KR20010007846A - Resilient Shoe - Google Patents

Abstract

PURPOSE: Provided is an elastic shoe having an improved impact adsorbability, which includes a sole part having an elastic member and drum type plate springs. CONSTITUTION: The elastic shoe comprises the elastic member(20) located on an out sole(10), two of the drum type plate springs(30) located in the two spaces(21) on the elastic member(20), a mid sole(40) and an in sole(50) located on the elastic member(20), wherein the drum type plate spring(30) is fabricated by coupling protrusions of one semicircle type plate spring and holes of the other semicircle type plate spring.

Description

Elastic Shoes {Resilient Shoe}

The present invention relates to a shoe having elasticity when walking. The structure of the shoes is variously developed according to the purpose of use, but it is divided into the upper part and the sole part which covers the upper part of the foot as a whole and maintains the appearance design and the shoe shape. It is stacked from the bottom to the outsole, midsole, insole and insole.

In the shoe structure, the midsole is designed to absorb the impact due to weight during walking or exercise by using an elastic material, but there was a limit in obtaining a sufficient effect. Among the shoes of the prior art, to compensate for these problems, shoes with a separate spring or air bag (air cushion) have been introduced to compensate for these problems, but a satisfactory shock absorbing effect is obtained in comparison with the complexity of the structure or the high cost. I could not.

In order to supplement the problems of the shoe according to the prior art, the present invention provides a sole structure that has a simple structure and improves shock absorption performance, giving comfort to pedestrians and stimulating the lower extremity of the lower body by jogging or walking. It is a technical problem of the present invention to achieve the same kinetic effect.

1 is an exploded perspective view of a shoe according to the present invention

Figure 2 is an exploded perspective view of a cylindrical spring having a coupling protrusion and a hole according to the present invention

Figure 3 is a perspective view of the hinge cylindrical spring according to the present invention

Figure 4 is a longitudinal cross-sectional view showing a wearing state of the shoe according to the invention

<Explanation of symbols for main parts of drawing>

10: outsole 12: spring fixing projection

20: elastic member 21: spring storage space

30: spring 40: midsole

50: insole 60: shoe body (upper)

The present invention focuses on improving the structure of a sole part in order to achieve the above technical problem. In more detail, the elastic member 20 is stacked on the upper surface of the outsole 10 and the cylindrical spring 30 having an elliptical cross section is embedded in two or three spaces 21 formed inside the elastic member. After that, the midsole 40 and the insole 50 are placed thereon to absorb the shock caused by the weight generated when the foot touches the ground during walking by the elasticity of the cylindrical spring and the elastic member, and the spring that is pressed when the foot falls off the ground. By using the repulsive force of the increase the propulsion force required to go forward gives comfort to pedestrians, and provides a shoe with elasticity characterized in that the blood circulation is smoothed by stimulating the exercise nerve of the lower body.

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

1 is an exploded perspective view of the "elastic shoes" according to the present invention. As shown in FIG. 1, the present invention consists of an upper part 60 and an insole 50 that is a sole part, a midsole 40, an elastic member 20, and an outsole 10. In order to improve the shock-absorbing capacity, the elastic member 20 is inserted between the outsole and the midsole, and a sole structure having a cylindrical spring 30 having an elliptical cross section in the space 21 formed therein is provided. do.

When explaining the function of the members constituting the shoes by parts,

Out Sole (10) of the shoe is a part in contact with the ground to prevent slipping and stability in accordance with the pattern during walking and exercise is a major part that determines the functionality of the shoe along with the midsole.

The elastic member 20 is sandwiched between the midsole 40 and the outsole 10 in a sandwiched form, and performs a function of absorbing and dispersing a shock applied to the foot during walking and exercising with the cylindrical spring 30. So it is one of the most important part with the spring in the shoe according to the present invention.

The midsole 40 serves as a lid covering the elastic member 20 and the spring 30 to prevent moisture or dust from penetrating and to impart impact force due to the weight of the elastic member 20 and the spring 30. Is responsible for distributing

In Sole (50) is in contact with the shoes directly in the bottom portion of the inner surface of the shoe to remove the foot and prevents foot fatigue and serves to remove athlete's foot and odor caused by sweat.

The upper part is a member constituting the upper part of the shoe. The upper part covers the upper part of the foot to protect the instep and the joint area and is the main application part of the design that determines the appearance of the shoe.

The present invention provides a shoe structure for efficiently absorbing and dispersing the impact force caused by weight generated when the foot touches the ground during walking or exercising, and increasing the propulsion force and providing comfort by using the elastic energy of the built-in spring. Since it is a subject, the following describes the shape, structure, material, and elastic member of the spring to be applied to the shoe according to the present invention.

First, the shape and characteristics required for the spring to be used in the present invention will be described. Springs are generally classified into coil springs and leaf springs. In the case of coil springs, steel wires of a certain thickness are wound on a cylindrical rod at a constant pitch and are used as tension or compression springs. In order to obtain a certain elasticity in the coil spring, the coil must be wound a certain number of times considering the thickness and pitch of the wire (coil rotation speed). It should be wound more than 4 rounds, which is not only used to calculate the "effective number of windings" needed to calculate the spring's elasticity, but also the number of turns of the coil when the pitch is widened in consideration of the thickness of the wire and the spring's displacement. The height of the spring becomes higher in proportion to.

In this case, the height of the sole is increased according to the height of the spring, which makes walking uncomfortable and increases the center of gravity, thereby increasing the risk of injury to the ankle. In addition, it is not suitable for shoes according to the present invention because it is as if a hard disc is attached to the bottom in relation to the position of the spring, thereby preventing the front gingival portion from naturally bending while lifting the heel while walking.

On the other hand, the leaf spring is mainly used for compression, and is used in the form of a leaf spring using a plurality of sheets as used in the suspension of a vehicle.

Advantages of the leaf spring in connection with the present invention is to lower the height of the shoe sole to reduce the risk of ankle injuries, and relatively high compressive force during running (2.2-2.8 times the weight, but in sports such as basketball or volleyball) Considering that the impact force generated during the leap and landing takes a shock of 4.1 ~ 7.1 times of body weight), the height and elasticity of the spring can be controlled by selecting the spring material and adjusting the shape (the degree of bending of the arc). It can be adjusted within the range, and unlike the case of the coil spring, when the heel is lifted while walking, the degree of preventing the natural bending of the front part is minimal.

Looking at the shape of the leaf spring to satisfy the above conditions, first, as shown in Figs. 2 and 3 in that the height of the spring must be low, the leaf spring having a cross-section of the elliptical half divided in the longitudinal direction up and down It is preferable to use the cylindrical spring 30 facing each other is advantageous because it lowers the height and less prevents the front part of the shoe from bending when walking.

Looking more closely at the shape of the spring, the height of the sole is relatively lower than the back of the spring in the heel, it is better to lower the height of the spring than the spring in the heel. Therefore, the degree of bending of the arc in the upper and lower spring pieces is relatively less bent and flattened. On the contrary, in the case of the spring placed on the heel, the impact time is short (0.02 to 0.03 seconds). Since the displacement of the spring is also generated because it is transmitted inside, the length of the spring is short and the degree of bending of the arc is also bent.

(Reference Figure 1)

Impact force at running

With respect to the shock-absorbing performance and shape of the spring, absorbing the impact force within the elastic section of the spring when it is applied up to 7.1 times its weight, as in some movements, is difficult given the constraints such as the height of the spring. In this embodiment, when the springs having different lengths of upper and lower springs are used, the non-linear elasticity generated when the other spring is less extended after one of the spring pieces is unfolded by the external impact force is used. It is advantageous to be able to use, and it is also possible to use two or more leaf springs.

In Fig. 2, as a preferred embodiment of the method of assembling the upper and lower spring pieces, the engaging projection 34 is formed at both ends of the upper and lower spring pieces, and the holes 35 are formed in the remaining spring pieces. To assemble the projections into the holes. This assembly method has the advantage that the structure is simple and does not use a separate assembly member, the cost is low.

Fig. 3 shows another embodiment of a method for assembling the upper and lower spring pieces, and combines both ends of the upper and lower springs with hinges 31 and 32 using rivets. Conventionally, there was a shoe configured to obtain elasticity by installing a leaf spring on a shoe sole, but both ends of the leaf spring were not effectively folded, so there was a disadvantage in that sufficient elasticity was not obtained. In the case of the present invention, both ends of the spring can be easily folded to effectively utilize the elasticity of the spring.

As mentioned above, there are methods for increasing spring elasticity by changing the material of the spring and changing the shape of the spring. Among them, the shape of the spring, that is, the degree of arc of the spring, is increased so that only the height of the spring is increased. Higher heights increase the height from the ground to the soles, making walking uncomfortable and increasing the risk of injuring the ankles while walking, so it is important that the height of the springs is not above a certain level. Preference is given to using steel.

The spring is installed in the inner space 21 of the elastic member 20, but if it is not fixed, it moves in the process of repeating the compression and extension movement of the spring while walking, so it is necessary to fix it in a proper manner.

As a specific fixing method, there are various forms such as a method of fixing the bandstrip to the upper surface of the lower spring piece, a method of forming an L-shaped hook on the outer side of the lower spring piece to the left and right of the lower spring piece, and fixing the springs therein. In the center of the lower spring piece, two holes 33 are formed to the left and right, and the upper surface of the outsole is formed with two projections 12 in the form of round head rivets at positions corresponding to the holes. ) And the outsole's protrusions are fixed.

The position where the spring is installed is, of course, a site that receives the impact force by weight or obtains the driving force necessary for walking, and the forefoot area of the sole that generates the driving force when walking (anatomically, the upper protruding point of the first metatarsal bone and the fifth The main installation site of the spring is the area where the walking axis connecting the top of the metatarsal bone passes) and the heel area that is impacted by weight. One or more springs may be added to the middle portion of the foot to increase the effect of shock absorption. However, when the number of springs is more than three, the structure becomes complicated and the cost increases.

(Reference figure 2)

Impact area during walking and load distribution imposed on it (footprint)

The size and elasticity of the spring can be determined in consideration of the size of the shoe, the load of the human body and the use of the shoe, and the size of the spring can be different depending on the installation position.

The elastic member 20 absorbs the impact force of the weight together with the spring. When the hardness of the material is too flexible in relation to the spring, the elastic member 20 has the same result as the foot wearer stepping on the spring alone. It will increase the fatigue of the foot and impede walking, on the contrary, if the spring is too hard, the spring will be compressed by the impact force, but since the elastic members around it are hard, the shock absorption by the spring will not occur smoothly, thereby achieving the object of the present invention. You will not be able to.

Therefore, it is important to select a suitable material, in the present invention is a preferred embodiment for the material of the elastic member 20 by laminating the molded polyurethane foam material by pressing or injection process in a single layer or several layers by use.

Meanwhile, the horizontal and vertical size of the spring space 21 formed in the elastic member 20 depends on the size of the spring determined based on the size of the shoe or the purpose of the shoe, and when the spring is pressed by the weight. The length of the space 21 is determined in consideration of the length of the, and the width of the space is 1 to 3mm wider to the left and right than the width of the spring to facilitate the work in the shoe assembly process.

Figure 4 is a longitudinal cross-sectional view showing the wearing state of the shoe in accordance with the present invention, the shoe upper 10 and the outsole 10, the elastic member 20, the midsole 40 is coupled to the use of the adhesive and sewing work.

Therefore, in the shoe according to the present invention, the midsole and insole are located on the upper surface of the elastic member, and the midsole and the insole also move up and down according to the vertical motion generated by repeating that the elastic member and the spring are compressed and stretched by the weight when walking. do. That is, when stepping out the foot in the shoe according to the present invention, when the outsole 10 of the shoe body touches the ground, the impact force by weight is applied to the spring 30 and the elastic member 20 through the midsole 40 The spring 30 is pressed downwards. At this time, as the deformation occurs in the spring, the impact force is absorbed, thereby protecting the joints of the ankle and knee and preventing the deformation of the foot.

Contrary to the above, when the foot falls from the ground during walking to restore the original state by the elasticity of the spring 30 and the elastic member 20, the midsole is pushed up, especially with the help of spring elasticity (repulsive force) By increasing the propulsion needed to double the pedestrian gives comfort to pedestrians, and both feet have elasticity to stimulate the exercise nerve of the lower body.

The above action is only a difference in the degree of deformation of the spring (30) when walking or vortexing will act continuously.

Shoes having elasticity according to the present invention is provided with an elastic member 20 and a cylindrical spring 30 in the sole of the shoe to exhibit excellent effects in absorbing and dispersing the impact of weight during walking, giving comfort to pedestrians and ankles and knees Protecting the joints and feet to support the center of the body and the support of the center of the foot at the same time have the elasticity of the lower body's exercise nerves and blood circulation smoothly can achieve the same exercise effect as jogging just walking.

In addition, by simplifying the structure of the spring and the sole, it is possible to supply a shoe having the above effect at an economical low cost.

Claims (6)

In ordinary shoes, two spaces 21 are formed in the front and rear of the stretchable member 20 stacked on the outsole 10, and the joining protrusions are formed at both ends of one of the upper and lower spring pieces in the space. A shoe having elasticity, characterized in that (34) is formed and the other end is formed with a cylindrical spring (30) assembled by forming a coupling hole (35), and the midsole (40) is fixed on the elastic member. . In ordinary shoes, two spaces 21 are formed in the front and back of the elastic member 20 stacked on the outsole 10, and both ends of the spring are hinged 31 and 32 inside the space. Installing a combined cylindrical spring (30), shoes having elasticity characterized in that the midsole 40 is fixed on the elastic member. The shoe with elasticity according to claim 1 or 2, characterized in that the cylindrical spring (30) is fixed to the upper surface of the outsole (10). According to claim 3, The cylindrical spring 30 is the upper surface of the outsole 10 in such a way that the holes 33 formed in the lower spring piece of the cylindrical spring 30 and the projection 12 formed in the shoe outsole 10 is combined. Shoes having elasticity, characterized in that fixed to. The shoe having elasticity according to claim 1 or 2, wherein the lengths of the upper and lower spring pieces constituting the cylindrical springs are different. The shoe having elasticity according to claim 1 or 2, wherein the upper and lower leaf springs constituting the cylindrical springs are formed in two pieces, respectively.