility is needed in conjunction with clearly definable endpoints of flexibility, the modified system "spine" would be an obvious solution. Also the o.g. "Kangaroo Effect" is associated with the ply structure of a spine, e.g. also conceivable for sports and running shoes!

LEGEND FOR THE TERMS

B = spine (backbone shank)

 V = vertebral body

 I = intervertebral space

 C = guide for click rail (thick bar)

 S = sticks / inter-vertebral discs

 R = rubber layer (rubber strap)

 U = upper strap

 L = lower strap

 Dents for rubber layer in the middle of the sticks

 F = ribs of the rubber layer A = angle of the vertebral bodies (angle of the vertebral bodies)

Claims

PROTECTION CLAIMS

1. An insole device for shoes especially for pointe shoes of

 Ballets, which - by means of a juxtaposition of "vertebral bodies" whose

 Intermediate spaces can be provided with appropriate "sticks" - free

 Flexibility on the one hand and offers definable flexibility to the other side, is characterized in that the components "spine" (Figure 2 - B), "sticks" (S) and "rubber layer" (R) in the pure mold composite, without screws, nails or adhesives can be easily assembled into each other or separated from each other, and thus a previously unachieved degree of permanent influence on all required characteristics of the insole is possible in the prior art. For this purpose, the "spine" (B) is provided, inter alia, with bays in the middle of each of their "vertebral bodies" (V) whose lateral ends undercut the material of the "spine" (Fig.2 below). The "rubber layer" (R) receives corresponding ribs, which can be accurately absorbed by the bays of the "spine". The protruding rib structure (F) allows the "rubber layer" like a muscle in the bays and undercuts of each vertebral body (V) of the

 "Spine" to grab themselves to fix themselves there, and with elastic control to synchronize the vertebral bodies with each other very accurately.

2. Device (according to claim 1) is characterized in that the "sticks" (Figure 5 - S) guarantee the stable mold combination and are protected against slipping sideways by by means of an additional bulge in its center (RS) on the integrated "Rubber layer" (R) can engage directly. Only manual lateral pressure on individual "Sticks" raises the integrated into the "spine" "rubber layer" slightly and pushes the "stick" under the "rubber layer" or back out if necessary.

3. Elastic "sticks" (according to claim 2) are characterized in that they are e.g. in the forefoot area of the pointe shoe with different shore hardnesses

 "Spine" an elastically resilient behavior as well as shock absorbing

 Lend properties.

4. The device (claim 1) without rubber layer - is characterized in that it is also possible with limited functionality, the necessary

 Counter tension of the "spine" only by the selected material and the

Material thickness above the vortex structure to define (Figure 4 - c). This solitary "Spine" defines its bending behavior solely via the angles (Fig. 4 - A), the distance between the vertebral bodies (V) to each other or by means of optional "sticks" (S).

5. The device (according to claim 1) is further characterized in that it is possible by the additional insert of a thin and flexible "mounting sole with click rail" (Figure 7), the "spine" easily in one with just this "mounting sole" to bring in pre-produced top shoe and if necessary, eg to change the "rubber layer", also remove it again. The "spine" receives to a corresponding guide rail at the front end (Fig7, - c), which can be pushed over the "click rail" of the "mounting sole" and firmly locks in the forefoot, while the back of the "spine" without connection to the outer shoe remains. The assembly of the insole only in the forefoot area of the pointe shoe guarantees high mobility through an optimal length compensation behavior between the inner and outsole. With an optional tool, it will later be easily possible to squeeze the "click rail" snap-in noses, the "spine" from the outer pointe shoe

 to take out and reuse in a new outer shoe.