DE4035416A1 - SHOE BASE, ESPECIALLY FOR SPORTSHOES - Google Patents

Abstract

Described is a sole for sports shoes in particular, the sole having a shock-absorbing layer and, joined to the side of this layer nearest the ground, an external wear layer which may incorporate a tread or carry a treaded layer. The shock-absorbing layer is made of hard, flexurally elastic plastic and has a number of supporting walls, disposed essentially parallel to the longitudinal exis of the shoe, which enclose cavities between them. Viewed in section, the supporting walls are disposed to fit together, inclined at an angle and/or curved, between the external wear layer and the top of the shock-absorbing layer.

Description

The invention relates to a shoe bottom, in particular for Sports shoes with the characteristics according to the preamble of Claim 1 and a method for the same Manufacturing.

The realization that especially to exercise athletically Activities certain shoes in their design biomechanical conditions must be coordinated prevailed in the meantime. This applies in particular to the design of the shoe bottom, on and with which the The foot rolls off the track and who has the task, on the one hand, the sometimes considerable Reduce and distribute impact forces to avoid health problems, on the other hand, to stabilize the foot sufficiently and during the rolling process so that the user maintains the feeling for the career (rail contact). To this purpose has been numerous in recent years Proposals made for the training of outsoles and partly also put into practice on it aim to achieve the natural target Movement behavior of the foot when rolling off as possible little to hinder, but it does influence that the best possible power transmission  is achieved during the run. Suggestions go in that direction there, the elastic compliance in the individual Sole sections to choose from differently Places that are heavily stressed to a large extent To achieve attenuation, pronation too extensive or To inhibit supination and shape changes in the foot to consider yourself during the rolling process.

With the vast majority of those for this purpose developed and put into practice shoe bottoms flat sole parts are made of resilient material Use, the pressure deformability of the Materials for controlling the properties mentioned is exploited. Possibly. will this compressibility of Outsoles and possibly midsoles through local recesses, Inserts, denser or less dense consistency of the Sole material, etc. affected. All of these suggestions which are designed to cushion, support and guide the Compressibility of essentially flat soles or use sole parts, but come up against one Limit in the compatibility of the different Conditions. This is drawn in that a Sufficient reduction, especially when running fast on hard tracks, high foot strength is actually only possible a relatively long deformation path, i.e. H. with soft Sole material that can be achieved. A long deformation path but requires a relatively thick outsole, through which however, the runner loses the desired track contact feeling and above all, not just directed vertically to the web Compression deformations, but also laterally, d. H. parallel to Permits path-wise deformations to a noticeable extent and thereby creates a feeling of swimming. To do this avoid and also a growing with the sole thickness Keeping the weight of the outsole low is therefore always in practice, a compromise was made, based on a Decreasing the damping ability  

There are always suggestions for so-called Bubble soles have been made in the shoe bottom more or less extensive chambers filled with compressed air are provided (see e.g. DE-OS 24 60 034). At a Shoe bottoms of the type mentioned at the beginning have also been made the air cushion function from in the longitudinal direction of the sole running air ducts combined with that through the Given the compressive deformability of the sole material Damping ability of the existing between the air ducts Support bars (DE-OS 36 10 354). Air cushion soles with In practice, however, extensive air chambers have the desired success is not achieved because it is not possible is the damping generated by the air pressure in the to differentiate individual zones of the sole so that they Meets requirements. Shoe bottoms in which the between air-filled longitudinal channels existing support webs in the essentially provide the damping effect and the shock-absorbing effect of the air ducts only supportive is used, have essentially those with the Compressive deformability associated, above disadvantages described.

Finally, a shock-absorbing shoe bottom is also known, where the side sole edge on the running side outstanding profile body are arranged and its interior a grating structure to save weight of vertically standing, crossing supporting walls has (EP-OS 2 06 438). The height of the sole edge laterally protruding profile body takes to the middle of the sole down, so that the bottom of the shoe is essentially only on supports the outer ends of the profile body and a Damping effect essentially by bending the Profile body and by squeezing the immediately above the marginal sole cavities arises. However, this structure only results in an edge Cushioning while the intermediate sole sections stay largely rigid and adapt to that Do not allow conditions when rolling the foot.

The object of the present invention is therefore a To create shoe bottom of the type specified, the with sufficient damping an adjustment of the Deformation behavior to the biomechanics of the foot allowed, easy to manufacture and light weight Has.

According to the invention, this object is achieved by Design according to the characterizing part of patent claim 1.

In the sole design according to the invention not the compressibility of a relatively soft compliant sole material, but the Bend deformability of retaining walls from a relative hard flexible material that is relative to the Load arranged obliquely and / or arched and are formed so that bending moments as a reaction arise. A hard set comes as the material Plastic, e.g. B. polyamide, polyurethane or PVC, in Consider a sufficiently elastic Resetting behavior. The retaining walls, which are in the run essentially in the longitudinal direction of the shoe bottom, essentially maintain their shape, but change in line with the shape of the sole, its width and one for example desired wedge shape of the shoe bottom Height. To accommodate the weight load and the Exercise of other sporting activities Forces form the supporting walls of a support structure, the Training of this support structure in particular Sole cross-section is of essential importance. Because form the retaining walls, viewed in the sole cross section, together with the top and the running cover layer a kind of framework in which the deformation behavior of the individual support walls the distribution of forces and the load the other supporting walls affected. In this way can by the geometric design and by the Wall thickness measurement a targeted anisotropic  Bending behavior can be achieved in the individual zones. The Anisotropy can be so pronounced that at a vertical load from the retaining walls formed support structure relatively compliant and is therefore damping, but against lateral loads is stiffened by the corresponding deformation, whereby the deformation process itself becomes a stiffening Geometry of the retaining walls leads. This will even at a relatively thick and therefore good cushioning shoe bottom avoid swimming to the side.

The wall thickness of the retaining walls is according to the one that occurs Interpret burdens. It is due to weight reasons preferably in a range of 1 to 3 mm. There with corresponding design relatively few Retaining walls are required can be obtained in this way extensive cavities next to the retaining walls, which makes the Weight of the shoe bottom is very low.

For the formation and arrangement of the retaining walls in Considering the sole cross-section, there are different advantageous basic structures by means of which Bending ability of the "truss structure" cheapest can be exploited. For example, the Cross-sectional support walls viewed through at least one support arch curved upwards or downwards, which is the weight load like a bridge floor records. Several support arches are expedient different widths and symmetrical to each other Longitudinal center line of the shoe bottom arranged.

According to another embodiment, the support walls form viewed in the sole cross-section, a multi-curved one Support arch that has the character of a waveform. So can between a double, up or down Curvature provided a counter-curvature of the support arch be, whose apex is approximately in the middle of the Sole width is.  

Significant for the anisotropic described above Behavior essential effects are obtained in particular if at least some of the retaining walls are only with the top the shock-absorbing sole layer or with the running side Cover layer firmly connected, but otherwise opposite these surfaces are slidably arranged.

The retaining walls can be maintained while maintaining their basic cross-sectional shape from tip to Go through the heel of the shoe bottom, being in adjustment to the desired sole width and height only that Change dimensions. However, it is also conceivable to Achieving special deformation characteristics Front sole with a different cross-sectional structure Form retaining walls as the rear sole.

One for the manufacture of the supporting structure of the Shoe bottom according to the invention particularly cheap The process is the blow molding process. Because here you can in a simple manner also such retaining walls, the one have closed borders, d. H. a cavity full enclose, be easily manufactured. Here, the Top of the shock absorbing sole layer or the running cover layer in one piece with at least one Number of retaining walls are blow molded. Then the running cover layer or Top of the shock absorbing layer with the free edges or surfaces of the retaining walls connected, so that a kind Box profile results.

Exemplary embodiments of the invention are described below of the accompanying drawings. In the The drawings show:

Figure 1 is a perspective view of a shoe equipped with a shoe bottom according to the invention.

Figure 2 is an exploded view of the individual parts of the shoe bottom.

Fig. 3 is a bottom view of the cushioning sole layer, wherein the continuous cover layer is removed;

Fig. 4, 5 cross sections along the lines IV-IV and VV in Fig. 3;

Fig. 6 is a bottom view of another embodiment of the shoe bottom of the invention;

Fig. 7 is a perspective view of the shoe bottom as shown in FIG 6, wherein the front sole portion and the rear sole portion are shown pulled apart.

. Fig. 8, 9 are cross-sections on the line VIII-VII and IX-IX in Figure 6, wherein the continuous cover layer is longitudinally drawn at a distance from the support walls having sole layer;

Fig. 10 can be produced in the blow molding process to 15 advantageous cross-sectional shapes, the preferred, and

Fig. 16, 17 cross-sectional views of the shoe bottom according to the invention, illustrating the deformation behavior at one-sided loads.

The athletic shoe according to Fig. 1 consists of a shaft 1 and a shoe bottom designated as a whole with 2, made up of FIG. 2 consists of a shock-absorbing sole layer 21, a continuous cover layer 22 and a profiled wear sole 23 made of the for the front sole and There are separate parts of the rear sole.

The shock-absorbing sole layer 21 has the structure shown in FIGS . 3 to 5 and essentially consists of an upper wall 210 , two side walls 211 and support walls 212 to 215 , which are integrally connected to the upper wall 210 . The outer side walls 211 diverge from the upper wall 210 and are connected to the support walls 212 , 215 arranged within them, each forming a closed cavity 217 , 218 and a running surface 219 , 220 . The support walls 213 and 214 form an annular closed tubular profile, which extends in a straight line approximately in the longitudinal center of the shoe bottom from its heel-side edge to the tip ( FIG. 3). The running surfaces 219 , 220 determine the sole contour in connection with the side walls 211 . Accordingly, they curve at the tip and at the heel to the respective apex and in this way close off the cavity between the support walls 212 , 213 and 214 , 215 at the front and rear. The front and rear ends of the tubular profile forming the support walls 213 , 214 can be closed by a protective strip (not shown) running transversely at the tip and heel of the shoe.

The running cover layer 22 is connected to the surfaces 219 , 220 and to the underside of the tubular profile, which forms the support walls 213 , 214 , by adhesive bonding or heat sealing. The wear sole parts 23 are in turn glued to the underside of the running cover layer 22 .

The inner wall structure of the shock-absorbing sole layer 21 in the exemplary embodiment according to FIGS . 1 to 5 has a similar design which is continuous from front to back and only changes in dimensions with regard to width and height, as can be seen from FIGS. 4 and 5. The cross-sectional design corresponds to that according to FIG. 8 and is therefore explained in connection with it:
The support walls 212 and 215 are at an angle of approximately 70 ° to the running cover layer 22 and are curved toward one another in their upper edge section, with which they run into the upper wall 210 and are connected to it. As a result, they form a bridge-like support arch that is subjected to bending when subjected to a load from above. The support walls 213 , 214 are arranged under the apex region of this support arch, and because of their curvature also undergo a bending outwards when subjected to a load. The upper wall 210 is widened beyond the two side walls 211 and bent back onto the side walls 211 and connected to them, so that a bead 222 running on both sides along the upper edge of the shoe bottom is thereby created. The running cover layer 22 , which is connected to the shock-absorbing sole layer in the finished state of the shoe bottom, has two hollow ribs 225 arranged symmetrically with respect to its longitudinal center line, which protrude into the cavities 226 between the support walls 212 , 213 and 214 , 215 .

In the embodiment according to FIGS. 6 and 7, the shock-absorbing sole layer 21 'in a front sole portion 230 and a rear sole part 231 is divided, the support structure formed by supporting walls not only in terms of the dimensions (height, width), but also with regard to the cross-sectional shape of the support walls differs. In FIG. 7 it is indicated that the front sole part 230 has support walls with a cross-sectional structure according to FIG. 8, while the rear sole part 231 has a cross-sectional structure corresponding to FIG. 9. This cross-sectional structure provides an upper wall 240 , side walls 241 and a bead 262 running longitudinally on both sides, which are identical in design to those in the cross-sectional shape according to FIG. 8 and therefore do not need to be explained in more detail.

However, the inner support structure, which is formed by a corrugated intermediate wall 242 , is different. The intermediate wall 242 forms a supporting arch, which has an upward arch section 243 and 244 on each side of the sole center and an intermediate, downward arch section 245 . The rising or falling walls of the arch sections 243 , 244 and 245 each form the support walls. The corrugated intermediate wall 242 is only firmly connected via its side edges to the side walls 241 , while the apex regions of the bulge sections 243 , 244 and 245 are not connected to the upper wall 240 or the running cover layer 22 ', but rather a small distance therefrom in the Comply with the order of 1 mm.

The front sole part 230 is connected to the rear sole part 231 via an oblique abutment surface 234 , which is formed by a flat intermediate plate, not shown.

The shock-absorbing sole layer 21 or the sole parts 230 , 231 of the shock-absorbing sole layer 21 'can be produced in a simple manner in the blow molding process. In the context of this method, the cavities 217 , 218 and the cavity enclosed by the tubular profile of the support walls 213 , 214 are formed, for example, from a tubular film of predetermined wall thickness in its still deformable state by being inflated in a separable blow mold. The same applies to the cavity located between the upper wall 240 and the intermediate wall 242 . The blow molding process is known and requires no further detailed explanation at this point. Subsequent to the production of the shock-absorbing intermediate layer, its connection takes place, for example by gluing or heat sealing, with the running cover layer 22 or 22 '.

Figs. 10 to 15 show further cross-sectional modifications, in which the shock-absorbing sole layer can be made 21 or 21 ', wherein a shaping in the blow-molding is also possible here. The parts to be connected to one another, namely the shock-absorbing sole layer and possibly the cover layer or the top of the shock-absorbing sole layer, are shown in a state before the mutual connection.

In the embodiment according to FIG. 10, the support walls are formed by a single support arch 270 which is symmetrical with respect to the cross-sectional center and which is integral with the side walls 271 and grown together with the upper wall 272 . The running-side cover layer 273 has flat longitudinal ribs 274 which have a wave shape in cross section.

The embodiment according to FIG. 11 has as support walls three tubular profiles 275 running alongside one another in the longitudinal direction of the sole, which form support walls of a similar type and function as explained in connection with the support walls 213 , 214 in the embodiment according to FIGS. 1 to 7.

In the shock-absorbing sole layer according to FIG. 12, the retaining walls formed by a first support arch 280 of greater width, which is integral with the side walls 281, while a second support sheet is attached 283 lesser width, with its "legs" on the machine side covering layer 284 and with its apex can be attached to the underside of the apex region of the further support arch 280 , but need not. In the latter case, the second support arch 283 is displaceably supported with respect to the first support arch.

The embodiment according to FIG. 13 is constructed largely the same as that according to FIG. 8 and differs only with regard to the shape of the tubular profile 285 , which is not supported between the hollow ribs 225 of the running cover layer, but directly on these hollow ribs themselves a connection between the tubular profile 285 and the hollow ribs can be made, but there can also be a mere support or even a small distance between these elements.

In the embodiment according to FIG. 14, the running cover layer and the supporting walls are formed as a one-piece unit by a plurality of tubular profiles with a polygonal cross section, which run alongside one another in the longitudinal direction of the sole and are connected to one another. This tube arrangement is stabilized by an upper wall 290 , which is stiffened on both sides by hollow beads 291 . This upper wall 290 is connected to the upper cover surfaces of the tubular profiles.

The embodiment according to FIG. 15 again largely corresponds to that according to FIG. 8. Different is the type of support walls 295 , 296 , which support the apex region of the support arch 297 and are formed by a closed tubular profile which is coil-shaped in cross section. The inwardly arched supporting walls 295 , 296 are subjected to bending under a vertical load and in extreme cases can be supported against one another.

FIGS. 16 and 17 show purely schematically the deformation behavior of the support structure shown in FIGS. 8 and 9 under a lateral load, which is indicated by the arrow P. If the supporting structure is loaded centrally and vertically from above, for example when the runner is resting on it, the individual supporting walls deform essentially symmetrically. If the load is indicated by the arrow P and acts obliquely from above and from the side, however, the support walls are loaded on one side. In this case, as the shown in FIG. 16 can be seen, both the right support wall 215 and the support walls 214 and 213 loaded by bending, so that the support wall is pressed flat 215, the support walls 213, 214 are, however, more curved. The left support wall 212 also experiences a certain greater curvature. In particular due to the flattened and therefore strongly curved shape of the support walls 213 and 214 on both of its long sides, which form the tubular profile, the support structure created in this way by deformation is stiffer in the transverse direction than before, so that a lateral displacement by bending deformation and thus a "swimming " is prevented.

According to FIG. 17, the one-sided load P in turn causes a flattening of the right bulge section 244 , but at the same time a shift of the middle bulge section 245 to the left, since it is not connected to the cover layer on the barrel side. As a result of this displacement, the left bulge section 243 experiences an increase in its bulge, which leads to a corresponding stiffening. This stiffening means that the left cross-sectional part has less deformability to the side, which in turn reduces lateral displacement of the shoe bottom and thereby prevents a feeling of swimming.

As far as due to the type of manufacture, for. B. in the way of Blow molding process that occurs in the shoe bottom Cavities between the retaining walls are sealed airtight are in the inside of the shoe or to the upper edge of the Equalizing openings opening at the outer edge of the sole, about different air pressure conditions inside and to avoid outside the shoe bottom.

Claims (17)

1. Shoe bottom, in particular for sports shoes, with a shock-absorbing sole layer ( 21 , 21 ') and a cover layer ( 22 , 22 ') connected to it on the running side, optionally profiled or with a profiled sole, the shock-absorbing sole layer consisting of an elastically flexible plastic and contains essentially in the longitudinal direction of the support walls ( 212 , 213 , 214 , 215 ) which form cavities ( 217 , 218 , 226 ) between them, characterized in that the shock-absorbing sole layer consists of a relatively hard, flexible plastic and that the support walls, in Viewed sole cross-section, run obliquely and / or curved in itself between the running cover layer and the top of the sole layer. 2. Shoe bottom according to claim 1, characterized in that support walls ( 212 to 215 ), viewed in the sole cross section, are formed by at least one support arch ( 270 , 280 , 283 ) which is simply curved upwards or downwards. 3. shoe bottom according to claim 2, characterized, that the support arch is approximately symmetrical to Sole cross-section center is arranged. 4. Shoe bottom according to claim 2 or 3, characterized in that the two ends of the support arch near the side walls ( 211 ) of the shock-absorbing sole layer are connected to the running cover layer. 5. Shoe bottom according to claim 3, characterized in that a plurality of support arches ( 280 , 283 ) of different widths are arranged one inside the other. 6. shoe bottom according to claim 4 or 5, characterized, that the two ends of the farthest of several Support arches with the respective side wall of the shock-absorbing sole layer are connected. 7. Shoe bottom according to one of claims 1 to 6, characterized in that support walls ( 213 , 214 ; 275 ; 285 ; 295 , 296 ), viewed in the sole cross section, are formed by at least one annularly closed support profile. 8. Shoe bottom according to claim 1, characterized in that support walls, viewed in the sole cross-section, are formed by a multi-wave curved support arch ( 242 ). 9. Shoe bottom according to claim 8, characterized in that the support arch has a double, upward or downward curvature ( 243 , 244 ) and an intermediate, downward or upward curvature ( 245 ), the apex of which lies approximately in the middle of the sole cross-section. 10. Shoe bottom according to one of claims 1 to 9, characterized, that at least some of the retaining walls only with the Top of the shock absorbing sole layer or with the running cover layer are firmly connected. 11. Shoe bottom according to one of claims 1 to 10, characterized in that the running cover layer has one or more hollow ribs ( 225 ) extending in the longitudinal direction of the sole, which protrude into cavities of the shock-absorbing sole layer. 12. Shoe bottom according to one of claims 1 to 10, characterized, that the running cover layer one or more, in Has longitudinal ribs running hollow ribs, on which support walls of the shock-absorbing Support the sole layer. 13. Shoe bottom according to one of claims 1 to 12, characterized in that the shock-absorbing sole layer is divided into a front sole part ( 230 ) and a rear sole part ( 231 ) which are connected to one another by a continuous running cover layer. 14. Shoe bottom according to claim 13, characterized, that the support wall arrangements of the front sole part and the rear sole part different from each other are.   15. shoe bottom according to claim 13 or 14, characterized, that the mutually facing end faces of the Front sole part and the rear sole part are closed. 16. shoe bottom according to claim 15, characterized, that the front sole part and the rear sole part on their mutually facing end faces are connected. 17. Method of manufacturing a shoe bottom according to one of claims 1 to 16, characterized, that the top of the shock absorbing sole layer or the running cover layer in one piece with the or a number of the support walls by blow molding be shaped and then the barrel side Top layer or the top of the shock-absorbing Layer with the free edges of the retaining walls is connected.