WO1988005272A1

WO1988005272A1 - Vibration dampening heel for shoes

Info

Publication number: WO1988005272A1
Application number: PCT/FR1988/000019
Authority: WO
Inventors: Michel Chabiland
Original assignee: Michel Chabiland
Priority date: 1987-01-13
Filing date: 1988-01-13
Publication date: 1988-07-28
Also published as: FR2609379A1; AU1182688A

Abstract

The heel for shoes is intended to dampen the vibrations generated when walking on hard ground and which are physiologically detrimental to the human body. The heel is characterized in that the heel-shank (1) is secured to the primary sole of the shoe by fixing means (2) which cooperate with the vibration dispersion plate (3) arranged inside the shoe at the arch of the foot. The vibration damper heel according to the invention is particularly intended to be fitted on so-called ''heeled'' shoes for ladies.

Description

VIBRATION DAMPING HEEL FOR SHOES

The present invention relates to footwear and. more particularly, the heels of women's shoes called "heels".

It has been observed for a long time, that women wearing shoes called "heels" on a regular basis, are often victims after several years of regular walking with these shoes, various disorders and / or various pains in the spine and / or the head.

Studies and medical research carried out in recent years have confirmed that the root cause of the abnormalities detected in these patients is caused by the vibrations emitted by the contact of the heel with the ground, particularly in those called "needle". These vibrations which propagate directly from the end of the heel, through the sole, to the heel of the person; goes up from the calcaneus bone e passing through the bones of the leg and the pelvis to the spine to cause over time, a premature wear of the vertebral and cervical discs with an incidence of the same order, in their course, on the femoral neck. These physiological problems have led in the past, many inventors to propose various solutions, the majority of which have sought to combat the harmful effects of these vibratio by limiting their emission by a suspension effect created by elastic means. The use of shoes made with these means shows that if the nuisance of vibrations is reduced, walking comfort, compared to a classic shoe of the same type, is also reduced. The manufacturers and users were not mistaken and none of the solutions proposed had commercial success. It is in fact generally accepted that a lady's shoe heel must, in order to be comfortable, have sufficient rigidity and have its "right toe" (end of the heel in contact with the ground) optimally placed in the configuration of the shoe.

The present invention provides a solution to the problem thus posed.

It proposes, by a combined effect of suspension and damping, to effectively neutralize the vibrations generated by 1 step.

REPLACEMENT SHEET According to a general aspect of the invention, the vibration-absorbing heel comprises a piece of metal preferably formed a heel-shank assembly whose primary characteristic is that the longitudinal axis AA of the heel is inclined on the front of the shoe, at point to be in its maximum inclination almost parallel to the axis passing through the center of the contact surfaces of the heel and the outsole with the ground (Fig 7) and in its minimum inclination the longitudinal axis AA can be confused with an axis passing substantially through the end of the heel in contact with the ground and the geometric center of the arched part (camber) of the shoe (Fig 8)

According to a second characteristic, the cushioning heel-shank is secured to the shoe using metallic screws or riveted studs passing through the various soles in order to cooperate inside the shoe with a so-called "dispersion" plate , preferably metallic.

Such an arrangement of the heel associated with the shank advantageously results in the vibrations emitted by the heel at the point of contact of the latter with the ground being diffused through the heel, then the shank to terminate by the fixing screws and nipples, in the dispersion plate, which, in close contact with the foot, transmits them to the arch of the foot which neutralizes them by absorbing them. Indeed, the arch of the foot is in its texture more absorbent of vibrations than the flesh of the heel enveloping the calcaneus bone.

Furthermore and complementarily, the shape of the heel-shank assembly contributes to producing on the shoe a very slightly elastic suspension effect which tends to significantly reduce the emission of vibrations emitted by the heel, all of which advantageously give it great rigidity. .

Those skilled in the art will understand by shank a generally metallic part serving as a stiffener at the point of the arch, in the middle part of the foot.

In cooperation with the foot, the heel-shank produces a shock-absorbing / suspension assembly which is all the more advantageous, moreover, since its conformation makes it less vulnerable than the classic "high" heels, which are particularly sensitive to holes in various floor plates and grids, steps and sidewalks - of all kinds. According to another characteristic, and in order to obtain an optimum damping / suspension effect, the longitudinal axis AA of the heel can take all the intermediate inclination positions comprised between the minimum and maximum positions described above (Fig 7 and 8 ), see even combining the minimum and maximum inclinations (Fig 9) with or without a hollowed out part in the central rib of the heel-shank.

The present invention will be described in more detail using the accompanying drawings in which: - Figure I shows a first embodiment of one invention.

- Figure 2 shows a detail view in vertical section first embodiment of the invention.

- Figure 3 shows a second embodiment of the invention.

- Figure 4 shows a detail view in vertical section of the second embodiment of the invention.

- Figure 5 shows a third embodiment of one invention. FIG. 6 represents a detail view in vertical section of the third embodiment of the invention.

FIG. 7 represents an arrangement of the heel according to the different embodiments of the invention.

- Figure 8 shows another arrangement of the heel seio the different embodiments of the invention.

- Figure 9 shows yet another arrangement of the heel according to the different embodiments of the invention.

- Figure 10 shows a variant according to the different embodiments of the invention. - Figure 11 shows a vertical and long tudinal sectional view of a fourth embodiment of the invention.

The characteristics and advantages of the invention will appear more precisely on examination of the detailed description of the various embodiments below: Figure 1 shows the vibration damping heel according to the first embodiment of the invention which comprises a part preferably metallic (1) which constitutes in itself the heel-shank, the lower right part starting from the center of the part to refine to its end forming the "butt end" of the heel and the oblique part comprising a short surface in the longitudinal plane and substantially flat in the transverse plane forming an arch and constituting the conta surface of the heel - shank with the sole of the shoe. The shape of the hollowed out part located at the rear of the shank and above the heel contributes, depending on its thickness, to optimizing the vertical elasticity and the lateral rigidity of the heel-shank that is compatible with good walking comfort. In this embodiment, the surface to be in contact with the shoe comprises 3 nipples (4) forming an integral part of the heel-shank (1) but which can also be added inserts, particularly in the case where the heel-shank is other than metallic. These nipples or inserts which are provided with a bore in their center, have the function, of a pa of ensuring a good fixing of the screws (2) in the heel-shank CI) by blocking: ia dispersion plate (3 ), under the action of screws (2), presses the different soles to take support on these nipples or inserts; on the other hand, to allow a solid positioning of the heel on the shoe so as to prevent any lateral or longitudinal displacements of the heel-shank (1) on the walking sole (7). Figure 2 shows a detailed section of this embodiment.

It should be noted that the number of screws, nipples and / or inserts is not limiting in this preferred embodiment: three v-is / nipples constituting an average, two screws / nipples may be sufficient, one screw / stud constituting of course the minimum.

According to this first embodiment and as shown in FIGS. 1 and 2, the dispersion plate (3) intended to be placed inside the shoe and which can be isolated from the foot by a thin insole (8) , represents a surface substantially identical to the contact surface of the heel (shank Cl) with the shoe; but it can however, for shoes of medium and large sizes be wider and especially longer on the back part or it can part cipate in the rigidity of all the different soles, if nothing has been provided for this purpose . The holes (b) in the dispersion plate C3) to receive the screws C2), are preferably milled in a bowl so that the screws C2) are not protruding! from plate C3).

FIG. 3 then shows the vibration damping heel according to a second embodiment which differs from the first mode in that the dispersion plate C3) is replaced by washers with a countersunk hole CI2) coming to secure the first sole (6) and the sole C7) as well as an accessory metal reinforcement shank CIO) provided with holes (11 allowing the passage of the nipples (4), with the heel-shank (1 by means of the screws C2) as it is shown in vertical section in Figure 4. This second embodiment, significantly less effective than the first embodiment is sufficient in an application on small and medium shoe sizes.

It should be noted that the metal reinforcement shank (10) is placed between the first sole (6) and the walking sole (7) as shown in Figure (4), but unlike the plate dispersion (3), it can only be placed in the upper half of the heel-shank-CD while extending a few centimeters on the back as shown in Figure 3.

In a third embodiment shown in Figures 5 and 6, the ta.1on-shank (1) has pins or inserts to be riveted C9) substantially longer in their projecting part than in the first and second embodiment. The dispersion plate C3) is replaced by washers with a countersunk hole (12), as for the second embodiment, which come to join by riveting the nipples or inserts the different soles with the heel-shank CD as shown in detailed section in figure 6.

This third embodiment, less effective than the first form, deserved to be described because it has the advantage of being economically more advantageous. This embodiment according to the invention may however advantageously include in place of the washers (12), a dispersion plate identical to that described above as well as accessoiremen a metal shank reinforcement (10). Figures 7,8 and 9 show three heel shapes, by way of example, compatible with embodiments 1, 2 and 3 among a large number of possibilities. We can observe in these three figures the maximum inclinations (Fig 7) and half CFig 8) of the longitudinal axis AA of the heel mentioned previously, as well as the intermediate combination of these inclinations CFig 9).

FIG. 10 represents a variant according to the first, the second and the third embodiment of the invention. A half-shell C13), preferably metallic, and applying p actement on a part of the rear half of the shoe, is interposed between the heel-shank CD and the walking sole (7) so as to constitute a plate of external dispersion advantageously complementing the effect of the internal dispersion plate C3). This embodiment is particularly suitable for "half-heel" shoes.

FIG. 11 represents a fourth embodiment of the invention. It is characterized in that the heel-shank CI) preferably metallic is secured to a thick sole C14) in semi-rigid or rigid plastic material molded, by the nipples 5C15) integral with the heel-shank. This fig is a representation in longitudinal / vertical section.

In this embodiment, the vibration damping effect is substantially analogous to embodiments 1, 2 and 3, with the difference that a significant portion of the vibrations emitted from the "right end" of the heel and propagating up to cambri are absorbed at the camber by the thick sole C14) itself.

In this latter embodiment, the heel-shank CD can be fixed to the sole C14) during the molding operation by injection of this sole, but also after injection, by riveting the nipples C15) .

Furthermore, various manufacturing studies have shown that the production of shock-absorbing heels in composite materials could be advantageously approached.

The use of these materials consisting of reinforced synthetic resins, such as for example polyester resins associated with glass and / or synthetic fibers, or more particularly in particular, epoxy resins associated with ca bone and / or kevlar fibers provide in the production of these heels greater lightness with substantially equal, or even superior mechanical characteristics, particularly with regard to their absorption capacity for vibrations and their fatigue strength compared to metallic materials such as light alloys.

At least two modes of using these posite materials can already be chosen. A first method consists in injecting under pressure into a mold, a synthetic resin i bearing reinforcing fibers. A second mode consists in injecting also under pressure into a mold, a synthetic resin only, impregnating a weaving of synthetic fibers previously placed in the mold. These two embodiments in composite materials are given by way of examples which are of course not limited.

The invention is intended to be adapted to shoes for women called "heel".

Claims

R E V E N D I C A T I O N S

1) - Vibration damping heel for a shoe charac¬ terized in that it comprises a part Cl), preferably metallic, forming a heel-shank assembly whose longitudinal axis AA of the heel is inclined on the front of the shoe to the point of being at its maximum inclination, substantially parallel to the axis passing through the center of the contact surfaces with the ground, the heel and the sole, secured to the shoe using means of binding C2) passing through the various soles (6) and (7) and cooperating with the dispersion plate (3) placed inside the shoe at the location of the arch of the foot (arch).

2) - Vibration damping heel for shoe charac¬ terized in that it comprises a piece (1), preferably of metal, forming a shank shank assembly whose longitudinal axis AA of the heel, in its minimum inclination on the 'having the shoe, may merge with an axis passing substantially through the end of the heel, in contact with the ground, and the geometric center of the arched part of the shoe, secured to the shoe using means of binding (2) passing through the various soles (6) and (7) and cooperating with the dispersion plate (3) placed inside the shoe, at the end of the arch of the foot.

3) - Vibration damping heel for shoe charac¬ terized in that it comprises a part (1), preferably metallic, forming a heel-shank assembly whose longitudinal axis AA of the heel can take all the intermediate positions inclination between the maximum inclination sensibleme parallel to the axis passing through the center of the surfaces in contact with the ground, the heel and the sole and a minimum inclination may be confused with an axis passing substantially through the end of the heel, in contact with the ground, and the geometric center of the arched part of the shoe, see combine this inclination with or without a hollowed out part in the central rib of the heel-arch (3) secured to the shoe with the using fastening means (2) passing through the different soles (6) and (7) and cooperating with the dispersion plate (3) placed inside the shoe at the location of the arch of the foot. 4) - Vibration damping heel according to any one of the preceding claims, characterized in that the heel-shank (1) is secured to the shoe by means of worm screws (2) cooperating with the dispersion plate (3 ) traversan

5 the first sole (6) and the walking sole (7) to be inserted in pins or centering inserts (4).

5) - Heel vibration damper according to any one of claims I, 2 or ι3 characterized in that the heel- shank (1) is secured to the shoe using met screws

£ 0 liques (2) cooperating with washers (12) passing through the first sole (6) and the step sole (7) to be inserted in nipples and centering inserts (4).

6) Vibration damping heel according to any one of claims 1,2 or 3 characterized in that a metal shank 5 of reinforcement (10) is placed between the first sole (6) and the walking sole (7) in the upper half of the heel-shank (l) while extending it a few centimeters on the back.

7) - Vibration damping heel according to any one of claims 1,2 or 3 characterized in that the heel- shank (1) is secured to the soles (6) and (7) by pins or centering inserts ( 9) cooperating by riveting on d washers (12).

8) - vibration damping heel according to any one of claims 1,2 or 3 characterized in that a half-shell (13) s' applying perfectly on part of the rear half of the shoe is interposed between the heel-shank (1) and the tread (7).

9) - Vibration damping heel according to any one of claims 1,2 or 3 characterized in that the heel- shank (1) is secured to a thick sole (14) in semi-rigid or rigid plastic material by frustoconical nipples (1 forming an integral part, by their small section, of the heel-shank. 5 10) - Vibration-absorbing heel according to claim 9 characterized in that the heel-shank (1) is secured to the sole (14), either during the injection molding operation or after riveting the studs (15). 11) - Vibration damping heel according to any one of claims 1,2 and 3 characterized in that 'the heel-cam- brio_. (I) can be made of a synthetic material composed by injection under pressure into a mold of a synthetic resin incorporating reinforcing fibers.

12) - Heel vibration damper according to any one of claims 1,2 and 3 characterized in that the heel-cam¬ brion (1) can be made of a synthetic material composed by injection under pressure in a mold of a synthetic resin alone impregnating a weaving of synthetic fibers previously placed in the mold.