ITTO20130148A1 - HEEL WITH REINFORCEMENT PLUG FOR FEMALE FOOTWEAR WITH HIGH HEEL - Google Patents

Description

DESCRIPTION

â € œHEEL WITH REINFORCEMENT PIN FOR WOMEN'S HIGH HEEL SHOESâ €

TECHNIQUE SECTOR

The present invention relates to a heel for high-heeled female footwear (ie a heel having a height greater than 5 cm).

ANTERIOR ART

To increase the comfort of a high-heeled women's shoe (i.e. to reduce the mechanical stresses to which the foot is subjected when walking with a high-heeled women's shoe), it was proposed to make the heel vertically elastic (i.e. It has been proposed to introduce a vertically directed elasticity in the heel).

To make the heel vertically elastic it has been proposed to divide the heel into an upper portion and a lower portion that can translate vertically with respect to each other and to interpose an elastic body between the two portions that establishes a mechanical connection between the two. portions themselves; the elastic body can be constituted by a metal spring (as for example described in the patent application FR2235655A1), or it can be constituted by a â € œsoftâ € element in plastic material (as for example described in the patent application DE8316581U1). However, this known solution has various drawbacks in that it requires a certain number of additional components, entails a significant complication at the level of the production process and is applicable only to a limited type of heel.

Patent application FR1002135A1 describes a female shoe provided with a heel in which a plurality of horizontal slits are obtained which give the heel a certain vertical elasticity; however, the solution described in this patent application does not allow to obtain an optimal walking comfort as the user clearly perceives a “transversal instability” (ie perpendicular to the walking direction).

Patent applications CH212632A, GB238134A and FR1247874A1 describe a female shoe provided with a heel, in whose external surface a plurality of horizontal grooves are obtained which have a modest depth (in practice not more than one or two millimeters) and are shaped like â € œUâ € to embrace the entire external surface; however, the solutions described in these patent applications do not allow to give the heel an adequate vertical elasticity.

DESCRIPTION OF THE INVENTION

The object of the present invention is to provide a heel for a high-heeled female shoe that is free from the drawbacks described above and, at the same time, is easy and economical to produce.

In accordance with the present invention, a heel is provided for a high-heeled female shoe according to what is stated in the attached claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will now be described with reference to the attached drawings, which illustrate some non-limiting examples of embodiment, in which:

Figure 1 schematically illustrates a high-heeled female shoe provided with a heel which does not form part of the present invention; â € ¢ Figures 2 and 3 are two different perspective views of the heel of Figure 1;

â € ¢ Figures 4, 5 and 6 are respectively a right side view, a rear view, and a left side view of the heel of Figure 1;

â € ¢ figure 7 is an enlarged scale view of a detail of figure 5;

â € ¢ Figure 8 is a perspective and vertical section view of an alternative embodiment of the heel of Figure 1;

â € ¢ Figure 9 is an enlarged scale view of a detail of Figure 8 made according to an alternative embodiment;

â € ¢ Figure 10 is a perspective view of an alternative embodiment of the heel of Figure 1;

â € ¢ Figure 11 is a perspective view of a further embodiment of the heel of Figure 1;

â € ¢ Figure 12 is a rear view of the heel of Figure 11;

â € ¢ Figure 13 is a perspective and vertical sectional view of the heel of Figure 12;

Figures 14 and 15 are two different perspective views of a further embodiment of the heel of Figure 1;

â € ¢ figure 16 is an enlarged scale view of a detail of figure 15;

â € ¢ Figure 17 is a perspective and vertical section view of a further embodiment of the heel of Figure 1 in accordance with the present invention;

â € ¢ Figure 18 is a perspective view of a heel stiffener of Figure 17; And

â € ¢ figure 19 is an enlarged scale view of a detail of figure 17; And

â € ¢ Figure 20 schematically illustrates a different high-heeled female shoe provided with a heel.

PREFERRED FORMS OF IMPLEMENTATION OF THE INVENTION

In figure 1, the number 1 indicates as a whole a high-heel female shoe provided with a heel 2 which does not form part of the present invention. Preferably, the heel 2 has a height greater than 5 cm.

According to what is illustrated in Figures 2 and 3, the heel 2 comprises a main structure 3 of elongated shape which develops along a vertical axis 4. The main structure 3 in correspondence with a lower base 5 is able to rest on the ground and in correspondence with an upper base 6 opposite the lower base 5 is able to be fixed to a sole 7 of the shoe 1.

As illustrated in figures 2-7, the main structure 3 of the heel comprises two slots 8 which are oriented horizontally (i.e. they are perpendicular to the vertical axis 4) and are arranged staggered vertically (i.e. at a certain vertical distance one from the ™ other). Each slot 8 crosses the main structure 3 from side to side along a longitudinal direction 9 (i.e. parallel to the walking direction), and is blind along a transverse direction 10 (i.e. perpendicular to the walking direction and therefore to the longitudinal direction 9) originating from an internal portion of the main structure 3 and ending at a side 11 of the main structure 3. Furthermore, the main structure 3 of the heel comprises two slots 12 which are oriented horizontally (ie they are perpendicular to the vertical axis 4) and are arranged staggered vertically (ie at a certain vertical distance from each other). Each slot 12 crosses from side to side the main structure 3 along the longitudinal direction 9, and is blind along the transverse direction 10 perpendicular to the longitudinal direction 9, originating from an internal portion of the main structure 3 and ending at one side 13 of the main structure 3 opposite side 11.

Preferably, the slots 8 are vertically intercalated with the slots 12, i.e. a slot 8 is vertically followed and / or preceded by a slot 12. In the embodiment illustrated in Figures 1-7, two slots 8 with two slits 12 are provided between intercalated them vertically; according to different embodiments, the number of slots 8 and / or 12 may be different (for example, there may be only one slot 8 and only one slot 12, there may be only one slot 8 and two slots 12, there may be two slots 8 and three slots 12, there may be three slots 8 and three slots 12 ...).

According to a preferred embodiment, each slot 8, 12 affects more than half of the main structure 3 along the transverse direction 10.

The slots 8 and 12 reduce the vertical stiffness of the main structure 3 and therefore give the main structure 3 a vertical elasticity. Obviously, the number and size of the slots 8 and 12 must be chosen as a compromise between the structural strength (which cannot be too small) and the deformation capacity (ie elasticity). As an example, the thickness of the slots 8 and 12 is generally between 0.5 and 4 mm. Thanks to the presence of the slots 8 and 12, the main structure 3 of the heel 2 behaves entirely like a compression spring so that if the vertical load exceeds a limit value, as can occur during walking, the â € œspireâ € of the â € œspring 'compact vertically one on the other, preserving the main structure 3 from breaking. The layout of the slots 8 and 12 is important in order to avoid (or in any case limit) the lateral flexion of the main structure 3 of the heel 2. Generally, an even total number of slots 8 and 12 (i.e. a symmetrical pattern with respect to the longitudinal plane , ie parallel to the longitudinal direction 9, of the main structure 3) is preferred as it avoids the onset of unwanted spurious bending.

The main structure 3 of the heel 2 can be made in many materials. As an example, the main structure 3 of the heel 2 can be made of plastic material (ABS or a thermoplastic technopolymer possibly loaded with glass fibers) which is normally injection molded already in the final shape, or the main structure 3 of the heel 2 it can be made of metal material (typically aluminum due to its lightness) which is normally machined from solid by material removal.

Depending on the material used to make the main structure 3 of the heel 2, to further increase the structural resistance of the main structure 3 to transverse loads (i.e. direct along the transverse direction 10) it is possible to provide for the presence of a reinforcement pin 14 ( illustrated in figure 8) which is made of very resistant material (for example steel) and is inserted inside the main structure 3 where it also performs the function of supporting the heel. Preferably, the reinforcing pin 14 is used when the main structure 3 of the heel 2 is made of low resistance plastic material.

According to the embodiment illustrated in Figure 8, the heel 2 comprises the reinforcement pin 14, which has a cylindrical shape, extends coaxially to the vertical axis 4, and is inserted inside a cylindrical seat 15 which is centrally located in the main structure 3. According to a preferred embodiment, the reinforcement pin 14 is integral, or rigidly fixed (for example glued), to a lower portion 16 of the main structure 3 arranged below the slots 8 and 12 and is mounted slidingly with respect to an upper portion 17 of the main structure 3 arranged above the slots 8 and 12.

Preferably, in a central portion 18 of the main structure 3 arranged in correspondence with the slots 8 and 12 (i.e. arranged between the lower portion 16 and the upper portion 17 of the main structure 3) the reinforcing pin 14 has an external dimension smaller than the dimension of the seat 15 so as not to touch the wall of the seat 15. In particular, in correspondence with the central portion 18 of the main structure 3 the reinforcing pin 14 locally has a reduction in the external diameter.

According to the embodiment illustrated in Figure 9, in correspondence with the upper portion 17 of the main structure 3 the seat 15 is internally lined with an anti-friction bushing 19 which is externally integral (for example by gluing) to the main structure 3 and internally accommodates the reinforcing pin 14 in a sliding manner. The presence of the anti-friction bushing 19 allows to ensure a better sliding of the reinforcement pin 14 with respect to the upper portion 17 of the main structure 3 even in the presence of temporary deformations of the upper portion 17 itself (which are possible due to the mechanical stresses generated by walking) .

According to the embodiment illustrated in Figures 10 and 12, inside the main structure 3 each slot 8 or 12 ends with a cylindrical surface arranged parallel to the longitudinal direction 9; this cylindrical surface makes it possible to avoid the presence of sharp edges inside the slot 8 or 12, consequently improving the resistance to fatigue. According to the variant illustrated in Figure 10, in each slot 8 or 12 the cylindrical surface has a diameter greater than the vertical dimension of the slot 8 or 12; this solution can be used if the slots 8 and 12 are made by machining from solid with a tool that involves the removal of material. According to the variant illustrated in Figure 12, in each slot 8 or 12 the cylindrical surface has a diameter equal to the vertical dimension of the slot 8 or 12; this solution is preferable if the slots 8 and 12 are made directly by injection molding of the main structure 3 since it avoids the formation of undercuts.

According to the embodiment illustrated in figures 11-13, only one slot 8 and only one slot 12 are provided, and the reinforcement pin 14 is provided which is slidingly coupled to an anti-friction bushing 19 which is externally integral with the structure 3 at the upper portion 17 of the main structure 3.

According to the embodiment illustrated in Figures 14-16, the main structure 3 comprises a through hole 20, which passes through the main structure 3 from side to side along the longitudinal direction 10 and is arranged in a central position in correspondence with the slots 8 and 12 (i.e. in correspondence with the central portion 18 of the main structure 3). Preferably, the through hole 20 has an elongated cross section having the largest dimension oriented vertically (ie parallel to the vertical axis 4).

The through hole 20 divides the main structure 3 vertically into two semistructures 3a and 3b (ie in two columns 3a and 3b) parallel and facing each other. According to a preferred embodiment, each half-structure 3a and 3b comprises at least one slot 8 and at least one slot 12, and and in a half-structure 3a / 3b the slot 8 is vertically aligned with the slot 12 of the other half-structure 3b / 3a and the slot 12 is vertically aligned with the slot 8 of the other semi-structure 3b / 3a.

In the embodiment illustrated in figures 14-16, it is possible to use an odd number of slots 8 and 12, since the alternation of slots 8 and 12 in the two semi-structures 3a and 3b still gives the main structure 3 as a whole adequate symmetry with respect to a longitudinal plane (ie a plane parallel to the longitudinal direction 9). It is important to note that the transverse stresses (i.e. directed along the transverse axis 10) tend to open the cracks 8 and 12 of a semi-structure 3a / 3b but to close the cracks 8 and 12 of the other semi-structure 3b / 3a which, compacting, guarantee an adequate mechanical seal; on the other hand, the longitudinal stresses (ie directed along the longitudinal direction 9) are supported by the vertical compaction of the coils of the half-structure 3a or 3b subjected to compression.

The material used for the embodiment illustrated in Figures 14-16 is preferably a material of the metallic type which allows to obtain sufficient mechanical strength even in the presence of very reduced transverse thicknesses.

According to a possible embodiment, at least part of the slots 8 and 12 (i.e. all the slots 8 and 12 or only some of the slots 8 and 12) can be filled with viscoelastic material (i.e. a material that exhibits an intermediate rheological behavior between "purely viscous materials" and "elastic materials") to give a damping effect in favor of walking comfort.

According to a further embodiment, each slot 8 or 12 ends with a cylindrical surface arranged parallel to the longitudinal direction 9, with a diameter preferably greater than the vertical dimension of the slot 8 or 12.

In the embodiment illustrated in Figures 17-19, the slots 8 and 12 (which confer a vertical elasticity) are transferred from the main structure 3 of the heel 2 to the reinforcing pin 14. In this embodiment, the reinforcing pin 14 comprises an upper portion 21 which is integral (for example by gluing) to the upper portion 17 of the main structure 3, a lower portion 22 which is integral (for example by gluing) to the lower portion 16 of the main structure 3, and an intermediate portion 23 which seamlessly connects the lower portion 22 to the upper portion 21 and has a vertical elasticity thanks to the presence of the slots 8 and 12. The intermediate portion 23 of the reinforcing pin 14 it includes the slots 8 and 12, which give vertical elasticity to the intermediate portion 23 and have the construction characteristics described above.

In the heel 2 described so far, in its various embodiments, the shock-absorbing effect is therefore obtained by structurally unloading the main structure 3 (or, alternatively, the reinforcement pin 14) by means of the slots 8 and 12 which reduce the vertical stiffness by amplifying it at the same time the possibilities of movement.

The heel 2 described above has numerous advantages. In the first place, the heel 2 described above has an optimal vertical elasticity that allows to reduce the negative stresses on the foot and leg of the user of the shoe 1 without penalizing, at the same time, the walk that remains â € œnaturalâ € (i.e. the user's walk is not disturbed or in any case negatively influenced by the vertical elasticity conferred by the slots 8 and 12). This result is obtained thanks to the presence of cracks 8 and 12 of different types and interspersed with each other which allow to offer adequate resistance even to transverse loads.

Furthermore, the heel 2 described above can be applied to any type of shoe 1 without significant constructive complications; for example, figure 20 illustrates a high-heeled female shoe 1 which is provided with a heel 2 of the type described above and is completely different from the shoe 1 illustrated in figure 1.

Finally, the production process to make the heel 2 described above is particularly simple and fast and therefore economical. In particular, in the heel 2 described above it is the main structure 3 itself that adapts to external conditions thanks to its intrinsic morphological and constitutive characteristics without the addition of additional components. The possible use of the reinforcement pin 14 does not particularly complicate the production process since the reinforcement pins are already normally present in many heels for high-heeled women's shoes.

The advantages of the present invention are particularly evident in a high heel, ie when the heel 2 has a height greater than 5 cm. Therefore, the present invention finds advantageous application to a heel 2 for high-heeled female footwear 1, which heel 2 has a height greater than 5 cm.

Claims (10)

R I V E N D I C A Z I O N I 1) Heel (2) for women's high-heeled footwear (1); the heel (2) includes: a main structure (3) of elongated shape which in correspondence with a lower base (5) is able to rest on the ground and in correspondence with an upper base (6) opposite to the lower base (5) is able to be fixed to a sole (7) of the shoe (1) and is divided into a lower portion (16) and an upper portion (17) sliding together vertically; and a reinforcement pin (14) which is inserted inside a seat (15) obtained centrally in the main structure (3); the heel (2) is characterized by the fact that the reinforcement pin (14) comprises an upper portion (21) which is integral with the upper portion (17) of the main structure (3), a lower portion (22) which is It is integral with the lower portion (16) of the main structure (3), and an intermediate portion (23) which seamlessly connects the lower portion (22) to the upper portion (21) and has a vertical elasticity. 2) Heel (2) according to claim 1, wherein the intermediate portion (23) of the reinforcing pin (14) comprises: at least one first slot (8) which is oriented horizontally, crosses the main structure (3) from side to side along a longitudinal direction (9), and is blind along a transverse direction (10) perpendicular to the longitudinal direction (9) originating from an internal portion of the main structure (3) and ending at a first side (11) of the main structure (3); and at least one second slot (12) which is oriented horizontally, crosses from side to side the main structure (3) along the longitudinal direction (9), and is blind along the transverse direction (10) perpendicular to the longitudinal direction (9) originating from an internal portion of the main structure (3) and ending at a second side (13) of the main structure (3) opposite the first side (11). 3) Heel (2) according to claim 2, wherein each first slot (8) is vertically misaligned with respect to the second slot (12). 4) Heel (2) according to claim 2 or 3, wherein: at least two first slots (8) and / or at least two second slots (12) are provided; And the first slots (8) are vertically intercalated with the second slots (12). 5) Heel (2) according to claim 2, 3 or 4, in which each slot (8, 12) affects more than half of the main structure (3) along the transverse direction (10). 6) Heel (2) according to one of claims 2 to 5, in which there are altogether an even number of slots (8, 12). 7) Heel (2) according to one of claims 2 to 6, wherein in a central portion (18) of the main structure (3) arranged in correspondence with the slots (8, 12), the reinforcement pin (14) has a external dimension smaller than the internal dimension of the seat (15) so as not to touch the wall of the seat (15). 8) Heel (2) according to one of claims 2 to 7, in which each slot (8, 12) ends with a cylindrical surface arranged parallel to the direction (9) longitudinal. 9) Heel (2) according to claim 8, wherein in each slot (8, 12) the cylindrical surface has a diameter greater than the vertical dimension of the slot. 10) Heel (2) according to one of claims 2 to 9, in which at least part of the slots (8, 12) are filled with viscoelastic material.