EP0504788A2 - Flexible, solelike stabilising element for shoe - Google Patents

Abstract

The invention relates to a flexible solelike stabilising element (10) for the manufacture of shoes. It consists essentially of a resilient sheet (11) which has great rigidity transversely to the longitudinal axis (1) of the shoe and great flexibility along the longitudinal axis (1) of the shoe. Size and shape of the sheet (11) are to be standardised to the minimum of a group of consecutive shoe sizes and shapes. The sheet (11) is surrounded by a layer made of sole material (15), the contour (16) of the sole material (15) being standardised to the maximum of the group of consecutive shoe sizes and shapes. The final shape of the stabilising element arises by punching out along the contour line (17) which extends only in the sole material (15) and not in the sheet material (11). <IMAGE>

Description

The invention relates to flexible, sole-like stabilizing elements for the production of shoes according to the preamble of claim 1.

From FR-B-24 57 081 a ski boot for cross-country skiing is known, in whose outsole made of plastic a special stiffening element is cast. This consists of lamellae which extend transversely to the longitudinal axis of the shoe and which are connected to one another by flexible connecting links. Thanks to this stiffening element, the ski boot has a high degree of rigidity transversely to the longitudinal axis of the shoe, good torsional ability around the longitudinal axis of the shoe and high flexibility in the longitudinal axis of the shoe. The user of such a ski boot thus finds a good stand in connection with a high walking and rolling comfort.

The stiffening lamellae and their connecting links can, for example, be stamped from a steel sheet.

A comparable stiffening element made of plastic for pouring into the outsole is known from FR-B-25 56 659.

From US-A-2 124 819 or also from EP-A-0 373 336, insoles for shoe soles are known which consist of a spring-hard steel sheet which is profiled in a corrugated sheet-like manner substantially transversely to the longitudinal axis of the shoe. Thanks to this profiling, these inserts also have a high degree of rigidity across the longitudinal axis of the shoe, a high degree of flexibility in the longitudinal axis of the shoe and, depending on the shape, a predeterminable good torsional ability around the longitudinal axis of the shoe.

Since a shoe upper cannot be attached to a corrugated sheet metal profile, in particular, these reinforcement sheets are either inserted between the outsole and the insole (US Pat. No. 2,124,819) or molded directly into the outsole, which is then connected to a shoe bottom produced using conventional technology.

The stiffening sheets are cut or punched out of large sheet metal sheets in the sizes corresponding to the shoes in a manner known per se. Since the steel sheet must be spring-hard, laser beams or high-pressure water jets are required for cutting, and high-performance punching tools are required for punching, which must be made for every shoe size, for every shoe shape and for left and right shoes. The costs for cutting such stiffening sheets are extremely high due to the expensive machine hourly costs and the long processing times for laser or water jet cutting, while the tool costs are low. When punching, however, the tool costs are extremely high, so that extreme costs also arise here, which make the use of the stabilizing plates particularly unprofitable in the fashion sector.

This is where the invention comes in, which is based on the object of specifying a flexible sole-like stabilizing element of the type mentioned at the outset, which can be produced inexpensively and is suitable for conventional shoe manufacture. Here, for example, the use of the stiffening plate in shoe manufacture as an insole, as a simple insert in shoe bottoms directly, as a built-in element, which, for. B. is incorporated into shell-like running or intermediate floors, or also possible with inserts and footbeds, in which the stiffening plate is received.

This object is achieved by a generic stabilizing element with the features according to the characterizing part of claim 1.

Thanks to the fact that a standardized outline of the sheet is used, there is no need for any shoe size, e.g. B. both in English as well as in French, centimeter or in Mondopoint sizes - to name just a few, for each side, i.e. left and right separately, for each shoe outline shape, e.g. B. round, angular, pointed, etc., to make their own, each very expensive high-performance punching tool. Instead of the otherwise almost infinite number of tools, which would drastically limit the use to outlines with very high quantities and still very high tool costs, only a few tools are required, which are also optimally utilized.

From this it follows that, after a certain number of standardized outlines have been worked out, any shoe outline, any shoe size can be produced with these standard sheets.

The prerequisite for this is that the deposits mentioned at the outset, for. B. according to FR-B-24 57 081, FR-B-25 56 659 or EP-A-0 373 336 attributed properties are present even with standardized outlines or do not significantly restrict them. On the basis of test series, it has clearly emerged that this is the case if, depending on the intended use, the main stress points of the foot are supported by the actual sheet metal and the "design" of the shoe is also taken into account. When using a single stabilizing element (approximately in the form of a sole) as an insole, insert, in a built-in element or as an insert / footbed sufficient if the standardized outline z. B. 70-90% of the sole outline.

When using several stabilizing elements in one sole, e.g. B. as a forefoot part and a heel part, which are optionally connected to each other with a web, or z. B. only as a forefoot part, the standardization according to the invention can be used with all the advantages equally. The ratio "actual stabilizing element to sole outline" is reduced analogously. Basically, for every standardization according to the invention, the outline of the sheet metal element is minimal, corresponding to the smallest size of a group of several shoe sizes, widths and shapes.

It should be pointed out here that "sheet metal" means not only metal sheets, in particular spring steel or spring bronze, but also spring elements made of non-metals, e.g. B. made of fiber-reinforced plastics.

A further standardization with corresponding cost advantages is achieved when using the stabilizing element as an insole according to the characterizing part of claim 2.

Thanks to the fact that both a standardized outline of the finished stabilizing element is used as an insole and a standardized outline of the sheet, there is no need to create a special tool set for each shoe size and shape; instead, the shape of the standardized insole desired for shoe manufacture is punched out with simple punching knives, as are common in the shoe industry, since the gap between the edge of the stabilizing element and the final shape is only filled with material that corresponds to the requirements of shoe production and e.g. . B. is punchable.

The same applies if the finished stabilizing element as an insole z. B. is used in the design "California". It is only necessary to take into account that the material can be sewn through.

Another purpose of the standardized stabilizing element with an additional possibility of standardization, the achievement of cost advantages and damping properties is achieved according to the characterizing part of claim 3.

Thanks to the fact that a standardized outline of the sheet is used, there is no need to purchase sheet metal processing tools for each shoe size and shape. At the same time, such a shoe provides the foot with a soft, elastic, in spite of all stability and torsional ability, and with the preferred use of a cushioned-elastic plastic foam also a cushioned appearance. Due to the use of soft-elastic sole material, preferably plastic foam, this type of stabilizing element is not an insole for the production of shoes using the adhesive sticking method; rather, it is a built-in sole part, which is preferably glued to the shoe bottom parts or shell soles.

The sole material is preferably a PU foam material or thermoplastic material. These can be optimally processed and adhere to the clean metal sheet. Depending on the requirements, the cleaned sheet may be pretreated with an adhesion promoter.

To the sheet for attaching the material, e.g. B. in a plastic injection mold, as well as a vulcanizing mold or the like, it is advisable to provide at least two fixing points or openings. Improve these and other breakthroughs also the adhesion between sheet metal and sole material through positive locking. In addition, these fixation points are the adjustment points for centering the punching knife and other tools in the later shoe production.

Depending on the later use of the stabilizing element, a partial covering with sole material is sufficient instead of a complete covering. When used as an insole replacement, for example, the underside only has to be smoothed in the area of the lasting fold.

The sole material can consist of thermoplastic, hot melt, rubber, latex or a cork-latex mixture. In the case of plastic or hot melt, the connection to the sheet is made by spraying, in the case of rubber or cork latex by vulcanization. Depending on the requirements, the sheet may be pretreated with an adhesion promoter.

Fig. 1

eine Draufsicht auf ein erstes flexibles, sohlenartiges Stabilisierungselement zur Herstellung von Schuhen,

Fig. 2

ausschnittsweise einen Querschnitt durch das Stabilisierungselement der Fig. 1 und

Fig. 3

eine Draufsicht auf ein weiteres flexibles, sohlenartiges Stabilisierungselement zur Herstellung von Schuhen.

The invention will be explained in more detail in the form of exemplary embodiments with reference to the drawing. Show it

Fig. 1

1 shows a plan view of a first flexible, sole-like stabilizing element for the production of shoes,

Fig. 2

sections of a cross section through the stabilizing element of FIGS. 1 and

Fig. 3

a plan view of another flexible, sole-like stabilizing element for the manufacture of shoes.

In Fig. 1 you can see a flexible, sole-like stabilizing element 10, which allows the production of shoes that have a high rolling comfort, that is, lengthways have a high flexibility to the longitudinal axis 1 of the shoe, high rigidity and lateral stability transversely to the longitudinal axis 1 of the shoe and overall good torsional ability. The stabilizing element 10 initially consists of a spring-hard sheet 11 stamped in a sole-sized manner in a standardized size, which is profiled in a corrugated sheet manner essentially transversely to the longitudinal axis 1 of the shoe. The outline 14 of the metal sheet 11 is minimal, corresponding to the smallest size of a whole group of shoe sizes and shapes.

A layer 15 of sole material is applied to the edge 14 of the metal sheet 11, the outline 16 of which is standardized to the largest size of the same group of shoe sizes.

The layer 15 can consist of thermoplastic, hot melt, rubber, latex or cork latex.

Since the metal sheet 11 must be made of spring-hard material, special machines are required for its production, for example cutters with laser beams or high-pressure water jets or also special punching tools. Stamping tools would normally have to be made in all sizes and shapes as well as for right and left soles. Thanks to the circumferential layer 15, however, each shoe factory can punch out a whole set of shoe sizes and shapes from the blanks 10, which are delivered in a few standardized sizes and shapes, using the usual punching knives, as is indicated by the dashed line 17. Adjustment points 13 in the metal sheet 11 serve to center the punching knife.

It has been found that the finished stabilizing element 10 retains its stabilizing properties if the width of the edge layer 15, which protrudes beyond the metal sheet 11 after punching out and serves as an insole outline, so to speak, is approximately 10-30% of the Dimensions, measured between finished insole outline 17 and actual sheet metal outline 14, do not exceed. For the rest, such a rubber or plastic edge 15 has the further advantage that a lasting wedge can not only be glued, but can also be fastened with tacks. The circumferential layer 15 can also be used for sewing in as an insole similar to the California design, the procedure being as described above.

In order to be able to position the metal sheet 11 exactly in a vulcanizing or injection mold, fixing points or perforations 12, 13 are provided. These openings 12 also enable a form-fitting anchoring between the metal sheet 11 and the plastic edge 15. In addition, the fixing points 13 can serve as adjustment points during later shoe manufacture, which, as shown in FIG. 1, mark, for example, the longitudinal axis 1 of the shoe.

Whether or not the metal sheet 11 is covered with rubber or plastic material 15 on the entire edge or over the entire area, as shown in FIGS. 1 and 2, depends on the later use of the stabilizing element 10.

Fig. 2 shows a section of a cross section through the completed stabilizing element 1 of Fig. 1. In particular, its underside is filled with the help of the rubber or plastic layer 15 so far that the lower surface of the plastic layer 15 without a profile, i. H. is essentially flat. The same applies to the top of the rubber or plastic layer 15.

In Fig. 3 you can see another flexible, sole-like stabilizing element 20, which here as a so-called insole part z. B. is inserted or glued into a cup-shaped outsole 2. It allows simple and inexpensive production of shoes that have a high rolling comfort and at the same time a high rigidity across and a good torsion about the longitudinal axis 1 of the shoe. The stabilizing element 20 consists of the spring-hard metal sheet 11 cut or punched in a sole-like shape or punched in a standardized size, which is profiled in a corrugated sheet-like manner substantially transversely to the longitudinal axis 1 of the shoe. The outline 14 of the metal sheet 11 is minimal, corresponding to the smallest size of a group of several shoe sizes and shapes.

The metal sheet 11 is covered with a soft-elastic plastic material 25, for example overmoulded or cast. Whose outline 26 agrees with the inner edge of the z. B. shell-shaped outsole 2, minus processing strengths.

The plastic layer 25 preferably consists of a damped-elastic plastic foam, as it has proven itself in the manufacture of soles for comfortable shoes which are gentle on the joints and spine. However, a latex or cork-latex mixture can also be used, which is then vulcanized onto the metal sheet 11.

The statements regarding the area ratio of sheet metal to circumferential outline 3 apply analogously to the descriptions in FIG. 1.

The outline of the shell sole 2 and the outline of the finished stabilizer element 20 are jointly standardized. The outline of the insert 20 corresponds to the smallest outline of a set of several shell sole or sole part sizes. Depending on the number of sizes, which are standardized and combined in a group, only the wall thickness of the shell sole 2 changes.

The stabilizing element according to the invention is suitable in principle for the production of all known types of street and sports shoes, but also of health shoes or safety shoes, the stabilizing effect of the metal sheet being more noticeable the softer the shoe bottom is.

Claims (8)

Flexible, sole-like stabilizing element (10, 20) for the manufacture of shoes, consisting essentially of a resilient sheet (11) which has a high degree of rigidity transversely to the longitudinal axis (1) of the shoe and a high flexibility longitudinally to the longitudinal axis (1), characterized in that that the sheet (11) is profiled substantially transversely to the longitudinal axis (1) of the corrugated sheet and that the size and shape of the sheet (11) are standardized to the minimum of a group of successive shoe sizes and shapes. Stabilizing element according to claim 1, characterized in that the size of the finished stabilizing element (10, 20) is standardized to the maximum of the group of shoe sizes and shapes, that the gap between the edge (14) of the sheet (11) and the edge ( 16, 26) of the finished stabilizing element (10, 20) is between approx. 10 and 20%, maximum also 30% of the dimensions and that the sheet (11) is coated with sole material (15, 25) which fills the gap. Stabilizing element according to claim 1, characterized in that the sheet (11) is encased or foamed with a soft elastic rubber or plastic material (25) which is used as a built-in sole part (20) for inserting or gluing into shell-shaped outsoles (2), shoe bottoms or Shoe bottom parts is formed, and that the gap between the edge (14) of the sheet (11) and the edge (16, 26) of the finished stabilizing element (10, 20) is between about 10 and 20% of the dimensions. Stabilizing element according to claim 3, characterized in that the size of the finished stabilizing element (10, 20) is standardized to the maximum of the group of shoe sizes and shapes. Stabilizing element according to one of claims 1 to 4, characterized in that the sheet (11) consists of fiber-reinforced plastic, hardened steel sheet or spring bronze. Stabilizing element according to one of claims 2 to 5, characterized in that the sole material (15, 25) is a thermoplastic, a hot melt, a rubber, a latex, a cork-latex mixture or a damped-elastic plastic foam, e.g. . B. polyurethane foam. Stabilizing element according to one of claims 2 to 6, characterized in that the sole material (15, 25) envelops the sheet (11) only in the region of the edge (14). Stabilizing element according to one of claims 1 to 7, characterized in that fixing and adjusting marks or bores (12, 13) are provided in the sheet (11) and / or in the sole material (15, 25).

Images