The invention relates to a shoe, in particular to a sports shoe, having a shoe upper and a sole part connected to the shoe upper, wherein the sole part comprises a sole body having a bottom region and a side wall region, wherein the bottom region and the wall region form a receiving chamber which is open at the top, wherein the receiving chamber is filled with a bulk material, wherein the bulk material consists at least partially, preferably completely, of a thermoplastic elastomer (TPE), wherein the filled receiving chamber is sealed by a closure body and wherein the closure body is a knitted fabric that forms a lattice structure. The invention further relates to a method for producing such a shoe.
A shoe of the generic type is known from US 2016/0007675 A1. Similar solutions are shown in US 2009/0313853 A1 and U.S. Pat. No. 5,617,650 A.
A shoe of a similar kind is known from WO 2017/097315 A1. Foamed plastic balls are arranged in a sole element which has a cavity and are held in the cavity by a closure element. The sole produced in this way is connected to the upper part of the shoe. In the present case, the closure element is formed by a film which allows the wearer's foot to feel loose plastic balls located in the cavity.
However, it has been found with this solution that sometimes the wearing comfort of the shoe is negatively affected with this type of closure element.
The invention is therefore based on the object of developing a shoe of the type described above in such a way that a further improvement in wearing comfort can be achieved. At the same time, an economical process for manufacturing the shoe is to be provided.
The solution of this object by the invention is characterized in that the lattice structure has a mesh width of at least 0.75 and at most 2.0 mm, wherein bodies of spherical or ellipsoidal shape are used as bulk material, wherein the dimensions of the bodies of the bulk material in the three spatial directions are between 3 mm and 6 mm, wherein the closure body is provided with a reinforcing layer in its edge region, wherein the reinforcing layer runs around the entire circumferential area of the closure body, and wherein a reinforcing plate is arranged in the bottom region of the sole body. The mesh width of the lattice structure of the closure body is thereby preferably largely constant over the extension of the closure body.
Thus, in contrast to the previously known solution, no foil or classical textile material is used to close the cavity in the sole body and to retain the particles of the bulk material located in it, but a grid structure is used, the mesh width of which does not fall below a minimum value (and also does not exceed a maximum value).
It has been found that a particularly comfortable wearing sensation can be achieved in this way with a generic design of the shoe with loosely arranged particles, in particular of foamed plastic balls.
The closure body is preferably designed as a flat fabric structure. A woven structure in the form of a Leno weave has proved particularly effective in this respect. In such a Leno fabric, a plurality of weft threads is provided which extend in a longitudinal direction; a plurality of warp threads extends perpendicularly thereto. The warp threads are wound around the weft threads to provide high strength to the fabric.
Preferably, the fabric structure is formed by a fiber-reinforced thread.
An air- and moisture-permeable membrane may be arranged above and/or below the closure body. In this context, it should be mentioned that here, as well as throughout the present description, the orientation “below” and “above” refers to a shoe when it stands with its sole on the ground.
The closure body may be directly or indirectly glued and/or sewn to the sole body.
A reinforcing plate is arranged according to the invention in the bottom area of the sole body. The reinforcing plate forms a cover layer that reinforces the sole structure and prevents sink marks.
The shoe upper may be glued and/or sewn to the sole part.
The shoe upper preferably has an upper portion that is stitched to a strobel sole at the bottom.
The above mentioned reinforcing layer can be formed by a glued-on film. It preferably runs around the entire circumferential area of the closure body as an edge seam with a width of between 0.5 cm and 2.5 cm.
The bodies of the bulk material can also be formed as hollow bodies. It is provided that the mesh width of the lattice structure is smaller than the dimensions of the bodies of the bulk material.
The bodies of the bulk material preferably consist of foamed thermoplastic elastomer. In particular, thermoplastic polyurethane (TPU), thermoplastic polyamide (TPA) and/or olefin-based thermoplastic elastomer (TPO) are considered here, with the said materials being expanded (foamed) in particular.
A further very preferred embodiment of the invention provides that a circumferential frame is arranged in the upper end region of the wall region of the sole body, which frame is connected, in particular glued, to the sole body, wherein the frame having a bearing surface for the closure body and in particular its edge region. With such a design, it can be achieved that the closure body can be stably connected to the other sole element and has a defined bearing surface in the edge region.
The proposed method for manufacturing such a shoe comprises the steps:
The production of the shoe in question is thus simplified and possible in an economical manner. All the above-mentioned embodiments can also be used in the above-mentioned process.
Due to the lattice structure of the closure body used, a stable manufacturing process can be achieved that reliably retains the particles of the bulk material in the cavity of the sole element.
When using the shoe, there is an improved wearing sensation, which is not achievable with the previously known solution.
Various possibilities are generally given for the production of the upper part of the shoe. In particular, it can be provided that the upper part of the shoe upper is produced in a classical manner, wherein the lower region, which extends below the sole of the foot of the wearer of the shoe, is, for example, a strobel sole (as explained above), which is sewn to the upper part of the shoe upper, for example. This can be done, in particular, in combination with a knitted upper portion of the shoe upper.
The sole part is preferably manufactured as an injection molded part or as a thermoformed part.
It can also be provided that at least one web-like structure is formed on the bottom area, which extends into the receiving space. This web-like structure forms wall areas within the receiving space which counteract the free displacement of the loosely filled bulk material and hold it in certain areas of the receiving space. This can have a positive effect on the walking experience when wearing the shoe.
The aforementioned web-like structure allows the sole to optimally support the foot in certain applications when used under load as intended. This can be relevant from the point of view that otherwise the (plastic) bodies located inside the receiving space of the sole part do not provide a great support function for the foot as a result of the fact that they are not connected to each other but are loosely arranged.
The plastic bodies preferably have a hardness between 75 and 90 Shore A, preferably between 80 and 85 Shore A. They preferably have a bulk density between 100 and 300 kg/m3.
The following should be mentioned with regard to the expanded thermoplastic polyurethane (E-TPU) that is preferably used for the plastic bodies that are introduced into the receiving space of the sole part: This material is known per se and is used in shoes. It is available, for example, under the name “PearlFoam” from Huntsman International LLC or under the name “Infinergy” from BASF SE. Regarding this material, explicit reference is made to WO 2005/066250 A1, where details on this material, i.e. expandable thermoplastic polyurethanes and their production, can be found.
With regard to the prior art of urethane-based thermoplastic elastomer, explicit reference is also made to WO 2010/010010 A1, in which an expandable, blowing agent-containing thermoplastic polymer blend containing thermoplastic polyurethane and styrene polymer is disclosed. The polymer blend may contain at least one further thermoplastic polymer. In particular, polyamide (PA), polymethyl methacrylate (PMMA), polycarbonate (PC), polyethylene (PE), polypropylene (PP), polyvinyl chloride (PVC), cellulose or polyoxymethylene (POM) can be used as a further thermoplastic polymer.
The sole part is preferably made of thermoplastic polyurethane (TPU), thermoplastic elastomer (TPE), polyamide (PA) and/or rubber material.
Having spoken of bulk material in connection with the bodies to be placed in the receiving space, this refers to individual particles which have no connection to one another. In particular, according to a preferred embodiment of the invention, the plastic bodies are placed in the receiving space of the sole part without connection to each other. Accordingly, the individual spheres or ellipsoids are not connected to one another by any means, but are placed loosely in the receiving space of the sole part.
The bulk material is preferably placed in the receiving space of the sole section in full packing and preferably under slight pressure.
The mentioned sole part can still be provided with an outer sole on the underside if required.
It has been shown that when a shoe, in particular a sports shoe, is designed in the manner specified above with regard to the compression behavior of the shoe and its recovery properties (after removal of the compressive force by the wearer's foot), very advantageous and comfortable wearing properties of the shoe can be achieved. This applies in particular to the aspect of strong temperature fluctuations.
If the proposed thermoplastic elastomers (in contrast to conventional polymers) are used as loose bulk material in the cavity of the sole, favorable conditions result due to the frictional properties between the individual particles, since they do not slide along each other in an undesirable manner but, despite being loosely arranged, provide a certain amount of strength when the wearer's foot deforms the bulk material. Thus, an optimal compromise is achieved between a certain massaging effect on the one hand and a sufficient hold of the foot during the use of the shoe on the other hand.
In the drawings embodiments of the invention are shown.
In
The sole part 3 has a sole body 4, which has a bottom region 5 and a wall region 6 with a circumferential edge, so that the bottom region and the wall region delimit a receiving chamber 7, which is designed and provided for receiving bulk material 8. The sole body 4 can be manufactured, for example, by an injection molding process or by a thermoforming process.
After the shoe upper 2 and the sole part 3 have been produced (which can be done simultaneously or in any order), the receiving chamber 7 is filled with bulk material 8, which is only indicated in
As can be seen from
It is essential that the closure body 9 is a knitted fabric which forms a lattice structure, the lattice structure having a mesh width w1, w2 (see
The shoe upper 2 is then placed on the sole part 3 prepared in this way and the sole part 3 is joined to the shoe upper 2. This can be done by sewing and/or gluing.
Accordingly, the lower area of the shoe upper 2 now rests—via the closure body 9—on the bulk material 8, so that a pleasant walking sensation is created when using the shoe.
In general, any material can be used as bulk material 8 (e.g. also sand), while spheres or ellipsoids made of foamed plastic material are preferred; details are given above.
First of all, a reinforcing plate 10 should be mentioned here, which is placed in the bottom region 5 of the sole body 4 in order to give the sole improved rigidity. The reinforcing plate 10 can also be one with spring-elastic properties to support the running movement.
In the upper section 11 of the shoe upper 2, this is made of a material (woven or knitted material) which is connected at the bottom to a strobel sole 12; in
A special design of the closure body 9 (lattice structure) is also particularly worthy of mention: This has a reinforcing layer 13 in a circumferential edge region, which is implemented by an applied film. The film can be glued on or bonded to the closure body 9 by a thermal process. A frame 16 is attached to the upper end of the wall region 6 of the sole body 4, which is designed as an oval annular structure and corresponds to the shape of the upper edge of the wall region 6. The frame 16 is connected, for example glued, to the upper end of the wall region 6. In this case, the frame 16 has a bearing surface 17 on which the closure body 9 rests with its edge. Here, the closure body 9 is glued to the frame 16 or fastened in some other way.
In the embodiment according to
By selecting the material-specific and geometric parameters (dimensions of the particles of the bulk material, size of the mesh, dimensions of the individual areas of the shoe upper and the sole part, choice of material, etc.), it is possible to influence the spring and damping behavior of the shoe and, in particular, of the sole.
While, as shown above, a loose insertion of individual bodies in the form of bulk material is envisaged, it is also possible in principle for said bodies made of said materials also to be coupled or joined together at least in part. In this respect, it is possible to create a structure in which a number of bodies are joined together, for example by microwave welding.
A similar composite of individual bodies can also be produced by embedding the individual bodies in a synthetic foam, in particular polyurethane foam, to create a structure that can be used to build the shoe sole.
This application is a U.S. National Stage application, filed pursuant to 35 U.S.C. § 371, of international application no. PCT/EP2018/085712, filed on Dec. 18, 2018, the contents of which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/085712 | 12/18/2018 | WO | 00 |