AT8105U1 - SOLE STRUCTURE WITH A COMPLEX WATER-BREATHABLE AND GAS-PERMANENT MATERIAL - Google Patents

Abstract

A sole structure having a complex water-impermeable and gas-permeable material, comprising a sole having a large substrate and an insole layered on an inner surface of the large substrate, wherein the large substrate is formed with at least one through-hole. On the inner surface of the large substrate, a flat punched piece is formed, which is formed with at least one through hole. The flat blank corresponding to the through-hole of the large substrate is combined with a water-impermeable and gas-permeable layer at least at the through-hole and disposed on the through hole of the large substrate so as to be covered, whereby the water-impermeable and gas-permeable layer effects water-proofing and gas-permeability.

Description

2 AT008105U1

The invention relates to the production of shoe soles and in particular to a further developed water-impermeable and gas-permeable sole structure.

A conventional water-impermeable and gas-permeable layer such as a Gore-5 Tex layer (the so-called century fabric) is composed of two dissimilar polymers. The one polymer is the nearly thermoplastic polyurethane (TPU), which gives a high rigidity. The other is ePTFE, which provides water impermeability and gas permeability. In this material, nine trillion micropores are distributed over an area of one square inch. The size of such a pore is a ten two-thousandths of the size of a water molecule in the liquid state. However, the size of such a pore is seven hundred times the size of a water vapor molecule. Thus, water molecules can not penetrate the pores, whereas water vapor molecules can be expelled through the pores. A water-impermeable, gas-permeable layer such as Gore-Tex may be applied to the inside of nylon and other fabrics to make clothes, shoes, gloves, etc. so as to repel the property of repelling wind and water but allowing air or gas through achieve. A wearer of such clothes or shoes can keep dry and warm and feel comfortable. Fig. 1 shows that the water-impermeable, gas-permeable layer, such as Gore-Tex, is adhered to the inside of a sole to provide water impermeability and vapor leakage, thereby keeping the foot of the wearer's foot dry. The sole 10 comprises a large substrate 11, a middle substrate 12 adjoining the large substrate, and an inner sole 13 layered on the middle substrate 12. The large substrate 11 is generally made of thermoplastic rubber (TPR), which is cheaper , manufactured.

Alternatively, the large substrate 11 may be made of TPU or PVC. To some extent, Gore-Tex has properties similar to those of TPU, while it is difficult to combine with TPR. Therefore, in the manufacture between the large substrate 11 and the middle substrate 12, the more expensive water-impermeable, gas-permeable layer 40 is adhered to prevent the penetration of water into the middle substrate 11 and the insole 13. As known to those skilled in the art, although steam is separated from the innerliner of the shoe, water still often remains between the large substrate 11 and the central substrate 12 at locations shown by arrows in FIG a user as unpleasant. In addition, when using the shoe, the sole has to withstand a great bending force and strong impact, so it is not readily possible to combine the materials by means of adhesive.

With the above structure, the water-impermeable, gas-permeable layer 40 is adhered to the sole 10 to keep water away from the foot of the user but allow the escape of vapor. However, such a substrate does not eliminate the problem that water remains between the large substrate 11 and the middle substrate 12 (or the insole 13). The melting point of the large substrate 11 is about 180 ° C. The melting point of the water-impermeable, gas-permeable layer 40 is about 120 ° C. In addition, these two materials are incompatible. As a result, the water-impermeable, gas-permeable layer 40 often melts or is unexpectedly damaged during the casting process when filling the higher-temperature material into the sole. The water-impermeable, gas-permeable layer 40 can therefore not readily be connected to the large substrate 11. 50

The invention is therefore based on the object to provide a sole structure with a complex water-impermeable and gas-permeable material, which does not have the disadvantages mentioned above and prevents water between the large substrate of the sole and the middle substrate of the sole (or the insole) remains. 55 3 AT008 105U1

This object is achieved by a sole structure according to claim 1. Further developments of the invention are specified in the dependent claims.

A method of making a sole structure with a complex impermeable and gas permeable material comprises the steps of: (a) preparing a flat blank with a through hole and combining a water impermeable and gas permeable layer with the flat blank, the layer being at least one side the through hole sealed; io (b): arranging the flat blank at a predetermined position in a sole shape, wherein an insulating portion covering a portion of the flat blank completely covers the through hole of the blank. (c): pouring plastic material into the mold, bonding the plastic material to the periphery of the flat blank not insulated by the insulating portion so as to form a one-piece, large substrate.

In the method of manufacturing a sole structure, the through hole of the flat blank may have a matrix-like pattern, and then the layer covers at least the through hole of the flat blank provided with the matrix-like pattern. 20

In the method of making a sole structure, in step (a), a porous sheet material is coated on the flat blank, then the porous sheet material is placed between the flat blank and the sheet and / or the porous sheet material with the top and bottom of the sheet is connected. 25

In the method of manufacturing a sole structure, the insulating portion can exactly cover the through hole of the flat blank.

In the method of manufacturing a sole structure, a plurality of mounting holes are formed along the circumference of the flat blank and the sheet material combined with the layer, the plastic material filling the mounting holes as it is filled into the mold to form the flat blank, layer and sheet material firmly connect.

Other features and advantages of the invention will become apparent upon reading the following description of preferred embodiments, which refers to the drawings; show it:

Figure 1 is an already mentioned cross-sectional view of the sole of a conventional gas-permeable shoe. 40 45 50

Fig. 2 is a perspective exploded view of the sole of the gas permeable shoe of the present invention;

Fig. 3 is a cross-sectional view of the sole of Fig. 2;

Fig. 4 is a sectional view of the composite sole of Fig. 3;

Fig. 5 is a bottom view of the sole of Fig. 4;

Fig. 6 is a perspective exploded view of the flat blank, sheet material and layer of the present invention, showing its connection relationship;

Fig. 6A is a sectional view showing the assembled assembly of the blank, sheet material and layer of Fig. 6 placed in a mold for casting the large substrate of the sole, wherein the plastic material has not yet been filled into the mold is;

Fig. 6B is a view corresponding to Fig. 6A with the plastic material filled into the mold;

Fig. 7 is a perspective exploded view of the flat blank, sheet material and layer showing a different connection relationship; 55 5 5 4 AT 008 105 U1

Fig. 7A is a perspective, exploded view showing that both the top and bottom of the layer are bonded to film materials; Fig. 8 is a sectional view showing the assembled structure of Fig. 7 set in a mold;

Fig. 8A is an enlarged view of the area A circled in Fig. 8;

Fig. 9 is a sectional view corresponding to Fig. 8, wherein plastic has been filled in the mold; and

9A is an enlarged view of the area A circled in FIG. 9. As shown in the drawing and initially in FIGS. 2 and 3, the sole structure 10 comprising a complex water impermeable and gas permeable material comprises a large substrate 11. The large one Substrate 11 may optionally be made of TPR, PVC, TPU or the like. On the large substrate 11, a middle substrate 12 and / or an insole 13 are layered. A predetermined inner portion of the large substrate 11 is formed with 15 through holes 14, 15 which may have any profile. The through holes 14, 15 are disposed in the front half, the rear half, or another portion of the large substrate 11.

On the inner surface 111 of the large substrate 11, a punched piece 16 combined with the water-impermeable and gas-permeable layer 40 is laid to cover the respective through holes 14, 15. The flat blank 16 is made of the same material as the water impermeable and gas permeable layer 40 or of a material which is compatible therewith. The flat punch 16 is formed with a matrix-like through hole 17 corresponding to the through hole 14 or 15 of the large substrate. In this embodiment, the matrix-like through-hole 17 has a matrix of several oblique ribs arranged as a shield. Such a matrix prevents foreign matter from passing through the through hole 17 directly into the shoe. The layer 40 has been fixedly connected to the flat blank 16 by means of high frequency wave or ultrasonic wave pressing. The layer 40 at least covers the through-hole 17 of the flat stamping 16. Generally, the area of the flat stamping 16 is greater than the area of the layer 40. In a preferred embodiment, a sheet material 22, such as a mesh or reinforcing sheet, is one of rigid material (such as TPU film) is bonded to at least one surface of the layer 40. The sheet material 22 is attached to the layer 40. In another embodiment, the positional relationship between the layer 40 and the sheet material 22 and its number are interchangeable and variable. In other words, the sheet material 22 may be disposed between the large substrate 11 and the layer 40 (not shown) or between the layer 40 and the middle substrate 12. Alternatively, the sheet material 22 may be placed on both the top and bottom of the layer 40. 40

4 and 5 show the further developed sole structure, to which the flat punched piece 16 combined with the layer 40 is applied. The water is rejected on the outer surface 112 of the large substrate 11 and prevented from entering the through hole and remaining between the inside of the large substrate 11 and the middle substrate 12. However, vapor generated from the foot may be expelled from the large substrate 11 through the water-impermeable and gas-permeable layer 40 at the through-hole 17 of the flat blank 16.

In Fig. 6, the properties of the material of the large substrate 11 are different from those of the flat punch 16. Therefore, they can be incompatible with each other and can not be easily connected. Accordingly, they are manufactured in a three-step manner.

In step (a), a sheet material 22 is placed between the flat blank 16 and the layer 40 55 or on the inner surface of the layer 40. The film material 22 may be a stiffer film body such as a porous, densely perforated TPU film or a mesh fabric film. The stiffness of the TPU film reinforces the flat blank 16 or layer 40 so as to resist intrusion of rocks or other contaminants under the sole and to prevent damage. 5

In step (b), the flat blank 16 connected to the layer 40 and the sheet material 22 is placed at a predetermined location in a sole mold 20. In order to cover exactly the peripheral area of the through hole 17 of the blank 16, an insulating portion or an insulating layer 21 is used. 10

In step (c), a (softened) plastic material 30 is filled in the mold 20 to cast the large substrate 11 in one piece. The plastic material 30 is firmly connected to the circumference of the flat punched piece 16. In the casting process, the plastic material 30 is separated by the mold 20 from the portion corresponding to the through hole 17. As a result, the plastic material 30 does not contact or damage that portion of the layer 40.

In order to solve the prior art problem that water may remain in the large substrate 11 or between the large substrate 11 and the middle substrate 12, the present invention has the following structural characteristics: 1. The large substrate 11 is on predetermined locations with through holes 14, 15 are formed. On the inner surface 111 of the large substrate 11, a punched piece 16 combined with a layer 40 is arranged corresponding to the position of the through hole 14. 25 2. The flat punched piece 16 is ausgebiidet with a matrix-like through hole 17 which corresponds to the through hole 14. The layer 40 covers at least the matrix-like through hole 17, and therefore, vapor developed by the large substrate 11 from the root can be discharged through the through hole 17 of the layer 40. However, the water on the outside of the sole is rejected by the layer 40 and prevented from entering the shoe through the sole. 3. The area of the flat blank 16 should be larger than that of the layer 40. In step (b), the insulating portion or layer 21 presses on the flat blank 16 to cover the layer 40. Therefore, the filled high-temperature plastic material 30 flows so as to connect to the peripheral portion of the flat blank 16, and the plastic material 30 does not contact and damage that portion of the layer 40 corresponding to the through-hole 17.

Figs. 7, 7A, 8 and 8A show a partially modified embodiment of the present invention. In this embodiment, a plurality of fastening holes 18, 23 are formed along the circumference of the flat punched piece 16 or 40 of the sheet material 22. When filling the plastic material 30 in the mold 20, this can flow unhindered into the mounting holes 18, 23. Accordingly, as shown in Figs. 9 and 9A, an insert wedge structure may be formed between the flat blank 16 or the sheet material 22 and the plastic material 30. The circumference of the film material 22 can also be formed like the flat punched piece 16 with a matrix of fastening holes 23. The mounting holes 23 are aligned with the mounting holes 18 of the flat punched piece 16. When filling the plastic material 30, this can also connect well with the film material 22. Accordingly, the large substrate 11, the flat blank 16, the layer 40, and the sheet material 22 can reliably adhere to each other. FIG. 9A shows that after penetration of the plastic material 30 into the mounting holes 18, 23, a portion 301 of the plastic material flows into the space between the bottom of the sheet material 22 and the mold to form the flat blank 16, layer 40, by means of the wedges and encapsulate or unite the sheet material 22 into a one-piece body. When the layer 40 is combined, it partially melts due to the high temperature. After melting, the formed pores fill with the plastic material 301. This increases the binding force of the one-piece body and prevents

Claims (20)

6 AT008105U1 parts of it will break off when bent. It should be noted that the flat blank 16 may be previously formed with a rough surface to increase the bonding force between the flat blank 16 and the plastic material 30. For example, an interface activator or the like may be applied to the surface of the flat blank 516 to clean and roughen it. Alternatively, the surface of the flat blank 16 may be directly mechanically roughened to achieve a better bonding effect. Although the invention has been described with reference to the preferred embodiments thereof, it will be understood that many other possible modifications may be made without departing from the spirit and scope of the invention as set forth in the appended claims. Claims: 1. A sole structure comprising a complex water-impermeable and gas-permeable material, comprising a sole (10) having a large substrate (11) and an insole (13), 20 layered on an inner surface (111) of the large substrate (11) in that the large substrate (11) is formed with at least one through-hole (14, 15); and on the inner surface (111) of the large substrate (11) is laid a flat punched piece (16) formed with at least one through hole (17) corresponding to the through hole 25 (14, 15) of the large substrate (11), wherein said flat blank (16) is combined with at least one of said through-hole (17) with a water-impermeable and gas-permeable layer (40), and said planar blank (16) is disposed on said through-hole (14, 15) of said large substrate (11) is that it is covered, whereby the water-impermeable and gas-permeable layer (40) causes water impermeability and gas permeability. 2. sole structure according to claim 1, characterized in that the through hole (17) of the flat punched piece (16) has a matrix-like pattern of a plurality of oblique ribs as a shield. 35 A sole structure according to claim 1 or 2, characterized in that a sheet material (22) such as a mesh fabric sheet or a high rigidity porous sheet is bonded to at least one outer surface of the water-impermeable and gas-permeable sheet (40). 40 4. sole structure according to claim 1 or 2, characterized in that a sheet material (22), such as a mesh fabric film or a porous film of high rigidity between the impermeable and gas-permeable layer (40) and the flat punched piece (16) is placed. 45 5. sole structure according to claim 1 or 2, characterized in that the water-impermeable and gas-permeable layer (40) is made of TPU material. 6. sole structure according to claim 3, characterized in that the water-impermeable so and gas-permeable layer (40) is made of TPU material. 7. sole structure according to claim 4, characterized in that the water-impermeable and gas-permeable layer (40) is made of TPU material. 8. sole structure according to claim 3, characterized in that the porous film (22) 7 AT008105U1 high rigidity made of TPU material is made. 9. sole structure according to claim 4, characterized in that the porous film (22) of high rigidity is made of TPU material. 5 10. sole structure according to claim 1 or 2, characterized in that two outer surfaces of the flat punched piece (16) are each connected to a mesh fabric film or porous film (22) of high rigidity. 11. Sole structure according to claim 1 or 2, characterized in that the water-impermeable and gas-permeable layer (40) has been combined by means of high-frequency wave or ultra-sound wave compression with the flat punched piece (16). 12. sole structure according to claim 3, characterized in that the water-impermeable 15 and gas-permeable layer (40) has been united by means of high-frequency wave or Ultraschallwellenver- pressing with the flat punched piece (16). 13. Sole structure according to claim 4, characterized in that the water-impermeable and gas-permeable layer (40) has been united by means of high frequency wave or Ultraschallwellenver- squeezing with the flat punched piece (16). 14 sole structure according to claim 5, characterized in that the impermeable and gas-permeable layer (40) has been united by means of high-frequency wave or Ultraschallwellenver-pressing with the flat punched piece (16). 25 15. sole structure according to claim 10, characterized in that the impermeable and gas-permeable layer (40) has been combined by means of high-frequency wave or ultrasonic wave compression with the flat punched piece (16). 16. sole structure according to claim 1 or 2, characterized in that the passage hole (14, 15) of the large substrate (11) on at least a part of the bottom surface of the sole (10) is arranged. 17. Sole structure according to claim 1 or 2, characterized in that in addition a central substrate (12) between the large substrate (11) and the insole (13) is arranged. 18. sole structure according to claim 3, characterized in that in addition a central substrate (12) between the large substrate (11) and the insole (13) is arranged. 40 19. sole structure according to claim 4, characterized in that in addition a central substrate (12) between the large substrate (11) and the insole (13) is arranged. 20. sole structure according to claim 5, characterized in that in addition a central substrate 45 (12) between the large substrate (11) and the insole (13) is arranged. 21. sole structure according to claim 10, characterized in that in addition a central substrate (12) between the large substrate (11) and the insole (13) is arranged. 22, sole structure according to claim 1 or 2, characterized in that the peripheral portions of the flat punched piece (16) and the film material (22) with corresponding Be-festigungslöchem (18, 23) are formed. 55 Including 8 sheets of drawings