阅读说明：本技术 用于鞋的鞋底 (Sole for shoes ) 是由 黎素友 安格斯·沃德洛 德克·梅泰勒 斯图尔特·大卫·莱恩哈特 达伦·迈克尔·伍德 查尔斯 于 2016-03-23 设计创作，主要内容包括：本发明描述具有鞋底夹层的用于鞋、特别是运动鞋的鞋底。鞋底夹层包括第一鞋底区域,其包括颗粒泡沫。鞋底夹层还包括鞋底夹层内的变形区,其中,所述变形区的体积比单个膨胀颗粒的体积更大,并定位成在鞋底被施压的情况下,第一鞋底区域的材料能够发生侧向变形。(The invention describes a sole for a shoe, in particular a sports shoe, having a midsole. The midsole includes a first sole region that includes a granular foam. The midsole further includes a deformation zone within the midsole, wherein the deformation zone has a volume greater than a volume of the individual expanded particles and is positioned such that the material of the first sole region is capable of lateral deformation under compression of the sole.)

1. A sole with a midsole, wherein the midsole comprises:

a first sole region comprising a granular foam; and

a deformation zone located proximate to the first sole region, wherein the deformation zone comprises a volume greater than a volume of an individual expanded particle of the granular foam and is configured such that the foam granules of the first sole region are deformable upon application of pressure to the sole.

2. The sole of claim 1, wherein the deformation is in a lateral direction.

3. The sole of claim 1, wherein the deformation zone is at least partially provided as an empty space.

4. A sole as recited in claim 1, wherein the midsole further includes a control element that limits deformation of the granular foam of the first sole region.

5. The sole of claim 4, wherein the control element includes at least a portion of the deformation zone.

6. The sole of claim 4, wherein the control element comprises a groove.

7. A sole according to claim 4, wherein the control element at least partially circumscribes a side of the first sole region.

8. The sole of claim 4, wherein the control element is free of particles of the particulate foam.

9. The sole of claim 1, wherein the deformation zone comprises a material capable of yielding to the deformation of the material of the first sole region.

10. The shoe sole of claim 9, wherein the yielding material has a deformation stiffness that is 5% -40% greater than the deformation stiffness of the first sole region.

11. A shoe having a sole according to claim 1.

12. The shoe sole of claim 1, further comprising:

a second sole region comprising a granular foam and providing a progressively increasing deformation stiffness in at least one predetermined direction.

13. The sole of claim 12, wherein the increase in deformation hardness is due at least in part to an increase in density of the granular foam of the second sole region in the at least one predetermined direction.

14. The sole of claim 12, wherein the at least one predetermined direction extends from a medial side of the sole toward a lateral side of the sole.

15. The sole of claim 12, wherein the deformation stiffness in the second sole region increases less in the area of the second sole region where impact occurs and more on the opposite side.

16. The sole of claim 15, wherein the second sole region slopes inwardly at least toward the impact region due to greater compression of the second sole region in the impact region.

17. The sole of claim 1, wherein at least one of the shape, size, and location of the deformation zone provides a desired property for the deformation zone.

18. A sole as recited in claim 12, wherein the first sole region extends into a forefoot region, wherein the second sole region extends into a heel region.

19. A sole as claimed in claim 12, wherein the first sole region and the second sole region are at least partially coincident.

20. Sole, it includes:

a midsole comprising a first sole region, wherein the first sole region comprises a granular foam;

a deformation zone within the midsole, the deformation zone comprising a volume greater than a volume of a single expanded particle positioned such that the foam particles of the first sole region are capable of lateral deformation when the sole is pressurized; and

a frame element at least partially surrounding the midsole and limiting the lateral deformation of the midsole if the sole is pressurized.

21. The sole of claim 20, wherein the frame element completely surrounds sides of a heel region and the frame element only partially surrounds sides of a forefoot region.

22. The sole of claim 20, wherein the frame member further includes a support member, wherein the support member is disposed on a lateral side of the heel region.

23. A sole as recited in claim 20, wherein the midsole further includes a control element that limits lateral deformation of the granular foam of the first sole region.

24. A sole according to claim 23, wherein the control element and the frame element at least partially coincide.

25. A sole as claimed in claim 20, wherein the frame element includes at least one rod for securing the frame element to the midsole.

26. A sole as in claim 25, wherein the at least one rod is at least partially surrounded by the granular foam of the midsole.

27. Sole, it includes:

a midsole comprising particles of a particulate foam; and

an outsole including at least one deformation zone comprising a volume greater than a volume of an individual expanded particle of the particulate foam;

wherein the at least one deformation zone is configured such that at least a portion of the granular foam of the midsole is deformable when the sole is pressurized;

wherein the outsole limits the deformation of the midsole under pressure of the sole.

Technical Field

The invention relates to a sole for a shoe, in particular for a sports shoe, and to a shoe with such a sole.

Background

In the manner of a sole, a shoe may be provided with various possible characteristics, which may, depending on the particular type of shoe, achieve different degrees of different characteristics. For example, a sole may prevent excessive wear of the shoe through its increased wear resistance. In addition, the sole is typically used for protective purposes, e.g., to protect the foot of the wearer from sharp or pointed objects stepped on by the wearer.

To further prevent injury to the wearer or overtraining of the wearer's musculoskeletal system, the sole may also provide improved stability against impact forces on the wearer's foot and against the ground. The sole may also provide increased grip of the shoe on the ground to facilitate agile movement and change of direction. There is a strong demand, in particular, for stability, grip and cushioning of lateral movements, such as tennis and basketball.

Summary of The Invention

The terms "invention," "present invention," "this invention," and "the invention" as used in this patent application broadly refer to the subject matter of this patent and the claims that follow. Statements containing these terms should not be understood to limit what is described herein or to limit the meaning or scope of the claims below. Embodiments of the invention covered by this patent are defined by the appended claims, not by the summary of the invention. This summary is a high-level overview of various embodiments of the invention, and it also introduces some concepts that are further described below in the detailed description section. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used alone to determine the scope of the claimed subject matter. The subject matter should be understood by reference to the entire specification of this patent, any or all of the drawings, and appropriate portions of the claims.

The term "particulate foam" is used herein to refer to the form of expanded polymeric particles. The particulate foam comprises a foamed material. Reference may be made to particulate foams by those skilled in the art, such as "beads", "bead foam", "foam beads" and/or other products known in the art.

The term "particulate foam component" is used herein to refer to a component made from particulate foam. The particulate foam component may comprise a particulate foam of one or more foaming materials. In some embodiments, the particles of the particulate foam and/or any combination thereof in the component made from the particulate foam may be randomly arranged.

The term "intumescent material" is used herein to refer to a material that has been foamed to form a particulate foam.

The term "deformation" is used herein to refer to movement of a material under load.

Certain embodiments of the present invention include a sole having a midsole. The midsole may include a first sole region comprising a granular foam, and a deformation region proximate the first sole region, wherein the deformation region is larger in volume than a single expanded granule of the granular foam and is configured to allow deformation of the granular foam of the first sole region under pressure loading of the sole.

In some embodiments, the deformation direction is sideways. The deformation zone may be provided at least partially for an empty space.

The term "particulate foam component" is used herein to refer to a component made from particulate foam. The particulate foam component may comprise one or more expanded material particulate foams. In some embodiments, the particulate foam particles in making the component from the particulate foam may be randomly arranged, aligned, and/or any combination thereof.

The term "expanded material" is used herein to mean that this is foamed to form a particulate foam material.

The term "deformation" is used herein to refer to the load of movement of a material.

Certain embodiments of the present invention include a sole having a midsole. The midsole may include a first sole region comprising the granular foam, and a deformation zone located proximate the first sole region, wherein the deformation zone has a volume greater than a volume of a single expanded granule of the granular foam and is configured to enable deformation of the granular foam of the first sole region if the sole is pressurized.

In some embodiments, the deformation direction is lateral. The deformation zone may be provided as an empty space.

The increase in deformation stiffness is due, at least in part, to the density of the granular foam in the second sole region increasing in at least one predetermined direction. In some embodiments, the at least one predetermined direction extends from the medial side of the sole toward the lateral side of the sole.

The increase in deformation stiffness in the second sole region increases less in the impact region and more on the opposite side in the second sole region. In these embodiments, at least the second sole region slopes inwardly toward the impact region due to the greater compression in the impact region in the second sole region. At least one of the shape, size, and location of the deformation zone provides a predetermined characteristic to the deformation zone.

In accordance with some embodiments, the first sole region extends into the forefoot region and the second sole region extends into the heel region. The first sole region and the second sole region may at least partially coincide.

In some embodiments according to the invention, the sole comprises a midsole comprising a first sole region, wherein the first sole region comprises a granular foam, a deformation zone located within the midsole, wherein the deformation zone has a volume greater than a volume of a single expanded granule, and is positioned such that the granular foam of the deformation zone is capable of lateral deformation when the sole is pressurized, and a frame element at least partially surrounding the midsole and limiting lateral deformation of the midsole when the sole is pressurized.

In some embodiments, the frame element completely surrounds the sides of the heel region and is only partially contained on the sides of the forefoot region. The frame element may further comprise a support element, wherein the support element is arranged at the lateral side of the heel region.

In some embodiments, the midsole further includes a control element that limits lateral deformation of the granular foam of the first sole region. The control element and the frame element may at least partially coincide.

In some embodiments, the frame element includes at least one rod for securing the frame element to the midsole. The at least one rod may be at least partially surrounded by the granular foam of the midsole.

According to some embodiments of the invention, the sole comprises: a midsole comprising particles of a particulate foam, an outsole comprising at least one deformation zone, the deformation zone having a volume greater than a volume of an individual expanded particle of the particulate foam, wherein the at least one deformation zone is configured such that at least a portion of the particulate foam of the midsole deforms when the sole is pressurized, and wherein the outsole limits deformation of the midsole when the sole is pressurized.

Detailed description of the drawings

In the following detailed description, various embodiments of the invention will be described with reference to the following drawings:

FIG. 1 is a view of a sole of a shoe without deformation zones, according to some embodiments of the present invention.

Figures 2a-2h are views of a sole of a shoe including deformation zones, according to some embodiments of the present invention.

FIG. 3 is a diagram illustrating the concept of a "tilting midsole" to relieve tension at the ankle, according to some embodiments of the invention.

FIG. 4 is a view of a sole of a shoe that employs the principles of inclination of FIG. 3, according to some embodiments of the present invention.

Figure 5 is an exploded view of a sole including a frame member according to some embodiments of the present invention.

Figure 6 is a view of a sole including a frame member according to some embodiments of the present invention.

Fig. 7 is an exploded view of a shoe including a sole, according to some embodiments of the present invention.

Figures 8-14 are views of a shoe including a sole, according to some embodiments of the present invention.

Fig. 15A is a top view of a midsole according to some embodiments of the invention including a first sole region and a first sole portion including a lattice structure.

Fig. 15B is a bottom view of the midsole of fig. 15A.

Figure 15C is a cross-sectional view of the midsole of figure 15A taken along line A-A.

Figure 15D is a cross-sectional view of the midsole of figure 15A taken along line B-B.

Figure 15E is a cross-sectional view of the midsole of figure 15A taken along line C-C.

Figure 15F is a cross-sectional view of the midsole of figure 15A taken along line D-D.

Figure 15G is a cross-sectional view of the midsole taken along line E-E of 15A.

Figure 15H is a medial view of the midsole of figure 15A.

Figure 15I is a side view of the midsole of figure 15A.

Figure 15J is a medial view of a midsole embodiment similar to the midsole shown in figure 2.

Fig. 15K is an enlarged perspective view of the midsole of fig. 15J.

Figure 16 is a perspective view of a sole component according to certain embodiments of the present invention.

FIG. 17 is a bottom view of a sole portion of a footwear piece, according to some embodiments of the invention.

FIG. 18 is a bottom view of a sole portion of a footwear piece, according to some embodiments of the invention.

FIG. 19 is a side view of a shoe having a granular foam midsole and an outer sole portion, according to certain embodiments of the invention.

FIG. 20 is a side view of a shoe having a granular foam midsole and an outer sole portion according to certain embodiments of the invention.

FIG. 21 is a side view of a shoe having a granular foam midsole and an outer sole portion according to certain embodiments of the invention.

FIG. 22 is a side view of a shoe having a granular foam midsole and an outer sole portion according to certain embodiments of the invention.

FIG. 23 is an exploded side perspective view of a sole having a granular foam midsole, a reflective layer, and an outer sole portion, according to certain embodiments of the present invention.

FIG. 24 is an exploded side perspective view of a sole having a granular foam midsole, a reflective layer, and an outer sole portion, according to certain embodiments of the present invention.

Fig. 25 is a side view of a soccer shoe having a particle foam sole sandwich wall, according to certain embodiments of the present invention.

Fig. 26 is a side view of a soccer shoe having a particle foam sole sandwich wall, according to certain embodiments of the present invention.

Fig. 27 is a side view of a frame member according to some embodiments of the invention.

Fig. 28 is a side view of a frame member according to some embodiments of the invention.

Fig. 29 is a rear view of the frame member of fig. 28.

FIG. 30 is an exploded perspective side view of a first sole portion and a first sole region, according to some embodiments of the invention.

Figure 31 is a bottom perspective view of a first sole portion and a first sole region joined together, according to some embodiments of the present invention.

Fig. 32 is a cross-sectional view of the interior of a soccer shoe, according to some embodiments of the present invention.

Figure 33 is an exploded perspective side view of an upper portion, a first sole region and a first sole component according to some embodiments of the present invention.

Figure 34 is an exploded perspective side view of an upper portion, a first sole region and a first sole component according to some embodiments of the present invention.

Fig. 35 is a cross-sectional view of the interior of a soccer shoe, according to some embodiments of the present invention.

Fig. 36 is a side view of an upper of a soccer shoe, according to some embodiments of the present invention.

Fig. 37 is a side view of an upper of a soccer shoe, according to some embodiments of the present invention.

Fig. 38 is a bottom view of an upper of a soccer shoe, according to some embodiments of the present invention.

Fig. 39 is a side view of a soccer shoe according to some embodiments of the present invention.

Fig. 40 is an upper perspective view of the soccer shoe of fig. 39.

Fig. 41 is a bottom view of a frame element of a soccer shoe, according to some embodiments of the present invention.

Fig. 42 is a bottom view of a frame element of a soccer shoe, according to some embodiments of the present invention.

Fig. 43A-C are different views of a soccer shoe, according to some embodiments of the present invention.

Detailed Description

According to one aspect of the invention, the above object is at least partly achieved by a sole for a shoe, in particular a sports shoe, with a midsole, wherein the midsole comprises a first sole region comprising a granular foam, and wherein the midsole further comprises a deformation zone within the midsole, wherein the deformation zone comprises a volume that is larger than the volume of a single expanded granule, and wherein the deformation zone is positioned such that the material of the first sole region is deformable downwards, sideways, or substantially sideways in case the sole is pressurized.

For example, in a tennis game, players may perform a number of different movement patterns: the foot may contact the ground via a posterior heel strike, a medial heel strike, a lateral heel strike, or a medial forefoot strike, and these different strike modes may result in ankle inversion, ankle eversion, ankle plantarflexion, ankle dorsiflexion, or MT extension, among others. In order to facilitate a fast execution of such movements, the sole should provide a good grip on the surface, it should also alleviate strain of the musculoskeletal system at least partly from these movements, as already mentioned above. This requires a high degree of stability of the shoe, in particular of the sole, so that the shoe does not "break through" under such strong impacts. One of ordinary skill in the relevant art will appreciate that the term "break through" means that the shoe fails to provide the necessary lateral support to the musculoskeletal system to prevent the ankle from overextending in the lateral direction.

On the other hand, it is desirable that the shoe also provide cushioning to the foot, particularly in the heel area, where the strongest impact forces typically occur, as well as providing good energy return for the wearer to improve his or her performance. To provide such cushioning and energy return effects, a granular foam may be employed, as such materials may have particularly good resiliency and cushioning. Examples of particulate foams may include expanded polypropylene ("ePP"), expanded polyamide ("ePA"), expanded polyether block amide ("ePEBA"), expanded thermoplastic polyurethane ("tpu"), and other similar materials. Furthermore, the use of a particulate foam may greatly facilitate the manufacture of soles containing such particles, since for example, in moulds where special arrangements of particles are not required, the particles may be blown or swept into the mould by means of an air stream, steam, liquid-like powder material, or the like. The granules can then easily be subjected to further processing steps, like pressure and/or steam treatment, or by melting the surface of the granules, adhering together thereunder, without the need for further binders or the like.

Foamed Thermoplastic Polyurethanes (TPU), for example, provide excellent elasticity and cushioning. Therefore, external impact when the sole contacts the ground can be buffered, so that comfort in wearing can be achieved. On the other hand, foamed TPU can provide a great deal of elasticity. Thus, the absorbed energy for the deformation of the sole is released again by the sole, said energy not being lost. The recovered energy can be used to move the sole away from the ground after the sole hits the ground without any substantial loss of energy as the sole rebounds. For example for tennis players, which means that he can change direction, reduce the effort to do so, and maintain a high level of flexibility over a longer period of time, thereby improving his overall performance.

However, this causes a problem in view of the above-mentioned need for a high stability sole. In a sense, high stability and grip are the requirements on the one hand and high damping and energy return are the requirements on the other hand, both opposite to each other. In particular, by "locking" the areas for high-energy return cushioning containing the granular foam in the areas intended to provide sole stability, surrounded by inflexible and inflexible materials, as in the case of sole structures known in the art, the good cushioning and resilience properties of the above-mentioned granular foams can be seriously impaired, since they are "everywhere" to go ". One of ordinary skill in the relevant art will appreciate that the term "locked" refers to an area that includes the particulate foam that limits deformation beyond surrounding materials that are inflexible and inflexible.

The entire pressure load is thus absorbed by the internal compression of the granular foam. However, even if the granular foams reach a level of compression at some stage, their elasticity and cushioning deteriorate, so that a large amount of energy may be lost during compression and subsequent expansion of the material, for example, due to hysteresis.

This problem is at least partially alleviated by the deformation zones provided in the midsole of the invention, which enable the material of the first sole region to deform laterally in the event of pressure being applied to the sole. Thus, the particulate foam may react to very strong forces, such as may occur upon impact with the ground, by at least partially "pressing" or "squeezing" into the deformation zone. Since the deformation zone has a volume greater than that of a single particle, it has sufficient space available without significantly compromising the integrity of the particle foam, destroying its granular structure.

As a result, undesirable internal compression of the granular foam can be avoided or at least reduced. Thus, the cushioning and resilient properties of the granular foam are maintained even under very high impact forces. Furthermore, by providing deformation zones having different locations and different sizes within the midsole, the exact resiliency and cushioning of the granular foam of the first sole region can be selectively and locally adjusted, as desired for a particular sole or shoe.

By providing deformation zones within the midsole of the sole, the foam of the particles may be protected from external factors like water, dirt, UV radiation, etc., e.g., the deformation zones may not be "crowded" with water or dirt.

Furthermore, by arranging the deformation zones in such a way that the particulate foam moves and/or presses in a lateral manner, i.e. by lateral deformation, the overall thickness and stability of the sole is maintained, giving the wearer the desired support, e.g. a rapid change of direction. Lateral deformation herein means deformation in a predominantly horizontal direction, or more precisely in a direction substantially parallel to the ground on which the wearer steps. Thus, deformation may occur primarily in the medial/lateral direction, or in the heel to toe direction, etc.

In some embodiments, a deformation zone is provided such that deformation occurs in a vertical direction. For example, the deformation zone may be disposed at and/or near the ground-contacting surface. In these cases, the deformation of the foam particles may create an expansion zone in the downward direction.

In some embodiments, the deformation zone is provided at least partially as an empty space.

This is an option, is easy to manufacture and may also help reduce sole or shoe weight, which may further contribute to improved wearer performance and shoe durability.

In some embodiments, the midsole further includes a control element that limits lateral deformation of the material of the first sole region.

As previously mentioned, substantial stability of the sole is necessary to prevent injury, provide a supportive feel to the wearer, and "engage" the ground when pedalled hard. By using such control elements, the exact cushioning and resilience properties of the first sole region can be further adjusted to achieve an optimal balance between softness and energy return on the one hand, and stability and support for the foot on the other hand.

In some embodiments, the control element comprises at least a portion of the deformation zone.

In this manner, the number of individual components of the sole may be reduced, thereby potentially reducing weight, saving manufacturing costs and adhesives, and improving the stability, durability, and environmental friendliness of the sole.

In certain embodiments, the control element comprises a groove. Furthermore, it is also possible that the control element comprises at least one slit and/or cut-out.

Furthermore, the grooves can be easily ground out in the control element. Here, the depth, width, length, cross-sectional shape, etc. of the recess can be influenced, for example by using different grinding tools, so that the cushioning and elasticity of the first sole region can be adjusted. Furthermore, the use of a recess, in particular a horizontal recess, as at least part of the deformation zone, such that the first sole region and the control element are in contact with each other in a region adjacent to the recess, may contribute to providing a good overall stability of the sole. Further design possibilities may be provided for the slits or cuts, and some or all of these functions may be shared.

In some embodiments, the control element surrounds the first sole region on both sides thereof.

In this way, the cushioning and elastic properties of the first sole region can be balanced, since the lateral deformation of the first sole region is controlled in all directions by the control element in the case of a pressed sole. In addition, such a structure may also help to improve the overall stability of the sole.

In certain embodiments, the control element is free of particles of the particulate foam. Due to the control element, among other things, serving to limit and control lateral deformation of the first sole region under pressure loading and to provide sole stability, the material of the control element may have greater stiffness and inherent stability than the first sole region. For such sole stabilizing components, as well as for foils or other shoe elements or textiles, suitable materials without foamed particles include, but are not limited to, EVA, PP, PA, PS, TPU, PEBA, and other similar materials. These materials are also relatively inexpensive, easy to process, and provide for advantageous use of the sole

In some embodiments, the control element may further include a material having particles of a particle foam that is greater than a hardness of the material of the first sole region.

In some embodiments, at least one protrusion extends into the void for securing the first sole region within the midsole. By using the protrusion to secure the first sole region within the midsole, the volume of the deformation zone may be increased while at the same time providing support that prevents the first sole region from moving out of position during use of the shoe/sole.

In some embodiments, the deformation zone comprises a material capable of producing a lateral deformation of the material of the first sole region.

Thus, the use of empty space within the midsole, for example, for stability or comfort reasons, may be avoided while still providing a sole with a "let-down" first sole region that may act to cushion the foot while providing a high energy return for the wearer. One of ordinary skill in the relevant art will appreciate that "release" refers to an area containing a granular foam that is deformed by being provided with a deformation zone without being organized beyond surrounding material that is inflexible and inflexible.

Furthermore, by using a yielding material in the deformation zone, the lateral deformation of the first sole region under pressure load of the sole can be controlled and adjusted more precisely than in a simple empty space.

In some embodiments, the deformable material within the deformation zone, i.e., the deformable material capable of yielding to the material of the first sole region, has a deformation hardness that is greater than 5% to 40% of the deformation hardness of the first sole region, and may further have a deformation hardness that is greater than 10% to 25% of the deformation hardness of the first sole region. For example, the first sole region may have a deflection hardness of approximately 40 Shore C, while the compliant material has a deflection hardness of 45-50 Shore C. In some embodiments, the first sole region may include an edpu (or other particulate foam) having a deflection hardness of approximately 40 shore C, while the deflection region including EVA (or another foamed or expanded material) has a deflection hardness of 45-50 shore C. In certain embodiments, the difference in deformation stiffness may be achieved by providing different materials, as in the examples described above. But they may also be provided with the same material and different densities.

The use of deformation zones with a compliant material having a deformation stiffness that is about 5% to 40% greater than the deformation stiffness of the first sole region, and which may also be about 10% to 25% greater than the deformation stiffness of the first sole region, provides overall stability to the sole, while also allowing sufficient deformation of the compliant material to "release" the first sole region to allow the desired cushioning and high energy return to the wearer. In particular embodiments, this design provides a midsole, including the first sole region and the deformation region, without any additional midsole components, which helps to reduce weight and manufacturing costs.

In some embodiments, the midsole includes a second sole region that includes a granular foam and has an increased hardness by deforming in at least one predetermined direction.

In many modes of motion, particularly in sports, the joints and musculoskeletal systems of athletes are often subjected to large forces. For example, in tennis, a large variety of tennis movements, such as ankle inversion or eversion, ankle plantarflexion or dorsiflexion, or MT extension, may result in ankle metatarsal and toe joint height shifts. By providing a second sole region comprising a granular foam in such a position of the sole that a similar impact may occur, the stress on the joints of the athlete may be relieved by the excellent cushioning properties of the granular foam, as already indicated above. In more detail, if the second sole region has a lower stiffness in deformation in the region where impact occurs (during medial cutting, such as the medial heel region or at rest), relative to the opposite side of the second sole region (such as the lateral heel region), then the second sole region, or the entire sole, will tilt inward toward the area of impact, due to the greater compression of the second sole region in the area of impact. Thus, the angle between the lower leg and the foot may be reduced, resulting in reduced stress at the ankle joint.

The increase in deformation stiffness may be due, at least in part, to an increase in density of the material of the second sole region in the predetermined direction.

Thus, the second sole region may be made of a single base material, resulting in an integrally formed second sole region having good structural integrity.

In some embodiments, the midsole may also include a greater number of sole regions. For example, a midsole may include three or four sole regions. One of ordinary skill in the relevant art will appreciate that a midsole may include any suitable number of sole regions, including but not limited to 20-30, or even more sole regions.

In some embodiments, the at least one predetermined direction extends from the medial side of the sole toward the lateral side of the sole.

As discussed above, medial cuts or stops are often encountered during lateral movements such as tennis or basketball, and the like, such that a "slanted sole" in a predetermined direction from the medial side to the lateral side may be used to relieve stress on the joints of a player, for example, during a tennis game.

In some embodiments, the first sole region extends to a forefoot region and the second sole region extends to a heel region.

High energy return is particularly important for pushing the foot off the ground, such as during running. The pushing-off takes place mainly in the forefoot region, so that the released first sole region can be particularly advantageous in the forefoot region. On the other hand, as discussed above, impact of the foot on the ground often occurs in the heel area of the foot, particularly during lateral motion as discussed above, such that a second sole area with variable deformation stiffness may be beneficial in the heel area. However, other arrangements are possible depending on the typical motion pattern involved in a given activity.

In some embodiments, the first sole region and the second sole region may at least partially coincide.

The effect of "releasing" the granular foam is thus for good cushioning and energy return, as well as reducing stress by means of "tilting" the sole region, which can be incorporated into a given area of the sole, if desired.

In some embodiments, the sole further includes a frame element that at least partially surrounds the midsole and limits lateral deformation of the midsole under compressive loading of the sole.

Such frame elements may serve, for example, to further increase the overall stability of the midsole or sole without significantly compromising the cushioning and resiliency characteristics of other midsole components. Thus, the frame element further increases the possibility of affecting the stability of the sole, which is essentially independent of the further options discussed above.

In some embodiments, the frame element may completely surround the sides of the heel region, while only partially encompassing the sides of the forefoot region.

Good stability is important, particularly in the heel area, where impact forces tend to occur, such as on the ground, as discussed above. Therefore, the foot should be stabilized in this area to avoid twisting or similar injuries of the slipping foot or ankle. On the other hand, some degree of freedom of movement in the forefoot region is also desirable to promote flexibility in dynamic pushing away of the wearer and foot from the ground.

In some embodiments, the frame element further comprises a support member, wherein the support member is disposed on a lateral side of the heel region.

Such support members, when disposed on lateral sides of the heel region, may further stabilize the foot, especially during medial cuts or stops, from "popping" the foot to the other side, which may easily lead to a tight ankle, for example. In some embodiments, the support member may be provided as an integral piece with the frame element in order to achieve the desired stability. In addition, the frame elements and/or support members may be covered internally with a soft coating to enhance comfort and help prevent chafing of the wearer's feet.

In certain embodiments, the control element and the frame element are at least partially coincident.

For example, the control element and the frame element may be provided as one piece. In particular, the control element may be provided as part of the midsole and the frame element may surround the midsole and/or the control element as a further stabilizing frame to further increase the stability of the sole. In this example, the stability may be further improved if the control element and the frame element are provided as a single integral piece without any seams, welded joints, gluing, etc.

In some embodiments, the frame element includes at least one rod for securing the frame element to the midsole. In some embodiments, the at least one rod is at least partially surrounded by the material of the midsole.

In this manner, the frame element may be positioned and secured to the midsole without the use of additional adhesives, such as glues or other chemical fasteners. However, such additional adhesives may still further strengthen the connection between the midsole and the frame element, if desired. Furthermore, the at least one rod may assume a further function, for example as a torsion bar.

Further embodiments of the invention are provided by footwear and embodiments of soles according to the invention as discussed herein.

It will now be mentioned here that in one embodiment of providing a shoe with a sole according to the invention, the different functions discussed herein are optional, rather than mandatory, and these features may also be combined, as deemed appropriate by the person skilled in the art, to achieve a certain desired result. The functions discussed herein, if considered to be more costly to achieve the desired results, may be omitted without departing from the scope of the invention.

Detailed description of the invention

The subject matter of embodiments of the present invention is described with specificity herein to meet statutory requirements, and the description is not intended to limit the scope of the claims. The claimed subject matter may be embodied in other ways, may include different elements or steps, and may be used in conjunction with other present or future technologies. Except when individual steps or arrangements or order of elements are specifically described, the description should not be construed as implying any particular order between various steps or elements.

Certain embodiments of the present invention are described in detail below with reference to athletic footwear. For example, some embodiments described herein may be applicable to sports requiring lateral movement, such as tennis, basketball, soccer, and the like. It is emphasized, however, that the present invention is not limited to these embodiments with respect to such fact. Conversely, the invention may also be applied, for example, to shoes for linear and lateral sports, such as basketball shoes, golf shoes, football shoes, climbing or dancing shoes, and other kinds of sports shoes or for traditional shoes, or to fashion or living goods.

Furthermore, many technical embodiments, several of which are described in more detail below, are conceivable as embodiments of the present invention. However, the present invention is not limited to the embodiments specifically described herein.

According to some embodiments of the invention, as shown in FIG. 1. The sole 100 has no deformation regions, including the midsole 102, having a first midsole component 110 and a first sole region 120, which may include a granular foam, including but not limited to eEPP, eEPA, epba, tpu, and other similar materials. First midsole element 110 may also include materials such as EVA, PP, PA, PS, TPU, PEBA, and other similar materials. In certain embodiments, the material of the first midsole component 110 comprises a greater hardness than the material of the first sole region 120 in order to provide the necessary stability of the midsole.

In the context of the present application, the term "sole region" may be used to mean a portion of a midsole that extends from a bottom surface of the midsole throughout the entire thickness of the midsole to a midsole top surface. Furthermore, the sole region may have any shape and may also be disposed in any portion of the midsole, i.e., also in an edge or the like of the sole. In addition, the sole region may also contain multiple discrete regions of the midsole. A "midsole element" on the other hand is any portion of a midsole.

However, the term "sole region" may have the meaning described above, but it should be noted that "sole region" may also generally designate a midsole or a general component of a sole. Thus, the sole region may also be a sole insert, disposed on one side of the sole or midsole, such as the top side of the midsole, or a portion of an insole or outsole, or the like.

In some embodiments, the sole 100 shown in FIG. 1 may include a first sole region 120 that is "locked" therein by being surrounded by the material of the first midsole portion 110. Thus, even though the material of first sole region 120, such as granular foam, may itself have very good cushioning and energy return properties, these beneficial properties may be compromised by being completely surrounded by first sole region 120 of a material made of harder material 110. In response to the pressure loading of sole 100, first sole region 120 may be compressed, particularly in first sole region 120. If the pressure load is too great for the material to move and/or deform under this strong load, the material in first sole region 120 may be compressed to the point where it loses, at least partially or temporarily, its beneficial properties (e.g., elasticity). For example, significant hysteresis may occur. In addition, there is a risk that the material of first sole region 120 may deteriorate and permanently lose its elasticity when subjected to such strong deformations for a long period of time.

Fig. 2a-h show another embodiment of a sole 200a according to the invention, which comprises deformation zones into which the granular foam of the first sole region can move and/or deform laterally.

In some embodiments, as shown in FIG. 2a, a sole 200a may include a midsole 202a having a first midsole portion 210 a. Midsole 202a may further include a first sole region 220a that includes a granular foam 225 a. The midsole 202a may also include a deformation region 230a within the midsole 202 a. The deformation zone 230a may comprise a volume greater than the volume of the individual expanded particles of the granular foam 225a, positioned such that the material of the first sole region 220a is capable of deforming laterally under the pressure load of the sole 200 a.

As will become apparent from the embodiments discussed below, the deformation zone may have a volume greater than the volume of a single expanded particle in the midsole. As used herein, "volume of individual foam particles" is understood to mean the average volume of foam particles in the first sole region when the sole is not under pressure. In some cases, the volume of the deformation zone is only, e.g., 1.5, 2, 5, or 10 times the volume of a single foamed particle. In other cases, it is significantly larger.

In some embodiments, as shown in fig. 2a, first sole region 220a is disposed in the heel region and has an oval shape (in a top view of midsole 202 a). In these embodiments, first sole region 220a may extend throughout the entire thickness of midsole 202a from its bottom side to its top side. However, first sole region 220a may also be disposed in different portions of midsole 202a, may have different shapes, may include multiple sub-regions, may be disposed on only one side of midsole 202a, and so forth.

Deformation zone 230a may completely surround the side of first sole region 220a, or may be provided at least partially as an empty space in a simple case. If so, first sole region 220a may be secured in place, for example, by attaching first sole region 220a to an insole (not shown) and/or an outsole (also not shown) that is to be secured to midsole 202 a. As discussed further below, the deformation zone may also be at least partially filled with a deformable material, for example a very soft material such as a gel-like material.

In some embodiments, as shown in fig. 2b, another possibility is provided to secure the position of the first sole region. In these embodiments, midsole 202b may additionally include at least one protrusion 240b that extends into deformation region 230a, which may be an empty space, as described above, to secure the position of first sole region 220a in midsole 202 b.

However, in further embodiments, deformation zone 230a may also include a material that enables the material of first sole region 220a to deform in the event of a compressive load being applied to sole 200a or 200 b. In some embodiments, the material of the deformation zone 230a may have a hardness of deformation of: greater than 5% to 40% of the deformation hardness of first sole region 220a, in particular greater than the deformation hardness of the granular foam of first sole region 220a, the material of deformation zone 230a may also have a deformation hardness of 10% to 25% greater. In this way, a good compromise is provided between sole stability and the ability of the material to deform at deformation region 230a on one side of first sole region 220 a.

It should be noted that the deformation zone 230a may also require a much larger portion of the midsole 202a or 202b than shown in figures 2a and 2 b. In particular, a separate, individual midsole portion 210a is an optional feature.

For example, first midsole portion 210a may be formed entirely or predominantly from deformation region 230a, deformation region 230a may be formed from EVA, having a deformation hardness of 45-50 shore C, and midsole 202a or 202b further includes a first sole region 220a, e.g., disposed in the heel region, with a particulate foam, e.g., a foamed thermoplastic polyurethane, having a deformation hardness of about 40 shore C, which may range from 40-80 shore C.

An additional embodiment of a sole 200c is shown in FIG. 2 c. In contrast to the embodiment of sole 200a, deformation zone 230c may include a plurality of sub-zones 231c, 232c arranged in a "sunflower-like" manner around first sole region 220 a. Thus, even if sub-regions 231c, 232c are disposed as empty spaces, the position of first sole region 220a is fixed by protrusions 240c formed between "leaves" 231c, 232 c. In addition, the expansion sub-areas 231c, 232c can also be at least partially filled with a material that enables a lateral deformation of the material of the first sole region 220 a. This may be desirable in order to increase the overall stability of the sole 200c and/or to avoid the use of empty spaces within the sole 200c, for example, for comfort or aesthetics, and the like.

In some embodiments, as shown in fig. 2D, a midsole 202D comprising a granular foam 225D having a first midsole 210D and a first sole region 220D may be included in the sole 200D. As previously described, for example, first midsole portion 210d may be first midsole portion 210a, and first sole region 220d may be first sole region 220 a. The midsole 202d may include a deformation region 230d within the midsole 202d, wherein the deformation region 230d has a volume greater than a volume of a single expanded particle of the granular foam 225d, the deformation region 230d being positioned such that the material of the first sole region 220d is capable of deforming laterally in the event that the sole 200d is subjected to a compressive load. Further, in this case, deformation region 230d may be disposed in a "sunflower-like" manner around first sole region 220d, and deformation region 230d may be provided as an empty space, or any other suitable structure. Protrusions 240d between the "sunflower leaves" may be used to secure the position of the first sole region 220 d.

In some embodiments, as shown in figure 2d, the sole 200d may further include an additional layer of material 250d disposed between the first midsole portion 210d and the deformation region 230 d. Layer 250d may comprise, for example, an elastomeric material, such as a soft EVA material. Accordingly, damage to first sole region 220d that might otherwise occur when first sole region 220d is a compression of potentially sharp or pointed protrusions 240d is avoided, as lateral deformation thereof under pressure loading in sole 200d is avoided and/or minimized. In addition, by providing a layer 250d of flexible and resilient material as a connection between first sole region 220d and projection 240d and first midsole portion 210d, first sole region 220d may remain fixed in place even when bent or twisted in sole 200d, since resilient material layer 250d may compensate to some extent for the resulting deformation. Thus, contact between protrusion 240d and first sole region 220d may be maintained, and first sole region 220d remains fixed in its position.

In further embodiments, as shown in fig. 2e, deformation zones 230e are provided as sub-regions 230e within first sole region 220e, such as empty spaces or filled with a deformable material, rather than being provided between the first sole region and the rest of midsole 202e, such as first partial midsole portion 210 e. Thus, in the present case, first sole region 220e may expand "inward" in response to pressure exerted on sole 200 e.

In certain embodiments, as shown in FIG. 2F, the midsole 202F may be entirely or at least primarily comprised of a first sole region 220F, which may include a granular foam, unlike the embodiments of soles 200a-200e discussed so far.

Furthermore, it should be noted that a first midsole portion as described in the above embodiments, for example made of a harder material, may be an optional feature of the invention compared to the first sole region and/or deformation zone.

In some embodiments, as shown in FIG. 2F, deformation zones 230F are provided as a number of unconnected sub-zones 230F within first sole region 220F, similar to the embodiment of sole 200e shown in FIG. 2 e. Such an embodiment of the sole 200f may be appropriate if a particularly flexible sole is desired, the stability of which is critical.

In some embodiments, as shown in fig. 2g, a sole 200g may include a midsole 202g having a first midsole portion 210 g. Midsole 202g may further include a first sole region 220g that includes granular foam. The midsole 202g may also include a deformation region 230g within the midsole 202 g. Deformation zone 230g may have a volume greater than the volume of a single expanded particle, and deformation zone 230g is positioned such that the material of first sole region 220g is able to deform laterally in the event sole 200g is under a compressive load.

However, the sole 200g herein may also include a control element 260g that limits lateral deformation of the material of the first sole region 220 g. For this purpose, the material of the control element 260g has a greater deformation hardness than the material of the first sole region 220 g. In some embodiments, the material of the control element 260 grams is free of particles of the particulate foam. For example, the control element 260g may include at least one material including, but not limited to, EVA, PP, PA, PS, TPU, PEBA, and/or the like.

The control element 260g may include the deformation zone 230g, or at least a portion thereof. In certain embodiments, as shown in fig. 2g, the deformation region 230g may be provided as a rectangular recess 230g in the control element. Groove 230g may remain as an empty space, or it may be at least partially filled with a material that laterally deforms the material of first sole region 220 g. The material of control element 260g itself may not cause a significant degree of lateral deformation of the material of first sole region 220 g.

Control element 260g may thus serve both to improve the overall stability of sole 200g, as described in the embodiment in which control element 260g is positioned in the heel region, and to "release" first sole region 220g, by providing a deformation zone 230g into which the material of first sole region 220g may expand laterally.

In an embodiment of sole 200g, as shown in fig. 2g, control element 260g may at least partially circumscribe a side of first sole region 220 g. In a further embodiment, the control element completely delimits the first sole region, so that the lateral deformation of the first sole region can be controlled and adjusted in all horizontal directions. In some embodiments, deformation region 230a of sole 200a, as shown in FIG. 2a, may instead be completely surrounded on the sides of first sole region 220a by control elements in the manner described above. For example, deformation zone 230a may be replaced by an oval-shaped plastic ring, such as a ring made of EVA, with a horizontal groove on its inside, into which the granular foam of first sole region 220a may expand laterally in the event of a compressive loading of the sole. The combination of such a control element and the first sole region with the granulated foam provides a very good stability of the heel region of the sole, as well as a high degree of cushioning and energy return to the wearer.

In some embodiments, as shown in fig. 2h, a sole 200h may include a midsole 202h having a first midsole portion 210 h. Midsole 202h may also include a first sole region 220h of two unconnected components 222h and 225 h. Two components 222h and 225h of first sole region 220h may include granulated foam. The two parts 222h and 225h may or may not be the same material (more than two parts are also possible).

In some embodiments, the midsole 202h may further include deformation regions 230h, 231h, 250h, 251h in the midsole 202h, the deformation regions 230h, 231h, 250h, 251h may be of a greater volume than the volume of the individual particles of the granular foam, and the deformation regions may be positioned such that the material of the first sole region 220h is capable of lateral deformation in the event that the sole 200h is compressed. As can be seen in the cross-sectional view along line B-B', shown in the lower part of fig. 2 h. Deformation zones 230h and 231h may extend throughout the entire thickness of midsole 202 h. In another aspect, deformed regions 250h and 251h may extend only half way through the thickness of midsole 202 h. This means that component 225h of first midsole region 220h is in direct contact with midsole 202h, in the example of first midsole portion 210h shown for the lower half of the entire circumference of component 225h of midsole 202 h. Thus, as an alternative to providing several expansion sub-regions 250h, 251h in a "sunflower-like" arrangement with protrusions disposed therebetween to secure component 225h, a simple empty space may be used, surrounding the upper half of component 225h, yet still resulting in a very stable midsole 202h, since component 225h is secured in the lower half of first sole region 220 h.

It should be understood that the arrangement shown in fig. 2h is merely exemplary and that many modifications and rearrangements of the embodiments discussed within the scope of the invention are possible.

Fig. 3 illustrates the concept of a "slanted sole" 300, as compared to a conventional midsole 350. Impact during lateral motion, such as a medial cut during tennis play, with a conventional midsole, the midsole will substantially maintain its contour, comparable to sole region 370 of FIG. 3. This results in a relatively large angle b between the heel and the lower leg of the wearer, which can lead to over-training of the ankle and metatarsophalangeal joints of the wearer, leading to fatigue and even injury. Sole 300, which incorporates the concept of "tilting". On the other hand, sole 300 may include sole region 320 that has an increased stiffness to deformation in at least one predetermined direction, in the example shown here, an impact in a lateral movement from the medial side of the foot toward the lateral side of the medial foot, the medial side of sole region 320 being softer than the lateral side and being more strongly compressed such that sole region 320 slopes inwardly toward the medial side of the foot. This allows the angle between the wearer's heel and his lower leg to be smaller, thereby reducing strain at the wearer's ankle and metatarsophalangeal joints. Such a design may result in improved endurance for the wearer and help prevent injury.

In accordance with certain embodiments of the present invention, as shown in FIG. 4, the sole 400 may include a midsole 402, and the midsole 402 may further include a first sole region 420, which may include a granulated foam. The midsole 402 may further include a deformation zone 430 within the midsole 402, wherein the deformation zone 430 has a volume greater than the volume of a single expanded particle, and the position of the deformation zone 430 may be set such that the material of the first sole region 420 is capable of lateral deformation under compression of the sole 400. Sole 400 may also include a control element 460 that limits lateral deformation of the material of first sole region 420. In some embodiments, the deformation zone 430 is provided as a rectangular recess 430 within the control element 460. With respect to first sole region 420, control element 460, and deformation region 430, it is contemplated that the embodiments of soles 200a-200h discussed above, and in particular the embodiment of sole 200g, are also applicable to the embodiments discussed herein.

In addition, sole 400 may include a second sole region 480, which may include a granular foam and may provide increased deformational stiffness in at least one predetermined direction. In some embodiments, the predetermined direction extends from a medial side of the sole 400 toward a lateral side of the sole 400. The predetermined direction may be selected, for example, for lateral movements such as tennis, based on strain at the ankle and metatarsophalangeal joints of the wearer during the lateral movement, as described above with respect to fig. 3. For other typical movement patterns, different predetermined directions may be selected to adjust the sole to the specific needs of that particular movement.

The concept of the second sole region with a progressive increase in deformation stiffness mentioned here in particular can be combined with any of the above-described or otherwise conceivable embodiments of the sole according to the invention and is not limited to the specific embodiment, in which the control element 460 of the heel region is shown.

In addition, first sole region 420 may extend to the forefoot region and second sole region 480 may extend to the heel region, as opposed to the example shown here. This inverted arrangement provides the beneficial effect of a "tilt effect" primarily in the heel region where impact with the ground primarily occurs. At the same time, the first sole region is "released" in the forefoot/toe region, where pushing off the ground often occurs, and therefore, good energy return is desirable.

In the exemplary embodiment of sole 400, as shown in FIG. 4, first sole region 420 and second sole region 480 are a single piece. In general, first sole region 420 and second sole region 480 may at least partially coincide. It is also possible, however, that first sole region 420 and second sole region 480 may be separate regions in sole 400. For example, component 225h of sole 200h may be a first sole region and component 222h may be a second sole region that deforms in at least one predetermined direction with increasing stiffness, e.g., from the medial side to the lateral side of the foot. Again, it will be apparent to those skilled in the art that various modifications and rearrangements of the embodiments described herein are possible without departing from the scope of the invention.

The increase in material density of second sole region 480 at least partially achieves an increase in crush stiffness, e.g., the mold may be filled with particles of a granular foam, increasing the height of the fill, and then the mold closed to achieve a uniform thickness of compressed particles within the mold, thereby achieving an increase in density in the direction of the fill height. However, an increase in the deformation hardness can also be achieved by an increase in the density of the change in the base material or the like.

In another embodiment of a sole 500 according to the present invention, as shown in FIG. 5, the sole 500 may include a midsole 510, and the midsole 510 may be a midsole of one of the embodiments discussed thus far herein. The sole 500 may also include a frame element 520 that at least partially surrounds the midsole 510 and may limit lateral deformation of the midsole 510 under pressure loads. Thus, the frame element 520 may be used to increase the overall stability of the sole 500 independent of other possibilities of midsole features discussed thus far, such as fine-tuned cushioning, energy return, and stability.

In some embodiments of the sole 500, as shown in FIG. 5, the frame element 520 may completely surround the midsole 510, except for the toe region 515 of the midsole 510. As noted above, push-off of the foot tends to occur at the toe, so the attributes of good energy return may be particularly important in toe area 515. As described above, by excluding the toe region from the frame element 520, the midsole material "relaxes" in the toe region 515, which increases its potential return energy, dissipating the deformation of the sole 500 during the step of returning to the wearer.

In additional embodiments of sole 500, toe region 515 may include thin zones of EVA that are easy to manufacture and provide stability to the toe region. In other embodiments, the toe region 515 may include the tpu, which is fully melted, e.g., a granular foam within the first sole region as discussed herein, such that the tpu has a greater deformation stiffness in the toe region 515 and may also provide stability.

The frame element 520 may further comprise a support member 525. The present sole 500 is primarily intended for use in lateral sports, such as tennis, where the support 525 may be disposed on a lateral side of the heel region. Thus, the support member 525 may support the heel during lateral movements, such as medial resection, and prevent the athlete's foot from "breaking" and straining the ankle. To avoid chafing of the wearer's feet, the frame element 520, particularly in the support member 525, may further include a soft coating on the inside.

This is further noted that a frame element similar to frame element 520 may at least partially coincide with a control element as described above. That is, the frame element may also serve to limit lateral deformation of the material of the first sole region, for example by including an expansion region like a groove or the like. For example, the frame element may be integrally formed with the control element within the midsole of the sole.

The frame member 520 may also include at least one rod 528. Rods 528 may be used to secure frame member 520 to midsole 510. In the embodiment shown here, rods 528 form a jig or cavity with the peripheral edge of frame member 520 into which midsole 510 may be press fit. Alternatively, the at least one rod 528 may also be at least partially surrounded by the material of the midsole 510 to secure the frame element 520 to the midsole 510. For example, the frame element 520 may be initially inserted into a mold, and the midsole material, such as the granular foam particles used for the midsole, may then be added thereto and processed. In this manner, the rods of frame element 520, for example, may extend throughout the interior of the midsole, thereby providing frame element 520 to the midsole without the need for adhesives such as glue (and still be added if desired).

In addition to helping to secure frame member 520 to midsole 510, the at least one rod 528 may also assume further functionality. For example, it may be a torsion bar to increase the torsional stiffness of sole 500.

In some embodiments, as shown in FIG. 6, sole 600 may include a midsole 610 and a frame element 620. The considerations discussed above with respect to sole 500 and midsole 510 and frame member 520 may also apply to this regard. Specifically, midsole 610 may be in accordance with any of the embodiments of midsoles in accordance with the present invention, as discussed herein or otherwise contemplated. Particular features of frame element 620 may completely surround the sides of the heel region of the midsole, but only partially include the sides of the forefoot region. As previously discussed, such a design provides good stability for the heel region, potentially in combination with the second sole region, providing the benefits of the "tilt effect" explained above, while also "freeing up" the toe region to facilitate maximum energy return to the wearer's foot during push-off.

Finally, shoes 710, 720, 730 according to further embodiments of the invention, as shown in fig. 7, include different frame elements 712, 722, 732, which provide different degrees of stabilization. For example, frame elements 712, 722 provide increased stability as compared to frame element 732, which includes support elements 715, 725 in the lateral heel region. Furthermore, the use of different materials and material thicknesses may increase the stability provided by the frame element.

Figures 8-15I show other embodiments of soles and shoes according to the invention. As will be apparent to those skilled in the art, these embodiments are merely possible designs, choices, and arrangements, not necessarily corresponding to actual soles or proportions of soles as shown in these depictions. The primary purpose of the embodiments below is to give the skilled person a better understanding that the features discussed above are possible design choices and combinations within the scope of the invention.

In some embodiments, as shown in fig. 8, footwear 800 and sole 805 may include a midsole and a plurality of outsole elements 899. The midsole may include a first sole region 820 that includes granular foam particles. The first sole region 820 may provide a number of individual rods 820, between which rods 820 empty spaces 830 may be present, the volume of these empty spaces 830 may be larger than the volume of a single expanded particle and may serve as deformation zones 830, the material of the first sole region 820 may expand laterally in case the sole 805 of the shoe 800 is compressed. In some embodiments, as shown in FIG. 9. The midsole 902 may include a first sole element 910, such as EVA or the like. The midsole 902 may further include a first sole region 920 that contains a particulate foam, such as tpu. First sole region 920 may also include a plurality of grooves or indentations 930 for deformation zones within first sole region 920 that are larger in volume than the volume of a single foamed particle. Under the pressure load of midsole 902, the material of first sole region 920 may expand laterally into deformation region 930. Deformation zones 930 may also extend the entire thickness of midsole 902, or they may be localized to one side of midsole 902 and penetrate to a depth into the material of first sole region 920, such as first sole region 920 or half the thickness of midsole 902 or the like. Control element 960 may be embedded in the material of first sole region 920, which may limit deformation of first sole region 920. Control element 960 may be provided as two separate, parallel components embedded in the material of sole region 920, which may be spaced apart by a short distance, such as 2mm or 5mm or 1cm, for example. In some embodiments, control element 960 may have a higher deformation stiffness than the material of first sole region 920. In this manner, control element 960 may also function as a stabilizing element in this example in addition to limiting lateral deformation of first sole region 920. As the wearer moves, the two portions of control element 960 may slide in opposite directions, as indicated by the two large arrows in FIG. 9, thereby supporting the wearer's foot and promoting the natural roll-off of the foot. At the same time, the components of control element 960 may act as torsion bars to increase the torsional stiffness of midsole 902, as indicated by the curved arrows in FIG. 9. Notably, a groove or notch 930 may be provided between the two components of control element 960 to facilitate movement between the two portions during movement of the wearer as described above, and to facilitate the natural roll-off of the foot.

In some embodiments, as shown in fig. 10, midsole 1002 may also include a first sole region comprising a granular foam. In this example, the first sole region has sub-regions 1020, 1025. The composition of first sole sub-regions 1020, 1025 may be substantially similar. However, the composition of the first sole sub-regions 1020, 1025 may also be different.

In general, various permutations, modifications, and rearrangements of the various portions of the various embodiments described herein of the first and second sole regions and control elements are contemplated as being within the scope of the present invention, in particular.

In some embodiments, as shown in fig. 10, the midsole 1002 may further include a deformation region 1030 in the midsole 1002, which may include a material that is capable of laterally deforming the material of the first sole region 102, 1025 under the compressive loading of the sole 1000. For example, first sole regions 1020, 1025 may include an tpu, e.g., having a durometer of approximately 40 shore C, and deformation region 1030 may include a relatively soft EVA, such as EVA having a durometer of 45-50 shore C.

In addition, the midsole 1002 may include a control element 1060 that circumscribes the first sole region 1020, 1025. In some embodiments, control element 1060 may include a harder EVA material and may be disposed on the lateral side of midsole 1002.

In some embodiments, as shown in fig. 11, sole 1100 may include a midsole 1102 with a first midsole portion 1110. The midsole may further include a first sole region 1120 that includes granular foam. First sole region 1120 may include two drop-outs (drop-ins) partially embedded in the material of first midsole portion 1110. However, first midsole portion 1110 may also include a window within the midsole. These windows provide deformation regions 1130 having a volume greater than the volume of the expanded particles of first sole region 1120, and the material of first sole region 1120 may expand laterally under the pressure load of sole 1100. The sole may further include additional sole components 1199, such as an outsole or frame elements as discussed previously.

In some embodiments, as shown in fig. 12, midsole 1202 may include a first sole region 1220 that includes a granular foam. In these embodiments, first sole region 1220 may include several wedge-shaped sub-regions. Between adjacent or some or all of these sub-regions 1220, midsole 1202 may further include a deformation region, which may include several of the sub-regions shown herein. The deformation region or regions may include a material that deforms the material of the first sole (sub-) region laterally under pressure applied to the midsole 1202. It is to be understood that only some of the midsole portions between adjacent and/or first sole sub-regions 1220 may include such a compliant material, while others may not.

In some embodiments, as shown in FIG. 12, provision may be provided that region(s) 1220 and/or deformation region(s) 1230 of the first sole may also contribute to increased flexibility of midsole 1202, in addition to the additional functions already discussed many times herein for the soles of the present invention.

In further embodiments, as shown in fig. 13, a midsole 1302 of the present invention may include a first sole region that includes a granular foam, such as eptpu. In these embodiments, the first sole region may include two sub-regions 1320 and 1325, one sub-region 1320 in the inner half of the heel region and the other sub-region 1325 disposed in the forefoot region, which is also the medial half primarily in midsole 1302.

Alternatively or additionally, one of sub-regions 1320 and 1325 may include a second sole region that may provide a tilting effect with the corresponding first sole region as discussed, with variable stiffness. For example, sub-region 1320 in the heel region of midsole 1302 has a stiffness that gradually increases from the medial to the lateral side of midsole 1302 to provide a slope during a lateral sidecut.

When considered in comparison to other embodiments discussed herein, the arrangement of the first sole region, or the arrangement of the plurality of sub-regions 1320 and 1325 thereof, which may be selected and modified throughout the midsole, as referred to multiple times herein, may have a number of different locations. As shown below, the first sole region or sub-region 1320, 1325 can be disposed in the heel region, midfoot region, forefoot region, and primarily on one side of the sole, the middle of the sole, the entire width, length, thickness of the midsole, and so forth. The same applies to the second sole region which may be present. With regard to the region of the second sole just mentioned, it is further pointed out that it is also possible to adjust its density by means of a number of different arrangements and modifications, and also to locally, finely tune the sole accordingly to the requirements of the application in a certain field.

Midsole 1302 may further include a first midsole portion 1310. This first midsole portion 1310 may, for example, comprise EVA or other suitable material. In this manner, first midsole portion 1310 may also serve as a control element 1310 that limits lateral deformation of the material of first sole region 1320 and/or 1325 under compression of midsole 1302. The control element 1310 may further include a deformation region (not shown) in the form of at least one horizontal groove or the like, see, for example, fig. 2g or fig. 4,.

In further embodiments, first midsole portion 1310 may also include a material that is capable of lateral deformation of first sole regions 1320, 1325, and thus first midsole portion 1310 may function as a deformation zone.

First sole sub-regions 1320 and 1325 may each include one (or possibly more) groove 1330, 1335 into which the material of first sole sub-regions 1320, 1325 may expand laterally under pressure loading. As already mentioned, these slots 1330, 1335 may extend the entire thickness of first sole sub-regions 1320, 1325, or even the entire thickness of midsole 1302, or they may only penetrate to a certain depth of the material, for example one third or half of the depth of first sole sub-regions 1320, 1325, although many further arrangements are possible. Additionally, grooves 1330, 1335 may correspond to openings in the outsole that will be attached to midsole 1302 to further enhance the functionality of the overall sole. In general, such openings in potential outsoles may be used in conjunction with other embodiments of the sole of the invention described herein.

In some embodiments, as shown in fig. 14, midsole 1402 may include a first midsole portion 1410 and a first sole region 1420 comprising granular foam. The midsole 1402 may include a groove 1430, which is coupled to the midsole 1402 as a deformation zone 1430 and a flexible zone, which may correspond to the middle along the outsole. With respect to the other examples given so far, other explanations and considerations of the invention apply to these embodiments, if applicable.

In some embodiments, as shown in fig. 15-26, the midsole 1502 may include multiple portions. For example, as shown in fig. 15, the midsole 1502 includes a first sole portion 1510 and a first sole region 1520.

First sole portion 1510 may be formed from a variety of materials including, but not limited to, EVA, rubber (e.g., blown rubber), polyurethane, or the like, and/or combinations thereof. First sole portion 1510 may have a ground contacting surface that may vary in profile, as shown in FIG. 15. In some alternative embodiments, shown in fig. 15H-I and 19, the ground contacting surface appears to be substantially flat.

First sole region 1520 may include granular foam. The first sole region may include a particulate foam, such as eptu, ePP, ePA, ePEBA, or eptu. In some embodiments, the particulate foam may be randomly arranged and/or aligned. For example, as illustrated in fig. 15J, the tpu foam particles are substantially randomly arranged to form a first sole region 1520.

As illustrated in fig. 15K, the first sole portion 1510 may include a lattice structure 1540 to be connected to the first sole region 1520. The lattice structure 1540 can include one or more open or deformed regions 1530. The lattice structure 1540 may provide abrasion resistance. In some cases, lattice structure 1540 may be configured to be able to serve as an outsole (e.g., material, thickness). In these cases, no additional outsole is required. In other embodiments, an outsole made of rubber, TPU, other materials, and combinations thereof, as are known in the art, may be additionally added. For example, the sole may include a lattice structure, without the need for an additional outsole.

As shown in fig. 15A and 15B, a first sole portion 1510 may be connected to the first sole region 1520. When the components are connected, first sole portion 1510 may extend beyond an edge of first sole region 1520, as shown in figure 15A.

The lattice structure 1540 can further include a plurality of open areas, represented as deformation zones 1530, as shown in fig. 15B. These deformation zones 1530 allow the expanded particulate material to deform because the volume of the open area is greater than the volume of a single foamed particle. During use, for example, when a pressure load is applied to the midsole 1502, the material of the first sole region 1520 may deform downward into these deformation regions 1530. The deformed region 1530 may extend throughout the lattice structure 1540. In some cases, the deformation region 1530 may be limited to certain other regions of the midsole 1502. Further, as depicted in fig. 15B and 17, the lattice structure 1540 may also include a controlled deformation region 1535. Here, the material of lattice structure 1540 may extend throughout first sole region 1520 in a reduced thickness in controlled deformation region 1535, deforming from the material of control first sole region 1520.

As illustrated in fig. 15J-K, the first sole region 1520 may extend throughout the entire thickness of the midsole 1502. Alternatively, first sole region 1520 may be limited to certain areas of the midsole, such as the forefoot and heel regions. For example, the shoe may have a first sole region positioned near the forefoot or heel. In some embodiments, multiple first sole regions may be used for the entire shoe. This may be the case where different parts of the shoe have different sole characteristics.

For example, the outsole may be made of rubber, with TPU added in predetermined areas. For example, as shown in fig. 15J, 15K, and 16-19, the sole 1500 may include a midsole portion 1502 and an outsole portion 1504, as shown in fig. 15K-16. Outsole portion 1504 may include a lattice structure 1540 having a plurality of deformation zones 1530, the deformation zones 1530 being volumetrically larger than the volume of an individual expanded particle and causing the expanded particle foam to deform adjacent deformation zones. The material of the first sole region 1520 may press or move downward into these deformation regions 1530 under a compressive load on the midsole 1502. Deformation region 1530 may either extend throughout lattice structure 1540 or be localized to certain areas of sole 1500. For example, fig. 15B, 16, 17, and 18 illustrate deformation zones 1530 of different sizes and positioned at different locations. Accordingly, portions of first sole region 1520 may deform downward into a deformation zone during use, e.g., when a wearer steps down on a portion of a shoe.

Further, some embodiments may include regions without deformation zones, or regions with deformation zones with thin layers of grid material, as shown in fig. 17. Such a thin layer of grid material may be used to control the deformation of the expanding foam and form the controlled deformation region 1535. Thus, the application of pressure on the footwear may cause deformation of the granular foam throughout the thickness of the midsole 1502 or may be confined to certain areas of the midsole, such as the forefoot and heel areas.

As illustrated in fig. 19-22, the structure of the sole may vary. For example, as shown in FIG. 19, footwear 1905 has a first sole portion 1910 and a first sole region 1920 with a relatively constant thickness along the length of the footwear. Forefoot region 1915 of first sole region 1920 has a substantially constant thickness, while a midfoot region of first sole region 1920 appears to become somewhat thicker moving from forefoot region 1915 toward heel region 1919. As depicted in fig. 19, the heel region 1919 has a relatively constant thickness. By varying the thickness of the expanded granular foam material, the mechanical properties of first sole region 1920 can be tailored to meet the desired specifications of the shoe and/or portions of the shoe.

In contrast, fig. 20-22 illustrate a plurality of shoes 2005, 2105, 2205 with various combinations of first sole regions 2020, 2120, 2220 and first sole portions 2010, 2110, 2210 having different thicknesses in different parts of the shoe. These differences are typically a result of the desired predetermined characteristics required for the footwear. Thus, it is possible to vary the geometry and/or thickness of the sole region and/or sole portion to form a sole having predetermined characteristics.

As illustrated in fig. 23, as an enlarged view, sole 2300 includes a layer 2380 positioned between first sole region 2320 and first sole portion 2310. Fig. 24 shows an assembled form of sole 2400, including layer 2480 positioned between first sole region 2420 and first sole portion 2410. Layers 2480, 2380 may include, but are not limited to, films such as decorative films, reflective films, protective films, conductive films, adhesive films, textiles, fabrics, and combinations thereof, as are known in the art. For example, as shown in fig. 23-24, layers 2380, 2480 are reflective films that extend along the entire length of the sole. In some cases, the films 2380, 2480 may be positioned in various portions or areas of the footwear. For example, a layer may include one or more pieces of material positioned at different locations between a first sole region and a first sole portion of a shoe. In particular, the protective film may be used for the areas with the highest bottom surface contact, and the reflective film may be used for the areas that are most clearly visible during operation.

In some embodiments, footwear 2502, 2602 may include a first sole region 2520, 2620 and a first sole portion 2510, 2610, as shown in fig. 25. First sole portion 2510, 2610 may include frame elements 2512, 2612. The frame elements 2512, 2612 may include ground-contacting surfaces. Thus, at least a portion of the first sole portion, i.e., the frame elements 2512, 2612, may act as an outsole. For example, as shown in FIGS. 25-26, bottom surface contacting surfaces may include cleats 2557, 2657.

In some examples, the ground-contacting surface of the footwear may be flat or substantially flat, provided with protruding elements, such as soles, brush elements, treads, any geometry known in the art, concave elements, and/or combinations thereof. The ground-contacting surface may include textured areas, smooth areas, tacky areas, and/or combinations thereof.

In some cases, portions of the ground-contacting surface advantageously have openings that communicate with the midsole and/or the first sole region. For example, as shown in the partial cross-section of the stud in figure 26. In some cases, the stud may include hollow studs 2658 that are filled with particulate foam. Some embodiments of the footwear may include hollow studs that enable the particle foam of the first sole region and/or midsole to deform into openings of the hollow studs during use.

As shown in fig. 25-26, the frame elements 2512, 2612 may extend from below the foot to the upper side of the shoe. In particular, the frame elements 2512, 2612 may include support members 2514, 2614 that extend upward around the heel. Thus, in some cases, the frame element may act as a heel counter. For example, in some cases, the support member of the frame element, in combination with the granular foam, may provide support consistent with conventional heel counters.

Additionally, examples of frame elements are shown in fig. 25-31, with fig. 25-31 depicting embodiments of the frame elements 2512, 2612, 2712, 2812, 2912, 3012, 3112 and the support members 2514, 2614, 2714, 2814, 2914, 3014, 3114 in which the support members of the frame elements at least partially encompass the sides of the heel region. The support members 2525, 2625, 2725, 2825, 2925, 3025, 3125 are integral parts of the support elements and the frame elements. The positioning of the support member on the frame element and/or the positioning of the support member may vary.

As depicted in fig. 25-26, frame element 2512 can include a portion of the midfoot region. In the forefoot region, as shown in fig. 25, frame element 2512 is defined on the sides of the upper.

The frame element 2712 shown in fig. 27 extends the support element 2714 upward in the heel region. Furthermore, in the forefoot region 2715, the frame element 2712 may also include a support member 2716, which is arranged on the lateral side of the heel region.

The support elements of the frame elements 2512, 2712 may include different geometries depending on the use of the shoe. Various configurations of the support elements and frame elements are illustrated in fig. 25-31. For example, fig. 25-27 illustrate various frame elements that extend upward beyond upper 2565, 2665 from the heel to the midfoot of the shoe. Other embodiments, shown in fig. 28-29, including the support elements 2814, 2914 of the frame elements 2812, 2912, are found primarily in the heel region of the frame elements 2812, 2912.

In some cases, the design of the frame element and/or the support element may be formed based on predetermined constraints. For example, predetermining values for body weight, bulkiness, etc., and the need to minimize pressure points may play a role. Fig. 28 shows an inside view of the frame element 2812. In this case, the geometry of the support element may allow more mobile movements. Further, a material that reduces the weight of the frame member according to this configuration is possible. For example, the frame element in combination with the granular foam may have a weight less than a conventional heel counter of a shoe while serving as a heel counter.

Fig. 29 illustrates a rear perspective view of the frame element 2812 of fig. 28. Support element 2912 is configured to wrap around the heel. Support member 2914 has a different support member 2925. Support members 2925 may be positioned so that they are free to move while still providing support to the user during use. For example, fig. 29 illustrates support member 2914 with supports 2925 positioned to free the achilles tendon to move. As illustrated, the number of potential contact points between the support and the Achilles tendon is reduced, helping to provide a comfortable fit.

As shown in fig. 30, sole 3000 may include a first sole portion 3010 and a first sole region 3020. First sole region 3020 may include a granular foam. As shown in fig. 30, a first sole region 3020 made of granulated foam may be formed in the shape of the first sole portion 3010. In some embodiments, first sole region 3020 may have one or more regions of a predetermined thickness. As shown in fig. 30, first sole region 3020 may include one or more raised regions 3047. In some embodiments, the frame element 3012 may include at least one rod 3028 that facilitates securing the frame element 3012 to the midsole.

Fig. 31 shows a first sole region 3120, fitting the first sole portion 3110, i.e. the frame element 3112. The shape of protruding areas 3147 on first sole region 3120 are configured to conform to the shape of openings 3149 in frame member 3112 between bar elements 3128. Thus, as shown in fig. 31, the rods may be at least partially surrounded by the granulated foam of the finished shoe. The granular foam of first sole region 3120 may have a thickness ranging from about 0.2 millimeters to about 20 millimeters. In some embodiments, a granular foam having a thickness between 0.5mm and 10mm will be used. For example, some shoes may include a first sole region having a thickness ranging from about 0.7 millimeters to about 5 millimeters.

As shown in the cross-sectional view of the shoe shown in fig. 32, the thickness of the protruding region 3247 of the granular foam component 3255 may substantially correspond to the thickness of the stems 3228, which stems 3228 are proximate to the protruding region of the granular foam. Thus, as shown in figure 32, the protruding region 3247 of the first sole portion 3210 fits within the opening 3249 in the first sole region 3220. The fit between the protruding region 3247 and the opening 3249 may be configured such that any gap between the opening 3249 defined by the rod member 3228 in the frame element 3212 and the protruding region of the first sole region 3220, 3247 is substantially minimized. This may reduce and/or inhibit the ingress of water and/or dirt into footwear having such sole structures. In addition, as shown in fig. 32, upper 3265 may position upper 3265 proximate first sole region 3220 and frame element 3212. Upper 32 is shown to include a shock absorbing plate 3267, a midsole wall portion 3269, and an upper portion 3271.

As illustrated in fig. 33, upper 3365 includes a shock absorbing plate 3367 and a midsole wall portion 3373. The suspension plate 3367 and midsole wall portion 3373 are made of a granular foam as shown in FIG. 33. The granular foam component may be molded separately and bonded together to form portion 3375, which is incorporated into upper 3365. Upper 3265, 3365, 3465 may be located adjacent to first sole region 3220, 3320, 3420, which is located adjacent to frame elements 3212, 3312 of first sole portions 3210, 3310, 3410, 3412, as shown in fig. 32-34. .

Alternatively, in some cases, the upper portion may include a shock absorbing plate and midsole arms that form a unitary piece for use in the described embodiments.

The thickness of the foam particles in each assembly may be based on predetermined characteristics and/or requirements for a particular component. The thickness of the granular foam used in the midsole wall ranges from 0.2 millimeters to about 20 millimeters. In some cases, a midsole wall portion having a thickness in the range of about 0.5 millimeters to about 10 millimeters may be included. The midsole wall portion may have a thickness in a range from about 1 millimeter to about 4 millimeters. The granular foam for a vibration damping deck may have a thickness ranging from about 0.2 millimeters to about 20 millimeters. In some cases, a damping plate having a thickness in a range of about 0.5 millimeters to about 10 millimeters may be included. The damper plate may have a thickness in the range of about 1mm to about 4 mm.

An example of a sole structure, particularly for sports that utilize studs, such as football, hockey, football, baseball, or the like, as shown in figure 34, includes an upper 3465 with midsole walls 3473 and a shock absorbing plate 3467, a first sole region 3420, and a frame element 3412. Midsole wall portion 3473, cushioning plate 3467, and first sole region 3420 may all be made of a granular foam. In addition, some embodiments may also include a granular foam insole. Thus, in some examples of a sole, the shock absorbing plate 3467, the first sole region 3420, and a granular foam insole (not shown) may each have a thickness ranging from 3 millimeters to about 9 millimeters, with a total thickness of granular foam of about 9 millimeters. In this example, the thickness of the midsole wall portion may be approximately 2 mm. The particulate foam may be formed at these sizes, and/or a greater thickness of the particulate foam may be formed and cut or divided into appropriate thicknesses and/or sizes. This is a non-limiting embodiment, however, in other examples or embodiments, shock absorbing plate 3467, first sole region 3420, and the granular foam insole may have any suitable thickness corresponding to any range of thicknesses described herein. Additionally, the insole may include a fabric portion on at least one side. For example, the fabric layer may be positioned adjacent to the side under the foot of the wearer in use.

As shown in the cross-sectional view of the shoe shown in fig. 35, upper 3565 is attached directly to first sole portion 3510. Accordingly, upper 3565 includes an upper 3571 and a shock absorbing plate 3567 to serve as a first sole region, i.e., a midsole. Upper 3565 is located proximate to first sole portion 3510, such as frame member 3512. As shown in fig. 35, the thickness of the damper plate in this structure may be about 0.5mm to about 20 mm. In some cases, the damper plate 3567 has a thickness ranging from about 1.0 millimeters to about 15 millimeters. The damper plate 3567 may have a thickness ranging from about 2 millimeters to about 10 millimeters.

In an alternative embodiment, the assembly, specifically the shock absorbing plate and midsole wall portion, may be cut from a sheet of granulated foam, processed, and mounted directly to the frame member.

The shock absorbing plates 3367, 3467, 3567 and midsole wall portions 3373, 3473, 3573 are made of the granular foam of fig. 33-35. The granular foam components may be separately molded and bonded together to form upper portions 3371, 3471, 3571, which are incorporated into upper 3565. For example, the particulate foam components, particularly the shock absorbing plates 3367, 3467, 3567 and midsole wall portions 3373, 3473, 3573 may be cut from a sheet of particulate foam material, then processed and assembled to the frame elements.

Fig. 36-37 illustrate an upper 3665, 3765 having midsole wall portions 3673, 3773 made from a granular foam component to be stitched to the upper portion and the granular foam plate (shown in fig. 38). As shown in fig. 38, a suspension plate 3867, and a midsole wall 3873, including a fabric 3881, are laminated to the granular foam suspension assembly. Fabric 3881 may be any material known in the art. The use of fabric 3881 provides additional support to the granular foam so that the granular foam components can be stitched together. The use of a fabric reduces the likelihood of tearing of the particulate foam, particularly in areas where the thickness of the particulate foam is relatively thin.

As illustrated in fig. 38, fabric 3881 faces the exterior of the upper on the granular foam cushioning assembly, and the interior of the upper on the midsole wall portions. The fabric may be a foam component laminated to the granules such that the fabric faces a lateral side of the upper, an interior of the upper, and/or combinations thereof. As shown, upper 3871 is attached to midsole wall 3873 and shock absorbing plate 3867 using a combination of needles and/or adhesives. In some instances, the particulate foam component may be applied to the upper using any bonding method known in the art of bonding materials, including, but not limited to: stitching, adhesive, bonding, welding, ultrasonic bonding, other bonding methods known in the art, and combinations thereof.

FIGS. 39-40 illustrate embodiments of a shoe utilizing a midsole wall of a granulated foam, and a granulated foam cushioning plate. In some cases, the footwear 3905, 4005 may include additional granular foam insoles. Insoles made of granular foam may have a thickness in the range of about 0.5mm to about 20 mm. In some cases, an insole may comprise a granular foam having a thickness in a range from 0.75 millimeters to about 10 millimeters. Insoles made of granular foam may have a thickness in the range of about 1mm to about 4 mm. The frame element may be constructed of any suitable material known in the art or any combination of materials, including but not limited to polyamides, such as polyamide 12, polyamide 11, or other polyamides known in the art, and/or composites thereof, thermoplastic polyurethanes, other materials known in the art, and/or combinations thereof.

In some embodiments, the frame element 2512 can be constructed from a variety of materials. For example, frame element 2512 may be constructed of polyamide, while at least a portion of cleats 2557 may be supported by TPU. As in the example of frame element 2512 shown in fig. 27 and 43, may be constructed largely or entirely of polyamide compound, while the spike tips 2561, 2661 are constructed of TPU material.

The choice of materials for the frame element and/or portions of the support member(s) will be apparent to those skilled in the art based on the intended use. For example, the material selected for shoes used on natural turf may be different from the material selected for shoes used indoors or for artificial turf.

The geometry and/or materials of the frame elements may depend on the use of the footwear. For example, football shoes, basketball shoes, soccer shoes may require additional support around the heel. The support elements may be positioned such that they provide support for use of the shoe where needed. Fig. 25-27 illustrate various frame elements in which the support element extends upward beyond the upper from the heel to the midfoot. In addition, embodiments include a support element in a forefoot region of the footwear. As shown in fig. 41-42, according to some embodiments of the invention, the sole includes a midsole having a first sole region 4120, 4220, shown as a granulated foam, and a deformation region 4130, 4230 in a first sole portion 4110, 4210. The deformation zone may be defined by a boundary of the sole portion. In general, the deformation zone has a volume greater than the volume of the individual expanded particles of the granular foam and is positioned to cause deformation of the granular foam under pressure loading of the sole. The sole also includes a frame member that at least partially surrounds the midsole and limits deformation of a first sole region of the midsole under compressive loading of the sole.

As shown in fig. 41-42, the outer layers 4185, 4285 of the granular foam may be positioned in the frame elements 4112, 4212. The outer layer of the granular foam may be flattened, textured, shaped, and/or have various regions comprising combinations thereof. Some examples of the outer layer of the particulate foam may include additional materials such as films, fabrics, and the like. For example, the outer layer 4285 of the granular foam may include a film on the outer surface to impart the foam color to the granules, as shown in fig. 42. Alternatively, such a film may be transparent. In some cases, such films may inhibit discoloration of the material and/or may impart strength and/or deformation properties to the material.

As shown in FIGS. 43A-C, a shoe 4305 frame element 4312, the frame element 4312 having different configurations on the medial and lateral sides of the shoe 4305. Fig. 43B shows the medial side of the shoe 4305 and frame element 4312. Medial support element 4387 is configured to provide heel support for a user during use while not reducing and/or inhibiting mobility. Lateral support element 4389 is shown in fig. 43C, which provides additional support to the lateral side of the foot. These configurations of the support elements may vary depending on the application.

In the following, further examples are described to facilitate the understanding of the present invention:

1. a midsole, wherein the midsole comprises:

a first sole region comprising a granular foam; and

a deformation zone located proximate to the first sole region, wherein the deformation zone comprises a volume greater than a volume of a single expanded particle of the granular foam and is configured to deform foam granules of the first sole region under sole pressure.

2. The sole of embodiment 1, wherein said deformation is in a lateral direction.

3. The sole according to the previous embodiment, wherein said deformation zone is at least partially provided as an empty space.

4. A sole according to any of the preceding embodiments, wherein the midsole further comprises a control element that limits particle foam deformation of the first sole region.

5. The sole of any of the preceding embodiments, wherein the control element comprises at least a portion of the deformation zone.

6. The sole of any of the preceding embodiments, wherein the control element comprises a groove.

7. The sole according to any of the preceding embodiments, wherein the control element at least partially bounds a boundary of the first sole region side.

8. The sole of any of the preceding embodiments, wherein the control element is free of particles of the particulate foam.

9. The sole according to any of the preceding embodiments, wherein the deformation zone comprises a material that deforms the material of the first sole region.

10. The shoe sole of embodiment 9, wherein the yielding material has a deformation hardness that is 5% -40% greater than the deformation hardness of the first sole region.

11. A shoe having a sole according to any preceding embodiment.

12. The sole according to any preceding embodiment, further comprising:

a second sole region comprising a granular foam and providing a progressively increasing deformation stiffness in at least one predetermined direction.

13. The sole of embodiment 12, wherein the increase in deformed hardness is due at least in part to an increase in density of the granular foam in the second sole region in at least one predetermined direction.

14. The sole according to any one of embodiments 12-13, wherein the at least one predetermined direction extends from a medial side of the sole to a lateral side of the sole.

15. The sole of any of embodiments 12-14, wherein the increase in deformed stiffness in the second sole region is less in the region of the second sole region where impact occurs and greater on the opposite side of the second sole region.

16. The sole of any of embodiments 12-15, wherein the second sole region slopes inwardly at least toward the impact region due to greater compression of the second sole region in the impact region.

17. The sole according to any one of the preceding embodiments, wherein at least one of the shape, size and location of the deformation zone provides a predetermined characteristic to the deformation zone.

18. The sole according to any of embodiments 12-16, wherein the first sole region extends into the forefoot region, and wherein the second sole region extends into the heel region.

19. A sole as in any of embodiments 12-16, wherein the first sole region and the second sole region at least partially overlap.

20. Sole, it includes:

a midsole comprising a first sole region, wherein the first sole region comprises a granular foam; said deformation zone within the midsole comprising a volume greater than the volume of the individual expanded particles and positioned such that in the event of sole load pressure, the foam particles of the first sole region deform laterally; and

a frame member at least partially surrounding the midsole and limiting lateral deformation of the midsole under sole load pressure.

21. The sole of embodiment 20, wherein the frame element completely surrounds sides of the heel region, and wherein the frame element only partially surrounds sides of the forefoot region.

22. The sole according to any one of embodiments 20-21, wherein the frame member further includes a support member, wherein the support member is positioned lateral to the heel region.

23. The sole of any of embodiments 20-22, wherein the midsole further comprises a control element that limits lateral deformation of the granular foam of the first sole region.

24. The shoe sole of embodiment 23, wherein the control element and the frame element at least partially coincide.

25. A sole as in any one of embodiments 20-24, wherein the frame member includes at least one rod for securing the frame member to the midsole.

26. The sole of embodiment 25, wherein the at least one rod is at least partially surrounded by the granular foam of the midsole.

27. Sole, it includes:

a midsole comprising particles of a particulate foam; and

an outsole comprising at least one deformation zone, the deformation zone comprising a volume greater than a volume of an individual expanded particle of the particulate foam;

wherein the at least one deformation zone is configured to deform at least a portion of the granular foam of the midsole upon application of pressure to the sole;

wherein the outsole defines the deformation of the midsole when the sole is pressurized.

In the different arrangements or assemblies illustrated in the figures and described above, components and steps not shown or described are still possible. Similarly, some features and subcombinations are of utility and may be employed without reference to other features and subcombinations. The examples of the present invention are for illustrative purposes and not to limit the invention, and alternative examples will be apparent to the reader of this patent. The invention is therefore not limited to the description above or in the drawings, but various embodiments and modifications do not depart from the scope of the appended claims.