JP2017000740A - Insole and shoe comprising removable insole - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an insole which can be produced in an easy manner and provides a kind of footbed and a comfortable feeling.SOLUTION: An insole designed for supporting a foot after the insole is inserted in a shoe so as to abut a sole section of the shoe, the insole comprising an integral plastic material forming a flexible planar base layer 1 out of which numerous resilient studs 2 arise, is easily manufactured and provides a comfortable feeling if the planar base layer 1 is designed as a contact surface for the foot. The studs are designed to extend from the base layer 1 to the sole section of the shoe, and the studs 2 are shaped of different heights so that upon weight-loading by the foot the flexible planar base layer 1 is deformed so as to conform with the shape of the underside of the foot as a three-dimensionally shaped footbed.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an insole designed to support a foot after an insole is inserted into a shoe so as to abut against a bottom section of the shoe, and the insole is a flexible one in which a large number of elastic studs are raised. It includes an integral plastic material that forms a planar base layer.

  The invention further relates to a shoe with a removable insole of the type described.

  Removable insoles for shoes are well known. They are composed of various materials and are often pre-shaped by thermoforming (eg EVA (ethyl vinyl acetate) foam) or sealed molds (eg PU (polyurethane) foam). Thereby, they form an insole in the shoe and the bottom section is not shaped or fully shaped to form the insole. Because this type of insole has a predetermined three-dimensional shape, many types must be manufactured to meet customer needs. The insole may extend the entire length of the foot or may be designed to support only a portion of the foot, such as the heel or forefoot.

  Since the essential part of the insole is made of a single piece of plastic material and is manufactured by injection molding, there are known insoles with a considerable number of elastic studs raised from a flexible planar base layer. An illustration of this type of insole is described by US2010 / 0175275A1. A number of elastic studs serve to provide a massage and reflexology system by contacting the bottom of a person's foot with the top of the stud. At the same time, shock absorption is realized by the elastic stud. The upper surface of the insole formed by the top of the stud is generally in contact with at least a portion of the bottom of the user's foot so that the massaging and reflexology system is maintained so that the massaging and reflexology system is maintained. May be contoured to match the contour of In this way, the interactive effects of massage, shock absorption, muscle stimulation and blood circulation are better imparted to the wearer's or user's foot. Therefore, the insole is only useful for users who desire a massage or reflexology effect and are ready to withstand strong and timeless contact between the foot insole and the bottom, and the point-like contact is a strong stimulus. It can be felt uncomfortable when provided to the foot, especially when the stud has a high hardness. US 2010/0175275 A1 therefore discloses an upper part of a cup-shaped stud thereby expanding the contact area between the insole and the user's foot.

  GB2418129A discloses an impact absorbing insole having a woven fabric surface upper layer that provides a surface of contact for a user's foot. The lower layer comprises a cell membrane structure that contains a chemically inert gel or fluid of sufficient viscosity to provide a cushioning effect when the cells are all the same size and compressed. In such a structure, the molding of the insole to form the insole must be done on the top layer by the conventional methods described above.

US2010 / 0175275A1 GB2418129A US4974345A US4908962A US5619809A

  It is an object of the present invention to provide an insole of the kind described above that can be manufactured in an easy manner, and to provide a kind of insole and a comfortable feel.

  According to the present invention, the insole is designed to support the foot after the insole is inserted into the shoe so as to contact the bottom section of the shoe, and a plurality of elastic studs are raised therefrom. An insole comprising an integral plastic material that forms a flexible planar base layer is designed such that the planar base layer is designed as the contact surface for the foot and the stud extends from the base layer to the sole section of the shoe, Shaped at various heights so that when loaded by the foot, the flexible planar base layer is deformed to conform to the shape of the underside of the foot as a three-dimensionally shaped insole It is characterized by that.

  According to the present invention, the stud is not used for massage and reflexology, but is used to easily form an insole for the user's foot due to weight loading. For this purpose, the studs are made at various heights so that in the absence of weight loading, the insole contacts the sole section of the shoe only with some studs having a relatively large height. In this state, the planar base layer remains planar. Smaller height studs are also compressed against the shoe sole section so that the weight loading causes the base layer to deform to allow the smaller stud to contact the shoe sole section. The stud height distribution is selected such that deformation of the base layer forms a more suitable insole for the base layer that functions as the contact surface of the foot. The base layer does not need to have direct contact with the foot, and may be covered with a flexible cover layer, preferably composed of fibers, leather or other materials with pleasant properties It should be noted. However, the cover layer does not substantially affect the deformation of the planar base layer whose deformation is determined by the dispersion and height of the studs on the underside of the insole. Thus, the base layer can be manufactured as a planar layer and nevertheless can form an insole when the weight of the user is loaded on the insole. With the studs on the lower side, the insole can be made of less material compared to an insole made of the same material and shaped to form a conventional type insole. With studs, there are multiple spaces between the studs where no material is required. In addition, the stud has elastic properties and, as the added weight increases, the stud contacts the sole section of the shoe, thereby contributing to the overall spring strength of the insole, thus creating innovative spring properties. . With studs, the insole of the present invention may be manufactured with approximately 60% of the material, ie approximately 60% of the weight required for the insole that forms the insole from the same perfectly shaped material. Only with the studs, the insole according to the invention has the function of adapting to the deformation of the individual foot due to weight loading.

  The studs may be dispersed over the entire length of the insole. For some purposes, allowing the stud base layer to deform to form an insole, while the stud is only part of the insole, e.g. only on the heel, only on the heel and on the planar arch And / or only on the toes, preferably on the underside of the insole. For some purposes, the insole according to the present invention is designed to support only a part of the length of the foot, such as the heel, the heel and the planar arch, and / or the toe. It is preferable to extend only the length of the part.

  In a preferred embodiment according to the present invention, the hardness of the material from which the base layer and stud are formed is between 30 Shore 00 and 50 Shore 00, more preferably between 33 Shore 00 and 45 Shore 00, More preferably, it can be between 35 Shore 00 and 40 Shore 00. Therefore, the material has a hardness between 80 Shore 00 and 100 Shore 00, and even in the case of soft massage sandals, the hardness is different from the materials used for massage and reflexology studs exceeding 50 Shore 00 It may be a soft material.

  In a preferred embodiment, the insole extends over the entire length of the foot, with studs of small height at the center and toe of the insole, at the edge of the heel and between the heel and toes. A stud having a larger height is provided at the intermediate portion. Preferably, the intermediate portion is the instep of the insole.

  For ease of manufacture, the stud is preferably a large stud without a cavity, for example.

  Preferably, the studs are designed to increase their diameter when compressed by a heavy load. The reduction in height due to the elastic weight load thus leads to a corresponding increase in diameter, whereby the studs extend into the intermediate space between the studs.

  In a preferred embodiment according to the invention, a number of vent holes are arranged in the base layer in the space between the studs. The expansion of the studs due to the weight load clearly reduces the space between the studs, thereby pushing air through the vents from the underside of the bottom to the lower surface of the foot that adds weight load to the insole.

A suitable material for the insole is a gel, in particular a polyurethane gel. In a preferred embodiment, the polyurethane gel may have a specific weight between 0.6 g / cm ³ and 1.1 g / cm ³ . A suitable gel is, in a preferred embodiment, such that the gel is covered by a film of non-adhesive material, which in this case may also be polyurethane, but selected to be non-adhesive and non-tacky. You may have adhesiveness.

  The present invention will be described in more detail with reference to the accompanying drawings.

The lower side perspective view concerning a 1st embodiment of an insole. The side view of the insole of FIG. The insole of FIG. 1 which shows dispersion | distribution of a stud seen from the bottom. The lower perspective view which concerns on 2nd Embodiment of an insole. The figure which looked at the insole of FIG. 4 from the bottom. Schematic which shows a deformation | transformation of a stud when a weight is loaded. A similar schematic drawing focusing on the ventilation effect through the ventilation holes. The bottom perspective view of an embodiment of an insole having only studs in the heel section. FIG. 6 is a bottom perspective view of an embodiment of an insole having only studs in the heel and planar arch sections. The lower perspective view of the insole extending only over the heel section of the foot length.

  The embodiment of FIGS. 1 to 3 is an integral insole made of a plastic material composed of a thin planar base layer 1 and a plurality of studs 2 below this base layer 1. The upper side of the base layer is manufactured as a flat surface 3 that serves as a contact surface for the user's foot. For this purpose, an integral insole made from a plastic material according to FIGS. 1 to 3 may have a cover layer on the upper side of the flat surface 3.

  Furthermore, the material of the insole that forms the base layer 1 and the stud 2 may be surrounded by a film of a material similar to the base layer 1 and the stud 2, but may be modified to be non-tacky or non-adhesive. . Note that when such an enclosing film is used, the cover layer for the flat surface 3 is applied to the enclosing film of the base layer 1 and the stud 2.

  The insole can be manufactured by casting liquid form material into a mold having deeper cavities within the stud 2 form and between the small planar cavities of the base layer. The cavities may be aligned with the non-stick film by applying a vacuum to the film by well known methods, for example by coating or by applying a release agent. The liquid material is then cast and allowed to be injected into the mold. After injection, the mold may be covered with a cover layer made of fiber, leather, or microfiber material, which is fixedly bonded to the material of the insole during the curing of the material in the mold, and the contact surface Function as.

  As shown in the figure, on the underside of the base layer 1, the stud 2 has various heights. They may have a rounded cylindrical shape at the tip. The cylindrical cross section has an annular shape. The diameter of the stud within the cylindrical portion essentially corresponds to the height of each stud. It can be seen that there is a higher stud 2a at the edge of the heel 4 of the insole. The stud 2 a at the edge is higher and has a larger diameter than the stud 2 b at the center of the flange 4.

  At the other end of the insole, that is, at the toe portion 5, the stud 2c is smaller than the stud 2b at the center of the heel portion. Between the toe part 5 and the heel part 4, there is an intermediate part 6 showing a higher stud 2d in the arcuate flat part of the insole, which is higher than the stud 2a at the edge of the heel part. The stud 2 d at the side edge of the intermediate portion 6 may have approximately the same size as the stud 2 a at the edge of the flange portion 4. The middle section 6 establishes the instep sole of the insole that is designed to contact the instep of the user.

  As shown in FIGS. 1 and 2, the insole as manufactured has only a relatively highest stud 2 tip, a support layer such as a shoe bottom section into which the insole may be inserted. To touch. In this state, the base layer 1 remains flat and planar. The stud is directed to the support surface like a shoe bottom section. When a user applies a weight load at the insole, the insole contacts the sole section of the shoe with all studs of varying heights. Thereby, the base layer 1 is deformed according to the dispersion of the studs 2 of various heights. The dispersion of the studs 2 is selected such that the base layer is transformed into an insole shape that lays the user's feet in a comfortable manner.

  It should be noted that the insole only contacts the sole section of the shoe through the stud 2 so that there is no direct contact to the support surface, i.e. part of the base layer, to the sole section of the shoe.

  FIG. 3 shows the dispersion of the studs 2 over the entire lower surface of the base layer 1. Since the height of the studs 2 is essentially equal to their diameter, it can be seen even from FIG. 3 where higher height studs are arranged.

  The rule that the height is equal to the diameter of the stud 2 may be neglected at the toe 5 where the diameter can be different and the stud can be made quite low at the toe 5 so that the height of the stud Note that it may be equal to twice this.

  The second embodiment of FIGS. 4 and 5 shows an insole made with the same principle but fitted with a somewhat thicker base layer 1 from which the stud 2 rises no more than 3 mm. Again, the height of the stud 2 is discrete so as to form an insole when the insole is loaded with the user's weight.

  FIG. 6 shows the effect of weight transmitted by the user's foot 7. The base layer 1 in the manufactured state, ie with the contour of the stud 2 without weight loading, is shown. There is a large space 8 between the studs 2. When a pressure of weight as shown by the arrows in FIG. 6 is applied, the stud is compressed against the bottom of the shoe and thereby deformed as shown at 2 '. Thereby, the space 8 'is considerably reduced in size. At the same time, the contact surface 3 ′ of the base layer 1 that is in pressure contact with the bottom of the foot 7 conforms to a contour corresponding to the contour of the bottom of the foot 7 due to the different compressibility of the stud 2.

  In the embodiment of FIG. 7, the base layer 1 is in the flat surface 3 of the base layer when the insole is loaded by the weight pressure by the foot 7, ie in the space 8 between the studs 2 below the foot 7. It has a vent hole 9 which is a through hole to be connected. A heavy load causes the same deformation of the stud 2 into the stud 2 'as shown in FIG. The reduced space 8 'between the studs 2' passes through the vent 9 'so that the bottom of the foot 7 is vented at every weight load of the insole while walking, running or standing. Air is pushed out of the space 8 '.

  Due to the large number of studs 2, the air is considerably pushed out through the vent holes 9. Extrusion of the air side from the weight-loaded insole is prevented and air is forced through the vent hole 9 so that the space 8 between the studs 2 as a hole is sealed against the surroundings. By providing a sealing edge at the outer contour of the insole, the effect can be enhanced. The sealing edge can have a form of small lip so that there is no significant effect on the elastic deformation of the stud 2 due to weight loading.

  The insole of the present invention can be manufactured with a flat, flat base layer 1 that is deformed by weight pressure so as to adapt to the shape of the foot 7 applying weight pressure and thus form a kind of insole.

  FIG. 8 shows a variation of the insole similar to the insole of FIG. 1 in the heel 4 such that the stud 2 at the bottom provides a midsole shape by weight loading as described above. However, the other part or section of the insole designed to extend over the length of the entire foot is free of studs 2 and therefore the insole is only composed of the base layer 1 in the other part, whereas in the heel region There is support with only stud 2.

  A further variation of the insole similar to the embodiment of FIG. 1 is shown in FIG. The insole has the stud 2 on the lower side in the collar part 4, and the intermediate part 6 includes an arch-shaped flat part. The distribution of studs with various heights may be the same as described in the previous embodiment. In this case as well, the insole is designed to extend over the entire length of the foot, but has the stud 2 only at the heel part 4 and the intermediate part 6, not at the forefoot part including the toe part 5, for example.

  All the embodiments of FIGS. 1 to 9 show an insole with a base layer 1 extending over the entire length of the foot 7 (or shoe), so as to fit the length of the foot 7 or the shoe for the particular application. It should be noted that it has grooves or simple lines that allow the length of the insole to be shortened.

  FIG. 10 shows an example of an insole according to the invention that does not extend over the entire length of the foot 7 but instead spans a specific part, ie the heel part 4 in the embodiment of FIG. The insole according to this embodiment has a distribution similar to that of the embodiment of FIG. 1 of the stud 2 on the lower side, such that the insole is formed by weight load by the heel of the foot 7. It will be apparent to those skilled in the art that an insole may be provided that extends over other portions of the foot length in the same manner, for example, an arcuate planar portion and / or a forefoot portion. Forefoot support may be particularly adapted to higher heel shoes, which are primarily weight loaded at the forefoot or toe of the foot 7.

  The insole extending over only a part of the length of the foot 7 provides adhesion to the underside of the insole, for example to the tip of the stud 2 or to the contact surface 3 of the base layer 1 for securing the insole to the foot 7. It may be protected against movement or slipping in the shoe by being manufactured from the material having or by applying a pad of sticky material. Of course, other fixations, for example mechanical fixation by side extensions that can be formed, fit into the corresponding side recesses of the shoe.

Claims (11)

  An insole designed to support the foot (7) after the insole has been inserted into the shoe so as to abut against the bottom section of the shoe, with a number of elastic studs (2) raised therefrom In an insole comprising an integral plastic material forming a unidirectional planar base layer (1), the planar base layer (1) is designed as a contact surface for the foot (7), and the stud is provided with the base layer ( Designed to extend from 1) to the bottom section of the shoe, the stud (2) is three-dimensional with the flexible planar base layer (1) when weight-loaded by the foot (7). An insole characterized in that it is shaped at various heights so as to be deformed so as to be conformal with the shape of the lower side of the foot (7) as an insole shaped into a shape.   There are studs (2b, 2c) in the center of the heel part (4) of the insole and the center of the toe part (5), and at the edge of the heel part (4), as well as the heel part (4) and the toe part. Insole according to claim 1, characterized in that the stud (2a) with a higher height is provided in the intermediate section (6) between (5).   Insole according to claim 2, characterized in that the intermediate part (6) is the upper part of the foot.   Insole according to any one of the preceding claims, characterized in that the stud (2) is a large stud.   Insole according to any one of the preceding claims, characterized in that the studs (2) are designed to increase their diameter when compressed by a heavy load.   Insole according to any one of the preceding claims, characterized in that a number of vent holes (9) are arranged in the base layer (1) in the space (8) between the studs (2). .   The insole according to any one of claims 1 to 6, wherein the plastic material of the insole is a gel.   The insole according to claim 7, wherein the gel is a polyurethane gel.   9. Insole according to claim 7 or 8, characterized in that the gel is covered with a film of non-adhesive material.   The insole according to claim 9, wherein the film is a polyurethane film.   A shoe comprising a bottom section, an upper section, and the removable insole according to any one of claims 1 to 10, wherein the insole abuts the bottom section by means of an upper part of the stud (2). shoes.