JP7201670B2 - Athletic prosthesis sole - Google Patents

Description

TECHNICAL FIELD The present invention relates to a sole attached to a contact area of a prosthetic leg for sports, and more particularly to a sole for a prosthetic leg for sports that suppresses slippage of the prosthetic leg during competition.

Conventionally, a prosthetic leg for competition (hereinafter referred to as a prosthetic leg for competition or simply a prosthetic leg) has a leaf spring-shaped foot portion that extends toward the toe side through the curved portion, and the contact area extends in an arc from the toe to the curved portion side. called) is known. Such a prosthetic foot for sports having a leaf spring-like foot portion is generally provided with a sole that contacts the road surface on the bottom surface of the contact area.

For example, Patent Literature 1 exemplifies a sole suitable for sports events such as jogging and running, which is attached to the lower surface of a bent leaf spring-shaped athletic prosthetic leg. That is, Patent Document 1 describes a sole having spikes attached to the lower surface of the sole that contacts the road surface, and a sole provided with a large number of outsole portions each having a hexagonal contact surface.

JP 2016-150189 A

However, in the sole exemplified in Patent Document 1, no consideration is given to preventing the prosthetic leg from slipping, that is, anti-slip properties. For example, when the race is held in the rain or the like, the race will be run on a wet road surface. At that time, if a water film exists on the road surface, the water film intervenes between the bottom surface of the sole and the road surface, and as a result of preventing the bottom surface from contacting the ground, a slip occurs. In particular, on road surfaces with a low coefficient of friction μ, such as asphalt and cobblestone, the wearer of the prosthetic leg may hesitate to accelerate further. Therefore, in order for the wearer of the prosthetic leg to fully demonstrate his running skills as an athlete, a sole having high anti-slip performance is required.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a sole for a prosthetic leg for sports with high anti-slip performance.

The inventors diligently investigated means for solving the above problems. That is, as a result of a detailed study of the grounding pattern of the prosthetic leg for sports, it was newly discovered that the prosthetic leg for sports exhibits a unique grounding pattern due to the shape of the leaf spring-like leg portion. Furthermore, the inventors have found that high anti-slip performance can be achieved by making the bottom surface of the sole correspond to the ground-contact form peculiar to the prosthetic foot for competition and separating the functions of the sole, and have completed the present invention. rice field.

The gist of the present invention is as follows.
(1) A sole of a prosthetic foot for competition, which is attached to the ground contact area of the prosthetic foot for competition, and the bottom surface is provided with a wear-resistant area having wear-resistant performance and a drainage area having drainage performance. , when defining an imaginary straight line extending parallel to the width direction of the sole at the central position in the longitudinal direction of the sole, in the front region of the bottom surface on the toe side bordering on the imaginary straight line, the area of the wear-resistant region is , the sole of the prosthetic foot for competition, wherein the area of the water drainage area is larger than the area of the water drainage area, and in the rear area of the bottom surface that is on the heel side of the imaginary straight line, the area of the water drainage area is larger than the area of the wear resistant area. .

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a sole for a prosthetic leg for sports with high anti-slip performance. By attaching this sole to a prosthetic leg for competition, there is an effect that the athlete's skill can be exhibited in any way.

1 is a side view of a prosthetic leg for competition to which a sole according to a first embodiment of the present invention is attached; FIG. FIG. 10 is a diagram for stepwise explanation of the movement of the foot portion and the contact pattern when the wearer wears the prosthetic leg for competition shown in FIG. 1 and runs straight. FIG. 10 is a diagram for stepwise explanation of the movement of the foot portion and the contact pattern when the wearer wears the prosthetic leg for competition shown in FIG. 1 and runs straight. FIG. 10 is a diagram for stepwise explanation of the movement of the foot portion and the contact pattern when the wearer wears the prosthetic leg for competition shown in FIG. 1 and runs straight. FIG. 10 is a diagram for stepwise explanation of the movement of the foot portion and the contact pattern when the wearer wears the prosthetic leg for competition shown in FIG. 1 and runs straight. It is a figure for demonstrating each area|region of a bottom face. FIG. 4 is a diagram showing the pattern of the bottom surface of the sole of the prosthetic leg for competition according to the first embodiment; FIG. 10 is a diagram showing the pattern of the bottom surface of the sole of the prosthetic leg for competition according to the second embodiment; FIG. 10 is a diagram showing the pattern of the bottom surface of the sole of the prosthetic leg for competition according to the third embodiment; FIG. 4 is a diagram schematically showing pattern elements that constitute a pattern of unevenness; FIG. 4 is a diagram schematically showing pattern elements that constitute a pattern of unevenness; FIG. 10 is a view showing the bottom surface of the sole provided with a pattern of concavities and convexities; It is a schematic cross-sectional view along the width direction of the foot portion of the sole. It is a schematic cross-sectional view along the width direction of the foot portion of the sole. It is a schematic cross-sectional view along the width direction of the foot portion of the sole. It is a perspective view which shows a ground contact part and a sole. It is a perspective view which shows a ground contact part and a sole. FIG. 4 is a perspective view showing a sole and an attachment margin before being attached to a grounding portion; It is a figure for demonstrating the thickness of the boundary vicinity of a tiptoe side sticking allowance part and a sole. It is a figure for demonstrating the thickness of the boundary vicinity of a bending part side sticking margin part and a sole. FIG. 4 is a diagram showing the bottom surface of the sole divided from a viewpoint different from that of FIG. 3 ; FIG. 14 is a diagram showing an example of the bottom surface of the sole in which patterns are arranged in accordance with the arrangement of the functional regions shown in FIG. 13; FIG. 14 shows a bottom pattern similar to FIG. 4, sectioned according to the sectioning of FIG. 13;

Hereinafter, the sole of the prosthetic leg for sports of the present invention (hereinafter also referred to as sole) will be described in detail by exemplifying embodiments thereof with reference to the drawings.

FIG. 1 is a side view of a prosthetic leg 1 for competition with a sole 5 according to the first embodiment of the present invention. A prosthetic leg 1 for competition has a leaf spring-like foot portion 2, and a sole 5 is attached to a contact area on the tip side thereof. Although not shown, the proximal end of the leg 2 is connected to a socket via an adapter, and the socket accommodates the stump of the wearer's leg, whereby the wearer wears the prosthetic leg. be able to. Adapters and sockets are used according to the position of the stump of the leg, such as a thigh prosthesis and a lower leg prosthesis. FIG. 1 shows the foot 2 and the sole 5 of the wearer of the athletic prosthesis 1 in an upright position.

Hereinafter, in the present embodiment, in the height direction of the prosthetic leg for competition, the side where the leg 2 is connected to the adapter is called the connection side, and the side that contacts the road surface S is called the ground side. Also, the toe T of the prosthetic leg 1 for competition refers to the foremost point where the leg 2 extends from the connection side and terminates. Further, the direction extending parallel to the road surface S from the toe T is referred to as the foot front-rear direction Y (the same direction as the sole front-rear direction Z when standing upright). Further, the width direction of the foot portion 2 is referred to as the width direction W (also referred to as the sole width direction W).

In this embodiment, the foot portion 2 of the prosthetic leg 1 for competition has a shape extending in a plate shape toward the toe T side via at least one curved portion, one curved portion 3 in the illustrated example. In FIG. 1, the leg portion 2 includes, in order from the connection side to the ground side, a straight portion 2a, a curved portion 2b that is convex toward the toe T side, a curved portion 3 that is convex to the rear side in the foot longitudinal direction Y, and a concave portion toward the ground side. and a ground contact portion 4 extending toward the toe T side in an arc which is convex toward the ground contact side.

Although the material of the leg portion 2 is not limited, it is preferable to use carbon fiber reinforced plastic or the like from the viewpoint of strength and weight reduction.

The grounding portion 4 has a grounding area 4s extending in an arc from the toe T toward the curved portion 3, and the sole 5 is attached to the grounding area 4s. The contact area 4s refers to the entire area in contact with the road surface S when the wearer wearing the prosthesis for competition 1 runs straight. contact with the road surface S via.

The sole 5 has a shape that follows the extending shape of the contact area 4s. Further, the ground side of the sole 5 is the bottom surface 5s. As shown in FIG. 1, the bottom surface 5s has a shape in which arcs X1 and X2 extend from the toe T side to the curved portion 3 side. In this embodiment, the arc X1 and the arc X2 have mutually different radii of curvature, but they may have the same radii of curvature.

In addition, the bottom surface 5s is on one side bounded by a line extending in the width direction W through a point C, which is a point of contact with the road surface S in a side view of the wearer in an upright state, on which the athletic prosthesis 1 is worn. On the other side, it has different performance. Point C is the point that first comes into contact with the road surface S when the vehicle reaches the upright position in a side view. In other words, the upright state means that the wearer, if only one leg is prosthetic, has a healthy leg that does not wear the prosthesis, and if both legs are prosthetic legs, the wearer supports the body with one prosthesis, and then puts the prosthetic leg 1 on the ground S. It refers to the state in which the vehicle comes into contact with the road surface S for the first time. Note that the point C is determined by the shape of the prosthetic leg, the manner in which it is worn, and the like. That is, the inventors determined that the boundary of the bottom surface 5s for separating the function of the bottom surface 5s based on the knowledge about the contact form obtained from the experiment described later is the point C, which is the point of contact with the road surface S when the wearer is standing upright. I came up with a new idea that is the standard.

Experimental results of the grounding configuration of the bottom surface 5s will be described below with reference to FIGS. 2A, 2B, 2C and 2D. Figures 2A, 2B, 2C, and 2D show, step by step, the movement of the foot portion 2 and the ground contact form of the bottom surface 5s when the wearer wearing the athletic prosthesis 1 having the above configuration runs straight. FIG. 3 is a diagram for explaining. The upper part of each drawing is a side view of the foot part 2 and the sole 5, and the lower part of each drawing is a transition of the ground contact form of the bottom surface 5s when the wearer wearing the prosthetic leg 1 for competition runs straight. is shown.

That is, FIG. 2A shows a state in which the wearer lowers the prosthesis for competition 1 lifted up onto the road surface S, and the whole weight is applied to the prosthesis for competition 1 . As shown in the lower part of the drawing, the area of the bottom surface 5s on the curved portion 3 side from the point C is grounded.

FIG. 2B shows a state in which the wearer steps forward from the state of FIG. 2A while the entire weight is applied to the athletic prosthesis 1. FIG. In the case of running by an able-bodied person, it is common to step on the ground in order from the heel side of the shoe sole that touches the ground first toward the toe side, but the prosthetic leg 1 for competition is curved more than the point where it first touches the ground. The contact area has moved to the part 3 side.

FIG. 2C shows a state in which the wearer swings forward the leg opposite to the side on which the prosthesis for competition 1 is worn, and starts the kicking motion of the prosthesis for competition 1 . When this kicking motion is started, the prosthetic leg for competition 1 touches the ground in a region on the toe T side of the point C of the bottom surface 5s.

FIG. 2D shows the state just before leaving the road surface S in the final stage when the wearer kicks the prosthetic leg 1 for competition. In order to kick out from the toe T of the bottom surface 5s, the toe T side is further grounded than in FIG. 2C.

Based on the experimental results shown in FIGS. 2A, 2B, 2C, and 2D, first, the bottom surface 5s is divided into the curved portion side region Q1 and the toe side region Q2 with the point C as a boundary, as shown in FIG. split. In addition, FIG. 3 shows the bottom surface 5s of the prosthesis for competition 1 in a flat state not along the contact area 4s.

That is, the bending portion side region Q1 is a region on the bending portion 3 side bounded by a line BL passing through the point C and extending in the width direction W of the foot portion 2 (sole width direction W) on the bottom surface 5s. As shown in FIGS. 2A and 2B, the bending portion side region Q1 is the region where the wearer first lands and performs a stepping motion with the entire weight of the prosthesis for competition 1 applied. Therefore, it is important that the curved portion side region Q1 sufficiently grips the road surface S so that the wearer can maintain the balance of the entire body even if the wearer puts the entire weight on the prosthetic leg 1 for competition. Therefore, in order to prevent slippage due to the water film interposed between the bottom surface 5s and the road surface S, the curved portion side region Q1 needs to have drainage performance higher than that of the toe side region Q2 other than the curved portion side region Q1. .
That is, the curved portion side region Q1 has a higher drainage performance than the regions other than the curved portion side region Q1, so that the sole 5 of the prosthetic leg 1 for competition prevents slipping due to the water film and achieves high anti-slip performance.

On the other hand, the toe side region Q2 is a region on the side of the toe T bounded by a line BL passing through the point C and extending in the width direction W of the foot portion 2 (sole width direction W) on the bottom surface 5s. The toe side region Q2 is a region for the wearer to swing forward the leg opposite to the side on which the prosthetic leg for competition 1 is worn, and perform a kicking motion of the prosthetic leg for competition 1. As shown in FIG. The toe-side region Q2 is a region where wear is particularly likely to progress because the wearer contacts the ground in order toward the toe T, and the wearer presses and slides the road surface S with the bottom surface 5s. Therefore, the toe side region Q2 needs to have higher wear resistance performance than the curved portion side region Q1.
That is, since the toe-side region Q2 has higher wear resistance than the curved portion-side region Q1, early wear of the toe-side region Q2 is avoided, and as a result, the entire surface of the sole 5 of the prosthetic leg 1 for competition wears gently. As a result, the service life of the sole 5 can be extended.

In addition, each of the bending portion side region Q1 and the toe side region Q2 is further divided as shown in FIG. 3 based on the grounding configuration shown in FIGS. is preferably provided.

That is, the portion Q2-1 of the toe-side region Q2 shown in FIG. 3 corresponds to the arc X1 continuing from the toe T in FIG. 1 with a constant radius of curvature. This portion Q2-1 tends to be the last to touch the ground when the wearer of the athletic prosthesis 1 performs a kicking motion, resulting in greater wear. Therefore, the portion Q2-1 must have particularly high wear resistance performance. That is, in the toe side region Q2, the portion Q2-1 has a higher abrasion resistance performance than the remaining portion Q2-2, thereby protecting the sole 5 from severe abrasion and prolonging the service life of the foot portion 2 itself. can do.

Next, in the bending portion side region Q1, the portion Q1-1 on the side of the toe T from the center M1 of the maximum length L1 along the foot front-rear direction Y is the region where the wearer first lands. In order to balance , it is especially necessary to prevent slippage. Therefore, it is preferable to prevent slippage more reliably and realize more stable running by providing a higher drainage performance than the other portion Q1-2 of the curved portion side region Q1.

Also, the portion Q1-2 is a portion closer to the bending portion 3 than the center M1 of the maximum length L1. In the bending portion side region Q1, as shown in FIG. 2B, the grounding portion is located on the bending portion 3 side of the portion Q1-1 that first touches the ground, that is, the portion Q1-2 on the side opposite to the direction in which the wearer advances. is changing. When the part Q1-2 touches the ground, the movement of the wearer's upper body trying to move forward and the movement of the ground contact part are temporarily reversed, and the high Propulsion is required. Therefore, first, it is essential that the portion Q1-2 has higher rigidity than the portion Q1-1. By providing the portion Q1-2 with higher rigidity than the portion Q1-1, it is possible to smoothly connect the stepping motion to the kicking motion, thereby achieving a high propulsive force.

In particular, when the bottom surface 5s has a pattern of a plurality of irregularities, it is preferable that the edge component in the width direction W of the leg 2 is larger in the portion Q1-2 than in the portion Q1-1. Also, the negative ratio of the portion Q1-2 is preferably smaller than that of the portion Q1-1. Here, the negative ratio refers to the ratio of the area of the concave portion with respect to the road surface S in plan view to the total area of the bottom surface 5s in plan view. With the above configuration, a high propulsive force can be exhibited during running.

Further, in order to effectively exert the driving force, it is preferable that the portion Q1-2 has a larger edge component in the width direction W of the foot portion 2 than the toe side region Q2. Furthermore, it is preferable that the portion Q1-2 has a higher negative ratio than the toe-side region Q2. According to the above configuration, the portion Q1-2 can exhibit a high propulsive force when the wearer performs a kicking motion.

Concrete means for realizing the above-described characteristics provided to each portion of the bottom surface 5s include, for example, devising a pattern consisting of unevenness by grooves formed in the bottom surface 5s, and the surface of the bottom surface 5s. There are devising properties, devising the cross-sectional shape of the sole 5, devising the material of the sole 5, and the like.

First, a first embodiment and a second embodiment will be described below in which each function is imparted by devising a pattern of unevenness on the bottom surface 5s. FIG. 4 is a diagram showing the pattern of the bottom surface 5s of the sole 5 of the prosthetic leg 1 for competition according to this embodiment.

In the pattern shown in FIG. 4 , a plurality of land portions 10 and land portions 11 partitioned by a plurality of grooves extending in the width direction W are arranged in the bending portion side region Q1. The land portion 10 is arranged closer to the toe T than the land portion 11 is. The land portion 10 includes a widthwise extending portion 10a extending in a substantially zigzag shape in the widthwise direction W, and a toe extending from the bent portion of the widthwise extending portion 10a in a convex direction toward the toe T side. The shape includes a side protruding portion 10b and a curved portion side protruding portion 10c extending toward the curved portion 3 from the curved portion of the width direction extending portion 10a that is bent in a convex direction toward the curved portion 3 side. The land portion 11 has a shape including a widthwise extending portion 11a, a toe-side projecting portion 11b, and a curved portion-side projecting portion 11c. By forming the widthwise extending portions 10a and 11a into a zigzag shape, it is possible to sufficiently secure edge components. Further, by forming the toe-side protrusions 10b and 11b and the curved-portion-side protrusions 10c and 11c, the edge component is further increased, and the bottom surface 5s and the road surface S are effectively connected on both sides in the foot front-rear direction Y. It is possible to cut the water film existing between them, and it is possible to realize high drainage performance.

4, a plurality of land portions 12 partitioned by a plurality of grooves extending in the width direction W are arranged in the toe side region Q2. The land portion 12 includes a widthwise extending portion 12a that extends in a substantially zigzag shape in the width direction W and a bent portion that is bent in a convex direction toward the toe T side. The widthwise extending portion 12a extends from the toe T-side protruding portion 12b extending so as to be convex in the direction inclined with respect to the front-rear direction Y) and the bent portion bent in the convex direction on the bending portion 3 side. and a bending portion-side protruding portion 12c that protrudes in the existing direction. Furthermore, along the zigzag shape extending in the width direction W, a plurality of linear grooves 13 intermittently extending are formed in the toe side region Q2. The land portion 12 is arranged closer to the curved portion 3 than the straight groove 13 , and the straight groove 13 is formed closer to the toe T than the land portion 12 . In addition, as shown in the figure, a land portion 14 having the same shape as the land portion 11 may be formed in the toe side region Q2.

In FIG. 4 , the land portion width w3 of the widthwise extending portion 11a of the land portion 11 is larger than the land portion width w2 of the widthwise extending portion 10a of the land portion 10 . Moreover, the land portion width w4 of the width direction extending portion 12a of the land portion 12 is larger than the land portion widths w2 and w3.

In the above configuration, in the curved portion side region Q1, the ratio of the area in plan view of the groove portion that is concave with respect to the road surface S to the total area in plan view of the bottom surface 5s, that is, the negative ratio is the toe side region. Larger than Q2. Therefore, in the curved portion side region Q1, it is possible to take in and discharge more moisture into the recessed grooves. Therefore, the curved portion side region Q1 has a higher drainage performance than the toe side region Q2.

On the other hand, the toe side region Q2 has higher wear resistance performance than the curved portion side region Q1. This is because the toe side region Q2 has a smaller negative ratio than the bending portion side region Q1 and maintains high rigidity.

A linear groove 13 is formed in the portion Q2-1 of the toe side region Q2. According to this configuration, the ground-contact portion Q2-1 has greater rigidity than the remaining portion Q2-2 of the toe-side region Q2, and has even higher wear resistance.

Also, in FIG. 4, in the bending portion side region Q1, the negative ratio of the portion Q1-1 is higher than that of the portion Q1-2, and more water can be taken into the groove and discharged. That is, the portion Q1-1 has higher drainage performance than the portion Q1-2.

Further, in the bending portion side region Q1, the land portion 11 is arranged in the portion Q1-2, and as described above, the land portion width w3 of the land portion 11 is larger than the land portion width w2 of the land portion 10. . Therefore, the portion Q1-2 has greater land rigidity than the portion Q1-1. Furthermore, the portion Q1-2 has a larger edge component in the width direction W than Q1-1. Also, as described above, the negative ratio of the portion Q1-2 is smaller than that of the portion Q1-1.

Further, the portion Q1-2 has a larger edge component in the width direction W than the toe side region Q2, and the negative ratio is also larger.

Next, referring to FIG. 5, the sole of the prosthetic leg for competition according to the second embodiment of the present invention will be described. The sole of the athletic prosthesis according to the second embodiment has the same characteristics as those of the first embodiment in the properties of each portion of the bottom surface of the sole.
A plurality of land portions 100, 110, 120 and 140 partitioned by a plurality of grooves extending in the width direction W are arranged on the bottom surface 50s of the sole 5 shown in FIG. Land portions 100, 110, 120 and 140 correspond to land portions 10, 11, 12 and 14 shown in FIG. When viewed from above, the bottom surface 50s of the sole 5 has a shape similar to that of the corresponding land portions. It has a stepped structure. The two-stage structure will be described with reference to land portion 120 . The land portion 120 has a stepped structure in which a second step block 120B is placed on a first step block 120A on the groove bottom side in the thickness direction of the sole 5 . The staircase portion of the first block 120A is indicated by a thick line in the drawing. The second-stage block 120B has a smaller surface area than the first-stage block 120A in plan view, but the second-stage block 120B and the first-stage block 120A have the same shape. When the wearer wearing the competition prosthesis 1 runs straight ahead, if the second block 120B first hits the ground and collapses, water intervening between the first block 120A and the road surface S will flow into the road surface S. It pushes out to the side and can drain moisture efficiently. Furthermore, the grounding of the first-stage block 120A after the second-stage block 120B makes it possible to secure a sufficient contact area with the road surface S without impairing the drainage performance. The land portions 100, 110 and 140 also have a stepped structure, including stepped portions indicated by thick lines.

Next, referring to FIG. 6, the sole of a prosthetic leg for competition according to a third embodiment of the present invention will be described. The bottom surface 500s of the sole 5 of the prosthetic leg for competition according to the third embodiment has a square shape with rounded corners in a plan view by forming concave grooves in the bottom surface 500s in the bending portion side region Q1. , a plurality of land portions 15 are partitioned. Land portions 16 a and 16 b are arranged on the bending portion 3 side of the land portion 15 in the bending portion side region Q<b>1 . The land portions 16a and 16b have a square shape with rounded corners in plan view by forming concave grooves in the bottom surface 500s, and have a larger area than the land portion 15 in plan view. In addition, the land portion 16b has a larger area in plan view than the land portion 16a. Land portions 17a and 17b having the same shape as the land portions 16a and 16b are also defined in the toe side region Q2. Further, in the toe-side region Q2, a land portion 18a having a rectangular shape with rounded corners in a plan view is formed on the side of the toe T relative to the land portions 17a and 17b, and is closer to the toe T than the land portion 18a. Secondly, the half land portion 18b is defined in such a manner that the depth of the groove gradually decreases toward the toe T side. Further, a plurality of linear grooves 19a and 19b inclined with respect to the width direction W are arranged on the toe T side of the half land portion 18b. In FIG. 6, a plurality of linear grooves 19a and 19b are alternately arranged along the width direction W. As shown in FIG. Further, in FIG. 6, a plurality of linear grooves 19a and 19b are alternately arranged along the foot front-rear direction Y. As shown in FIG. The straight grooves 19a and the straight grooves 19b are inclined in opposite directions with respect to the width direction W. As shown in FIG.

The bending portion side region Q1 and the toe side region Q2 shown in FIG. 6 have the same functions as the bending portion side region Q1 and the toe side region Q2 in the sole of the prosthetic foot for competition according to Embodiments 1 and 2. can be given.

In the case where each function is imparted by a pattern of unevenness on the bottom surface 5s, the pattern shown below is not limited to the pattern of the above embodiment. Each pattern will be described with reference to FIGS. 7, 8 and 9. FIG. Note that FIGS. 7 and 8 schematically show pattern elements forming a pattern of unevenness. By changing the numbers and specifications of these elements for each of the regions and portions described above, it is possible to provide the functions required for each region and each portion.

For example, as shown in FIG. 7, a pattern in which a plurality of vertical grooves 30 extending along the foot front-rear direction Y are formed can be used. According to the above configuration, the water taken into the vertical grooves 30 flows with the movement of the sole, and the water can be efficiently discharged from the ends of the vertical grooves 30 . By varying the width and depth of the longitudinal grooves 30 for each portion of the bottom surface 5s, it is possible to impart a pattern that prioritizes either drainage performance or wear resistance performance.

Moreover, as shown in FIG. 8, a pattern in which a plurality of annular continuous grooves 31 and 32 are formed can also be used. The annular grooves 31 and 32 enable efficient intake and discharge of moisture regardless of various directions of input acting on the bottom surface 5 s of the sole 5 . By varying the width and depth of the annular grooves 31 and 32 or the ring diameter for each portion of the bottom surface 5s, it is possible to impart a pattern that prioritizes either drainage performance or wear resistance.

The bottom surface 5s may have a pattern in which only the vertical grooves or only the circular grooves are formed, or may have a pattern in which the vertical grooves and the circular grooves are combined. Furthermore, the pattern may be a combination of annular grooves and lateral grooves.

Furthermore, the pattern shown in FIG. 9 can also be used as the bottom pattern. In this pattern, a plurality of vertical grooves 33 with openings at one end or both ends are formed on the bottom surface 5000s of the sole 5, on the sole edge on the toe T side and the curved portion 3 side, and communicate with the vertical grooves 33 in the width direction. A plurality of oblique grooves 34, 35, 36 and 37 extending obliquely to W and opening at the sole edge are formed. As illustrated, the inclined grooves 34 and 35 extend from the center of the bottom surface 5000s in the width direction W toward the edge of the sole in the bending portion side region Q1 while being inclined toward the bending portion 3 side. On the other hand, in the toe side region Q2, the inclined grooves 36 and 37 extend from the widthwise center of the bottom surface 5000s toward the sole edge while being inclined toward the toe T side. According to the above configuration, it is possible to realize the drainage performance according to the contact form of the prosthetic leg 1 for competition. That is, the bottom surface 5000s changes its grounding portion from the first grounding portion Q1-1 to a portion Q1-2 closer to the curved portion 3 side. Along with the transition operation, the water taken into the groove flows along the slope of the groove from the side of the toe T to the side of the curved portion 3, and is discharged from the opening of the edge of the bottom surface 5000s. Furthermore, as the ground contact portion changes from the curved portion side region Q1 to the toe side region Q2, the moisture taken into the groove flows along the slope of the groove from the curved portion 3 side to the toe side T side, and the sole 5 is discharged from the opening at the edge of the Efficient drainage can be realized by the above action. As shown in FIG. 9, the groove width is increased in areas where priority is given to drainage performance, and the groove width is decreased in areas where priority is given to wear resistance performance.

In any of the examples described so far, the depth and number of grooves formed on the bottom surface of the sole 5 are arbitrary. By increasing the groove depth, drainage performance can be further improved. Furthermore, increasing the number of grooves can also improve drainage performance.

In addition, by improving the drainage performance of the entire sole 5 with the pattern described so far, by devising the surface properties of the bottom surface, such as changing the introduction density of sipes, surface roughness, riblets, etc. shown below. It is also possible to control wear performance and drainage performance on a region-by-zone and part-by-part basis.

For example, by forming a plurality of sipes thinner than the grooves on the bottom surface of the sole 5, drainage performance can be improved. Higher drainage performance can be obtained by increasing the number of sipes. For wear resistance performance, this relationship should be reversed. This is the same for the surface roughness and riblets below.

By providing the bottom surface of the sole 5 with microscopic unevenness, the surface roughness can be adjusted, and the drainage performance and wear resistance performance can be enhanced. When the surface roughness is made to be rougher, it is possible to take in water between the microscopic irregularities, and it is possible to realize high drainage performance.

In addition, by providing so-called riblets in which fine grooves are continuously arranged in the width direction W or the foot front-rear direction Y, moisture intervening between the road surface S and the bottom surface of the sole 5 is gradually released by capillarity. It can penetrate into each fine groove of and achieve higher drainage performance.

Furthermore, by applying a water-repellent finish to the bottom surface of the sole 5, the water adhering to the bottom surface can be efficiently removed, and the drainage performance can be improved.

Next, a case where each function is imparted by devising the cross-sectional shape of the sole 5 will be described. 10A, 10B and 10C are schematic cross-sectional views along the width direction W of the sole 5. FIG.

10A and 10B, the thickness of the sole 5 is the thickest at the center in the width direction W and gradually decreases toward the edge side of the sole in the width direction W. In FIGS. The sole 5 may have a shape in which the thickness gradually decreases linearly, as shown in FIG. 10A, or may have a shape in which the thickness gradually decreases in an arc, as shown in FIG. 10B. According to the above configuration, when the bottom surface of the sole 5 (the lower surface of FIGS. 10A and 10B ) touches the ground, water on the road surface S is pushed out from the center side in the width direction W of the sole 5 toward the edge side of the sole. can be properly drained. The entire sole 5 may have the above configuration, or only a portion of the sole 5 may have the above configuration.

Further, as shown in FIG. 10C, the sole 5 may have a structure having a plurality of cones that are convex toward the ground. In the illustrated example, the sole 5 has a plurality of quadrangular pyramids 40 projecting toward the ground. According to the above configuration, the plurality of square pyramids 40 form a spike-like bottom surface of the sole 5, effectively cutting the water film existing between the bottom surface 5s and the road surface S and grounding from the top, resulting in high drainage. performance can be achieved. Moreover, since water can pass through the gaps formed between the plurality of square pyramids 40, high drainage performance can be achieved. In addition, it is not limited to a quadrangular pyramid, and may be a cone or a polygonal pyramid other than a quadrangular pyramid. Further, by varying the size of the cone corresponding to each region of the bottom surface of the sole 5, it is possible to achieve wear resistance.

11A and 11B are perspective views showing the contact portion 4 and the sole 5. FIG. As shown in FIG. 11A, the sole 5 has a hidden groove 41 that opens toward the ground contact portion 4 on the side of the interface between the ground contact portion 4 and the sole 5 . The hidden grooves 41 extend along the width direction W and open at both edges of the sole 5 . According to the above configuration, since moisture on the road surface is taken into the hidden grooves 41 from both ends in the width direction W of the foot portion 2 and discharged, the intrusion of moisture between the bottom surface 5s and the road surface S is prevented. , high drainage performance can be obtained. Although not shown in FIG. 11A, when an adhesive is interposed between the grounding portion 4 and the sole 5, the sole 5 opens on the side of the interface with the adhesive. A groove or recess is formed.

Also, as shown in FIG. 11B, the sole 5 may have a composite groove in which a circular groove 42 formed in the bottom surface 5s and a groove 43 penetrating the sole 5 along the width direction W communicate with each other. . According to the above configuration, moisture present between the bottom surface 5s and the road surface S can be taken in through the circular grooves 42 and discharged efficiently from the ends of the grooves 43 penetrating in the width direction W. Further, by combining such a composite groove with the uneven grooves of the bottom surface 5s, it is possible to adjust the rigidity of the sole 5 and impart characteristics corresponding to each region of the bottom surface 5s.

Next, a case where each function is imparted by devising a part or all of the material of the sole 5 will be described. For example, part or all of the sole 5 may be made of felt, sponge, non-woven fabric, or the like, so that the drainage performance can be enhanced by the water absorbing action of each material. A similar effect can also be obtained by using foamed rubber for part or all of the sole 5 and by the water-absorbing action of the foamed rubber.

The sole 5 of the athletic prosthesis 1 of the present invention described so far is manufactured by, for example, a method of processing a rubber sheet with a laser beam, a method of using a mold, or a method of manufacturing using a 3D printer. be able to.

In addition, in the prosthetic leg for competition 1 of the present invention, the sole 5 is attached to the contact area 4s via an adhesive, but the attaching means is not limited to the adhesive, and is attached using a fastener such as a belt. good too. Furthermore, in the present embodiment, the sole 5 is worn in direct contact with the contact area 4s, but a cushioning material (not shown) or an adhesive may be interposed between the sole 5 and the contact area 4s. .

An example of mounting means for the sole 5 will now be described with reference to FIGS. 12A, 12B and 12C. FIG. 12A is a perspective view showing the sole 5 and the attachment margin before being attached to the ground contact portion 4. FIG. Note that the pattern of the bottom surface 5s is omitted in FIG. 12A. As shown in the figure, the toe-side sticking margin portion 6 and the curved portion-side sticking margin portion 7 are integrally connected to the sole 5 . The toe-side attachment margin 6 is joined along the edge of the sole 5 on the side of the toe T, has a fan-like shape, and is divided by two cuts 8a and 8b. Further, the curved portion side sticking margin portion 7 is joined to the edge of the sole 5 on the curved portion 3 side. FIG. 12B is a diagram for explaining the thickness in the vicinity including the boundary between the toe-side attachment allowance portion 6 and the sole 5. FIG. Also, FIG. 12C is a diagram for explaining the thickness in the vicinity including the boundary between the bending portion-side sticking allowance portion 7 and the sole 5 . As shown in FIG. 12B, the toe-side attachment allowance portion 6 extends with a constant thickness th2 that is thinner than the thickness th1 of the sole 5, and the thickness gradually increases toward the boundary B1 with the sole 5. ing. Further, the curved portion side sticking allowance portion 7 extends with a thickness th3 that is thinner than the thickness th1 of the sole 5, and the thickness gradually increases toward the boundary B2 with the sole 5. As shown in FIG. According to the above configuration, when the sole 5 is attached to the ground contact portion 4, the sole 5 and the ground contact portion 4 can be attached in close contact with each other without bending or forming a gap. For example, when the thickness th1 of the sole 5 is 2.25 to 3.0 mm, the thickness th2 of the toe side sticking margin 6 and the thickness th3 of the curved side sticking margin 7 are 1.5 to 2.0 mm. be able to.

Next, the relationship between the areas of the functional regions on the bottom surface 5s of the sole 5 will be described. FIG. 13 is a diagram showing the bottom surface 5s of the sole 5 divided from a viewpoint different from that of FIG.

As shown in FIG. 13, on the bottom surface 5s of the sole 5, the toe T (see FIG. 1) side of the sole front-rear direction Z (the same direction as the foot front-rear direction Y when standing upright) with the virtual straight line VL as a boundary. A front region P1 and a rear region P2 on the heel side in the longitudinal direction Z of the sole are provided. A "virtual straight line VL" shown in FIG. 13 is a virtual straight line that extends parallel to the sole width direction W (the same direction as the width direction W in FIG. 3) at the central position in the sole front-rear direction Z. As shown in FIG.

The front region P1 is a region that is more likely to wear during a kicking motion than the rear region P2, as described with reference to FIGS. 2A-2D. Conversely, the rear region P2 is a region that is more likely to slip during a stepping motion than the front region P1, as described with reference to FIGS. 2A to 2D. The inventor of the present invention focused on the difference in the functions of the front region P1 and the rear region P2, and as a result of repeated studies, determined that each functional region arranged in the front region P1 and the rear region P2 is arranged in a specific area relationship and arrangement. By doing so, it has been found that the wear resistance performance and drainage performance of the bottom surface 5s can be improved. The area relationship and arrangement of the functional regions will be described in detail below.

As shown in FIG. 13, the bottom surface 5s of the sole 5 is provided with a wear-resistant area R1 and a drainage area R2.

The wear-resistant region R1 is a region having wear-resistant performance. The drainage region R2 is a region having drainage performance. The wear-resistant region R1 is a region having higher wear-resistant performance than other functional regions, and at least a region having higher wear-resistant performance than the drainage region R2. Also, the drainage region R2 is a region having a higher drainage performance than the other functional regions, and at least a region having a higher drainage performance than the wear-resistant region R1.

The wear resistance performance can be set, for example, by the negative ratio of the uneven pattern formed on the bottom surface 5s. When the wear resistance performance is set by the negative ratio of the pattern, the wear resistance performance of the wear resistance region R1 can be ensured by setting the negative ratio of the wear resistance region R1 to a predetermined value or less. Further, by making the negative ratio of the wear-resistant region R1 smaller than the negative ratio of the drainage region R2, the wear-resistant performance of the wear-resistant region R1 can be made higher than the wear-resistant performance of the drainage region R2.

Also, the wear resistance performance may be set according to, for example, the difference in the amount of material. When the wear resistance performance is set according to the difference in material, the wear resistance performance of the wear resistance region R1 can be ensured by forming the wear resistance region R1 with a material having excellent wear resistance performance. Further, by forming the wear-resistant region R1 from a material having better wear-resistant performance than the drainage region R2, the wear-resistant performance of the wear-resistant region R1 can be made higher than the wear-resistant performance of the drainage region R2. can.

The drainage performance can be set, for example, by the negative ratio of the uneven pattern formed on the bottom surface 5s. When the drainage performance is set by the negative ratio of the pattern, the drainage performance of the drainage region R2 can be ensured by setting the negative ratio of the drainage region R2 to a predetermined value or more. Further, by making the negative ratio of the drainage region R2 larger than the negative ratio of the wear-resistant region R1, the drainage performance of the drainage region R2 can be made higher than the drainage performance of the wear-resistant region R1.

The method of forming the wear-resistant region R1 and the drainage region R2 is not limited to the use of the negative ratio or the like of the uneven pattern formed on the bottom surface 5s as described above. However, by setting the negative ratio, the magnitude relationship of the wear resistance performance and the magnitude relationship of the drainage performance of the wear resistance region R1 and the drainage region R2 can be simultaneously set to the above-described desired relationship, so the negative ratio can be set. It is preferable to set wear resistance performance and drainage performance by using.

Here, in the front area P1 on the toe T side (see FIG. 1) of the bottom surface 5s with respect to the imaginary straight line VL, the area of the wear-resistant area R1 is made larger than the area of the drainage area R2. Further, in the rear area P2 on the heel side of the bottom surface 5s bordering on the imaginary straight line VL (same as the curved portion 3 side in the athletic prosthesis 1 shown in FIG. 1), the area of the drainage area R2 is the area of the wear resistant area R1. Make it larger than the area.

By setting the area of the wear-resistant region R1 and the area of the drainage region R2 on the bottom surface 5s of the sole 5 to the above relationship, the drainage performance is improved in the rear region P2 where the wearer's entire weight is applied during stepping. Therefore, it is possible to suppress a slip caused by a water film interposed between the bottom surface 5s and the road surface S (see FIG. 1). As a result, the gripping force between the rear region P2 and the road surface S during the stepping operation can be enhanced. That is, it is possible to realize the sole 5 having high anti-slip performance during running. In addition, since wear resistance performance can be enhanced in the front region P1 where the wearer presses and slides the road surface S with the bottom surface 5s when kicking out, early wear of the front region P1 can be avoided. can be done. That is, it is possible to extend the service life of the sole 5 .

In the example shown in FIG. 13, the front region P1 has a plurality of wear-resistant regions R1 occupying a certain area. Therefore, the area of the wear-resistant region R1 in the front region P1 is represented by the total area of the areas of the plurality of wear-resistant regions R1. The same applies to the case where there are a plurality of drainage areas R2 occupying a certain area in the front area P1. The area of the drainage region R2 in the front region P1 is represented by the total area of the areas of each of these plurality of drainage regions R2. Furthermore, the area of the wear-resistant region R1 and the area of the drainage region R2 in the rear region P2 are also expressed in the same manner as the area of the wear-resistant region R1 and the area of the drainage region R2 in the front region P1. be.

FIG. 14 shows an example of arranging a pattern of unevenness forming the wear-resistant region R1 and a pattern of unevenness forming the drainage region R2 in accordance with the arrangement of the functional regions shown in FIG. In this way, by arranging the patterns corresponding to the respective functional areas, it is possible to realize the sole 5 having high anti-slip performance during running. Also, the service life of the sole 5 can be lengthened.

FIG. 15 is a diagram showing the pattern of the bottom surface 5s similar to FIG. In the example shown in FIG. 15, the area in which the straight groove 13 is formed (see frame "I" of the two-dot chain line in FIG. 15) and the area in which the land portion 12 is formed (the two-dot chain line in FIG. (see frame "II") corresponds to the wear-resistant region R1. In addition, in the example shown in FIG. 15, the region where the land portion 10 is formed (see the double-dotted chain line frame “III” in FIG. 15) corresponds to the drainage region R2. Furthermore, in the example shown in FIG. 15, the area where the land portions 11 and 14 are formed (see the two-dot chain line frame "IV" in FIG. 15) does not correspond to the wear-resistant area R1, but to the drainage area R2. is also not applicable. Although the details will be described later, the region where the land portions 11 and 14 are formed corresponds to the propulsion region R3 having propulsion performance.

As shown in FIG. 15, in the front region P1 on the toe T side (see FIG. 1) of the bottom surface 5s with respect to the imaginary straight line VL, the area of the wear-resistant region R1 is larger than the area of the drainage region R2. More specifically, the drainage region R2 does not exist in the front region P1 shown in FIG. That is, the front region P1 shown in FIG. 15 is composed of a wear-resistant region R1 and a propulsion region R3, which will be described later.

Further, as shown in FIG. 15, in the rear area P2 on the heel side of the bottom surface 5s bordering on the imaginary straight line VL (same as the curved portion 3 side in the athletic prosthesis 1 shown in FIG. 1), the area of the drainage area R2 is is larger than the area of the wear-resistant region R1. More specifically, the wear resistant region R1 does not exist in the rear region P2 shown in FIG. That is, the rear region P2 shown in FIG. 15 is composed of a drainage region R2 and a propulsion region R3, which will be described later.

Further, in the bottom surface 5s shown in FIG. 15, the wear-resistant region R1 is arranged only on the side of the toe T (see FIG. 1) with respect to the drainage region R2.

More specifically, in the bottom surface 5s shown in FIG. 15, a linear groove 13 is formed as the wear-resistant region R1 from the toe T (see FIG. 1) side toward the heel side, and A region where the land portion 12 is formed, a region where the land portion 14 is formed as the propulsion region R3, a region where the land portion 10 is formed as the drainage region R2, and a land portion 11 as the propulsion region R3 are formed. are arranged in order. That is, in the bottom surface 5s shown in FIG. 15, the front region P1 does not include the drainage region R2, and the rear region P2 does not include the wear-resistant region R1. When viewed from the entire bottom surface 5s, the wear-resistant region R1 is arranged only on the toe T side with respect to the drainage region R2.

By arranging the wear-resistant region R1 only on the side of the toe T (see FIG. 1) with respect to the water-discharging region R2, drainage performance during the stepping motion and wear-resistant performance during the kick-out motion, can be further enhanced.

However, the configuration is not limited to that shown in FIG. 15 as long as the wear-resistant region R1 is arranged only on the side of the toe T (see FIG. 1) with respect to the drainage region R2. The bottom surface may be such that the front region P1 is composed only of the wear-resistant region R1, and the rear region P2 is composed only of the drainage region R2. Further, the wear-resistant region R1 and the drainage region R2 are arranged in the order of the wear-resistant region R1 and the drainage region R2 from the toe T side of the front region P1 toward the heel side, and the rear region P2 is the wear-resistant region. It may be a bottom surface that does not include R1 but includes the drainage region R2. Conversely, the front region P1 does not include the drainage region R2 but includes the wear-resistant region R1, and the wear-resistant region R1 and the drainage region R2 form the wear-resistant region R1 from the toe T side toward the heel side of the rear region P2. , the drainage area R2.

Furthermore, as shown in FIG. 15, the total area of the wear-resistant region R1 on the bottom surface 5s is preferably larger than the total area of the drainage region R2 on the bottom surface 5s. With such a configuration, it is possible to maintain a balance between wear resistance performance and drainage performance. In other words, it is possible to prevent either the wear resistance performance or the drainage performance from becoming excessive or insufficient.

Next, the propulsion region R3 will be explained. A propulsion region R3 having propulsion performance is provided on the bottom surface 5s shown in FIG. 15 on the heel side (rear side in the longitudinal direction Z of the sole) with respect to the drainage region R2.

As described above, the contact area of the bottom surface 5s during running moves toward the heel side from the drainage area R2 during the stepping motion (see FIGS. 2A and 2B). Next, the contact area moves toward the toe T (see FIG. 1) toward the kicking motion, and moves to the wear-resistant area R1 in the vicinity of the toe T (see FIGS. 2C to 2D). Therefore, the portion on the heel side of the drainage region R2 requires a high propulsive force toward the kicking motion in the latter half. Therefore, as shown in FIG. 15, the propulsion area R3 is preferably provided at least on the heel side with respect to the drainage area R2. In this way, a high propulsive force can be obtained, and the grounding portion 4 (see FIG. 1) of the prosthetic leg 1 for competition is damaged by colliding with the road surface S (see FIG. 1) on the heel side of the drainage area R2. can be suppressed.

When the wear resistance performance is compared in the wear resistance region R1, the drainage region R2, and the propulsion region R3, the relation "wear resistance region R1>propulsion region R3>drainage region R2" holds.

Further, when the drainage performance is compared in the wear-resistant region R1, the drainage region R2, and the propulsion region R3, the relationship is "drainage region R2>propulsion region R3>wear-resistant region R1."

Furthermore, when the propulsion performance is compared in the wear-resistant region R1, the drainage region R2, and the propulsion region R3, "propulsion region R3>wear-resistant region R1>drainage region R2."

In the example shown in FIG. 15, the wear resistance performance, drainage performance, and propulsion performance of the wear resistance region R1, drainage region R2, and propulsion region R3 are set by adjusting the negative ratio. In the example shown in FIG. 15, the negative ratio increases in the order of the drainage region R2, the propulsion region R3, and the wear-resistant region R1.

In the example shown in FIG. 15, the total area of the wear-resistant region R1 on the bottom surface 5s is larger than the total area of the drainage region R2 on the bottom surface 5s. On the other hand, the total area of the wear-resistant region R1 on the bottom surface 5s is preferably smaller than the total area of the total area of the drainage region R2 and the propulsion region R3 on the bottom surface 5s. In the example shown in FIG. 15, the total area of the wear-resistant region R1 on the bottom surface 5s is smaller than the total area of the total area of the drainage region R2 and the propulsion region R3 on the bottom surface 5s. In this way, the relationship of "the total area of the drainage region R2 < the total area of the wear-resistant region R1 < the total area of the drainage region R2 and the propulsion region R3" allows the wear resistance performance, the drainage performance, and the propulsion performance to be balanced. can be secured. That is, it is possible to prevent any one of wear resistance performance, drainage performance, and propulsion performance from becoming excessive or insufficient. Further, when the wear-resistant region R1, the drainage region R2, and the propulsion region R3 are functionally separated based on the negative ratio, by increasing the area occupied by the drainage region R2 and the propulsion region R3, which have a large negative ratio, the sole 5 (See FIG. 1, etc.).

As shown in FIG. 15, the wear-resistant region R1 includes a first region R1a located on the toe T side (see FIG. 1) and a second region R1b located on the heel side with respect to the first region R1a. I have. More specifically, in the example shown in FIG. 15, the region in which the linear groove 13 is formed (see the two-dot chain line frame "I" in FIG. 15) corresponds to the first region R1a. Moreover, in the example shown in FIG. 15, the area|region in which the land part 12 is formed corresponds to 2nd area|region R1b.

The first region R1a of the wear resistant region R1 has higher wear resistance performance than the second region R1b of the wear resistant region R1. In the example shown in FIG. 15 , the area where the linear grooves 13 are formed has a smaller negative ratio than the area where the land portions 12 are formed. Therefore, the area where the straight grooves 13 are formed has higher wear resistance than the area where the land portions 12 are formed (see the two-dot chain line frame "II" in FIG. 15). However, the wear resistance performance may be differentiated due to the difference in materials and the like.

Further, the second region R1b of the wear resistant region R1 has higher propulsion performance than the first region R1a of the wear resistant region R1. In the example shown in FIG. 15, the area where the land portion 12 is formed has a larger edge component than the area where the straight groove 13 is formed. Therefore, the region where the land portion 12 is formed has higher propulsion performance than the region where the straight groove 13 is formed.

By setting the wear resistance performance and the propulsion performance in the first region R1a and the second region R1b in the wear resistance region R1 to the above relationship, in the wear resistance region R1, the propulsion performance up to the final stage of the kicking operation, It is possible to achieve both wear resistance performance in the final stage of the kicking action.

Furthermore, the area of the first region R1a of the wear resistant region R1 is preferably smaller than the area of the second region R1b of the wear resistant region R1. In this way, the propulsion performance up to the final stage of the kicking motion can be further enhanced in the wear-resistant region R1. The ratio of the area of the first region R1a to the area of the second region R1b is preferably 0.25 to 0.8, more preferably 0.33 to 0.5, and 0.45. is particularly preferred.

Further, the ratio of the area of the second region R1b of the wear-resistant region R1 to the area of the drainage region R2 adjacent to the heel side of the second region R1b of the wear-resistant region R1 may be 0.6 to 1.5. It is preferably 0.8 to 1.2, and particularly preferably 1.1.

Furthermore, the ratio of the area of the propulsion region R3 located on the heel side of the drainage region R2 of the rear region P2 to the total area of the bottom surface 5s is preferably 0.25 to 0.6, and 0.35 to 0. 0.5 is more preferable, and 0.42 is particularly preferable.

The area relationship and arrangement of each functional region have been described for the same pattern as the bottom surface 5s shown in FIG. Therefore, the description is omitted here.

In any of the above-described embodiments, fluorine is preferably applied to groove walls and groove bottoms of widthwise grooves that define widthwise land portions in the pattern of the bottom surface of the sole. By applying fluorine to the groove walls and the groove bottom of the width direction groove, the drainage performance on the bottom surface of the sole can be improved.

Examples of the present invention will be described below, but the present invention is not limited thereto.
An invention example sole of the present invention and a comparative example sole are made as prototypes, and the performance is evaluated. Inventive example soles are provided with functions such as drainage performance defined in the present invention due to changes in pattern arrangement and grooves on the bottom surface of the sole. Among the comparative example soles, Comparative Example 1 has a uniform sole pattern on the bottom surface. Moreover, Comparative Example 2 has a pattern different from that of the present invention.
Regarding the drainage performance and wear resistance performance, the index of Q1-1 of Comparative Example 1 is taken as 100, and the larger the index, the better the drainage performance and wear resistance performance of the part.
The comparative example soles and the inventive example soles produced as prototypes as described above are attached to the prosthetic foot for competition shown in FIG.

In Comparative Example 1 and Inventive Example 4, the drainage performance and wear resistance performance of each portion of each region Q1 and Q2 were evaluated from the results calculated by simulation. Also, in Comparative Example 2 and Invention Examples 1 to 3, the drainage performance and wear resistance performance of each portion of each region Q1 and Q2 are evaluated in the same manner as in Comparative Example 1 and Invention Example 4.

[Anti-slip performance]
The following test is performed with a 1 mm water film on the glass surface and a load of 980 N applied to the prosthetic leg for competition. A spring scale is attached to the joint between the prosthetic leg for competition and the stump of the foot, and the spring scale is used to pull the prosthesis for competition to the toe side in the front-rear direction of the foot, and the value of the spring scale at the time when the prosthesis for competition starts to slide is measured. index.
The index of Comparative Example 1 is set to 100, and the larger the index, the better the anti-slip performance.
[Abrasion resistance performance]
An athlete with a healthy leg on the left side wears a prosthetic leg for competition on the right side and indexes the appearance of the entire bottom surface after running 200 km on a public road. Note that the index of Comparative Example 1 is set to 100, and the larger the numerical value, the more excellent the abrasion resistance performance of the sole. In Comparative Example 1 and Invention Example 4, an athlete with a healthy leg on the left side wore a prosthetic leg for competition on the right side, and after running 200 km on a public road, the appearance of the entire bottom surface was indexed. Also in Comparative Example 2 and Invention Examples 1 to 3, the appearance of the entire bottom surface is indexed in the same manner as in Comparative Example 1 and Invention Example 4.

1: Competition prosthesis 2: Foot 2a: Straight part 2b, 2c: Curved part 3: Curved part 4: Contact part 4s: Contact area 5: Sole 5s, 50s, 500s, 5000s: bottom surface 6: toe-side sticking margin portion 7: curved portion-side sticking margin portion 8a, 8b: notch 10, 11, 12, 14: land portion 10a, 11a, 12a: width direction extending portion 10b, 11b, 12b: toe-side protrusions 10c, 11c, 12c: curved-portion-side protrusions 13, 130: linear grooves 110, 110, 120, 140: land portions 15, 16a, 16b, 17a, 17b, 18a : Land portion 18b: Semi-land portion 19a, 19b: Straight groove 30: Vertical groove 31, 32: Groove 33: Vertical groove 34, 35, 36, 37: Inclined groove 40: Square pyramid 41 : Hidden groove 42, 43: Groove P1: Front region P2: Rear region Q1: Curved side region Q2: Toe side region Q1-1, Q1-2, Q2-1, Q2-2: Part , R1: wear-resistant region, R1a: first region, R1b: second region, R2: drainage region, R3: propulsion region, S: road surface, T: toe, W: width direction (sole width direction), X1, X2 : Arc, Y: Foot fore-and-aft direction, Z: Sole fore-and-aft direction, VL: Virtual straight line

Claims (6)

A sole of a prosthesis for competition, which is attached to the contact area of the prosthesis for competition,
A wear-resistant region having wear-resistant performance and a drainage region having drainage performance are provided on the bottom surface,
When defining an imaginary straight line extending parallel to the sole width direction at the central position in the sole front-rear direction,
In a front region of the bottom surface on the toe side with respect to the imaginary straight line, the area of the wear-resistant region is larger than the area of the drainage region,
The sole of a prosthetic foot for competition, wherein in a rear region of the bottom surface on the heel side with respect to the imaginary straight line, the area of the drainage region is larger than the area of the wear-resistant region. 2. The sole of an athletic prosthesis according to claim 1, wherein in said bottom surface said wear-resistant area is arranged only on said toe side with respect to said drainage area. 3. The sole of an athletic prosthesis according to claim 2, wherein the total area of said wear-resistant area on said bottom surface is greater than the total area of said drainage area on said bottom surface. A propulsion area having propulsion performance is provided on the bottom surface on the heel side with respect to the drainage area,
4. The sole of the athletic prosthesis according to claim 3, wherein the total area of the wear-resistant region on the bottom surface is less than the total area of the sum of the total area of the drainage region and the total area of the propulsion region on the bottom surface. The wear-resistant region comprises a first region located on the toe side and a second region located on the heel side with respect to the first region,
The first region of the wear resistant region has higher wear resistance performance than the second region of the wear resistant region,
5. The sole of the athletic prosthesis according to any one of claims 2 to 4, wherein the second area of the wear-resistant area has a higher propulsion performance than the first area of the wear-resistant area. 6. The sole of the athletic prosthesis according to claim 5, wherein the area of said first region of said wear-resistant region is smaller than the area of said second region of said wear-resistant region.

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