EP2200469A2 - Shoe with sprung sole - Google Patents

Abstract

A shoe with a sprung sole is presented. The shoe comprises a upper shoe 10, a flexible, air-permeable insole 11 and a sole structure comprising a mid-sole 22, a buffer sole 21 end a hard flexible abrasion-resistant outsole 20. The movement of the sole under loading has the effect of activating an interior ventilation, which acts on the user's feet. On the other hand, the shoe enforces 'walking with the correct posture'.

Description

Shoe with spring-loaded sole

The present invention relates to a shoe with sprung sole according to the preamble of patent claim 1.

There are many shoes that support the posture, ligaments, musculoskeletal system, and requirements for a healthy spine, in short, a back pain free body of modern man. Among others, patents EP0999764B1 and EP1124462B1 describe such shoes of special construction.

The construction according to the teachings of the aforementioned patents allows the rolling go to arise by "turning" or "rolling" the foot over an "edge" in the sole.Therefore, special training courses are offered to accompany the sale of such shoes called "MBT" to explain the users the right application of this kind of footwear. Although with these types of construction, the desired objective of the rolling movement is already quite well achieved, there is still the disadvantage that the existing in the sole edge with improper use of the shoes and false effects on posture, musculoskeletal system and Spine triggers. If, for example, one does not pay close attention to the rolling movement, unpleasant and unfavorable blows to the musculoskeletal system occur.

Another disadvantage of these constructions is for closed shoes. It is easy to see that a sole and a shoe, which requires the wearer's active use of his muscles, as well as all the fine muscles of the foot, also generates heat. Closed shoes based on this design principle have the disadvantage that heat is not dissipated. The result is heavy perspiration and hot feet of the wearer. This occurs when the sole construction is combined with closed shoes. Only the offered open shoes and sandals avoid this disadvantage.

Among other things, the principle of this construction is based on the fact that the hardness of the impact is absorbed by a so-called "heel button" made of soft-elastic material, which occurs when the foot occurs and the rolling movement from the rear edge of the heel in hard transition to the fulcrum of this one above described pivot axis shifted in the middle of the shoe.

Every wearer can avoid the hard impact with every shoe, if he pays attention to it. The aim of a comfortable shoe, however, should be to be able to benefit from the advantages of the shoe and sole construction even without any special training, so that one unconsciously moves or even is forced to walk properly. This has also been achieved to a certain extent with the construction based on the aforementioned patents, with this so-called "heel probe." Unfortunately, this has also resulted in a weak point in the design.

The present invention now has the object to improve a shoe with a sole of the type mentioned in such a way that a rolling walking is possible without the hard transition through an existing pivot axis. At the same time, an internal ventilation system is to be installed for closed shoes, which dissipates heat during walking with this kind of therapy shoes on the feet.

This object is achieved by a shoe with a sprung sole with the features of claim 1. Further Features of the invention will become apparent from the dependent claims and the advantages thereof are explained in the following description.

In the drawing shows:

Figure 1 section through a shoe with cavity

Figure 2 section through a shoe with bale sole

3 shows a cross section through a shoe with a cavity

4 shows a cross section through a shoe with openings

5 shows a section through a shoe with openings

6 shows a cross section through a shoe with openings and bale sole

7 shows a section through a shoe with a cavity and openings

Fig 8 section through shoe construction

Fig 9 Exploded view of shoe construction

Fig 10 Detail shoe construction with openings

FIG. 11 Semi-finished product representation of shoe construction

Fig 12 section through shoe construction with resilient means

The figures represent preferred exemplary embodiment proposals, which will be explained in the following description. A sole consisting of outsole 20, midsole 22 buffer sole 21 and soft elastic insole 11 is fixedly connected to an upper shoe 10. The upper shoe 10 is made of soft material such as leather, plastic, textile or their combination. It can be designed as a closed shoe or only as a sandal upper part. The insole 11 is made of soft elastic material and may also be connected together as a unit or part of the same with the buffer sole 21.

The outsole 20 is made of elastically stable and above all abrasion resistant material. It gives the whole shoe the necessary support, therefore it must also have enough inherent strength.

Between outsole 20 and insole 11 at least one midsole 22 is installed. The midsole 22 may be connected to the outsole 20 and constructed like a bridge. Between the midsole 22 constructed as a bridge and the outsole 20, a cavity 30 is created (FIG. 1). This cavity can be filled with gas, liquid or with a bale 23 (Figure 2). Depending on the structure of the sole, the midsole 22 made of different, hard elastic materials such as metal or plastic be. So that the latter has sufficient intrinsic strength, fiber-reinforced plastic, for example, can be used. The shape of the midsole 22 is determined by the desired manner, whether it should be used for walking, walking on sand or for orthopedic corrections shoe.

The bridge-like shape of the midsole 22 allows for all possible shapes. It may be spherical as shown in Figure 4, but also designed as a large arc or in a shape adapted to the corresponding footprint. It can be connected at any point with the outsole 20. Decisive for the effect of the resilient midsole 22 are inherent elasticity and strength of the material of which it consists, as well as size and shape of the resulting between outsole 20 and midsole 22 cavities 30. In the drawings, only one cavity 30 is shown. However, it is self-evident that a plurality of cavities 30 can also be created between the midsole 22 and the outsole 20, so that such cavities 30 can be arranged, for example, under the heel of the foot, under the heel or in the region of the metatarsus. The spaces between the midsole 22 and the insole 11 fill a so-called buffer sole 21. The buffer sole 21 is made of a soft material and conforms to the foot, with the insole 11 merely serving as a surface protection and closure of the buffer sole 21 or being part thereof.

In the form described so far, the cavities 30 are completed and therefore, depending on what they are filled with, act as a cushion. It is disadvantageous that only the elasticity of the medium located in this cavity 30 combined with the elasticity of the bridge-forming midsole 22 can be obtained.

The insole 11 can basically be made permeable to air. This is made possible, for example, by arranging over the entire surface of the insole 11 small through openings 31, or the material of the insole 11 is permeable to air similar to filters. If the air permeability is achieved by means of openings 31, these can be arranged more densely or less densely depending on the area. Likewise, the insole 11 may be air permeable at certain points and less permeable to air at other locations. It is conceivable, for example, that in the Area of the toes strives for a more intense ventilation, as in the area of the metatarsus.

Now, as shown in Figs. 4 and 5, this cavity 30 having recesses 32 passing through the midsole 22, buffer sole 21 and insole 11 to the foot may e.g. the air which is located in the cavity 30 escape through the midsole 22, the buffer sole 21 and the insole 11 in the direction of the foot. If a bale 23 is installed in the cavity 30, this bale 23 can also have continuous recesses, as shown in FIG.

With the help of other resilient means made of metal, foam or rubber (Figure 12) which are arranged in the region of the recesses 32 or fill their existing space partially or completely, the elasticity of the entire sole structure 21,22,23,11 in addition and over the surface the sole is adjusted differently.

The air permeability of the insole 11 is achieved by the arrangement of the openings 31 or by the choice of different permeable materials. The substructure of the sole structure is then adjusted accordingly. The insole 11 can also be made of rigid-elastic material, so that point loads such as occur with metal springs can be distributed by the insole 11 in the way that the feet of the user is not exposed to extreme point loads.

The shape of the inventive shoe can be designed differently depending on the nature of the sole structure. Thus, as shown in Fig. 7 and Fig. 12, it may have the sole of any shape and e.g. also have a round rolling shape on the heel. The domed shape of the midsole 22 may form a cavity 30 towards the outsole 20 (FIG. 1), or a cavity 30 against the insole 11 (FIG. 8).

Instead of an insole 11 and a cavity 30 between midsole and insole 11 (Figure 8), the cavity 30 may be filled by material as mentioned above and form a so-called bale sole 23 (Figure 8). In this embodiment, midsole 22, bale 23 and insole 11 may be made of one piece. This part may consist of materials of various types, but also of the same material.

Claims

A shoe with a sprung sole consisting of an upper shoe (10), an elastic and air-permeable insole (11), wherein between the insole (11) and a hard-elastic and abrasion-resistant outsole (20) is arranged a resilient sole structure, characterized in that at least one midsole (22) and a buffer sole (21) form the sole structure (21, 22), the shape of the shoe being designed independently of the type of sole construction.

2. Shoe with sprung sole according to claim 1, characterized in that a midsole (22) with the

Outsole (20) is not completely covered, with the appropriately prepared midsole

(22) with the outsole (20) at predetermined locations at least one cavity (30).

3. Shoe with spring-loaded sole according to claim 2, characterized in that in the cavities

(30) Gas is located.

4. Shoe with sprung sole according to claim 2, characterized in that in the cavities

(30) Liquid is.

5. Shoe with sprung sole according to claim 2, characterized in that the cavities (30) are filled by material and a bale sole

(23) form.

6. Shoe with sprung sole according to claim 1, characterized in that the insole (11) has openings (32).

7. Shoe with sprung sole according to claim 1, characterized in that the insole (11) consists of air-permeable material.

Shoe with sprung sole according to claim 1 and 5, characterized in that the sole structure

(21,22,23) has vertical recesses (32).

A shoe with a sprung sole according to claim 8, characterized in that the vertical recesses (32) are aligned with the openings (31) of the insole (11) in such a way that they are open towards the upper shoe.

10. Shoe with sprung sole according to claim 8, characterized in that in the vertical recesses (32) resilient means (25) are arranged.

A shoe with a sprung sole according to claim 10, characterized in that the resilient means (25) at least partially fill the recesses (32).

12. Shoe with sprung sole according to claim 10, characterized in that the resilient means (25) are made of plastic.

Shoe with sprung sole according to claim 10, characterized in that the resilient means (25) are made of metal.

14 shoe with sprung sole according to claim 10, characterized in that the insole (11) is soft-elastic.

15 shoe with sprung sole according to claim 1, characterized in that the insole (11) consists of air-permeable material.

16 shoe with sprung sole according to claim 1, characterized in that the insole (11) consists of elastic material.