EP4427620A1 - New shoe construction - Google Patents

Abstract

A shoe construction (1) containing a frame and support area which comprises a forefoot section (5) and a heel section (7) and is designed in the form of an arched bridge (8) which extends between the forefoot section and the heel section. The arched bridge comprises a lower bridge arch (9) formed on both sides of the foot and an upper bridge arch (11), wherein the upper bridge arch is guided in the direction of the imaginary instep of a foot and the lower bridge arch extends in the region of the imaginary longitudinal arch (12) of the foot, so that a reinforcement which extends below the lower bridge arch is fixed to the lower bridge arch or in the region of the upper bridge arch.

Description

The invention relates to a novel shoe construction.

Footwear in the form of shoes has been known since ancient times and has evolved with mankind. An essential aspect of shoes is their protective function for the feet. The development of the most diverse shoe designs over the centuries has essentially been based on the structure of the foot.

Basically, every foot consists of the toes, the metatarsus and the tarsus. The body weight is mainly carried by three points: the heel, the ball of the big toe and the ball of the little toe.

The foot has a longitudinal arch and a transverse arch. These arches are tensioned by muscles and maintained by ligaments and act like shock absorbers. They are very important for the function of the feet. A sinking of the arch results in misalignments of the foot, such as flat feet, fallen arches and splay feet.

From an evolutionary perspective, the human foot muscles are adapted to changing, rather soft surfaces, such as forests, steppes and other natural soils. As human society developed, paths and roads were expanded and increasingly paved. This represented an ever greater overload for the muscles of the human foot.

The traditional shoe essentially has two main components, an upper part, called the shaft, and a lower part, which represents the sole.

The bottom has a sole, whereby a distinction is usually made between the inner sole, also called the insole, and the outsole. The insole is flat and serves the purpose of stiffening the sole. Because it is rather stiff, it only allows for slight nuances in the dynamic movement of the foot.

From handmade, very sturdy and coarse footwear in earlier centuries, the trend was increasingly towards light shoes, which further increased the strain on the foot muscles on the widely paved roads and paths of cities and towns, with the resulting foot deformations caused by the collapse of the longitudinal arch and transverse arch of the foot.

Based on this, the present invention was therefore based on the object of providing a shoe construction which supports the foot muscles and is better adapted to the individual shape of the foot of each individual.

This object is achieved by a shoe construction with a frame and holding area which has a forefoot section and a heel section and is designed in the form of a bridge which extends between the forefoot section and the heel section, with a lower and an upper bridge arch, wherein the upper bridge arch is guided in the direction of the imaginary instep of a foot and has a reinforcement in the area of the instep, in the longitudinal direction of the shoe construction, and the lower bridge arch extends in the area of the imaginary longitudinal arch of the foot, so that a reinforcement which extends below the lower bridge arch is fixed to this or to the upper bridge arch.

In this way, it is possible to capture and recreate the foot in its natural form. The three main points that support the healthy foot are supported: the heel with the heel bone, the metatarsophalangeal joints and the tips of the toes, each with the associated muscles. This takes into account the fact that the muscles of the three areas of the foot mentioned the foot is naturally arched, comparable to the string of a sports bow.

This can make a significant contribution to foot health compared to conventional shoes. The harder the surface to be walked on, the more likely the muscles in question are to become tired. If they are not supported effectively, as is made possible by the shoe construction according to the invention, the result is an increasing collapse of the arch of the foot. In fact, the number of foot deformities requiring orthopedic treatment is increasing. The shoe construction according to the invention can counteract this.

Preferably, the reinforcement is formed in the form of a lacing, wherein the lacing is guided in an opposite arched manner to the lower bridge arches formed on both sides of the foot.

In conventional lace-up shoes, which are the most suitable for effectively supporting the foot, the arch of the foot is pushed downwards more due to the lacing and thus becomes flatter in shape. The foot muscles are also overloaded and the arch of the foot breaks downwards under the lacing.

This effect is avoided in the shoe construction according to the invention by raising or suspending the foot in its natural position.

Because the lacing or other form of reinforcement is arched in the opposite direction to the lower bridge arches on both sides of the foot, it can accommodate the natural shape of each foot. Individual anatomical differences can be taken into account. Overall, the fixation of the foot and the adaptation to any individual foot shape is possible in a much better way than with conventional shoe designs.

According to a further embodiment of the shoe construction according to the invention, it can be provided that the lacing is formed from laces or lacing wires, which can in particular be guided in a spiral shape.

The construction principle of the foot can be compared schematically to a spiral. Joints, ligament structures and muscle groups run in a spiral screw connection around the foot, from the back outside, i.e. the outside of the heel, to the front inside, i.e. to the ball of the big toe. The two ends of the spiral - forefoot and heel - screw together in opposite directions, so to speak: the forefoot turns inwards, the heel outwards. This creates the dynamic three-dimensional structure of the healthy foot. The screw connection is the basis for the dynamics of the foot.

The spiral lacing takes this principle into account and adds a reinforcing reinforcement to the outside that corresponds to the construction principle of the foot. This spiral lacing has proven to be a very effective reinforcement and armouring.

At least one of the upper bridge arches can have a reinforcement in the area of the instep, in the longitudinal direction of the shoe construction, wherein the reinforcement, which extends below the lower bridge arch, is fixed to this upper bridge arch.

According to a further embodiment of the shoe construction according to the invention, the lacing can be formed from at least one lacing wire, wherein the at least one lacing wire is arranged and laced so as to run over a small wheel.

In this context, reference is made to the so-called Boa system, which is still quite new on the market. The shoe is laced by turning a wheel over which a thin steel cable runs. With this system, the lacing can be adjusted very precisely, which prevents pressure points. Re-lacing is not necessary, the lacing remains the same tightness all day long. The disadvantage of the system is mainly the higher price.

Alternatively, it can also be provided that the lacing is formed from at least one lacing wire, and that the at least one lacing wire is fixed to the upper bridge arch by a lacing pin.

In the following, the fastening means according to the invention will be explained in more detail using exemplary embodiments and the accompanying drawings.

Fig. 1a:

eine schematische Darstellung der erfindungsgemäßen Schuhkonstruktion als Brückenbodenkonstruktion gemäß einem ersten Ausführungsbeispiel,

Fig. 1b:

eine schematische Darstellung eines Ausschnittes der erfindungsgemäßen Schuhkonstruktion in Form einer Fersengabel,

Fig. 1 c:

eine schematische Darstellung der erfindungsgemäßen Schuhkonstruktion als Brückenbodenkonstruktion gemäß einer Variante des ersten Ausführungsbeispiels mit einem ringförmigen Fersenabschluss,

Fig. 2:

eine schematische Darstellung der erfindungsgemäßen Schuhkonstruktion als Brückenbodenkonstruktion gemäß einem zweiten Ausführungsbeispiel,

Fig. 3:

eine schematische Darstellung der erfindungsgemäßen Schuhkonstruktion als Brückenbodenkonstruktion gemäß einem dritten Ausführungsbeispiel,

Fig. 4:

eine Aufsicht auf eine Schuhkonstruktion nach einem der vorhergehenden Ausführungsbeispiele,

Fig. 5:

einen Schuh, enthaltend eine Schuhkonstruktion nach einem der vorhergehenden Ausführungsbeispiele,

Fig. 6:

eine Ansicht einer Variante einer Armierung für eine Schuhkonstruktion nach einem der vorhergehenden Ausführungsbeispiele.

They show:

Fig. 1a:

a schematic representation of the shoe construction according to the invention as a bridge floor construction according to a first embodiment,

Fig. 1b:

a schematic representation of a section of the shoe construction according to the invention in the form of a heel fork,

Fig. 1c:

a schematic representation of the shoe construction according to the invention as a bridge bottom construction according to a variant of the first embodiment with an annular heel closure,

Fig. 2:

a schematic representation of the shoe construction according to the invention as a bridge floor construction according to a second embodiment,

Fig. 3:

a schematic representation of the shoe construction according to the invention as a bridge floor construction according to a third embodiment,

Fig.4:

a plan view of a shoe construction according to one of the preceding embodiments,

Fig.5:

a shoe comprising a shoe construction according to one of the preceding embodiments,

Fig.6:

a view of a variant of a reinforcement for a shoe construction according to one of the preceding embodiments.

In Fig. 1a a shoe construction according to the invention is shown according to a first embodiment and is designated overall by the reference number 1. Fig. 1a a shaft 3 can be seen, which in the example is made of leather. The term shaft 3 refers to the usual term for conventional shoe constructions, in which the shaft 3 is a general term for the upper part of a shoe. This shaft 3 does not necessarily have to be made of leather. Other materials, breathable textile membranes such as Gore Tex ^® , textiles of various types, natural materials such as cotton or synthetic fibers, composite materials and structures, solid plastic bodies or carbon fiber bodies can also be selected as shaft materials, although this list is merely exemplary.

Basically, however, this shaft 3 is constructed differently than is the case with conventional shoe constructions. The shoe construction 1 according to the invention comprises a frame and a holding area, with the shaft 3 forming the frame area, which is divided into a forefoot section 5 and a heel section 7 and is designed in the form of an arched bridge 8 that extends between the forefoot section 5 and the heel section 7. On both sides of the respective foot, the shaft 3 has a lower bridge arch 9 and an upper bridge arch 11. In this case, the designation as a bridge arch 11 is not to be understood as being limited to an arched construction with regard to the shape. In particular, the upper bridge arch 11 can have a substantially straight end instead of an arched one and can also be angular. It is essential that the upper bridge arch 11 is guided in the direction of the imaginary instep of the foot. The bridge arch construction extends essentially in the area of the forefoot section 5, with the lower bridge arch 9 extends in the area of the imaginary longitudinal arch 12 of the foot.

A reinforcement extends to below the lower bridge arch 9, spans the longitudinal arch 12 of the foot and is fixed in the area of the upper bridge arch 11 according to this embodiment. The reinforcement is again designed in this embodiment in the form of a lacing 13. Other forms of reinforcement are also possible. The lacing 13 is guided in an opposite arch shape to the lower bridge arches 9 formed on both sides of the foot. It can consist very simply of laces, such as those used for hiking shoes and mountain boots. However, it should be pointed out again that the reinforcement is not limited to the lacing 13 or to the laces as a design of the lacing 13, but can be achieved in a variety of ways. In one variant, the lacing can be made of wide bands. For example, bands with a width of up to 3 cm were used. In particular, the bands can be designed as leather bands. As an alternative to leather bands, bands made of synthetic leather or plastic can be used.

The lacing 13 in the form of laces or lacing wires used as reinforcement in the exemplary embodiment is wound in a spiral shape around the foot, i.e. the sole of the foot. This winding results in a particularly stable lacing 13. The natural arch of the foot is supported by the laces or wires and thus the foot being raised to the stable reinforcement in the form of the arched bridge 8.

The arched bridge 8 is designed in such a way that it extends from the heel bone of the foot to the metatarsophalangeal joints of the big toe and little toe. The arched bridge is anchored here by connecting one and the other of the sides of the foot, while the foot is exposed in the area of the lower bridge base 9 and is only held in place by the reinforcement, ie here the lacing 13, if desired or required by the design of the shoe or dictated by fashion.

In order to be able to adapt the reinforcement, i.e. here the lacing 13, to the respective foot shape and to hold it in the area of the arch of the foot, the lifting to the stable stiffening in the form of the arch bridge 8 must be done individually. Therefore, the shoe construction also includes a mechanism for winding up the lacing 13. This mechanism, which is still to be explained, can be attached to the upper bridge arch 11 or in the area of the upper bridge arch 11. In the example, the lacing 13 is made possible by a lacing pin 15.

Lacing pins are well known in the shoemaking industry. They are essentially a tubular bent sheet metal strip that is attached to the end of a cord, in this case the laces of the lacing 13, and thus enables winding.

The winding causes the foot to hang and thus to straighten it into a natural position, which corresponds to a natural pre-tension of the arch of the foot, which a foot that is not yet deformed or degenerated shows.

As an alternative to the lacing pin 15, the lacing 13 is regulated according to a variant of this embodiment via a rotary wheel not separately shown in the figures and is adjusted to the required circumference.

In this case, a wire lace is used and tightened using a tensioning element, such as a wheel. It can then be loosened again with a single movement. The hanging and thus straightening of the foot via the arch of the foot into its natural position, and thus the pre-tension, is then achieved using the aforementioned rotary wheel as an adjustment wheel.

This prevents the foot from sinking. The lacing 13 takes every possible foot anatomy into account, and an existing misalignment can also be absorbed and at least stabilized, if not at least partially reversed. In addition, the tensioning element can be used to adjust the desired pre-tension of the reinforcement. In other words, the support can be regulated as desired by the person depending on the intended use.

Regardless of whether the mechanism for winding up the lacing 13 is placed directly on the upper bridge arch 11 or in the area of the upper bridge arch 11, it requires reinforcement there, which in the exemplary embodiment is incorporated as additional stiffening in the cover sheet of the shoe to be manufactured. For the sake of explanation, it should be noted that the upper of a shoe consists of several interconnected layers, with the area of the inner upper essentially being described here. This is connected to an outer upper, possibly via an intermediate upper. The connection can be made, for example, by sewing or gluing. The cover sheet mentioned is assigned to the outer upper.

In this case, the mechanism for winding the lacing 13 is located in the area of the upper bridge arch 11, not on it itself. An example of this is the design as Fig. 1c it shows. Both alternatives are to be regarded as equivalent in terms of their inventive success.

In the area of the heel 17, the shoe construction according to the invention encloses the foot, but leaves the heel 17 free as a problem area that must be protected from pressure. The area of the heel 17 can be designed differently within the scope of the shoe construction according to the invention. On the one hand, the shoe construction can have a fork-shaped design in the form of a heel fork 19. This heel fork 19 is formed approximately X-shaped, as in Fig. 1b illustrated in sections and thus separately.

The heel fork 19 in the area of the heel 17 can additionally cooperate with a support of the shoe construction in a lower section of the respective leg 21. The support of the shoe construction is designed according to one embodiment as a support sleeve 25. The heel fork 19 ends approximately above a respective ankle 23 of the leg 21 and is connected to the support sleeve 25 in one piece or in several pieces, e.g. by sewing. The said support sleeve 25 is made of Fig. 1a not apparent. It is in Fig. 1c shown.

However, no heel fork 19 has to be provided in the design, but rather an approximately ring-shaped heel end 27 can be formed, which leaves the heel 17 free and unloaded by pressure through the ring-shaped recess. An alternative form of the heel end 27 is formed approximately Y-shaped, as in Fig.2 shown.

In a further development of the shoe construction according to the invention, as Fig.2 shows, this comprises a modified guide of the bridge construction and is not only additionally continued in the area of the forefoot section 5 with the toes 29, but in such a way that a sole section 33 is also added in the area of the heel 17.

In this second embodiment of the shoe construction 100, features that correspond to the first embodiment described so far are given the same reference numbers, but extended by 100. The forefoot section mentioned is now given the reference number 105 and has the toes 129, and in the area of the heel 117, Fig.2 the sole section 133 was added.

Also according to the Fig.2 In the third embodiment of the shoe construction 100 according to the invention shown, the shaft 103 forms the frame area, which is divided into a forefoot section 105 and a heel section 107 and is designed in the form of an arched bridge 108 that extends between the forefoot section 105 and the heel section 107. On both sides of the respective foot, the shaft 103 has a lower bridge arch 109 and an upper bridge arch 111. In this case, the designation as bridge arch 111 is not to be understood as being limited to an arched construction with regard to the shape. In particular, the upper bridge arch 111 can have a substantially straight end instead of an arched one and can also be angular. It is essential that the upper bridge arch 111 is guided in the direction of the imaginary instep of the foot. The bridge arch construction extends essentially in the area of the forefoot section 105, whereby the lower bridge arch 109 extends in the area of the imaginary longitudinal arch 112 of the foot.

Basically, the arched bridge 108 representing the shaft 103 is modified from the first embodiment in that the lower bridge arches 109 and upper bridge arches 111 located on both sides of the respective foot are narrower than in the first embodiment. This is due to the fact that the upper bridge arch 111 is only guided towards, but not completely up to, the imaginary instep of the foot. The lower bridge arch 109 extends in the area of the imaginary longitudinal arch of the foot.

The reinforcement extends to below the lower bridge arch 109 and, according to this embodiment, is fixed above the upper bridge arch 111 and is again designed in the form of a lacing 113. The lacing 113 is guided in an opposite arc shape to the lower bridge arches 109, 111 formed on both sides of the foot. It again consists in a very simple manner of laces, such as those used for hiking shoes and mountain boots. However, it should be pointed out again that the reinforcement is not limited to the lacing 113 and not to the laces as an embodiment of the lacing 113, but can be achieved in a variety of ways in order to enable the support of the longitudinal arch of the foot developed according to the invention.

In order to adapt the reinforcement in the form of the lacing 113 to the respective foot shape and to be able to hold the foot in the area of the arch, the lifting to the stable stiffening in the form of the arched bridge 108 is also carried out via a mechanism for winding up the lacing 113, which is arranged above the upper bridge arch 111. A lacing pin 115 is used for winding up. Other mechanisms that fulfill the purpose of winding up or dropping are also possible.

In the area of the heel 117, the shoe construction 100 according to the invention does not enclose the foot, as is still provided in the first embodiment. Here, the area of the heel 117 remains free and the arched bridge 108 is instead guided approximately to the point where the heel 117 rests on the ground, where it ends in a sole 133.

Yet another development of the shoe construction 200 according to the invention according to a third embodiment is shown in Fig.3 In this embodiment, features that correspond to those described so far are given the same reference numbers, but with 200 additional reference numbers.

In Fig.3 For the sake of simplicity, the reinforcement in the form of the lacing and thus also the lacing pin were omitted. The training according to Fig.3 This results from the fact that the shoe construction in the area of the forefoot, which includes the toes 229, is continued in a very stable construction, so that a sole section 231 is created in the area of the forefoot, on which the toes 229 are supported, as is already the case for the variant according to Fig.2 is intended.

The construction as it Fig.3 This is particularly advantageous if the shoe is intended for a foot that has a hallux valgus, a pathological misalignment of the big toe in which the metatarsophalangeal joint of the big toe deviates towards the outer edge of the foot and thus laterally.

This problem area, which is often perceived as painful and can also be described as a neuralgic point, is left out in the shoe construction according to the invention, as Fig.3 illustrated, and thus a pressure point is omitted.

In the area of the heel 217, an X-shaped heel fork 219, which forms a ring-shaped heel end, or alternatively an approximately Y-shaped heel fork can be used in an equivalent manner.

Also according to the Fig.3 In the third embodiment of the shoe construction 200 according to the invention shown, the shaft 203 forms the frame area, which is divided into a forefoot section 205 and a heel section 207 and is designed in the form of an arched bridge 208 which extends between the forefoot section 205 and the heel section 207. On both sides of the respective foot, the shaft 203 has a lower bridge arch 209 and an upper bridge arch 211. In this case, the designation as bridge arch 211 is not to be understood as being limited to an arched construction with regard to the shape. In particular, the upper bridge arch 211 can have a substantially straight end instead of an arched one and can also be angular. It is essential that the upper bridge arch 211 is guided in the direction of the imaginary instep of the foot. The bridge arch construction extends essentially in the area of the forefoot section 205, with the lower bridge arch 209 extending in the area of the imaginary longitudinal arch 212 of the foot.

Basically, the arched bridge 208 representing the shaft 203 is modified from the first embodiment in that the lower bridge arches 209 and upper bridge arches 211 located on both sides of the respective foot are narrower than in the first embodiment. This is due to the fact that the upper bridge arch 211 is only guided towards, but not completely up to, the imaginary instep of the foot. The lower bridge arch 209 extends in the area of the imaginary longitudinal arch of the foot.

The reinforcement extends below the lower bridge arch 209 and, according to this embodiment, is fixed above the upper bridge arch 211 and can be designed in the form of lacing. The lacing is guided in an arc in the opposite direction to the lower bridge arches 209, 211 formed on both sides of the foot. It again consists in a very simple manner of laces, such as those used for hiking shoes and mountain boots. However, it should be pointed out again that the reinforcement is not limited to the lacing and not to the laces as the design of the lacing, but can be effected in a variety of ways in order to achieve the inventive developed to enable support of the longitudinal arch 212 of the foot.

Fig.4 shows the top view of a shoe construction according to one of the first, second or third embodiments, for which the reference numerals are to be used as examples which are already in Fig.3 has been used. The Fig.4 The reinforcement shown is formed by a lacing 213, which is tightened by means of a lacing pin 215. The lacing pin can be rotatably mounted on the forefoot section 205 and/or on the heel section 207. The lacing wraps around the upper bridge arches 211 and lower bridge arches 209, as for example in Fig.3 was shown. The lacing pin 215 can absorb tensile forces that act on the lacing pin 215 through the lacing 213 when the foot is loaded. The foot is supported by the lacing 213 so that its arch structure is maintained even under long-term loading. By means of the lacing, which works together with the arch bridge 208, a sinking of the arch of the foot when the foot muscles become tired can be prevented and thus misalignment of the foot can be prevented.

Fig.5 shows a view of a shoe which contains a shoe construction according to one of the preceding embodiments. The closing element shown as a buckle can, in the closed state, prestress a reinforcement (not shown) according to one of the preceding embodiments in accordance with the arch structure of the foot, so that the advantages of the shoe construction according to the invention can be achieved.

Fig.6 shows a view of a variant of a reinforcement for a shoe construction according to one of the preceding embodiments.

In Fig.6 a shoe construction according to the invention is shown according to a fourth embodiment and is designated overall by the reference number 300. As in the previous embodiments, an upper 303 is visible, the upper 303 generally designating the upper part of a shoe as a generic term.

The shoe construction 303 according to the invention comprises a frame region and a holding region, wherein the shaft 303 forms the frame region, which is divided into a forefoot section 305 and a heel section 307 and is designed in the form of an arched bridge 308 that extends between the forefoot section 305 and the heel section 307. On both sides of the respective foot, the shaft 303 has a lower bridge arch 309 and an upper bridge arch 311. In this case, the designation as bridge arch 311 is not to be understood as being limited to an arched construction with regard to the shape. In particular, the upper bridge arch 311 can have a substantially straight end instead of an arched one and can also be angular. It is important that the upper bridge arch 311 is guided in the direction of the imaginary instep of the foot. The bridge arch construction extends essentially in the area of the forefoot section 305, whereby the lower bridge arch 309 extends in the area of the imaginary longitudinal arch 312 of the foot.

A reinforcement extends to below the lower bridge arch 309, spans the longitudinal arch 312 of the foot and is fixed in the area of the upper bridge arch 311 according to this embodiment. In this embodiment, the reinforcement is designed as lacing 313 in the form of a flexible band element. Other forms of reinforcement are also possible. The lacing 313 is guided in an arc in the opposite direction to the lower bridge arches 309 formed on both sides of the foot. It can consist very simply of laces, such as those used for hiking shoes and mountain boots. However, it should be pointed out again that the reinforcement is not limited to the lacing 313 and not to the laces as an embodiment of the lacing 313, but can be achieved in a variety of ways.

The lacing 313 in the form of laces or lacing wires used as reinforcement in the embodiment is guided in several tracks around the foot, ie the sole of the foot. The lacing 313 comprises a winding which is attached to a rotating element 315, by means of which the lacing 313 can be put into a tensioned state. By actuating The length of the lacing 313 can be changed by means of the rotary element. For this purpose, the lacing contains ends that are fixed to the rotary element. When the rotary element is subjected to a rotary movement, the lacing is either wound up on the rotary element, thus pre-tensioning the sole, or unwound so that the pre-tension is released and the shoe can be taken off. The rotary element can be locked in any position so that the pre-tension of the lacing 313 can be adapted to the desired area of use of the shoe. The natural arch of the foot is supported by the lacing straps or lacing wires, and thus the foot, being raised to the stable stiffener in the form of the arched bridge 308.

The arched bridge 308 is designed in such a way that it extends from the heel bone of the foot to the metatarsophalangeal joints of the big toe and the little toe. The arched bridge is anchored here by connecting one and the other of the sides of the foot to each other, while the foot is exposed in the area of the lower bridge floor 309 and is only held in place by the reinforcement, i.e. here the lacing 313.

In order to be able to adapt the reinforcement to the respective foot shape and to hold it in the area of the arch of the foot, the sole can be raised and stably stiffened in the form of the arch bridge 308. Therefore, the shoe construction also includes a mechanism for winding up the lacing 313 in the form of the rotating element. The rotating element 315 is rotatably attached to a tab that connects the two bridge arches 308 on each side of the foot as well as the forefoot section and the heel section. The tab can be designed as a shell element, for example. The tab can be attached to the upper bridge arch 311 or in the area of the upper bridge arch 311. Winding up the lacing 313 causes the foot to hang up and thus straighten it up into a natural position that corresponds to a natural pre-tension of the arch of the foot, which a foot that is not yet deformed or degenerated shows.

According to this embodiment, the pre-tension of the lacing 313 can be regulated via a rotary element 315 designed as a rotary wheel and can be adjusted to the required extent.

In this case, a wire lace can be used to advantage, which can be tightened using the rotary element or a wheel element connected to it. The pre-tension can then be released again with a single movement. The hanging and thus straightening of the foot via its arch into its natural position, and thus the desired pre-tension, is then achieved using the rotary wheel as an adjustment wheel.

This prevents the foot from sinking. The lacing 313 takes every possible foot anatomy into account, and an existing misalignment can also be caught and at least stabilized, if not at least partially reversed.

Regardless of whether the mechanism for winding up the lacing 313 is applied directly to the upper bridge arch 311 or in the area of the upper bridge arch 311, it requires reinforcement there, which in the exemplary embodiment is incorporated as additional stiffening in the cover sheet of the shoe to be manufactured. For the sake of explanation, it is pointed out that the upper 303 of a shoe can consist of several interconnected layers, with the area of the inner upper essentially being described here. This is connected to an outer upper, possibly via an intermediate upper. The connection can be made, for example, by sewing or gluing. The cover sheet mentioned can in particular be designed as a tab and, according to this definition, is to be assigned to the outer upper.

The mechanism for winding the lacing 313 can be located in the area of the upper bridge arch 311, not on it itself, as Fig. 1c Both alternatives are to be regarded as equivalent in terms of their inventive success.

In the area of the heel 317, the shoe construction according to the invention encloses the foot, but can use the heel 317 as a problem point to be protected from pressure free, as shown in the previous embodiments. The area of the heel 317 can be designed differently within the scope of the shoe construction according to the invention. On the one hand, the shoe construction can have a fork-shaped design in the form of a heel fork. This heel fork is formed approximately X-shaped, as in Fig. 1b illustrated in sections and thus separately.

The heel fork in the area of the heel 317 can also cooperate with a support of the shoe construction in a lower section of the respective leg. According to one embodiment, the support of the shoe construction is designed as a support cuff 325. The heel fork ends approximately above a respective ankle 323 (shown schematically in dashed lines) of the leg and can be connected to the support cuff 325 in one piece or in several pieces, e.g. by sewing.

With reference to all previously explained embodiments, a modification will now be explained, which is not shown again with an additional figure. This modification is possible for all previously shown and explained shoe constructions, for illustration purposes the corresponding reference numerals of Fig.3 or Fig.4 used.

Here too, the reinforcement extends below the lower bridge arch, encircles the longitudinal arch 212 of the foot, but according to this modification is not fixed in the area of the upper, but in the area of the lower bridge arch 209. The reinforcement is again in the form of a lacing 213 in this embodiment. Other forms of reinforcement are also possible. The lacing 213 is guided in an opposite arch shape to the lower bridge arches 209 formed on both sides of the foot and each of the arches is attached to the lower bridge arch 209. In contrast to the previous embodiments, a mechanism for winding up the lacing is omitted here.

The arched bridge 208 is again designed in such a way that it extends from the heel bone of the foot to the metatarsophalangeal joints of the big toe and little toe. The anchoring of the arched bridge 208 takes place here by connecting one and the other of the sides of the foot to each other, while the foot is exposed in the area of the lower bridge floor 209 and is only held in place by the reinforcement, i.e. here the lacing 213.

Claims (10)

Shoe construction (1, 100, 200, 300) containing a frame and holding area which comprises a forefoot section (5, 105, 205, 305) and a heel section (7, 107, 207, 307) and is designed in the form of an arched bridge (8, 108, 208, 308) which extends between the forefoot section and the heel section, wherein the arched bridge comprises a lower bridge arch (9, 109, 209, 309) formed on both sides of the foot and an upper bridge arch (11, 111, 211, 311), wherein the upper bridge arch is guided in the direction of the imaginary instep of a foot and the lower bridge arch extends in the region of the imaginary longitudinal arch (12, 112, 212, 312) of the foot, so that a reinforcement which extends below the lower bridge arch, is fixed to the lower bridge arch or in the area of the upper bridge arch. Shoe construction according to claim 1, characterized by a reinforcement in the form of a lacing (13, 113, 213, 313), wherein the lacing is guided in an opposite arc shape to the lower bridge arches formed on both sides of the foot. Shoe construction according to claim 2, characterized in that the lacing is formed from lacing bands or lacing wires which are guided in a spiral shape. Shoe construction according to one of claims 1 to 3, characterized in that at least one of the upper bridge arches has a reinforcement in the region of the instep, in the longitudinal direction of the shoe construction, and that the reinforcement, which extends below the lower bridge arch, is fixed to this upper bridge arch. Shoe construction according to one of the preceding claims, characterized in that the reinforcement contains a tensioning element. Shoe construction according to one of the preceding claims, characterized in that the tensioning element contains an element from the group consisting of a lacing pin (13, 113, 213) or a rotary element (313). Shoe construction according to one of claims 5 or 6, characterized in that the pre-tension of the lacing can be adjusted by means of the tensioning element. Shoe construction according to one of claims 5 to 7, characterized in that the lacing is formed from at least one lacing wire or one lacing band, and that the at least one lacing wire or the at least one lacing band is arranged and laced so as to run over the tensioning element. Shoe construction according to one of claims 2 to 7, characterized in that the lacing is formed from at least one lacing wire or one lacing band, and that the at least one lacing wire or the at least one lacing band is fixed to the upper bridge arch by a lacing pin. A shoe comprising a shoe construction according to any one of the preceding claims.

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