NL9500145A - Football shoe sole, method of manufacturing a football shoe sole and football shoe thus obtained. - Google Patents

Description

Short designation: Sole for a football shoe, method for manufacturing a sole for a football shoe and football shoe thus obtained.

The present invention relates to a sole for a football boot, comprising a midsole and an insole, which insole comprises underside protrusions distributed over the surface of the insole. The present invention further relates to a method of manufacturing the sole and a football boot and a method of manufacturing a football boot. ·

Such a football boot sole, consisting of a midsole and a midsole, the midsole comprising closed projections on the underside, distributed over the surface thereof, is known from European patent application 0.340.053. According to this patent application, the sole for a football shoe consists of a bottom layer of dense, closed compact material, such as rubber, and a light top layer of expanded material, such as polyurethane foam. The insole includes closed protuberances that define openwork portions, which are typically located in the fore foot and heel support areas, the top layer filling the openwork areas to form skates. Such skates have excellent flexible projections.

A disadvantage of such shoes is the moderate shock absorption. When practicing football, where acceleration, stopping, evasive maneuvers, strong and repeated loads in different positions and jumps often occur, good shock absorption is very important to prevent muscle injuries and fatigue. Another drawback of such shoes is the asymmetrical pressure distribution in the shoes. An asymmetrical pressure distribution means that the pressure in the heel of the shoe differs from the pressure in the forefoot of the shoe. This leads to the feeling of penetrating the stud from the bottom of the sole to the foot itself. The wearer of such shoes speaks in such a case of tired feet and possible numbness in the foot. The comfort of such shoes is therefore low. The insole must also be resistant to wear and give good stability to the foot to prevent injuries.

The object of the present invention is to provide a football shoe sole which has better cushioning and pressure distribution in the sole than the football shoes as are known in the art.

Another object of the present invention is to provide a soccer shoe sole which prevents penetration of the closed projections to the foot.

These objectives are achieved by the use of a sole for a football shoe according to the invention and the sole of a football shoe, as stated in the preamble, according to the invention characterized in that the insole and the midsole are made of polyurethane and that the midsole the underside of which has studs distributed over the surface, which studs are engageable in the notches of the closed protrusions of the insole. The insertion of the studs of the middle insert into the notches of the closed protrusions of the insole prevents penetration of the closed protrusions to the foot. Such a construction of the midsole and insole also results in a symmetrical pressure distribution in the shoe, whereby a better cushioning in the sole is obtained and the feeling of tired feet is not perceived.

Preferably, the polyurethane of the insole has a higher hardness or density than the polyurethane of the midsole. The use of polyurethane with different hardnesses or densities results in good shock absorption. Good shock absorption means less chance of sports injuries and is experienced by the wearer of the shoe as a comfortable feeling. The use of polyurethane with different hardnesses or densities also results in a symmetrical pressure distribution in the shoe. In addition, the application of polyurethane with a high density or hardness in the insole ensures good resistance to wear.

In the most efficient and simple embodiment, the sole for a football shoe is preferably manufactured by spraying the intermediate directly onto the sole of the sole. The advantage of this is that good adhesion is created between the midsole and the insole.

In another preferred method of manufacturing a soccer shoe with a midsole and a midsole according to the invention, the sole for a soccer shoe is preferably made by spraying the midsole directly to the upper material (without adhesive joints) and spraying the insole directly on the mezzanine (also without adhesive joints). The advantage of this is that the top material of the football shoe is quilted because of the excellent adhesion of the intermediate sock to the upper material of the football shoe on the one hand and of the insole to the intermediate sock on the other.

To prepare polyurethane, a polyisocyanate composition consisting of a prepolymer and free polyisocyanate is reacted with a mixture of polyols, water and optional additives. Organic polyisocyanates which can be used to prepare the polyisocyanate compositions include aliphatic, cycloaliphatic and aralylphatic polyisocyanates. The polyether polyols used for the preparation of the prepolymer have an average nominal functionality of 2-6, preferably 2-4. These compounds have a number average molecular weight of 2,000-6,000, preferably 2,000-5,000 and especially 3,000-5,000. The polyether polyols which can be used to prepare the isocyanate-terminated prepolymer include products obtained by the polymerization of ethylene oxide with another cyclic oxide. The isocyanate-terminated prepolymer is prepared by reacting excess polyisocyanate and the polyether polyol to obtain a prepolymer having the desired NC0 (isocyanate) value. The polyol used to react with the isocyanate-terminated prepolymer may have a number average molecular weight of 500 to 10,000, preferably 750-6,000, and an average normal functionality of 2-6. Suitable polyols are polyesters, polyester amides, polythioethers, polycarbonates, polyacetals, polyolefins, polycyloxanes and polyethers. The amount of water used as a foaming agent can be varied in the known manner to achieve the desired density. Suitable amounts of water are generally at least 0.3 parts by weight, preferably 0.3 to 1.2 parts by weight, per 100 parts by weight of the reaction system. The reaction system may further include conventional additives such as catalysts, surfactants, dyes, stabilizers, fillers and chain extension agents and crosslinking agents. The preparation of polyurethane with different densities or hardnesses is a known technique per se and is described in European patent applications 0 358 328, 0 393 903, 0 497 492, 0 508 548 and 0 547 760, which can be considered incorporated herein.

The present invention will now be explained with reference to a figure and test examples.

The attached drawing shows a perspective bottom view of a sole of a football shoe according to the invention.

Studs 1 are provided with studs 3 over the surface of the intermediate bin 1. The bottom sole 2 has closed projections 4 on the underside thereof, distributed over the surface of the bottom sole 2. The closed projections 4 contain notches 5. The studs 3 of the intermediate piece 1 are engageable in the notches 5 of the closed projections 4 of insole 2.

Test example 1

Determination of the shock absorbing properties of shoe soles with a high load rate.

This test is performed to determine the shock absorbing properties of shoe soles.

The set-up consists of a punch driven by a linear motor. The stamp collides with the shoe draped around a foot model. The foot model with the shoe can be put in different positions with respect to the stamp, whereby the stamp collides with the shoe heel. Displacement and force with sensors are recorded with each collision. In a first measurement, the punch moves against the shoe at a very slow speed until a force of at least 800 N is reached. The amount of indentation that occurs here is stored in the computer. The movement is performed at a nearly constant speed. Four different speeds are applied, namely 0.01, 0.03, 0.09, 0.32 m / sec. The result of this test is a displacement force characteristic in which a compression phase and a decompression phase can be distinguished. The slope of the compression phase is a measure of the stiffness of the compressed material. The area between the compression and decompression curves is a measure of the energy loss that occurs upon impact.

The study was conducted with three shoe types. Types A and C (without studs on the middle) and type B (sole construction according to the invention). Types A and C are commercially available football boots.

Table 1 below shows the initial stiffness for different speeds. Table 2 shows the final stiffness for different speeds. Table 3 shows the energy loss for the different speeds.

TABLE 1

Initial stiffness (N / mm): mean and standard deviation per speed

TABLE 2

Final stiffness (N / mm): mean and standard deviation per speed

TABLE 3

Energy loss (N / mm): mean and standard deviation per speed

Tables 1 and 2 above show that the initial stiffness for shoe type B at all speeds used is lower than the initial stiffness for shoe types A and C. The same applies to the final stiffness, as shown in Table 2. Table 3 shows that the energy losses that occur for shoe type B for the different speeds is higher than for shoe types A and C. These shock absorption tests show that the shoe type B according to the invention has better shock absorption than the shoe types A and C.

Test example 2

Determination of the pressure distribution in the shoe.

The same shoe types as in Example 1 were used. The shoes are fitted around a standard mechanical foot, with a pressure measuring system fitted between the foot and the shoe. Then the whole is placed in a step simulator, where the shoe / foot is placed on a hard surface with a maximum vertical load of 2000 N, whereby the heel and front of the shoe soles are loaded separately. The pressure measurement system assesses the penetration of the studs on the bottom of the foot. Table 4 shows the area per pressure area in the front section.

TABLE 4

Area per pressure area in the front part

From Table 4 above, it can be seen that the fore-side pressures in shoe type A and to a lesser extent in shoe type C are higher and more concentrated than in shoe type B of the present invention. In addition, shoe type B according to the present invention exhibits the most symmetrical pressure distribution in the shoe. Shoe type C mainly shows an asymmetrical pressure distribution in the front.

Claims (4)

A football boot sole, comprising a midsole and a midsole, the midsole comprising closed projections on the underside distributed over the surface of the sole, characterized in that the midsole and the midsole are made of polyurethane and the midsole is attached to the underside has the studs distributed over the surface of the intermediate pad, which studs are engageable in the notches of the closed protrusions of the insole. 2. Sole according to claim 1, characterized in that the polyurethane of the insole has a higher density or a higher hardness than the polyurethane of the intermediate sole. Method for manufacturing a sole according to claim 1 or 2, characterized in that the intermediate sock is injected directly onto the insole. Football boot provided with a sole, characterized in that the sole corresponds to a combination of a midsole and insole as described in claims 1 and 2. 5_ Method for manufacturing a football shoe according to claim 4, characterized in that the intermediate sock is injected directly onto the upper material of the football boot and the insole is injected directly onto the intermediate sock.