FR2915855A1 - Sole for shoe, has dynamic shock absorbing system with fluid flow control device for controlling flow of fluid circulating in conduit which connects two variable volume containers, where control device is controlled by user - Google Patents

Abstract

The sole (18) has a dynamic shock absorbing system comprising a variable volume container (2) arranged in a heel (19) of the sole, and a variable volume container (3) arranged in a sole front part (20). A conduit connects the two containers, where the conduit and the containers are filled by incompressible fluids e.g. air. The system has a fluid flow control device for controlling a flow of fluid circulating in the conduit, where the control device is controlled by a user. The containers are made of resilient plastic material, and an upper wall of the containers is made of an elastic material. An independent claim is also included for a dynamic shock absorbing method for a sole of a shoe.

Description

Field of the Invention The present invention relates to a sole of

  shoe which comprises a shock absorbing system, a shoe comprising this sole and a method of dynamic damping shock adjustable.

  PRIOR ART The sole of a shoe has several functions, including the protection of the foot, the stabilization of the foot, the damping or the absorption of shocks and the protection of the shoe from premature wear due to the repeated contact of the shoe. sole with the ground. For the user, shock absorption is particularly important. The force with which the foot touches the ground is proportional to the weight of the user, and shocks caused by walking or running are suffered by the skeleton and in particular by the joints of the user. These shocks must therefore be absorbed by soles designed for this purpose to protect the user from possible negative effects such as injuries. The use of cushions incorporated into shoe soles and filled with air and / or liquid is well known in the art. Especially for sports shoes and especially running. US 5,718,063 discloses a shoe whose sole includes a layer with two cushions, respectively filled with liquid and air, to minimize impact shock. US 4,567,677 includes a sole with a cushion filled with water and air. The cushion has two regions, in the heel and in the front part of the sole, and the flow of fluid between these two regions is restricted by flow restriction means. Thus, in addition to the damping, a foot massage action is provided by the sole. In US 5,493,792, there is a shoe sole with a pad having a plurality of areas partially separated from each other by walls. Fluid contained in the pad circulates from one area to another, in a manner that is modulated by the partial partition walls. A cushion filled with liquid and partitioned by partition walls having openings is disclosed in US Patent 3,765,422. Fluid circulates between some compartments of the cushion through openings in the partition walls. A fully hollow and partially fluid-filled shoe sole is disclosed in US 4,100,686. The fluid can flow freely in the sole without restriction or modulation of the flow. In US 5,131,174, a multi-chamber cushion filled with liquid is described. Shock absorption is accomplished by the flow of liquid between the compartments and thus depends on the flow rate of the liquid flow. BRIEF DESCRIPTION OF THE INVENTION Compared to the state of the art which has just been described, the invention aims at a shoe sole providing a foot massage and dynamic shock damping that is adjustable by the user according to the invention. of its mass and according to the use that will be made of the shoe. In its most general embodiment, the invention relates to a shoe sole comprising a heel and a sole front part, a dynamic shock absorbing system, the dynamic shock absorbing system comprising a first container. of variable volume disposed in the heel of the sole, a second container of variable volume disposed in the front part of the sole, at least one connecting conduit connecting the first container and the second container, one or more fluids filling the first container, the second container and the conduit; the shoe sole is characterized in that the dynamic shock absorbing system comprises a device for adjusting a flow of fluid flowing in at least one of the ducts, said adjustment device being adjustable by the user. In a first variant embodiment of the shoe sole according to the invention, the first container has a bottom wall and an upper wall, the bottom wall and the top wall of the first container being superimposed on one another and connected to each other. sealingly to each other by at least one side wall, and the second container having an upper wall and a lower wall, the lower wall and the upper wall of the second container being superimposed on one another and connected to each other; to one another in a sealed manner by at least one side wall. In a second variant of embodiment compatible with the general embodiment and with the first variant of the shoe sole according to the invention, the first container comprises an inner chamber and an outer chamber, separated from one another by a lateral interior wall, openings of the inner wall, for example calibrated holes, allowing fluid passage between the inner and outer chambers.

  In an alternative embodiment compatible with the embodiments described above of the shoe sole according to the invention, the second container comprises an inner chamber and an outer chamber, separated from each other by a lateral inner wall. , the inner wall of the openings of the inner wall, for example calibrated holes for a fluid passage between the inner and outer chambers. In an alternative embodiment compatible with the embodiments described above of the shoe sole according to the invention, the flow control device comprises a means of deformation of the cross section of a portion of at least one connecting conduits.

  In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, the flow control device comprises a control body, the adjustment body being of a rectangular parallelepiped shape. and comprising a front opening and a rear opening so that the connecting duct can pass through the adjustment body, a movable adjusting plate, adjusting means for adjusting the position of the adjusting plate, the position of the adjusting plate setting a deformation of at least one of the conduits. In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, the adjustment plate is rectangular in shape and comprises guide means, the guide means of the plate comprising by for example, a peg protruding from each of the two short edges of the adjusting plate, two side walls parallel to the duct, the two side walls each comprising a slot, the tenons of the adjusting plate being arranged in the slots in a movable manner. The adjusting means for adjusting the position of the adjusting plate comprises a threaded hole passing through the adjusting plate, a setting screw or bolt passing through the upper wall of the adjusting body and the threaded hole of the adjusting plate, the rotation of the adjusting plate. the adjusting screw or bolt causing the adjusting plate to move in a direction determined by the axis of the adjusting screw or bolt. The advantage of this embodiment is that the user can easily and at any time adjust the intensity of damping using a screwdriver or an Allen key.

  In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, the first container and the second container are made of resilient plastic material.

  In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, the upper wall of the first container and the upper wall of the second container are of elastic material. In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, most of the absorbent action is related to fluid displacement. The damping in this embodiment is thus very little related to the aging of a material, for example, silicone or EVA foam, since the absorbing action is linked only very little to the compression and decompression of this material. In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, the fluid is incompressible. In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, the fluid is air. In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, the fluid comprises air and liquid.

  In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, the surface of the upper wall of the first container is different from the surface of the bottom wall of the first container. This makes it possible to adapt the shape of the container to the shape of the heel of the sole. In an alternative embodiment compatible with each of the embodiments described above of the shoe sole according to the invention, the height of the side wall of the first container is different from the height of the side wall of the second container. The invention also relates to a shoe comprising a shoe sole according to any one of the embodiments of the sole according to the invention.

  The invention also relates to a method of dynamic shock absorption for a shoe sole, where a heel impact force is absorbed at least partially, by a fluid flowing in a connecting conduit of a first container located in the heel of the sole to a second container located in a front portion of the sole, wherein a forefoot impact force is at least partially absorbed by a flow of fluid moving through the connecting conduit of the second container to the first container. The dynamic shock damping method is characterized in that the flow of fluid between the first and second containers is adjustable by a user adjustable flow control device, the flow rate adjustment in the conduit contributing to the adjustment of the flow rate. cushioning of the heel strike or the front of the sole on the ground. In the most general embodiment of the method of dynamic shock absorption for a shoe sole according to the invention, the flow control device 5 comprises a deformation means of the cross section of a portion of the conduit. BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the invention will appear on reading the detailed description below, together with the drawings in which: FIG. 1 is a schematic representation of a shoe comprising a soleplate 10 according to FIG. FIG. 2 illustrates the shoe sole according to the invention comprising a user-adjustable system for dynamic shock absorption and integrated into the sole, FIG. 2 comprises part a) representing a side view. the sole and a portion b) representing a perspective view of the sole. FIG. 3 shows the user-adjustable dynamic damping system in a preferred embodiment of the invention; FIG. 3 comprises parts a), b) and c) respectively showing a side view, a top view and a perspective view of the damping system. FIG. 4 comprises diagrams (a) and (b) respectively showing a perspective view and a side view of the first container of the dynamic and adjustable shock absorbing system integrated into the shoe sole according to the invention, and FIG. 4c) shows a section of the first container in a preferred embodiment of the invention; FIG. 5 shows diagrams a) and b) respectively showing a perspective view and a side view of the second container of the system. adjustable dynamic shock absorption system integrated in the shoe sole according to the invention, and FIG. 5c) is a section of the second container in a preferred embodiment of the invention, and FIG. 6 illustrates the device of FIG. damping adjustment according to a preferred embodiment of the invention.

  Detailed Description In Figure 1, an example of shoe 50 is shown. The shoe 50 has a sole 18 according to an embodiment of the present invention. FIG. 2 illustrates a dynamic shock absorption system 1 integrated in the sole plate 18 of the boot 50. For this purpose, recesses 51, 52 provided for this purpose are present respectively in the heel 19 and the sole front portion 20 of the shoe. The dynamic shock absorption system, as illustrated in FIG. 3, comprises two cushions, that is to say a first container 2 and a second container 3. The first and second containers 2, 3 are housed respectively in the recesses 51, 52 of the heel 19 and the sole front portion 20 of the boot 50. The physical shapes of the first container 2 and the second container 3 are adapted to the shape of the shoe sole in which the containers 2, 3 are housed, the shape of the sole itself being adapted to the type of shoe (walking, running, city, shoes with high heels, etc.). The first container 2 housed in the recess 51 of the heel 19 has a bottom wall 22 and an upper wall 21 which are superimposed on one another and connected to each other in a sealed manner by at least one wall 23. The second container 3 housed in the recess 52 of the sole front portion 20 also has an upper wall 24 superimposed on a lower wall 25, and these two walls 24, 25 are connected to each other in a sealed manner by at least a side wall 26. The two containers 2, 3 which are respectively in the heel 19 and the front sole portion 20 of the boot are connected together by at least one connecting duct 4 having a reduced section allowing the passage of fluid from one to the other. The first container 2, the second container 3 and the plurality of conduits 4 form a sealed system filled with a fluid. Part of the fluid can pass from one container to the other through the plurality of ducts 4. The plurality of ducts 4, by their reduced cross section relative to the section of the cushions, makes it possible to restrict the flow of the fluid and to limit the flow rate of the flow inside the duct 4. According to the invention, the cross section of at least one of the ducts 4 is adjustable by means of adjustment means. In a preferred embodiment of the invention, the duct 4 is of deformable material and the section adjustment means are deformation means of the section of at least one of the ducts 4. FIGS. advantageous embodiment of the invention whose particularity is that it comprises two ducts 4. According to a preferred embodiment of the invention, for the two containers 2, 3, the upper walls 21, 24 are deformable by the impact of the foot on the ground. The other walls of the two containers 2, 3 are contiguous to corresponding walls of the recesses 51, 52 6 respectively in which the containers 2, 3 are housed in the sole. The upper walls 21, 24 are made of a sufficiently elastic material so that pressures exerted by the foot on an upper wall of one or the other of the containers can be transformed into a pressure exerted on the fluid contained in this container and consequently in a displacement of the fluid by the deformation of the cushion. According to a preferred embodiment of the invention, illustrated in Figure 4c, the first container 2 comprises an inner chamber 33 and an outer chamber 34, the inner chamber 33 and the outer chamber 34 having in common the upper wall 21 and the lower wall 22 of the first container 2. An inner side wall 37 between the inner chamber 33 and the outer chamber 34 has holes 39 so that the fluid filling the first container 2 can circulate between the inner chamber 33 and the outer chamber 34. size and the number of holes 39 are adjusted and adapted to the type of fluid on the one hand and the size of the shoe on the other hand. Thus, when a force is exerted on the upper wall 21 of the first container 2, the pressure of the fluid increases mainly in the inner chamber 33, and a portion of the fluid passes into the outer chamber 34 through the holes 39. The flow rate of the flow of fluid between the inner chamber 33 and the outer chamber 34 is restricted by the size of the holes, the flow velocity is limited so that the deceleration time of the part of the foot which is above the sole portion front or heel at the moment when this part hits the ground is increased. During a phase during which the soleplate no longer touches the ground, the pressure exerted by the foot on each of the upper walls of the front and rear containers is released, and the pressures inside the containers are rebalanced by fluid transfer. through the conduit 4, the container where the pressure is greater than that of the other container when the shoe leaves the ground. The second container 3 may also include an inner chamber 35 and an outer chamber 36 separated by a wall 38 with holes 40, as shown in Figure 5c. The portion of the fluid from the first container arrives in the outer chamber 36 of the second container 3 and passes through the holes 40 in the wall 38 in the inner chamber 35 for compensation of the different fluid pressures in the outer chamber 36 and the inner chamber 35. .

  In Figure 6 is shown an exemplary embodiment of a flow control device 5 according to the present invention. The flow control device 5 is located between the first container 2 and the second container 3. The device 5 is arranged to adjust the flow rate of the fluid flow in the conduit 4 by a deformation effect of the straight section of the conduit 4 and thus makes it possible to modify the flow restriction by means of a mechanical system. A portion of the flow control device 5 is accessible via an opening in a not shown insole of the boot 18, to provide the user the ability to adjust the shock damping at his convenience or possibly to stop completely. the displacement of the fluid. According to a preferred embodiment of the invention, the flow control device 5 comprises a control body 6 through which the duct or the plurality of ducts 4 pass. It is this embodiment of the adjusting device 5 which is illustrated in Figure 6. The adjusting body 6 has the shape of a rectangular parallelepiped. It comprises two openings, a front opening 10 and a rear opening 14. The duct or the plurality of ducts 4 pass through the adjustment body 6 by passing through the openings 10, 14. The adjustment body 6 has three walls which are parallel to the duct, an upper wall 30 having a hole 32 for a bolt rod to pass through, and two side walls 13, 15. The two side walls 13, 15 comprise grooves or as shown in Figure 6 vertical slots 9. The adjusting device 5 further comprises an adjusting plate 7. The adjusting plate 7 is rectangular in shape. It comprises two pins 31 protruding from the two short edges of the adjusting plate 7. The tenons 31 of the adjusting plate 7 are inserted into the grooves or slots 9 of the side walls 13, 15 of the adjusting body 6. In this way, adjusting plate 7 is guided in translation between the upper and lower walls 30 of the adjusting body 6. A screw or a bolt 8 comprising a head and a threaded rod 17, has its head resting on the edges of the through hole 32 of the upper wall 30 of the adjusting body 6. The threaded rod 17 is engaged with a corresponding threaded portion fixed on the adjusting plate 7. It can be a nut fixed to the adjusting plate 7 or, if the adjusting plate 7 is thick, a threaded through hole 16 of the adjusting plate 7. The lower part of the threaded rod of the bolt 8 is fixed in known manner in translation to the lower edge of the adjusting body 6 by fixing means in translation 11. The lower part of the threaded rod 17 of the bolt 8 is made to cooperate with the translational fixing means 11, so that the bolt can not move in the direction of the axis of the bolt. The body 6 provided with the adjusting plate 7 is disposed between the first and second containers 2, 3. The operation is as follows. The tenons 31 and the grooves or slots 9 constitute means for guiding the adjusting plate 7. The threaded portion 17 and the threaded hole 16 constitute means for adjusting the position of the adjusting plate 7. The adjusting plate 7 and the upper wall 30 of the adjusting means 5 together constitute a mechanical means of deformation 7, 30 of a conduit 4 at least. When guided by the guiding means 9, 31 the adjusting plate 7 moves, the ducts 4 are flattened more or less between the deformation means 7, 30. This deformation of the duct or ducts 4 causes a modification of the cross section of ducts 4 and therefore a flow control in this conduit.

  Note that the adjusting plate 7 has been shown flat. It may comprise grooves for example trapezoidal, the width of the groove being wider towards the opening than in the bottom of the groove. In the damping system incorporated in the soleplate according to the present invention, the fluid filling the first container 2, the second container 3 and the conduit 4 can be either air or a liquid, or both of the air and a liquid. Depending on the choice of fluid, the cross section of the conduit 4 must be adapted. The more viscous the fluid, the greater the cross-section of the duct must be to maintain a given flow by a given force. In the case where the fluid is a liquid, since the liquids are very little compressible, the operation of the system relies on the dynamics of the fluids to create the damping shocks due to walking or running. When the heel of the foot is placed on the ground, an impact force acts on the first container 2 and deforms its upper surface. Thus, the volume of the first container 2 decreases under pressure, and the liquid in the container 2 expands through the conduit 4 to the second container 3. In this way the shock of the heel is damped. The volume of the fluid in the second container 3 will increase by a value equal to the decrease in the volume of the fluid in the first container 2, creating an increase in damping for the soles of the feet. When the soles of the feet attack the ground, the second container 3 will recreate the dynamics to the first container 2 to prepare the attenuation of the shock of the heel to the ground during the next step. The shock attenuation depends on the weight of the person and the pressure for example, stroke or step exerted on the containers 2, 3.

  The shock absorption in the sole is adapted to the impact force of the foot on the ground, since the greater the force in one of the cushions, the greater the volume of liquid moved in the other cushion will be large. At the same time, the shock damping is adjustable by the user who can adjust the flow rate in the duct 4 by using the flow control device 5. Thus, the damping varies according to the flow rate of the flow between a maximum value and a minimum value. If the fluid is air, the damping is mainly based on the compressibility of the air in the containers 2, 3. When an impact force acts on one of the containers 2, 3, its upper surface 21, 24 deforms, the pressure of the air contained in this container increases. The air with the high pressure thus damped the impact of the foot on the ground. Only a part of the compressed air moves via the duct 4 into the other container 2, 3. If the fluid in the shock-absorbing system 1 comprises air and a liquid, the fluid is partially compressible. Thus, the shock absorption is due to both the increase in the pressure of the gaseous fluid and the dynamics of the liquid fluid when an impact force acts on one of the cushions.

  The damping depends on the type of fluid filling the two containers 2, 3 and the duct 4. The embodiments of the invention presented above are only examples of a shoe sole comprising a damping system of dynamic and adjustable shock. Variations can be made to concrete achievements while remaining within the scope of the invention. Thus, for example, the containers 2 and 3 can be formed directly in the soles without the presence of separate lower and outer side walls of the corresponding inner surfaces of each of the recesses 51, 52. In the example shown, the adjustment plate is movable. in translation, it could also be mobile in rotation.

Claims (18)

claims   A shoe sole (18) having a heel (19) and a front sole portion (20) and a dynamic shock absorbing system (1), the dynamic shock absorbing system (1) comprising: a first container (2) of variable volume disposed in the heel (19) of the sole, a second container (3) of variable volume disposed in the front part of the sole (20), at least one conduit (4) connecting the first container (2) and the second container (3), and one or more fluids filling the first container (2), the second container (3) and the conduit (4); the shoe sole (18) being characterized in that the dynamic shock absorbing system (1) comprises a device (5) for adjusting the fluid flow, circulating in at least one of the conduits (4), said adjusting device (5) being adjustable by the user.   The shoe sole (18) according to claim 1, wherein the first container (2) has a bottom wall (22) and an upper wall (21), the bottom wall (22) and the top wall (21) of the first container (2) being superimposed on each other and sealingly connected to each other by at least one side wall (23), and wherein the second container (3) has a top wall (24); ) and a lower wall (25), the lower wall (25) and the upper wall (24) of the second container (3) being superimposed on one another and sealingly connected to one another by at least one side wall (26).   Shoe sole (18) according to claims 1 and 2, wherein the first container (2) comprises an inner chamber (33) and an outer chamber (34), a lateral inner wall (37) between the inner chamber (33) and the outer chamber (34), the inner wall (37) having calibrated openings (39) for fluid passage between the inner (33) and outer (34) chambers.   The shoe sole (18) according to claim 3, wherein the second container (3) comprises an inner chamber (35) and an outer chamber (36), a side inner wall (38) between the inner chamber (35) and the outer chamber (36), the inner wall (38) having calibrated openings (40) for fluid passage between the inner chamber (35) and the outer chamber (36).   Shoe sole (18) according to any one of the preceding claims, wherein the flow control device (5) comprises means for deformation (30, 7) of the cross-section of a portion of the conduit (4). .   The shoe sole (18) according to any one of the preceding claims, wherein the flow control device (5) comprises a control body (6), the adjustment body (6) having the shape of a parallelepiped rectangle and comprising a front opening (10) and a rear opening (14) so that at least one of the ducts (4) can pass through the adjusting body (6), a movable adjustment plate (7), a adjusting the position of the adjusting plate (7), the position of the adjusting plate (7) controlling the deformation of at least one of the ducts (4).   The shoe sole (18) according to claim 6, wherein the adjusting plate is rectangular in shape and comprises translational guiding means (31), and wherein the adjusting means of the adjusting plate position comprise a threaded hole (16) passing through the adjusting plate (7), an adjusting screw or bolt (8) passing through the upper wall (30) of the adjusting body (6) and the threaded hole (16) of the adjusting plate (6). adjusting, the rotation of the adjusting screw or bolt (8) causing the adjusting plate (7) to move in a direction determined by the axis of the adjusting screw or bolt (8).   Shoe sole (18) according to claim 6, wherein the adjusting body (6) has two side walls (13, 15) parallel to one direction of the conduits (4), the guide means of the plate comprising a tenon. (31) protruding from each of the two short edges of the adjusting plate (7), a slot or groove (9) disposed in each of two side walls of the adjusting body (6), the tenons (31) of the plate of adjusting (7) being guided in the slots or grooves (9) of the side walls (13, 15).   9. The shoe sole (18) according to any of the preceding claims, wherein the first container (2) and the second container (3) are of resilient plastics material.   10. The shoe sole (18) according to any one of the preceding claims, wherein the upper wall (21) of the first container (2) and the upper wall (24) of the second container (3) are of elastic material.   11. The shoe sole (18) according to any of the preceding claims, wherein the fluid is incompressible.   The shoe sole (18) according to any one of the preceding claims, wherein the fluid is air.   13. The shoe sole (18) according to any one of the preceding claims, wherein the fluid comprises air and liquid.   The shoe sole (18) according to any one of the preceding claims, wherein the area of the top wall (21) of the first container (2) is different from the area of the bottom wall (22) of the first container ( 2).   The shoe sole (18) according to any one of the preceding claims, wherein the height of the side wall (23) of the first container (2) is different from the height of the side wall (26) of the second container ( 3).   16. A shoe (50) having a shoe sole (18) according to any one of the preceding claims.   17. Dynamic shock absorbing method for a sole (18) shoe (50), wherein a force of impact of a heel (19) of the sole (18) is absorbed at least partially by a circulating fluid in a connection duct (4) of a first container (2) located in the heel (19) of the sole (18) to a second container (3) located in a front part of the sole, where a force of impact of the forefoot is at least partially absorbed by a flow of fluid moving via the connection duct (4) from the second container (3) to the first container (2), characterized dynamic damping method characterized in that the flow of fluid between the first and second containers (2, 3) is adjustable by a user-adjustable flow control device (5), the flow control in the conduit (4) contributing to the adjustment shock absorbing the heel (19) or the front (20) of the sole (18) on the ground.   The dynamic shock absorbing method for a shoe sole (18) according to claim 17, wherein the flow control device (5) comprises means for deforming the cross section of a portion of the conduit (4). ) connection.