JP5161626B2 - Buffer structure and sole structure of sports shoe using the buffer structure - Google Patents

Description

  The present invention relates to a buffer structure, and more particularly to an improvement in structure to allow a more flexible design.

  As the buffer structure, for example, the one shown in Japanese Patent Application Laid-Open No. 11-235202 has been proposed by the present applicant. This buffer structure is configured by arranging a plurality of strip-shaped corrugated sheets in parallel and connecting the strip-shaped corrugated sheets to each other by a connecting portion.

  In addition, the pamphlet of International Publication No. 2006/129737 discloses an upper plate, a wave-like lower plate having at least two bulging portions disposed below the upper plate and forming a gap with the upper plate, and a lower plate A sole structure including a plurality of outsole portions attached to the lower surface of each of the bulging portions and separated in the front-rear direction is shown.

Further, in JP-A-2003-339405, an upper and lower plate disposed opposite to each other with a certain gap in the vertical direction and an upper convex surface are fixed to the upper plate. In addition, a sole structure including a corrugated plate whose lower convex surface is fixed to the lower plate is shown.
JP 11-235202 A (see FIG. 1) International Publication No. 2006/1229837 Pamphlet (See Figure 1A) JP 2003-339405 A (see FIG. 2)

  In the buffer structure shown in Japanese Patent Application Laid-Open No. 11-235202 described above, when an impact load is applied, the impact load is absorbed by deformation so that the corrugated peak portion of each strip corrugated sheet sinks downward. Is done. At this time, the connecting portion is twisted by each deformed belt-like corrugated sheet, and the connecting portion acts as a torsion bar. Absorbed.

  However, in this case, since each belt-like corrugated sheet is composed of a continuous wave shape in the front-rear direction, the deformation generated in some of the wave shapes propagates in the front-rear direction and affects the adjacent wave shape. Effect.

  Further, in the sole structure shown in the above International Publication No. 2006/1229837 pamphlet, the bottom surface of each bulging portion of the lower plate abuts on the grounding surface via each outsole portion when the shoe lands, The impact load is absorbed by the gap between the upper and lower plates acting as a cushion hole.

  However, even in this case, the shock load is absorbed by the deformation of the wave shape of the lower plate, and the wave shape of the lower plate is continuous in the front-rear direction. Will affect the wave shape.

  Furthermore, in the sole structure shown in the above Japanese Patent Application Laid-Open No. 2003-339405, when the shoe lands, the upper convex surface of the corrugated plate is deformed so as to sink downward, so that the gap between the upper and lower plates acts as a cushion hole. By doing so, the impact load is absorbed.

  In this case, the corrugated plate has a structure in which the upper convex surface is fixed to the upper plate and the lower convex surface is fixed to the lower plate, so that the deformation generated in a part of the wave shape is difficult to propagate in the front-rear direction. It has become. However, in this case, since the upper convex surface and the lower convex surface of the corrugated plate are restrained by the upper and lower plates, free deformation of the corrugated plate is restricted.

  The present invention has been made in view of such conventional circumstances, and the problem to be solved by the present invention is that deformation that has occurred in a part of the structure is allowed while allowing free deformation of the structure itself. An object of the present invention is to provide a buffer structure having a structure capable of preventing propagation to other portions. Further, the present invention seeks to provide a buffer structure that can be designed with a high degree of freedom by such a structure.

  The buffer structure according to the invention of claim 1 is configured by juxtaposing at least two plate-like pieces having a curved shape from the front end to the rear end in the front-rear direction and overlapping a part thereof, One adjacent plate-like piece has a notch, and the other plate-like piece has a projecting portion to be inserted into the notch.

  According to the first aspect of the present invention, when the impact load is applied, the impact is absorbed by the plate-like piece being compressed and deformed in a direction in which the curved shape becomes flat. In addition, when the plate-shaped piece is deformed, the deformation of the plate-shaped piece is simply changed so that the amount of overlap between the protruding portion of the plate-shaped piece and the notch of the adjacent plate-shaped piece that overlaps the plate-shaped piece is changed. Can be prevented from propagating as it is to the adjacent plate-like piece. That is, in this case, since the plate-like piece on which the impact load is applied supports the load independently of the other plate-like pieces, a structure including an independently suspended plate-like piece can be realized.

  Thus, according to the first aspect of the present invention, it is possible to prevent the deformation generated in each plate-shaped piece from propagating to other plate-shaped pieces while allowing the free deformation of each plate-shaped piece itself.

  In this case, the degree of freedom is high by adjusting the overlap amount of adjacent plate-like pieces or changing the length between the front and rear ends of the plate-like pieces corresponding to the wavelength of the corrugated plate. Design becomes possible.

  For example, by increasing the overlap amount of adjacent plate-like pieces, a large number of plate-like pieces can be arranged in a limited area. In addition, as the length between the front and rear ends of the plate-like piece is increased, the compression hardness (hardness of compressive deformation) decreases, but the cushioning property increases, while the length between the front and rear ends of the plate-like piece. As the thickness is shortened, the cushioning property decreases, but the compression hardness increases and the stability is improved. In this case, for example, by increasing the overlap amount between the adjacent plate-like pieces while increasing the length between the front and rear ends of the plate-like pieces, both cushioning properties and stability can be achieved.

  According to a second aspect of the present invention, in the first aspect, the buffer structure further includes a base, and the front and rear end surfaces of each plate-like piece are fixed to the surface of the base.

  According to a third aspect of the present invention, in the first aspect, the notch is formed in the central portion of the end face of the plate-like piece.

  In this case, the protruding portion of the adjacent plate-like piece is similarly formed at the center portion of the end face, and each plate-like piece can be configured symmetrically with respect to the center line in the front-rear direction, thereby The piece can support the impact load in a balanced manner on the left and right.

  In addition, the notch may be formed in the corner | angular part of the end surface of a plate-shaped piece, as described in invention of Claim 4.

  According to a fifth aspect of the present invention, there is provided a shock absorbing structure in which first, second and third plate-like pieces having curved shapes from the front end to the rear end are arranged side by side in the front-rear direction and one of the adjacent plate-like pieces. The first and second plate pieces adjacent to each other have a notch, and the other plate-like piece is inserted into the notch. An overhanging portion, and one of the adjacent second and third plate-like pieces has a notch, and the other plate-like piece is inserted into the notch. Have.

  According to the fifth aspect of the present invention, when the impact load is applied, the plate-like piece to which the impact load is applied is compressed and deformed in a direction in which the curved shape becomes flat, whereby the impact load can be absorbed. In addition, when the plate-shaped piece is deformed, the amount of overlap between the protruding portion (or notch) of the plate-shaped piece and the notch (or protruding portion) of the adjacent plate-shaped piece that overlaps with this changes. Therefore, the deformation of any plate-like piece can be prevented from propagating as it is to the remaining plate-like pieces. That is, in this case, the plate-like piece on which the impact load is applied supports the load independently from the remaining plate-like pieces, so that a structure including an independently suspended plate-like piece can be realized.

  Thus, according to the invention of claim 5, it is possible to prevent the deformation generated in each plate-shaped piece from propagating to the remaining plate-shaped pieces while allowing the free deformation of each plate-shaped piece itself.

  Further, in this case, the amount of overlap between adjacent first and second plate-like pieces, or the amount of second and third overlap can be adjusted, or the front and back of each plate-like piece corresponding to the wavelength of the corrugated plate A design with a high degree of freedom is possible by changing the length between the ends.

  For example, by increasing the overlap amount of adjacent plate-like pieces, a large number of plate-like pieces can be arranged in a limited area. In addition, as the length between the front and rear ends of the plate-like piece is increased, the compression hardness (hardness of compressive deformation) decreases, but the cushioning property increases, while the length between the front and rear ends of the plate-like piece. As the thickness is shortened, the cushioning property decreases, but the compression hardness increases and the stability is improved. In this case, for example, by increasing the overlap amount between the adjacent plate-like pieces while increasing the length between the front and rear ends of the plate-like pieces, both cushioning properties and stability can be achieved.

  In the invention of claim 6, in claim 5, the second plate-like piece has a generally Y-shaped or V-shaped shape.

  In this case, the second plate-shaped piece has a notch at one end and a protruding portion at the other end.

  In a seventh aspect of the present invention, in the fifth aspect, all of the first to third plate-like pieces have a substantially Y-shaped or V-shaped shape.

  In this case, each of the first to third plate-like pieces has a notch at one end and an overhanging portion at the other end, whereby one type of plate-like piece is formed. Since it is sufficient to prepare it, it is easy to manufacture.

  According to an eighth aspect of the present invention, in the fifth aspect, the second plate-like piece has a protruding portion at the front and rear ends thereof.

  In this case, the first and third plate-like pieces each have a notch at the end portion adjacent to the second plate-like piece.

  In the ninth aspect of the present invention, in the fifth aspect, the second plate-like piece has a substantially H-shaped shape having notches at the front and rear ends thereof.

  In this case, each of the first and third plate-like pieces has an overhang portion at an end portion adjacent to the second plate-like piece.

  According to a tenth aspect of the present invention, in any one of the first to ninth aspects, when a deformation is applied to the curved surface of any plate-like piece, the deformation is independent of the deformation of the other plate-like pieces. To be done.

  According to an eleventh aspect of the present invention, in any one of the first to ninth aspects, when the curved surface of any plate-like piece is deformed by applying a load, the deformed plate-like piece is adjacent to the other piece. The size of the notch or the protruding portion and the overlap amount are set so as not to interfere with the plate-like piece.

  In the invention of claim 12, at least two rows of the buffer structures according to claim 1 or 5 are arranged in parallel in the front-rear direction, and the plate-like pieces corresponding to the left-right direction are connected to each other.

  In this case, two rows (or more) in the front-rear direction composed of the respective plate-like pieces disposed in the front-rear direction are disposed on the left and right, and a wide area can be covered. In addition, in this case, since the plate-like pieces corresponding to the left and right directions are connected to each other, the deformation applied to one end side in the left and right direction is propagated toward the other end side in the left and right direction. Become. Accordingly, only one end side of the buffer structure is not greatly deformed, and the entire left and right direction is deformed from one end side to the other end side of the buffer structure, so that the stability as the buffer structure is increased.

  In the invention of claim 13, the buffer structure according to claim 1 or 5 is arranged in at least two rows in the front-rear direction, and the plate-like pieces corresponding to the left-right direction are separated from each other.

  In this case, two rows (or more) in the front-rear direction composed of the respective plate-like pieces disposed in the front-rear direction are disposed on the left and right, and a wide area can be covered. In addition, in this case, since the plate-like pieces corresponding to the left and right directions are separated from each other, the deformation applied to the plate-like piece on one end side in the left-right direction is changed to the plate-like piece on the other end side in the left-right direction. Is not propagated. Thereby, the cushioning property and stability on one end side can be controlled independently from the other end side.

  As described in the invention of claim 14, the buffer structure is used as a sole of sports shoes, for example. Further, as described in the invention of claim 15, the buffer structure is provided at least on the heel portion in the sole of the sports shoe, or as described in the invention of claim 16. It is provided on the entire surface from the heel portion to the toe portion in the sole of the sports shoe.

  In these cases, the shock received during the landing of the shoes can be absorbed and mitigated by the buffer structure.

  According to a seventeenth aspect of the present invention, in any one of the fourteenth to sixteenth aspects, a recess is formed in the sole, and the buffer structure is provided in the recess.

  In this case, since it can comprise so that a buffer structure may not be exposed to the exterior of shoes, it can prevent that soil, sand, etc. permeate the inside of a buffer structure at the time of a game.

  According to an eighteenth aspect of the present invention, the cushioning structure according to any one of the first to thirteenth aspects constitutes the sole of the creat shoe, and the creat is attached to the lower surface of the plate-like piece.

  In this case, providing the creat increases the rigidity of the plate-like piece and increases the compression hardness, but by increasing the length between the front and rear ends of the plate-like piece, the increase in the compression hardness is offset. It is possible to improve cushioning properties. Further, in this case, the cushioning property can be increased, so that the feeling of pushing up from the creat can be reduced.

  As described above, according to the buffer structure according to the first aspect of the present invention, at least two plate-like pieces having a curved shape from the front end to the rear end are arranged in the front-rear direction so that each part overlaps. In addition to the parallel arrangement, a notch is provided in one adjacent plate-like piece, and an overhanging part is provided in which the notch is inserted into the other plate-like piece, so that the plate-like piece is compressed when an impact load is applied. Not only can the impact load be absorbed by deforming the curved shape in a flat direction, but also when the plate-shaped piece is deformed, the overhanging portion of the plate-shaped piece and the adjacent plate-shaped piece that overlaps this are cut. Since it only deforms so that the amount of overlap with the notch changes, each plate-shaped piece itself is allowed to freely deform, but the deformation generated in each plate-shaped piece is prevented from propagating to other plate-shaped pieces. it can. In this case, the degree of freedom is high by adjusting the overlap amount of adjacent plate-like pieces or changing the length between the front and rear ends of the plate-like pieces corresponding to the wavelength of the corrugated plate. Design becomes possible.

  According to the buffer structure according to the second aspect of the present invention, the first, second and third plate-like pieces each having a curved shape from the front end to the rear end are juxtaposed in the front-rear direction and adjacent plates And a notch is inserted into one of the adjacent first and second plate-like pieces, and a notch is inserted into the other plate-like piece. A projecting portion in which a notch is inserted into one of the adjacent second and third plate-like pieces, and a notch is inserted into the other plate-like piece. Since each is provided, when the impact load is applied, the plate-like piece on which the impact load is applied is compressed and the curved shape is deformed in a flattened direction so that the impact load can be absorbed. At the time of deformation, it overlaps with the protruding portion (or notch) of the plate-like piece. The deformation of each plate-like piece is allowed while the deformation of the plate-like piece is allowed while the amount of overlap with the notch (or projecting part) of the plate-like piece is changed. Propagation to the remaining plate-like pieces can be prevented. Further, in this case, each plate shape corresponding to the wavelength of the corrugated plate or the overlap amount of the adjacent first and second plate pieces and / or the second and third overlap amounts is adjusted. A design with a high degree of freedom is possible by changing the length between the front and rear ends of the piece.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
[First embodiment]
1 to 4B are views for explaining a buffer structure according to a first embodiment of the present invention. FIG. 1 is a perspective view of the buffer structure, and FIG. 2 is a separate view of the buffer structure of FIG. FIG. 3A is a side view of the buffer structure, FIG. 4A is a schematic view of the state before deformation of the buffer structure, and FIG. 4B is a diagram of the state after deformation of the buffer structure. It is a schematic diagram shown. In these drawings, the same reference numerals indicate the same or corresponding parts.

  As shown in FIGS. 1 to 3, the buffer structure 1 is configured by arranging four plate-like pieces 11, 12, 13, 14 having a curved shape in the front-rear direction (arrow X direction). . Each plate-like piece is curved in a convex shape from the front end to the rear end. Adjacent plate-like pieces are arranged on the base 10 in a state where a part thereof overlaps each other.

  Each of the plate-like pieces 11 to 14 is a member made of, for example, a resin. Specifically, a thermoplastic material such as thermoplastic polyurethane (TPU) or polyamide elastomer (PAE) is used, and an epoxy resin or unsaturated resin is used. Thermosetting materials such as polyester resins are also used. Moreover, as a constituent material of each plate-shaped piece 11-14, it is also possible to use an ethylene-vinyl acetate copolymer (EVA), rubber, or the like.

  The plate-like piece 11 has a front end face 11 </ b> A and a rear end face 11 </ b> B fixed on the base 10. An arc-shaped notch 11C is formed in a substantially central portion of the rear end face 11B. The plate-like piece 12 has an overhanging portion 12D that protrudes forward from the front end side center, and the overhanging portion 12D is inserted into the notch 11C of the plate-like piece 11. A front end surface 12 </ b> A of the overhang portion 12 </ b> D is fixed on the base 10 as a front end surface of the plate-like piece 12. An arc-shaped notch 12 </ b> C is formed at a substantially central portion of the rear end surface 12 </ b> B of the plate-like piece 12. The rear end surface 12 </ b> B of the plate-like piece 12 is fixed on the base 10. The plate-like piece 12 has an overhanging portion 12D on the front end side and a notch 12C on the rear end side, so that the entire plate-like piece 12 is formed in a generally flat Y shape.

  The plate-like pieces 13 and 14 have a flat, generally Y-shape similar to the plate-like piece 12. That is, the overhanging portion 13D of the plate-like piece 13 is inserted into the notch 12C of the plate-like piece 12, and an arcuate notch 13C is formed at a substantially central portion of the rear end face 13B. The front end surface 13A of the overhang 13D is fixed on the base 10 as the front end surface of the plate-like piece 13, and the rear end surface 13B of the plate-like piece 13 is fixed on the base 10. Further, the overhanging portion 14D of the plate-like piece 14 is inserted into the notch 13C of the plate-like piece 13, and an arc-like notch 14C is formed at a substantially central portion of the rear end surface 14B. The front end surface 14A of the overhanging portion 14D is fixed on the base 10 as a front end surface of the plate-like piece 14, and the rear end surface 14B of the plate-like piece 14 is fixed on the base 10.

  In other words, since the notches are formed in the rear end surfaces of the plate-like pieces 11 to 14, each plate-like piece 11 to 14 has a pair of leg portions on both the left and right sides of the rear end surface. Have. That is, each plate-like piece 11-14 has leg parts 11L, 12L, 13L, 14L on one side of the rear end face, and has leg parts 11R, 12R, 13R, 14R on the other side.

As shown in FIG. 4A, λ ₁ = λ ₂ = λ where λ ₁ , λ ₂ , λ ₃ , λ ₄ are the distances in the front-rear direction between the front and rear end faces of the plate-like pieces 11, 12, 13, and it has a ₃ = _{λ 4.} Further, the overlap amount between adjacent plate-like pieces 11 and 12 is δ ₁ , the overlap amount between the plate-like pieces 12 and 13 is δ ₂ , and the overlap amount between the plate-like pieces 13 and 14 is δ _{When 3} is set, δ ₁ = δ ₂ = δ ₃ . Here, the overlap amount of each plate-like piece is represented by a distance in the front-rear direction from the position where each plate-like piece intersects to the tip of the overhang portion when the buffer structure 1 is viewed from the side. ing.

  Next, the effect of a present Example is demonstrated using FIG. 4A and FIG. 4B.

  When an impact load is applied to the buffer structure 1 (FIG. 4A) from above and below, the plate-like pieces 11 to 14 are compressed and deformed in a direction in which the curved shape becomes flat, as shown by a one-dot chain line in FIG. 4B. Thus, the impact load can be absorbed. At this time, the plate-like piece 11 supports the load by the front end surface 11A and the leg portions 11L and 11R on the rear end side, and the plate-like pieces 12 to 14 have the protruding portion front end surfaces 12A to 14A, and The load is supported at three points of the leg portions 12L to 14L and 12R to 14R.

At this time, since the front and rear end faces of the plate-like pieces 11 to 14 are fixed on the base 10, the longitudinal distance λ between the front and rear end faces of the plate-like pieces 11 to 14 is changed before and after the deformation. Absent. That is, before and after the deformation, the longitudinal distance of the plate-like piece 11 remains λ _1. Similarly, the longitudinal distances of the other plate-like pieces 12, 13 and 14 are λ ₂ , λ ₃ and λ ₄ , respectively. Remains.

Each plate-like piece 11-14 only deform | transforms so that overlap amount (delta) with the notch of each adjacent plate-like piece may change. That is, the overlap amount of each of the plate-like pieces 11 and 12 is δ ₁ before the deformation, but becomes δ ₁ ′ (≠ δ ₁ ) after the deformation. Similarly, the overlap amount of the plate-like pieces 12 and 13 is δ ₂ before the deformation, but becomes δ ₂ ′ (≠ δ ₂ ) after the deformation. The overlap amount is δ ₃ before the deformation, but becomes δ ₃ ′ (≠ δ ₃ ) after the deformation.

  More preferably, when the plate-like pieces 11 to 14 are deformed by applying a load, the deformation is performed independently from the deformation of the other plate-like pieces. That is, when the plate-like pieces 11 to 14 are deformed by a load applied thereto, the respective notches or overhang portions are prevented so that the deformed plate-like pieces do not interfere with other plate-like pieces adjacent thereto. And the amount of overlap between the overhang and the notch are set.

  Thereby, it can prevent that the deformation | transformation of each plate-shaped piece 11-14 propagates to an adjacent plate-shaped piece as it is. That is, in this case, since the plate-like piece on which the impact load is applied supports the load independently of the other plate-like pieces, a structure including an independently suspended plate-like piece can be realized.

  The adjacent plate-like pieces 11 to 14 are configured so as not to interfere with each other as described above while the load is relatively small, and when the load exceeds a certain magnitude (threshold), It is also possible to configure such that the protruding portion of the other plate-shaped piece interferes with the notch of the other plate-shaped piece. In this case, the rigidity of the entire buffer structure increases with the threshold as a boundary.

  Thus, according to the present embodiment, it is possible to prevent the deformation generated in each plate-shaped piece from propagating to other plate-shaped pieces while allowing the free deformation of each plate-shaped piece itself.

  In this case, the degree of freedom can be adjusted by adjusting the overlap amount δ of the adjacent plate-like pieces or changing the length λ between the front and rear end faces of the plate-like pieces corresponding to the wavelength of the corrugated plate. High design is possible.

  For example, by increasing the overlap amount δ between the adjacent plate-like pieces, a large number of plate-like pieces can be arranged in a limited area. Further, as the length λ between the front and rear ends of the plate-like piece is increased, the compression hardness (hardness of compressive deformation) is reduced, but the cushioning property is increased. On the other hand, the distance between the front and rear ends of the plate-like piece is increased. As the length λ is shortened, the cushioning property is lowered, but the compression hardness is increased and the stability is improved. In this case, for example, by increasing the overlap amount δ of each adjacent plate-like piece while increasing the length λ between the front and rear ends of the plate-like piece, both cushioning and stability can be achieved. Become.

  In the first embodiment, the second to fourth plate-like pieces 12, 13, and 14 are formed in a flat and substantially Y-shape, but the front end of the first plate-like piece 11 is shown. In addition, the first plate-like piece 11 may be formed in the same flat and generally Y-shape by providing an overhang portion. In this case, since all the plate-like pieces 11 to 14 have the same shape, it becomes easy to manufacture and assemble the buffer structure.

  In the first embodiment, a notch is formed at the rear end of the fourth plate-like piece 14, but this notch may be omitted.

  Further, for example, a protruding portion is formed at the rear end of the second plate-shaped piece 12, and a notch for receiving the protruding portion is formed at the front end of the third plate-shaped piece 13. Good. In this case, the 2nd plate-shaped piece 12 has an overhang | projection part in the front-and-rear end, and the 3rd plate-shaped piece 13 is formed in the substantially H shape which has a notch in the front-and-rear end. . At this time, the shape of the second plate-like piece 12 is an I-shape extending in the front-rear direction by omitting the portion extending in the Y-direction and including only the projecting portion in the front-rear direction. May be.

  In the first embodiment, the longitudinal distance λ between the front and rear end faces of each plate-like piece and the overlap amount δ between adjacent plate-like pieces are all made equal between the plate-like pieces. Although shown, application of the present invention is not limited to this. The front-rear direction distance λ and the overlap amount δ may be made different between the plate-like pieces.

In the region of the plate-like piece with the long longitudinal distance λ, the cushioning property is increased, and when the overlap amount is increased, the density of the plate-like member is increased, so that the rigidity of the entire buffer structure is increased.
[Second Embodiment]
In the first embodiment, the example in which the second to fourth plate-like pieces 12, 13, and 14 are formed in a flat and substantially Y-shape is shown, but the application of the present invention is not limited to this. 5 and 6 show a buffer structure according to a second embodiment of the present invention. In the figure, the same reference numerals as those in the first embodiment denote the same or corresponding parts.

  As shown in FIGS. 5 and 6, in the second embodiment, the second to fourth plate-like pieces 12, 13, and 14 are formed in a substantially V-shape or a substantially Y-shape.

  Also in this case, when the impact load is applied, the plate-like piece 11 supports the load by the front end surface 11A and the respective leg portions 11L and 11R on the rear end side, and each plate-like piece 12-14 has the protruding portion front end surface 12A. 14A, and the legs 12L to 14L and 12R to 14R, the load is supported, and the plate-shaped pieces 11 to 14 are compressed and deformed in a direction in which the curved shape becomes flat, Can absorb impact load.

  Also in this case, the deformation of each of the plate-like pieces 11 to 14 is prevented from being propagated as it is to the adjacent plate-like piece. Thus, a structure including an independent suspended plate-like piece can be realized. In this way, it is possible to prevent the deformation generated in each plate-shaped piece from propagating to other plate-shaped pieces while allowing free deformation of each plate-shaped piece itself.

  In the second embodiment, the second to fourth plate-like pieces 12, 13, and 14 are formed in a substantially V shape or a substantially Y shape. The first plate-like piece 11 may be formed in the same general V shape or general Y shape by providing an overhanging portion at the front end of 11. In this case, since all the plate-like pieces 11 to 14 have the same shape, it becomes easy to manufacture and assemble the buffer structure.

In the second embodiment, a notch is formed at the rear end of the fourth plate-like piece 14, but this notch may be omitted.
[Third embodiment]
In the first and second embodiments, a notch formed in each plate-like piece is arranged in the center of the end surface of the plate-like piece, and each plate-like piece is configured symmetrically with respect to the center line in the front-rear direction. The example in which the plate-like piece can support the impact load in a balanced manner on the left and right is shown, but the application of the present invention is not limited to this. FIG. 7 shows a buffer structure according to a third embodiment of the present invention. In the figure, the same reference numerals as those in the first and second embodiments denote the same or corresponding parts.

  As shown in FIG. 7, in the third embodiment, the notches 12C, 13C, and 14C formed in the plate-like pieces 12, 13, and 14 are respectively front end surfaces of the plate-like pieces 12, 13, and 14. Is formed at one of the corners. Further, in this example, the relationship between the protruding portion and the notch formed in each plate-like piece is opposite to that in the front-rear direction with respect to the first and second embodiments. That is, the overhanging portion 11D formed on the plate-like piece 11 is inserted into the notch 12C formed on the plate-like piece 12, and similarly, the overhanging portion 12D of the plate-like piece 12 becomes the plate-like piece 13. The projecting portion 13D of the plate-like piece 13 is inserted into the notch 14C of the plate-like piece 14. Each of the plate-like pieces 12, 13, and 14 has leg portions 12R, 13R, and 14R at the end portion on the opposite side to the end portion on the notch forming side of the front end surface where the notch is formed.

  When the impact load is applied, the plate-like piece 11 supports the load at the front end surface 11A and the rear end side overhanging portion 11D, and the plate-like pieces 12-14 are respectively connected to the leg portions 12R-14R and the overhanging portions 12D˜. It is supported by 14D, and each plate-like piece 11-14 is compressed and its curved shape is deformed in a flattened direction, so that an impact load can be absorbed.

  Also in this case, the deformation of each of the plate-like pieces 11 to 14 is prevented from being propagated as it is to the adjacent plate-like piece. Thus, a structure including an independent suspended plate-like piece can be realized. In this way, it is possible to prevent the deformation generated in each plate-shaped piece from propagating to other plate-shaped pieces while allowing free deformation of each plate-shaped piece itself.

  In the third embodiment, the second to fourth plate-like pieces 12, 13, 14 except for the first plate-like piece 11 have the same shape. By forming a notch also in the front end of 11, all the plate-shaped pieces 11-14 may have the same shape, In this case, manufacture and an assembly of a buffer structure become easy.

In the third embodiment, the overhanging portion 14D is formed at the rear end of the fourth plate-like piece 14, but the overhanging portion 14D is omitted and the rear end surface 14B is extended in the left-right direction. May be.
[Other Example 1]
In each of the above embodiments, an example in which four plate-like pieces are arranged in the front-rear direction has been shown. However, the number of plate-like pieces is not limited to this, and the present invention includes at least two plate-like pieces. It is applicable to what is installed.
[Other Example 2]
In each of the above-described embodiments, an example in which the buffer structure is arranged in one row in the front-rear direction has been described, but the application of the present invention is not limited to this. The buffer structures may be arranged in parallel in at least two rows in the front-rear direction. At this time, the plate-like pieces adjacent in the left-right direction (arrow Y direction) may be connected to each other or separated from each other. Good.

In this case, two rows (or more) in the front-rear direction composed of the respective plate-like pieces disposed in the front-rear direction are disposed on the left and right, and a wide area can be covered. Here, when the plate-like pieces corresponding to the left-right direction are connected to each other, the deformation applied to the one end side in the left-right direction is propagated toward the other end side in the left-right direction. Further, when the plate-like pieces corresponding to the left-right direction are separated from each other, the deformation applied to the plate-like piece on one end side in the left-right direction is not propagated to the plate-like piece on the other end side in the left-right direction.
[Application Example 1]
8 and 9 are views for explaining an example in which the buffer structure according to the present invention is applied to a midsole of a sports shoe, wherein FIG. 8 is a partial cross-sectional side view of the shoe, and FIG. It is a plane schematic diagram of a sole. In these drawings, the same reference numerals as those in the above-described embodiments indicate the same or corresponding parts.

  As shown in FIG. 8, the sports shoe 100 includes an upper 101 and a midsole 102 to which a lower portion is fixed. A recess 102a is formed in the heel portion of the midsole 102, and the buffer structure 1 according to the present invention is provided in the recess 102a.

  The buffer structure 1 is composed of plate-like pieces 11, 12, and 13 in this example. The front and rear end surfaces of the plate-like pieces 11, 12, 13 are fixed to the upper wall surface of the recess 102a (corresponding to the base surface in each of the above embodiments). In addition, an outsole 103 is fixed to the lower part of the midsole 102, and the curved surfaces of the plate-like pieces 11, 12, and 13 are movable on the outsole 103 without being fixed to the outsole 103. It is in

  At the time of landing on the shoe, the heel portion receives an impact load, and this load is absorbed and alleviated by deforming the plate-like portions 11, 12, and 13 of the shock absorbing structure 1 so that the curved shape becomes flat. it can. In this case, since the buffer structure 1 is provided in the recess 102a of the midsole 102, the buffer structure 1 can be configured not to be exposed to the outside of the shoe. Thereby, it can prevent that soil, sand, etc. permeate the inside of buffer structure 1 at the time of a game.

The buffer structure may be provided not only on the heel part of the midsole of the shoe but also on the entire surface from the heel part to the toe part.
[Application Example 2]
FIG. 10 is a side view showing an example in which the buffer structure according to the present invention is applied to a creat shoe. Here, a spike shoe for baseball is taken as an example of the creat shoe. In the figure, the same reference numerals as those in the above embodiments denote the same or corresponding parts.

As shown in FIG. 10, the spike shoe 100 ′ has a sole 105, and a spike (creet) 110 is attached to the lower surface of the forefoot portion of the sole 105. Further, the buffer structure 1 according to the present invention is provided on the lower surface of the collar portion of the sole 105. The buffer structure 1 is composed of plate-like pieces 11 and 12 in this example. The front and rear end surfaces of the plate-like pieces 11 and 12 are fixed to the lower surface of the sole 105. A creat 110 is attached to the lower convex surface of each curved shape of the plate-like pieces 11, 12.
In this case, when an impact load is applied to the heel portion at the time of landing on the shoe, the load is deformed in a direction in which the curved shapes of the plate-like portions 11 and 12 of the buffer structure 1 become flat. Can absorb and relax. Also, in this case, providing the creat increases the rigidity of the plate-like piece and increases the compression hardness, but by increasing the length between the front and rear ends of the plate-like piece, the increase in compression hardness is offset. Thus, the cushioning property can be improved. Further, in this case, the cushioning property can be increased, so that the feeling of pushing up from the creat can be reduced.

1 is a perspective view of a buffer structure according to a first embodiment of the present invention. It is the perspective view which looked at the said buffer structure (FIG. 1) from another angle. It is a side view of the said buffer structure. It is the schematic diagram which looked at the state before a deformation | transformation of a buffer structure from the side surface. It is a schematic diagram which shows collectively the state after a deformation | transformation of a buffer structure (FIG. 4A). It is a perspective view of the buffer structure by the 2nd example of the present invention. It is the perspective view which looked at the said buffer structure (FIG. 5) from another angle. It is a perspective view of a buffer structure according to a third embodiment of the present invention. It is side surface partial sectional drawing which shows the example by which the buffer structure by this invention was applied to the midsole of the shoes for sports. FIG. 9 is a schematic plan view of the midsole (FIG. 8). It is a side view which shows the example in which the buffer structure by this invention was applied to the spike shoes for baseball.

Explanation of symbols

1: Buffer structure

10: Base

11: First plate-like piece 11A: Front end surface 11B: Rear end surface 11C: Notch

12: 2nd plate-shaped piece 12A: Front end surface (extrusion part front end surface)
12B: Rear end face 12C: Notch 12D: Overhang

13: Third plate-like piece 13A: Front end surface (extrusion portion front end surface)
13B: Rear end face 13C: Notch 13D: Overhang

14: Fourth plate-like piece 14A: Front end surface (extrusion portion front end surface)
14B: Rear end face 14C: Notch 14D: Overhang

λ: Distance in the front-rear direction between the front and rear end faces of the plate-like pieces δ: Overlap amount of adjacent plate-like pieces

100: Sport shoes 102: Midsole 102a: Recess

100 ': Spike shoes for baseball 105: Sole 110: Creet

Claims (18)

A buffer structure,
It is configured by arranging at least two plate-like pieces each having a curved shape from the front end to the rear end in parallel in the front-rear direction and overlapping a part thereof,
While one adjacent plate-like piece has a notch, the other plate-like piece has a protruding portion to be inserted into the notch,
The buffer structure characterized by the above-mentioned. In claim 1,
The buffer structure further comprises a base;
The front and rear end surfaces of each plate-like piece are fixed to the surface of the base,
The buffer structure characterized by the above-mentioned. In claim 1,
The notch is formed in the center of the end face of the plate-like piece,
The buffer structure characterized by the above-mentioned. In claim 1,
The notch is formed at a corner of the end face of the plate-like piece,
The buffer structure characterized by the above-mentioned. A buffer structure,
The first, second and third plate-like pieces each having a curved shape from the front end to the rear end are arranged side by side in the front-rear direction, and a part of each of the adjacent plate-like pieces is overlapped with each other,
One plate-like piece of the adjacent first and second plate-like pieces has a notch, and the other plate-like piece has a projecting portion to be inserted into the notch, and the adjacent second piece. , One plate-like piece of the third plate-like pieces has a notch, and the other plate-like piece has an overhanging portion to be inserted into the notch,
The buffer structure characterized by the above-mentioned. In claim 5,
The second plate-shaped piece has a substantially Y-shaped or V-shaped shape,
The buffer structure characterized by the above-mentioned. In claim 5,
All of the first to third plate-like pieces have a generally Y-shaped or V-shaped shape,
The buffer structure characterized by the above-mentioned. In claim 5,
The second plate-like piece has a protruding portion at the front and rear ends thereof,
The buffer structure characterized by the above-mentioned. In claim 5,
The second plate-shaped piece has a substantially H-shaped shape having notches at the front and rear ends thereof.
The buffer structure characterized by the above-mentioned. In any one of Claim 1 thru | or 9,
When a load acts on any of the plate-like pieces, the deformation is performed independently from the deformation of the other plate-like pieces.
The buffer structure characterized by the above-mentioned. In any one of Claim 1 thru | or 9,
When any one of the plate-like pieces is deformed by a load, the size of the notch or the protruding portion is set so that the deformed plate-like piece does not interfere with another plate-like piece adjacent to the plate-like piece. , And overlap amount is set,
The buffer structure characterized by the above-mentioned. The buffer structure according to claim 1 or 5 is arranged in parallel in at least two rows in the front-rear direction, and the plate-like pieces corresponding to the left-right direction are connected to each other,
The buffer structure characterized by the above-mentioned. The buffer structure according to claim 1 or 5 is arranged in parallel in at least two rows in the front-rear direction, and the plate-like pieces corresponding to the left-right direction are separated from each other.
The buffer structure characterized by the above-mentioned. The buffer structure according to any one of claims 1 to 13 is used as a sole of sports shoes.
Sole structure of sports shoes characterized by that. The buffer structure according to any one of claims 1 to 13 is provided at least on a heel portion in a sole of a sports shoe.
Sole structure of sports shoes characterized by that. The buffer structure according to any one of claims 1 to 13 is provided on the entire surface from the heel portion to the toe portion in the sole of the sports shoe.
Sole structure of sports shoes characterized by that. In any of claims 14 to 16,
A recess is formed in the sole, and the buffer structure is provided in the recess.
Sole structure of sports shoes characterized by that. The buffer structure according to any one of claims 1 to 13 constitutes a sole of a creat shoe, and a creat is attached to a curved lower surface of the plate-like piece.
Sole structure of sports shoes characterized by that.