The present invention relates to a shoe sole as well as a shoe comprising such sole.
To date, many shoe soles have been proposed, which generally comprise a more or less complex structure, and usually with a higher or lower hardness based on the user's needs and the activity for which they are provided.
The soles commonly used or conceived are generally too “soft” or too “rigid”.
To this regard, the soles which are too soft are comfortable to wear and do non stiffen and excessively prevent the user's foot mobility, but in the case they meet or are over a ground roughness, such as a rock, they deform without being able to guarantee a dumping such to prevent the transmission of the deformation to the user's foot.
Instead, the soles which are too rigid, if on one side they dampen or, de facto, protect the respective foot of a user from any deformation caused by ground roughnesses, they cannot be used in a comfortable and desired way.
US2009260259A1, US2006010716A1 and EP1985195A1 teach respective solutions according to the state of the art.
One object of the present invention is that of providing a new shoe sole.
Another object of the present invention is that of providing a new shoe sole which is able to perfectly adapt even to irregular grounds, as well as to the roughnesses thereupon.
Another object of the present invention is that of providing a new sole, which is suitable for inferiorly deforming in a localized manner, thereby preventing the transmission of the deformations encountered to a user's foot.
Another object of the present invention is that of providing a sole capable of providing stability, traction ad adherence in any situation.
Another object of the present invention is that of providing a new shoe provided with a sole as above.
According to one aspect of the invention, a sole is provided according to the present principles.
The present application refers to preferred and advantageous embodiments of the invention.
Other features and advantages of the invention will be more apparent by the description of embodiments of a sole and a shoe, given by way of example in the accompanying drawings, wherein:
In the accompanying drawings equal parts or portions are marked with the same reference numbers.
With reference to
The first component 2 can be made of a material selected from the group comprising natural or synthetic elastomers, thermoplastic materials, thermosetting materials and rubbers. Moreover, the first base component 2 can be reinforced or not, for example reinforced by means of unidirectional fibres, woven or non-woven fabrics, natural fibres, synthetic fibres, metal fibres, aramid fibres, glass fibres, carbon fibres and/or composite fibres.
The sole then comprises a second top component 3 connected to the first base component 2, preferably directly connected, i.e. with reciprocal parts, in particular edge parts, in contact with each other and, thus, preferably without interposition of other components or elements of the sole. According to a variant, between the first component 2 and the second 3 component or, better, between respective edge portions, the lower portion of an upper 6 could be placed, for example, moulded.
To this regard, the first 2 and the second 3 component can be connected in a removable way (for example in order to disassemble and replace the third component, which will be discussed below), if desired through hinges, joints or mechanical couplings (shape engagements, fit insertions, interlocking, etc.) or can be fixed to one another, if desired with a glue or through welding.
The second top component 3 is preferably made of a rigid ore semi-rigid material and is designed to guide the foot of a user during the movement as well as to allow a controlled foot torsion in the various directions.
The second top component 3 can be made of a single material or a plurality of materials, if desired EVA (ethylene-vinyl acetate) with hardness equal to 80-90 shore C degrees, or of thermoplastic polymers, such as TPU (thermoplastic polymer), with hardness equal to 60-70 shore D degrees. Moreover, such component 3 can be made of several parts or be in a single piece.
The second component 3 has the function of providing stability as well as flexibility to the respective sole and shoe. Such second component 3 performs the function of guiding the foot during the walk/run or movement and allows, at the same time, a controlled torsion in the various directions. To this regard, the second component 3 could be so as to provide a uniform or non-uniform resistance to bending, with the meaning that it could be such to withstand to bending following sole movements or deformations along established directions, and not to withstand or however not to oppose resistance to bending along other directions or it could show different resistance to deformation in respective different parts.
The sole 1 is then provided with at least one third intermediate component 4 placed between the first base component 2 and the second top component 3 or better in a receiving zone RZ delimited by the same, if desired with part of an upper 6.
The third intermediate component 4 has an hardness lower that the second top component 3 and is designed to control and dissipate the deformation of the first base component 2, so as to prevent or reduce the deformation propagation from the first base component 2 to the second top component 3, and then to the user foot wearing the sole 1, or better the respective shoe 5. The third intermediate component 4 is advantageously made of an expanded, light and with a low density material.
To this regard, the first base component 2 is such to deform in a localized manner when it engages an obstacle or a roughness R (see
In essence, the third component 4 is designed to support the body weight of a user on the second component 3 and to prevent the pressing of the latter, controlling at the same time the first component 2 deformation, so as to keep the latter substantially in the correct shape when it engages a roughness R on the ground.
The third component 4 preferably comprises an elastomer (more or less expanded) of organic or inorganic nature, for example EVA or PU with different degrees of resilience and compression hysteresis. Alternatively, the third component could be a fluid, such as a gas, in that case the receiving zone of the same would be fluid or gas tight.
Moreover, the third component 4 can comprise, as will be better said below, two or more layers coupled with each other, both one over the other or side by side.
The third component 4 is not glued to the first 2 and the second 3 component. To this regard, the third component 4 is in any case, preferably, in contact with the respective internal faces of the first 2 and second 3 component. Moreover, the third component 4 could be coated by means of a suitable lubricant.
According to a particularly advantageous embodiment:
As regard, then, the compression, the measure unit thereof is the percentage of deformation with respect to the initial thickness subjected to a force of 1.8 KN for a determined time period at a determined temperature.
According to the present invention, a shoe 5 is then provided, comprising a sole 1.
The shoe 5 comprises an upper 6, which is connected to the second top component 3 and, if desired at the top of the third intermediate component 4.
If desired, the upper 6 delimits, together with the first 2 and the second 3 component a receiving zone RZ of the third component 4.
A sole according to the present invention is capable of adapting and deforming correctly at a ground roughness R, so as to “copy” or match in a complementary manner to such roughness R.
To this regard, should the shoe 5 rest on a roughness R (during a walk, a run, etc.), the third component 4 would deform at a respective second deformation zone DZ4 close to the first deformation zone DZ2 of the first component 2, thereby allowing a controlled and localized deformation of the first component 2, but without transferring the deformation to the second component 3 or to the bottom wall 6a of the upper 6 and, thus, to the user's foot; that is to say that the second deformation zone DZ4 is in any case confined and not extended for the entire height or thickness of the third component 4, so as not to involve the second component 3 or the bottom wall 6a of the upper 6 or anyway, the user's foot.
This assures a higher adherence to the ground and a reduced wear of the tread layer 2a of the first base component 2, this because the surface of a sole 1 according to the present invention in contact with a roughness R is actually larger than the traditional soles, wherein the deformation of the respective tread is not controlled and is not such as to allow an adjustment complementary to the roughness R. Thus, given the same applied forces, the contact surface of a sole according to the present invention is higher than the soles according to the state of the art and guarantees a lesser wear than that of the present invention.
With reference now, in particular, to the not limiting embodiment shown in
The first tread lower layer 2a and the second upper layer 2c are provided only at the intermediate section 2d, while the annular section 2e is not provided with blocks 2b.
The annular section or each lateral section 2e can show a first lower length 2e1, extending upwards from the outer edge of the intermediate section 2d and is substantially tapered or anyway with distance from the sole centre-line decreasing when approaching the intermediate section 2d, as well as a second upper length 2e2, extending upwards from the edge of the first lower length 2e1, and is substantially tapered or anyway with distance from the sole centre-line decreasing when moving away from first lower length 2e1.
Alternatively, the annular section or the lateral sections 2e can have a substantially curved configuration with concavity facing toward the inside of the sole 1 or the receiving zone RZ of the third component 4.
The first component 2 is basically composed of a plate made in a single piece, with substantially constant thickness, even if it can have lateral sections 2e with thickness lower than the intermediate section 2d.
The second component 3 can have, instead, a base wall 3a, if desired substantially flat and annular or delimiting a central through or, alternatively, not annular opening 3b.
The second component 3 can comprise also a first tubular or annular wall or one or more first lateral walls 3c extending upwards, in use, from the outer edge of the base wall 3a. The first tubular or lateral wall 3c can extend, for example, substantially at right angle with respect to the base wall 3a.
The second component 3, if desired, is provided with a second tubular or annular wall or one or more second lateral walls 3d, extending downwards, in use, from the outer edge of the base wall 3a. The second tubular or lateral wall 3d can extend, for example, substantially at obtuse angle or inclined or slightly curved with respect to the base wall 3a, so as to be tapered or with distance from the sole centre-line decreasing when approaching the base wall 3a.
The upper, in use, end of the first component 2 is enclosing and abutting as well as in connection on the second tubular or lateral wall 3d.
Moreover, the second tubular or lateral wall 3d can show a first portion 3d1 having higher width, and then a second portion 3d2 having lesser width so as to delimit a step or shoulder 3e external or facing the outside of the sole 1. In that case, the upper, in use, end of the first component 2, for example the upper, in use, end of the annular section 2e, for example of the second upper length 2e2 of the latter, is enclosing and abutting as well as connected (for example welded or glued) on the second tubular or lateral wall 3d, for example on the second portion 3d2 of the latter.
The first 3c and/or the second 3d tubular wall extend for the entire sole perimeter, that is to say from the front to the rear and along both sides of the same.
Alternatively to a first and a second tubular wall, respective sections of lateral walls can be provided, extending from respective perimeter portions of the base wall 3a, for example two sections of first lateral wall and two sections of second lateral wall, each extending along a respective side of the sole.
The third component 4, instead, is placed in a receiving zone RZ delimited by the internal face of the first component 2, which is defined by the internal face of the intermediate section 2d and the annular section or lateral sections 2e, and by the internal and lower face of the second component 3 or, better, by the internal and lower face of the base wall 3a and of the second tubular or lateral wall 3d.
In such case, if the base wall 3a is annular, then the receiving zone RZ is delimited also by part of the upper 6 or by a bottom wall 6a of the same, otherwise the receiving zone RZ is delimited only by the components now indicated.
Anyway, the third component 4 advantageously substantially fills the receiving zone RZ or however it is in contact against the internal face of the first component 2 or the inner face facing, in use, downwards of the second component 3, this is to say that the third component 4 engages and abuts in a substantially continuous way against all the faces delimiting the respective receiving zone RZ.
With reference more in detail to the upper 6, the upper can be housed and connected (glued, sewed, etc.) to the second component 3, for example with a portion housed inside the cradle zone delimited by the internal and upper face of the second component 3 or, better, by the internal and upper face of the base wall 3a and of the first tubular or lateral wall 3c.
More particularly, the upper 6 comprises a bottom wall 6a placed resting on the internal and upper face of the second component 3, for example of the base wall 3a, as well as a tubular lateral wall 6b extending upwards from the outer edge of the bottom wall 6a.
In
With reference to
The lower plate-like element 4a shows, for example, density different from the upper plate-like element 4b.
Thanks to such expedient, the sole is in particular suitable for the use (walk, running) on uneven grounds, guaranteeing however an excellent stability, traction and adherence. In that case, it is possible to obtain the first component 2 and the lower layer element 4a so that they are very deformable, without transferring, however, a deformation to the upper layer element 4b and, thus, the user.
Instead, the embodiment illustrated in
The rib/s 2g and/or the shank sections 3g extend/s within the receiving zone RZ of the third component/s so as to delimit or split, actually, the sole in one or more differentiated deformation zones DDZ. In each zone a respective third intermediate component 4 can be placed or the same component 4 can extend and be housed in all the differentiated deformation zones DDZ.
To this regard, according to the embodiment shown in the figures, the sole provides for each rib 2g a respective shank section 3g, i. e. a shank section vertically, in use, substantially aligned to the respective rib 2g, in such a way that by deforming the first component 2 an abutment of the rib 2g or of a tip 2h thereof is obtained on the shank section 3g or on a free end of the same. Moreover, the rib or the ribs 2g can comprise a tip 2h intended to be slidingly or loosely (that is not to size) housed in a groove 3h formed in the free end of the or of a respective shank section 3g, so that the tip 2h of the rib 2g is slidably housed inside the groove 3h of the shank section 3g, thereby promoting the engagement between the rib 2g and respective shank section 3g, after the deformation of the first component 2, if desired, once the same engages a roughness R on the ground.
The rib/s 2g and/or the shank sections 3g extend, for example, substantially parallel to the sole direction F-R, that is along the longitudinal axis of the sole or transversally or orthogonally to such direction.
The rib/s 2g and/or the shank sections extend, for example, substantially parallel to the sole direction F-R (see for example
The rib 2g can be formed through a folded or curved portion of the first component 2, so as to delimit a respective groove 2m open toward the outside of the first component 2, and thus, in use, downwards. In essence, in that case, the base component 2 has one or more grooves 2m, each substantially aligned with a respective rib 2g, so that it shows for each differentiated deformation zone DDZ a respective substantially flat or slightly curved section 2n of the first component 2, designed to come into contact with the ground, which section is separated from the substantially flat or slightly curved sections 2n of the other differentiated deformation zones.
Moreover, the rib/s 2g and/or the shank section/s 3g can be designed to provide a stopping point or stop line of the deformation of the first component 2.
To his regard, in fact, when the first component 2, during the run or the walk, engages or passes over a roughness R, it would deform, this causing, as a result of a predetermined deformation, the impact of the rib 2g or a shank section 3g on the surface facing thereto of the second 3 or first 2 component.
With reference to the embodiment of
In that case, the base wall 3a of the second component 3 would not be annular and would not delimit any central through opening.
Alternatively, see for example the embodiment illustrated in
According to such variant, the receiving zone RZ of the third intermediate component 4 is delimited only by first component 2, second component 3 and intercepting member or filter 7, so that the intermediate component 4 is completely enclosed between the first component 2, the second component 3 and intercepting member or filter 7.
The intercepting member or filter 7 would be, in that case, designed to isolate, together with the first 2 and second 3 component, the intermediate component 4 with respect to the upper 6 and the foot of a user.
As it will be understood, a sole according to the present invention is capable of optimally adapting to uneven ground as well as the roughnesses present on the same, and can deform lowerly in a localized manner, without transferring deformations to the user's foot.
Moreover, a sole according to the present invention is also stable and has high traction and adherence thanks to the combination of above illustrated components.
A sole according to the present invention has in essence an operation similar to that of a tyred wheel, wherein the base component corresponds to a pneumatic tyre, the top component to a wheel rim and the intermediate component to an inner tube.
With reference to the solutions according to the state of the art, it is noted that the same do not teach a sole and a shoe as those according to the present invention.
To that regard, as far as US2009260259A1 is concerned, it teaches a solution having an external sole, an intermediate sole and a plate-like support group extending up to the external sole. US2009260259A1 does not specify that the plate-like support group is in a material harder than the intermediate sole.
Moreover, as it will be noted, the plate-like support group includes lateral fins, extending up to the external sole and enclose partly the intermediate sole, so that the intermediate sole is not able to prevent or reduce the propagation of deformations from the outer sole to the plate-like support group, but instead, every stress imparted to the external sole, is transferred unchanged, through the fins, to the plate-like support group and, thus, to the user's foot.
Modifications and variations of the invention are possible within the scope of protection defined by the claims.
Number | Date | Country | Kind |
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102015000015601 | May 2015 | IT | national |
This is a division of co-pending application Ser. No. 15/156,915 filed May 17, 2016, the entirety of which is incorporated herein by reference.
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Number | Date | Country |
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1985195 | Oct 2008 | EP |
Number | Date | Country | |
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20210219656 A1 | Jul 2021 | US |
Number | Date | Country | |
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Parent | 15156915 | May 2016 | US |
Child | 17222441 | US |