EP0682886B1 - Shoe sole - Google Patents

Abstract

At least part of the profiled tread blocks (14) on the sole are laminated. The laminations are divided from each other by cuts crosswise to the direction of stress applied to the sole and depending on the terrain. The height of the laminations corresponds to the height of the profiled blocks and their width corresponds to a fraction of the height of the lamination. The profiled blocks have gaps crosswise to the lengthwise direction of the laminations. The laminations are formed by incisions (22) in the profiled blocks and end alternately on the rim of the sole of the shoe or spaced apart from the rim (20) of the sole. <IMAGE>

Description

The invention relates to a shoe sole made of elastomeric material with a running profile formed by profile blocks according to the preamble of claim 1.

Shoe soles with tread blocks are made of sturdy hiking shoes or winter shoes. The soles of the shoes are profiled trained so that the soles are non-slip and the Give the wearer of the shoes a good stability. However, such soles lose their slip resistance smooth, wet surfaces such as PVC coverings, tiles or especially on snowy or icy floors. When snowy or icy documents cause slight slippage on the contact surface to form a wedge Water between the contact surface of the sole and the ground surface, so that the friction decreases greatly and falls can often no longer be avoided.

In order to create an improvement here, special Snow soles developed that are also used in trekking come. These soles have a variety of treads with free spaces between the tread lugs. Of the The area share of the open spaces is quite high, so that the Surface pressure of the tunnels on the floor is increased, which gives improved slip resistance.

However, such soles have the disadvantage that higher material stress due to the higher surface pressure the abrasion and wear of the shoe sole strong is increased. It cannot be compensated for by greater material hardness be, since this causes the coefficient of friction in the Rule were reduced. Also the contact areas with increasing wear wider, so that the slip resistance especially on wet, smooth surfaces.

A shoe sole is known from EP-A 0 410 163, the Profile comprises at least one stud, the lower surface of the stud has a lamella field on a partial area. The Slats stand with a compared to the stud height low height from the lower surface of the tunnel.

Based on this state of the art, it is the task of Invention, a shoe sole with improved slip resistance to provide with different soil conditions.

This problem is solved by an object with the Features of claim 1. With this indicated in claim 1 The solution is particularly surprising on smooth, wet surfaces a greatly increased Slip resistance of the shoe sole according to the invention; because for one is the formation of a water wedge due to the slats between the sole contact surface and the underlay, because the water can be squeezed out through the lamella gaps. Secondly, the slats bend sufficiently under load, so that many profile edges through the slats are formed on the contact surface of the profile block form the bottom. Opposite a sole with a smooth tread block contact surface is the slip resistance at the sole according to the invention greatly increased.

Because the slats are due to their relatively large height bend strongly, the edges of the slats grind abraded over time, so that even in the unloaded Condition, i.e. when the slats are not bent the surface of the tread blocks is uneven. So that is even when the sole of the shoe is not so heavily loaded, for example when putting on the shoe sole, already a better one Slip resistance due to this uneven surface given. Overall, the configuration according to the invention leads to a significant improvement in the sole properties in terms of their slip resistance.

The sole of the shoe according to the invention is laminated Profile blocks should be softer because the lamellas are uneven and rotational movements of the wearer bend. The joints are then less stressed.

The design of the shoe sole according to the invention and the This increases the slip resistance, which opens up the possibility of cheaper or more efficient to use in production Using materials for the shoe sole without thereby impairing the slip resistance, as in critical Situations when using suitable materials, like PU, the slip resistance of rubber can be achieved.

If the slats are transverse to the main sole loading direction according to claim 2 they can stretch out easily bend and unfold their effects particularly advantageous.

Advantageous configurations of the lamella dimensions are Subject matter of claim 3.

In the embodiment according to claim 4 are in the profile blocks Gaps formed transversely to the longitudinal direction of the slats, so that a profile block has several lamella groups.

According to claim 5, the slats are in the simplest way formed by incisions made in the profile blocks.

Further advantageous embodiments are the subject of Claims 6 to 11.

Figur 1

eine Ansicht eines Schuhs mit der erfindungsgemäßen Schuhsohle,

Figur 2

eine Ansicht des Laufprofils der Schuhsohle,

Figur 3 - 5

Seitenansichten eines Profilblocks der Schuhsohle,

Figur 6A-6D

Abwandlungen des Laufprofils der Schuhsohle in einer zusammenhängenden Darstellung.

In the following the invention is described in detail using an exemplary embodiment with reference to the drawing. The drawing shows:

Figure 1

2 shows a view of a shoe with the shoe sole according to the invention,

Figure 2

a view of the running profile of the shoe sole,

Figure 3-5

Side views of a tread block of the shoe sole,

Figure 6A-6D

Modifications of the running profile of the shoe sole in a coherent representation.

In the drawing, the same parts are only included once Provide reference numbers.

In Figures 1 and 2, a shoe sole 10 is shown, the an elastomeric material such as rubber, polyurethane, PVC or the like. The shoe sole 10 has a running profile 12, which is formed from profile blocks 14 and 16. Between the profile blocks 14, 16, a free space 18 is formed. The profile blocks 14 are essentially cuboid and arranged parallel to the edge 20 of the shoe sole 10. The profile blocks 16 located away from the edge 20 are in this embodiment in the form of a cross in plan view trained (Fig. 2).

In Figure 3, one of the profile blocks 14 is a side view shown. The profile block 14 is by incisions 22, which extend away from the edge 20, divided into slats 24. The slats 24 thus extend essentially transverse to the local sole loading direction. The slat height H roughly corresponds to the profile block height. The width B of the slats 24 corresponds to a fraction of the slat height H. This ensures that the fins 24, as shown in Figure 4, can bend under load. For worn soles or with shallow depths H, which are smaller than B, the effect diminishes since the lamellae become less and less "bent". The lower edges 26 the slats 24 form the support surface in the unloaded state of the profile block 14 (Fig. 3). When loading the The sole of the shoe 10 lies due to the bending of the slats 24 the contact surface of the profile block 14 is only linear with its edges 28 of the slats 24 (Fig. 4) on the floor on. The slat edges 26 are through the slats 24 and edges 28 channels 30 formed. Through the channels 30 can Forming or existing water in the open spaces 18 are pressed.

After a certain period of use the shoe sole 10 are the edges 28 of the lamellae 24 are ground and have a as shown in Figure 5, rounded shape. That is also in the unloaded state of the shoe sole 10, the contact surface of the profile block 14 is no longer level (Fig. 5). So are in unstressed or slightly loaded condition of the shoe sole 10 already formed channels 32 through which between the support surface and water under the pad into the open spaces 18 can drain.

The slats can also be arranged next to each other at a distance be. As a result, the are already in the unused state Shoe sole channels for water drainage between the slats educated. With this shoe sole, the slats can already be provided in the mold of the shoe sole.

The slats 24 can be flat in their longitudinal direction be as shown in Figure 2. The straight ends here Incisions on the sole edge. Instead it can be provided that the slats, or part of the slats, shown in Figure 6A are designated 24 'at a distance in front of the sole edge 20 end up.

According to embodiment 6B, the slats 24 and 24 ' alternately on the edge of the sole or at a distance from the edge of the sole 20 end up. This is particularly recommended in places that are heavily used, such as on the rear paragraph or on the Toe.

According to embodiment 6C, in addition to the slats 24 or 24 and 24 '' a running parallel to the sole edge 20 Incision 25 may be provided, the one additional edge offers protection against slipping in the transverse direction.

The slats can also have a wavy configuration have, which is somewhat more complex in terms of production technology. This is indicated schematically in FIG. 6D at 24 ″. A wavy design would also in the tread blocks Longitudinal direction of the slats a certain bending elasticity give. With wear there is a different removal also made on the longitudinal direction. This results in on the sole surface a number of points increased Surface pressure that does not decrease due to wear.

Such a bending elasticity in the longitudinal direction can also through transverse to the longitudinal direction and in the profile blocks intended column can be effected.

The shoe sole described is also for leisure, sports and Everyday shoes can be used with success. Because an improvement The slip resistance of the shoe soles is particularly high great on wet and slippery ground conditions Value to increase accident safety.

Claims (11)

1. Shoe sole made from an elastomeric material, having an outsole profile (12) formed by profile blocks, with at least some of the profile blocks comprising strips (24, 24', 24''),
   characterized in that the strips (24, 24', 24'') make up the profile block and the height of the strips (H) is substantially equal to the height of the profile block.
2. Shoe sole according to claim 1, characterized in that said strips extend crosswise to the typical local loading direction of the sole.
3. Shoe sole according to any of the preceding claims, characterized in that the width (B) of the strips is equal to a fraction of the strip height (H).
4. Shoe sole according to any of the preceding claims characterized in that gaps extending crosswise to the lengthwise direction of the strips are formed in the profile blocks.
5. Shoe sole according to any of the preceding claims, characterized in that the strips are formed by cuts (22) made in the profile blocks.
6. Shoe sole according to any of the preceding claims, characterized in that the strips are plane.
7. Shoe sole according to any of the preceding claims, characterized in that the strips are undulated in their lengthwise extension (Fig. 6D).
8. Shoe sole according to any of the preceding claims, characterized in that the strips are arranged at a spacing one beside the other.
9. Shoe sole according to any of the preceding claims, characterized in that the strips end at a distance from the sole edge (20) (Fig. 6A).
10. Shoe sole according to any of the preceding claims, characterized in that the strips end alternately at the sole edge and at a distance from the sole edge (20) (Fig. 6B).
11. Shoe sole according to any of the preceding claims, characterized in that in addition to the strips extending crosswise to the lengthwise circumferential direction at least one strip (25) is provided that extends in parallel to the sole edge 20 (Fig. 6C).

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