WO2023044943A1

WO2023044943A1 - High energy storage sole based on hollow high-elasticity structure

Info

Publication number: WO2023044943A1
Application number: PCT/CN2021/121382
Authority: WO
Inventors: 吴荣照; 林秀欣; 袁雄文; 钟素丹
Original assignee: 福建鸿星尔克体育用品有限公司
Priority date: 2021-09-27
Filing date: 2021-09-28
Publication date: 2023-03-30
Also published as: CN113662323A

Abstract

A high energy storage sole based on a hollow high-elasticity structure, relating to the field of shoe soles. The sole comprises a topsole (1), a midsole (2) and an outsole (3), sequentially arranged from top to bottom. The topsole (1) and the midsole (2) are detachably connected, multiple through holes (4) in communication with each other are symmetrically arranged on two sides of the bottom of the outsole (3), and a first elastic energy storage apparatus is disposed between the midsole (2) and the outsole (3) at a position corresponding to the heel. The first elastic energy storage apparatus comprises an airbag ball (5) fixedly penetrating through the heel of the midsole (2), one-way air valves being disposed at both sides of the airbag ball (5), and an air outlet pipe (6) and an air inlet pipe (7) being arranged at two sides of the airbag ball (5), so that air outside the sole can pass through a first air channel (11) and the air inlet pipe (7) under the action of a fan (12) and negative pressure to instantaneously fill the airbag ball (5). In the instantaneous filling process, the airbag ball (5) instantaeously generates high elasticity at the heel. And, by means of the airbag ball (5), the air outlet pipe (6), a mounting groove and two first air channels (11), a cyclic high energy storage system is formed at the heel of the sole.

Description

A high-energy-storage sole based on a hollowed-out high-elastic structure

technical field

The invention relates to the field of shoe soles, and specifically refers to a high-energy storage shoe sole based on a hollow high-elastic structure.

Background technique

Sports shoes play a vital role in sports. They can provide users with good shock absorption, stability and motion control. The foot, leg and spine provide shock absorption protection. The current soles are simply made of elastic materials to improve the elasticity of the soles. requirements.

Contents of the invention

The object of the present invention is to overcome the above disadvantages and provide a high energy storage sole based on a hollow high elastic structure.

The invention discloses a high-energy-storage shoe sole based on a hollow high-elastic structure. The shoe sole includes an upper bottom, a middle bottom and a large bottom arranged in sequence from top to bottom. The upper bottom and the middle bottom are detachably connected. The large bottom There are a plurality of interconnected through holes symmetrically arranged on both sides of the bottom of the bottom, and a first elastic energy storage device is arranged at the position corresponding to the heel between the midsole and the outsole. The airbag ball at the heel is provided with one-way air valves on both sides of the airbag ball. The ventilation directions of the two one-way air valves are opposite. One of the one-way air valves is used for the exhaust of the airbag ball, and the other one-way air valve It is used for the air intake of the airbag ball, and the air outlet pipe and the air inlet pipe are arranged on both sides of the airbag ball, and the corresponding positions on the surface of the outsole are provided with connecting grooves detachably connected with the air inlet pipe and the air outlet pipe, and the surface is also provided with There is a first groove suitable for the airbag ball, the end of the air inlet pipe and the air outlet pipe far away from the airbag ball is provided with a connecting head for connecting with the connecting groove, and a first installation groove is also arranged in the outsole. The two sides of a mounting groove are provided with first air passages communicating with it, and the two first air passages communicate with the air inlet pipe and the air outlet pipe through the connection between the connecting groove and the connector, and the first installation groove and the through hole connected.

Preferably, the diameters of both ends of the air outlet pipe and the air inlet pipe near the airbag ball are larger than the diameter of the other end.

Preferably, a fan is rotatably arranged in the first installation slot.

Preferably, the connection head includes a threaded sleeve, a connecting plate and a sealing gasket arranged in the threaded sleeve, the sealing gasket is located above the connecting plate, and both the air inlet pipe and the air outlet pipe pass through the connecting sleeve and the sealing gasket and are connected to the connecting plate. The groove wall of the groove is provided with threads suitable for the threaded sleeve.

Preferably, the bottom surface of the midsole is located on both sides of the airbag ball and is provided with two second installation grooves, and the winding drums for winding the air inlet pipe and the air outlet pipe are rotatably installed in the two second installation grooves.

Preferably, the airbag includes an outer sphere, an inner sphere sheathed in the outer sphere, an air outlet and an air inlet are arranged on both sides of the outer sphere, and the side of the inner sphere close to the air inlet is attached to the inner wall of the outer sphere and the inner The inside of the sphere is connected to the air inlet, and the other side is separated from the air outlet. The side wall of the inner sphere is a hollow cavity structure. The hollow cavity structure is connected to the air inlet, and the end near the air outlet is concave. An annular air outlet vented to the air inlet is formed.

Preferably, a second elastic energy storage device is provided at the position corresponding to the sole of the foot between the midsole and the outsole, and the second elastic energy storage device includes a third installation groove arranged in the outsole, and is slidably arranged in the third installation groove. The elastic mechanism inside, the bottom of the elastic mechanism is located in the third installation groove, the top runs through the third installation groove and extends upward to connect with the bottom surface of the midsole, and a buckle device is arranged at the bottom of the third installation groove, and the buckle device can The elastic mechanism is clamped and fixed, and the elastic mechanism is fixed in the third installation groove. The bottom surface of the large bottom is also provided with an adjustment mechanism, which can adjust the buckle device, and can control the buckle device to lock the elastic mechanism. Tight fix.

Preferably, the elastic mechanism includes a chuck arranged in the third installation groove, a connecting rod passing through the third installation groove and a first return spring sleeved on the connecting rod, the bottom end of the connecting rod is connected with the chuck, and the top end Connected with the bottom surface of the midsole, the first return spring is located between the midsole and the outsole.

Preferably, the upper bottom includes a bottom layer, a first airbag body and a second airbag body arranged on the surface of the bottom layer and arranged at intervals.

Preferably, there are multiple second elastic energy storage devices arranged side by side.

By adopting the above-mentioned technical solution, the beneficial effect of the present invention is that during the exercise, the heel of the foot generally touches the ground first, so that the heel will squeeze the airbag ball, so that the air in the airbag ball passes through the air outlet pipe and the first airbag instantaneously. The air channel 11 is discharged into the first installation groove. Since the air is discharged at a faster speed, and the diameter of the air outlet pipe gradually decreases during the air transportation process, the flow rate of the air is faster when the air enters the first installation groove. If the air flow rate is fast, the fan can be driven to rotate. Due to the negative pressure formed by the rotation of the fan and the air in the airbag ball being evacuated, the air outside the sole can pass through the first air duct and the air intake pipe under the action of the fan and the negative pressure. Instantly fill the airbag ball. During the instant filling process, the airbag ball instantly produces high bounce on the heel. Through the airbag ball, air outlet pipe, installation groove and two first air passages, a high-circulation high energy storage system is formed at the heel of the sole.

Description of drawings

Fig. 1 is a schematic view of the sole structure of the present invention;

Fig. 2 is the enlarged view of place A in Fig. 1 of the present invention;

Fig. 3 is an enlarged view at B place in Fig. 1 of the present invention;

Figure 4 is an enlarged view at C in Figure 1 of the present invention;

Fig. 5 is an enlarged view at D place in Fig. 1 of the present invention;

Fig. 6 is an enlarged view at F place in Fig. 1 of the present invention;

Fig. 7 is a schematic diagram of the outsole structure of the present invention;

Fig. 8 is a sectional view of the airbag of the present invention;

Fig. 9 is a plan view of the upper bottom of the present invention.

Explanation of main reference signs: 1 upper bottom, 2 middle bottom, 3 outsole, 4 through hole, 5 airbag ball, 51 outer sphere, 52 inner sphere, 6 air outlet pipe, 7 air intake pipe, 8 connecting groove, 9 first concave Groove, 10 first installation groove, 11 first air passage, 12 fan, 13 threaded sleeve, 14 connection plate, 15 sealing gasket, 16 second installation groove, 17 reel, 18 air outlet, 19 air inlet, 20 The third installation slot, 21 chuck, 22 connecting rod, 23 first return spring, 24 card slot, 25 block, 26 second return spring, 27 fourth installation slot, 28 bump, 281 upper bump, 282 lower Bump, 29 toothed roller, 30 rack, 31 pull cord, 32 guide roller, 33 bottom layer, 34 first air bag body, 35 second air bag body, 36 slide block, 37 fourth installation groove, 38 push tube, 39 The third return spring, 40 pressing plate, 41 second air channel, 42 sealing area, 43 flexible curling, 44 protrusion, 45 connection hole.

Detailed ways

The implementation of the present invention will be described in detail below in conjunction with the accompanying drawings and examples, so as to fully understand and implement the process of how to apply technical means to solve technical problems and achieve technical effects in the present invention. It should be noted that, as long as there is no conflict, each embodiment and each feature in each embodiment of the present invention can be combined with each other, and the formed technical solutions are all within the protection scope of the present invention.

Also, in the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of embodiments of the invention. It will be apparent, however, to one skilled in the art that the present invention may be practiced without the specific details or in the particular manner described.

In this disclosure, terms such as "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", etc. indicate The orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, and is only a relative term determined for the convenience of describing the structural relationship between the components or elements of the present disclosure. It does not specifically refer to any component or element in the disclosure, and cannot be understood as Limitations on this Disclosure.

The invention discloses a high-energy-storage shoe sole based on a hollow high-elastic structure. Referring to Fig. 1 and Fig. 7, the shoe sole includes an upper bottom 1, a mid The bottom 2 is detachably connected, and the adjustment of the height of the entire sole can be realized through the disassembly and assembly of the upper bottom 1. The outsole 3 adopts a hollowed-out design, and specifically, there are a plurality of interconnected multiple shoes symmetrically arranged on both sides of the bottom of the outsole 3. The through holes 4 realize the elastic energy storage of the sole under the adjustment of each through hole 4. Specifically, during the exercise process, the through hole 4 is squeezed, and during the extrusion process, the sole carries out energy storage. During the exercise, The energy-stored sole provides the athlete with a reverse force to achieve the effect of energy storage and high elasticity. At the same time, multiple through-holes 4 allow the wind to pass through the sole through multiple through-holes 4 to reduce the impact of the sole during exercise. resistance.

Between the midsole 2 and the outsole 3, a first elastic energy storage device is arranged corresponding to the heel, and the first elastic energy storage device includes an airbag ball 5 fixedly penetrating through the heel of the midsole 2, on both sides of the airbag ball 5 Both are provided with one-way air valves, and the ventilation directions of the two one-way air valves are opposite. One of the one-way air valves is used for the exhaust of the air bag ball 5, and the other one-way air valve is used for the intake of the air bag ball 5. The two sides of airbag ball 5 are provided with air outlet pipe 6 and air intake pipe 7, and the diameters of the two ends of air outlet pipe and air inlet pipe 7 close to air bag ball 5 are all greater than the pipe diameter of the other end, so that air bag ball 5 can quickly air out when air outlet And the gas is gradually compressed, and the air can be inhaled quickly during the air intake, so that the airbag ball 5 can be filled with air in an instant, and the corresponding positions on the surface of the outsole 3 are provided with connecting grooves that are detachably connected with the air intake pipe 7 and the air outlet pipe 6 8, and the surface is also provided with the first groove 9 that is compatible with the airbag ball 5, and the end of the air inlet pipe 7 and the air outlet pipe 6 away from the airbag ball 5 is provided with a connecting head for connecting with the connecting groove 8. The bottom 3 is provided with a first installation groove 10, and a first air passage 11 communicating with it is arranged on both sides of the first installation groove 10. The two first air passages 11 are connected and connected between the connecting groove 8 and the connector The air intake pipe 7 and the air outlet pipe 6 are connected, and the first installation groove 10 is connected with the through hole 4, so that the air outside the sole can enter the first installation groove 10, and a fan 12 is arranged in the first installation groove 10. During the exercise, the heel of the foot generally touches the ground first, so that the airbag ball 5 is squeezed at the heel, so that the air in the airbag ball 5 is instantly discharged into the first installation groove 10 through the air outlet pipe 6 and the first air passage 11. Because the speed of air discharge is faster, and the air flow rate is faster when the air enters the first installation groove 10 due to the diameter of the air outlet pipe 6 gradually decreasing during the conveying process, the fan 12 can be driven more if the air flow rate is fast. Rotate, due to the negative pressure formed by the rotation of the fan 12 and the air in the air bag ball 5 being evacuated, the air outside the sole can pass through the first air channel 11 and the air intake pipe 7 instantaneously under the action of the fan 12 and the negative pressure. The ball 5 is full, and in the process of instantaneous filling, the airbag ball 5 instantly produces high elasticity on the heel, and through the airbag ball 5, the air outlet pipe 6, the installation groove and the two first air passages 11, the heel of the sole forms a cycle of high energy storage system.

Referring to Fig. 2, the specific connector includes a threaded sleeve 13, a connecting plate 14 and a sealing gasket arranged in the threaded sleeve 13, and the sealing gasket 15 is located above the connecting plate 14, and the air inlet pipe 7 and the air outlet pipe 6 all pass through the connecting sleeve and the sealing gasket 15 and connected with the connection plate 14, the groove wall of the connection groove 8 is provided with threads that are compatible with the threaded sleeve 13, and the outer surface of the threaded sleeve 13 is also provided with threads, so that the threaded sleeve 13 can be screwed into the connection groove 8 Realize the connection between the inlet pipe 7 or the outlet pipe 6 and the first air passage 11. When the threaded sleeve 13 is inserted into the connection groove 8, when there is air circulation in the inlet pipe 7 or the outlet pipe 6, the air will squeeze the connection plate 14 and The sealing gasket 15, under the action of air pressure, makes the connecting plate 14 continuously squeeze the sealing gasket 15, realizes the airtightness of the connection between the connecting groove 8 and the threaded sleeve 13, and prevents the air inlet pipe 7 or the air outlet pipe 6 from being connected to the first ventilation pipe. There is an air leakage between the channels 11, and two second installation grooves 16 are arranged at the bottom surface of the midsole 2 at both sides of the airbag ball 5. Referring to FIG. The trachea 7 or the air outlet pipe 6 are too long, in order to prevent bending between the air inlet pipe 7 or the air outlet pipe 6, resulting in unsmooth air circulation, the air inlet pipe 7 or the air outlet pipe 6 can be wound on the winding drum 17, effectively Prevent the air intake pipe 7 and the air outlet pipe 6 from being bent.

Referring to Fig. 8, the airbag ball 5 includes an outer sphere 51, an inner sphere 52 sleeved in the outer sphere 51, an air outlet 18 and an air inlet 19 are arranged on both sides of the outer sphere 51, and the inner sphere 52 is near the side of the air inlet 19 Fitted with the inner wall of the outer sphere 51 and the inside of the inner sphere 52 is connected with the air inlet 19, and the other side is separated from the air outlet 18. The side wall of the inner sphere 52 is a hollow cavity structure, and the hollow cavity structure is consistent with the The air inlet 19 is connected, and one end close to the air outlet 18 is recessed to form an annular air outlet 18 ventilated to the air inlet 19. When the air enters the inner sphere 52 from the air inlet 19, it enters the hollow cavity structure at the same time. , and pass into the inner sphere 52 again from the annular air outlet 18, at this moment, both sides in the inner sphere 52 all have air to pass into, produce the air intake structure that both sides are opposite in the inner sphere 52, make both sides pass into The air in the inner spheroid 52 collides, so that a collision impact force is generated in the inner spheroid 52, and further improves the size of the high elastic force generated by the airbag ball 5 when the force is stored.

Referring to Fig. 1, a second elastic energy storage device is provided at the sole of the foot between the midsole 2 and the outsole 3, and the second elastic energy storage device includes a third installation groove 20 arranged in the outsole 3, and is slidably arranged on the second Three elastic mechanisms in the installation groove 20, the bottom of the elastic mechanism is located in the third installation groove 20, the top runs through the third installation groove 20 and extends upward to connect with the bottom surface of the midsole 2, and the bottom of the third installation groove 20 is provided with a card buckle device, the buckle device can clamp and fix the elastic mechanism, and fix the elastic mechanism in the third installation groove 20, and the bottom surface of the outsole 3 is also provided with an adjustment mechanism, which can adjust the buckle device, The buckle device can be controlled to clamp and fix the elastic mechanism. Referring to FIG. 3, the specific elastic mechanism includes a chuck 21 arranged in the third installation groove 20, a connecting rod 22 passing through the third installation groove 20, and a connecting rod sleeved on the connecting rod. The first return spring 23 on 22, the bottom end of the connecting rod 22 is connected to the chuck 21, and the top end is connected to the bottom surface of the midsole 2. The first return spring 23 is located between the midsole 2 and the outsole 3. Specifically, the buckle The device comprises two draw-in slots 24 symmetrically arranged on the side walls of the third installation slot 20, two draw-in blocks 25 and two second return springs 26 arranged in the two draw-in slots 24, and the second return springs 26 are located between the draw-in slots 24 and Between the blocks 25, one end is connected to the inner wall of the slot 24, and the other end is connected to the block 25. The end of the block 25 away from the second return spring 26 has a rounded corner structure and can extend into the third installation groove 20. , during the downward movement of the chuck 21, the clamp block 25 can be squeezed to overcome the elastic force of the second return spring 26 and move toward the inside of the slot 24. 26 moves into the third installation groove 20 and clamps and fixes the chuck 21 on the bottom of the third installation groove 20. At this time, the first return spring 23 is fully compressed, and the gap between the midsole 2 and the outsole 3 4, the adjustment mechanism includes a fourth mounting groove 27 arranged at the bottom of the outsole 3 and open at the bottom, a projection 28 slidingly mounted in the fourth mounting groove 27, and a protrusion 28 rotatably disposed in the fourth mounting groove 27. Inside the toothed roller 29, the surface of the toothed roller 29 is a gear structure, the top of the bump 28 is provided with a rack 30, the rack 30 is meshed with the toothed roller 29, when the bump 28 drives the rack 30 to move upward At this time, the toothed roller 29 can be driven to rotate. The adjustment mechanism also includes a pull cord 31 arranged in the outsole 3. One end of the pull cord 31 passes through the second return spring 26 to connect with the block 25, and the other end is wound on the belt. The toothed roller 29 also includes a plurality of guide rollers 32 that are arranged in the outsole 3 and are in contact with the stay cords 31. The stay cords 31 in the outsole 3 and the guide rollers 32 have corresponding installation grooves (not shown). , during the movement, when the heel of the sole touches the ground and squeezes the bump 28, the bump 28 drives the rack 30 to move upwards, and then drives the toothed roller 29 to rotate to wind up the pull cord 31, so that the pull cord 31 pulls The clamping block 25 moves to the inside of the clamping groove 24, so that under the action of the first complex spring, the midsole 2 and the outsole 3 are separated, and the first The elastic force of the return spring 23 is instantly converted into the kinetic energy of the sole, so that the sole of the sole forms a high-elastic energy storage structure. When the sole leaves the ground, the block 25 moves in the third installation groove 20 under the action of the second return spring 26 At this time, the pull cord 31 will be driven to move in the opposite direction. At this time, the toothed cylinder 29 will rotate in the opposite direction, and the rack 30 will drive the bump 28 to move downward, so that the bump 28 will reset.

Referring to Fig. 1, a plurality of second elastic energy storage devices are arranged side by side between the outsole 3 and the midsole 2, and the projections 28 are also arranged side by side on the bottom surface of the sole. , so that each bump 28 is continuously squeezed, so that the sole generates greater elastic force under the action of multiple first return springs 23, and the bump 28 is divided into two detachably connected upper parts with the bottom surface of the big bottom 3 as the dividing line. The bump 281 and the lower bump 282, specifically the upper bump 281 and the lower bump 282 are detachably connected by threads. By disassembling the lower bump 282, it is possible to use the second elastic energy storage device according to actual needs. It is convenient for the wearer to choose freely.

Referring to Fig. 1 and Fig. 9, the upper bottom 1 includes a bottom layer 33, a first air bag body 34 and a second air bag body 35 arranged at intervals on the surface of the bottom layer 33, and between the first air bag body 34 and the second air bag body 35 A third elastic energy storage device is provided, and the position of the third elastic energy storage device corresponds to the arch of the sole of the foot. With reference to Fig. 6, the third elastic energy storage device includes a slide block 36 arranged on the bottom 33 surface, The fifth installation groove 37, and the third return spring 39 and the push tube 38 installed in the fifth installation groove 37, the slider 36 is adapted to the shape of the arch of the sole of the foot, and the bottom of the slider 36 is provided with a The pressure plate 40 in the fifth installation groove 37 (the pressure plate 40 can slide in the fifth installation groove 37, and the fifth installation groove 37 is a T-shaped groove structure), both sides in the fifth installation groove 37 are connected with the first An air bag body 34 and the second air passage 41 communicated with the second air bag body 35, one end of the push tube 38 is connected through the pressing plate 40, and the other end extends into the second air passage 41 close to the second air bag body 35, the third The return spring 39 is sleeved on the push tube 38, and one end is connected with the pressure plate 40, and the other end is connected with the side wall of the fifth installation groove 37. There is also an elastic spring between the second airbag body 35 and the second airway 41. A sealing area 42 made of material, the sealing area 42 is provided with a vent hole for communicating between the second air channel 41 and the second air bag body 35, and the side of the vent hole near the first air bag body 34 is set as a cone Shaped mouth structure, during the movement, the soles of the feet will squeeze and slide, and drive the slider 36 and the pressure plate 40 to move to the rear side, and the pressure plate 40 overcomes the elastic force of the third return spring 39 to drive the push tube 38 to move in the second air passage 41 , until the end of the push tube 38 is along the tapered structure, and enters in the second air bag body 35 through the vent hole so that the air in the first air bag body 34 passes in the second air bag body 35, the vent hole of the sealing area 42 is due to Made of elastic material, it is in a sealed state without being squeezed. Similarly, a third elastic energy storage device for the second airbag body 35 to communicate with the outside of the upper bottom 1 is also provided at the heel of the bottom layer 33. , the structure of the slider 36 of the third energy storage device matches the shape of the heel of the foot, and the second air passage 41 of the third energy storage device directly communicates with the outside of the upper bottom 1, so that the remote mobilization can , the sole of the foot squeezes the first airbag body 34 and the slide block 36 at the same time, the air in the first airbag body 34 passes into the second airbag body 35, and the air in the second airbag body 35 is also completely discharged through the vent hole. After the feet, the air quickly fills the first air bag body 34 and the second air bag body 35 from the second air channel 41 at the outer end of the upper bottom 1, and in the process of the air in the second air bag body 35 entering the first air bag body 34, Because the length of the push tube 38 is the longest enough, during the reset process of the push tube 38, the air in the first air bag body 34 is just filled, and the first air bag body 34 and the second air bag body 35 are instantly charged when the air is filled. Produce high elastic force, on the other hand two slide blocks 36 are under the effect of two 3rd back-moving springs 39, to the arch of the foot place and the heel place of sole. The high elastic force of the reaction can further improve the elastic force of the whole sole, so that the athlete can save more effort during the exercise. The slider 36 between the first air bag body 34 and the second air bag body 35 is arranged on the side close to the first air bag body 34 There is a flexible bead 43, the top of the flexible bead 43 is connected to the slider 36, and the bottom end is wound up on the lower end of the slider 36, and when the slider 36 is moving, the bottom of the flexible bead 43 is always in contact with the upper bottom 1 The surface of the flexible curl 43 can fill the gap between the slider 36 and the surface of the upper bottom 1. Under the action of the flexible curl 43, it can effectively prevent the skin on the sole of the foot from sinking into the gap between them, causing damage to the sole of the foot. Referring to Fig. 9, the periphery of the bottom layer 33 is provided with a plurality of protrusions 44, and the periphery of the corresponding outsole 3 is provided with a plurality of connection holes 45 adapted to the protrusions 44, through which each protrusion 44 is connected to each The cooperation of the hole 45 realizes the detachable connection between the upper bottom 1 and the outsole 3, which facilitates the disassembly and assembly of the upper bottom 1.

It should be noted that many specific details have been set forth in the above description in order to fully understand the present invention, but the present invention can also be implemented in other ways different from those described here, therefore, the protection scope of the present invention is not limited by limitations of the specific embodiments disclosed above.

Claims

A high-energy-storage shoe sole based on a hollow high-elastic structure, which includes an upper bottom, a middle bottom, and a large bottom arranged in sequence from top to bottom, and is characterized in that: the upper bottom and the middle bottom are detachably connected, and the large bottom The two sides of the bottom of the bottom are symmetrically provided with a plurality of interconnected through holes, and a first elastic energy storage device is provided between the midsole and the outsole at the position corresponding to the heel. The airbag ball at the heel of the bottom is provided with one-way air valves on both sides of the airbag ball. The ventilation directions of the two one-way air valves are opposite. The valve is used for the air intake of the airbag ball, and an air outlet pipe and an air inlet pipe are arranged on both sides of the airbag ball. The corresponding positions on the surface of the outsole are provided with connecting grooves that are detachably connected to the air inlet pipe and the air outlet pipe, and the surface is also A first groove matching the airbag ball is provided, and the end of the air inlet pipe and the air outlet pipe far away from the airbag ball is provided with a connecting head for connecting with the connecting groove, and a first installation groove is also arranged in the outsole, the Both sides of the first installation groove are provided with a first air channel communicating with it. The two first air channels communicate with the air inlet pipe and the air outlet pipe through the connection between the connecting groove and the connector. The holes are connected.
The high-energy-storage shoe sole based on hollow high-elastic structure according to claim 1, characterized in that: the diameters of the two ends of the air outlet pipe and the air inlet pipe near the airbag ball are larger than the diameter of the other end.
The high-energy-storage shoe sole based on hollow high-elastic structure according to claim 1, characterized in that: a fan is rotatably arranged in the first installation groove.
The high energy storage shoe sole based on the hollow high elastic structure according to claim 1, characterized in that: the connecting head includes a threaded sleeve, a connecting plate and a sealing gasket arranged in the threaded sleeve, the sealing gasket is located above the connecting plate, and Both the air pipe and the air outlet pipe run through the connecting sleeve and the sealing washer and are connected to the connecting plate, and the groove wall of the connecting groove is provided with threads suitable for the threaded sleeve.
The high-energy-storage shoe sole based on the hollow high-elastic structure according to claim 1, characterized in that: the bottom surface of the midsole is provided with two second installation grooves at the positions on both sides of the airbag ball, and the two second installation grooves are rotated and installed. There are winding drums for winding the inlet pipe and the outlet pipe.
The high-energy-storage shoe sole based on hollow high-elastic structure according to claim 1, characterized in that: the airbag ball includes an outer sphere, an inner sphere sheathed in the outer sphere, and an air outlet and an air inlet are arranged on both sides of the outer sphere , the side of the inner sphere close to the air inlet is attached to the inner wall of the outer sphere and the inside of the inner sphere is connected to the air inlet, and the other side is separated from the air outlet. The side wall of the inner sphere is a hollow cavity structure. The hollow cavity structure communicates with the air inlet, and one end close to the air outlet is recessed to form an annular air outlet ventilated to the air inlet.
The high energy storage sole based on the hollow high elastic structure according to claim 1, characterized in that: a second elastic energy storage device is provided at the corresponding position between the midsole and the outsole, and the second elastic energy storage device It includes a third installation groove set in the outsole and an elastic mechanism slidingly arranged in the third installation groove. The bottom of the elastic mechanism is located in the third installation groove, and the top of the elastic mechanism passes through the third installation groove and extends upward to connect with the bottom surface of the midsole , the bottom of the third installation groove is provided with a buckle device, the buckle device can clamp and fix the elastic mechanism, and fix the elastic mechanism in the third installation groove, and the bottom surface of the big bottom is also provided with an adjustment mechanism. The mechanism can adjust the buckle device, and can control the buckle device to fasten and fix the elastic force mechanism.
The high-energy-storage shoe sole based on hollow high-elastic structure according to claim 7, characterized in that: the elastic mechanism includes a chuck arranged in the third installation groove, a connecting rod passing through the third installation groove, and a connecting rod sleeved on the connecting rod. For the first return spring on the rod, the bottom end of the connecting rod is connected with the chuck, and the top end is connected with the bottom surface of the midsole, and the first return spring is located between the midsole and the outsole.
The high-energy-storage shoe sole based on the hollow high-elastic structure according to claim 1, wherein the upper sole comprises a bottom layer, a first air bag body and a second air bag body arranged on the surface of the bottom layer at intervals.
The high-energy-storage shoe sole based on hollow high-elastic structure according to claim 7, characterized in that: there are multiple second elastic energy-storage devices arranged side by side.