Multi-scenario grip sole

By designing gripping, anti-slip, and drainage zones on the sole, the problem of slipping on wet surfaces is solved, enabling stable walking and improved safety in various scenarios.

CN224402998UActive Publication Date: 2026-06-26SHANGHAI UNIV OF SPORT +2

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANGHAI UNIV OF SPORT
Filing Date
2025-09-04
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing shoe soles are prone to slipping on wet and slippery surfaces, leading to unstable walking and failing to meet the anti-slip requirements for wearing shoes in various scenarios.

Method used

Design a multi-scenario grip sole, including a gripping area, an anti-slip area, and a drainage area. The gripping area provides grip friction, the anti-slip area provides dynamic friction and assists in drainage, and the drainage area quickly discharges fluid through connected first and second drainage channels, enhancing the anti-slip performance of the sole.

Benefits of technology

The shoes enhance the stability and anti-slip performance of the soles on wet and slippery surfaces, reducing the risk of slipping. They are suitable for various usage scenarios and improve walking safety and comfort.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a multi -scene ground -hugging shoe sole in the technical field of shoe sole, including the shoe body, the shoe body includes the ground -hugging area, the antiskid area and the drainage area, the ground -hugging area sets up in the front end, the tail end and one side of shoe body bottom, the antiskid area sets up in the other side of bottom, the utility model discloses through the first drainage groove and multiple second drainage grooves of drainage area intercommunication, when facing the wet and slippery road condition, let multiple first drainage groove and second drainage groove cooperate drainage, guarantee the quick both sides of fluid and export, set up multiple ditches on the ground -hugging boss of ground -hugging area, when the sole of foot strides, and the ground -hugging area is the main stress area, and through multiple ditches cooperate second drainage groove and further quickly guide fluid of the main stress area and export one side, increase the contact area with the foundation simultaneously, increase friction, reduce the sliding risk when the sole of foot strides, avoid the skidding in the walking process.
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Description

Technical Field

[0001] This utility model relates to the field of shoe sole technology, specifically a multi-scenario grip shoe sole. Background Technology

[0002] As an indispensable part of daily life, shoe soles play a crucial role in protecting feet and providing a comfortable wearing experience. Their grip performance is also a key indicator of shoe quality. Traditional sole designs are often tailored to specific scenarios; for example, athletic shoes emphasize grip and stability during exercise, while casual shoes prioritize comfort and lightweight design.

[0003] However, the existing single anti-slip area on the sole can no longer meet the anti-slip needs of wearing shoes in multiple scenarios. When facing wet and complex road conditions, ordinary soles are prone to slipping when walking on wet and slippery roads, making it difficult to walk stably and resulting in poor performance. Utility Model Content

[0004] The purpose of this invention is to provide a multi-scenario grip sole to solve the problem mentioned above that ordinary soles are prone to slipping on wet and slippery surfaces, making it difficult to walk stably and resulting in poor performance.

[0005] To achieve the above objectives, this utility model provides the following technical solution:

[0006] A multi-scenario grip sole includes a shoe body, the shoe body including a gripping area, an anti-slip area and a drainage area, the gripping area being disposed at the front end, the rear end and one side of the bottom of the shoe body, the anti-slip area being disposed on the other side of the bottom, the gripping area and the anti-slip area being disposed adjacent to each other, the gripping area being used to provide grip friction, and the anti-slip area being used to provide dynamic friction and assist in drainage;

[0007] The drainage area includes a first drainage channel and multiple second drainage channels, which are connected. The first drainage channel is located in the adjacent area of ​​the gripping area and the anti-slip area and extends through both areas. The second drainage channels are located through the gripping area. The gripping area includes a number of spaced-apart gripping protrusions. Multiple side grooves are formed on the gripping protrusions, which are connected to the second drainage channels. The gaps between the gripping protrusions are used to assist drainage. Both the second drainage channels and the side grooves are used to enhance drainage.

[0008] As a further embodiment of this utility model: the width of the first drainage trough is greater than the width of the second drainage trough, and a number of triangular pyramids are evenly distributed in the first and second drainage troughs.

[0009] As a further embodiment of this utility model: the height of the triangular pyramid is less than the depth of the first drainage trough and the depth of the second drainage trough, and the spacing between the plurality of triangular pyramids is equal.

[0010] As a further embodiment of this utility model: the triangular pyramid is an equilateral triangular pyramid, and several of the triangular pyramids are spaced apart to form a hexagon.

[0011] As a further embodiment of this utility model: the side ditch is wedge-shaped, and the opening angle of the side ditch is 30°-60°.

[0012] As a further embodiment of this utility model: several triangular blocks are connected to the gripping protrusion, and a triangular cavity is formed in the middle of the triangular block.

[0013] As a further embodiment of this utility model: the anti-slip area includes a first anti-slip protrusion and a second anti-slip protrusion, the first anti-slip protrusion and the second anti-slip protrusion are connected adjacent to each other at intervals, the first anti-slip protrusion is disposed on the outer edge of the anti-slip area, the second anti-slip protrusion is disposed on the other side of the anti-slip area, the first anti-slip protrusion and the second anti-slip protrusion are both hexagonal, the first anti-slip protrusion and the second anti-slip protrusion are arranged adjacent to each other at intervals, and the gap between the first anti-slip protrusion and the second anti-slip protrusion is used to assist in drainage.

[0014] As a further embodiment of this utility model: the first anti-slip protrusion is connected to a plurality of rhomboid protrusions, and the second anti-slip protrusion is connected to a plurality of triangular protrusions, wherein the rhomboid protrusions and the triangular protrusions are all connected to fish scale-shaped protrusions.

[0015] Compared with the prior art, the beneficial effects of this utility model are:

[0016] 1. In this utility model, the gripping area and the anti-slip area are set in separate zones to prevent slipping. The gripping area has several gripping protrusions to enhance the grip during starting or sudden stopping, ensuring the effective transmission of power and reducing the risk of slipping. The anti-slip area further improves the anti-slip performance of the shoe in wet and slippery environments and enhances the overall stability. Multiple areas provide multiple points of friction, allowing the wearer to walk stably when facing wet and slippery road conditions. It is suitable for a variety of usage scenarios and has a good effect.

[0017] 2. In this utility model, the first drainage channel and multiple second drainage channels in the drainage area are connected. When facing slippery road conditions, the multiple first drainage channels and second drainage channels work together to drain water, ensuring that the fluid is quickly discharged from both sides. Multiple side grooves are opened on the gripping protrusions in the gripping area. When the foot steps, the gripping area is the main stress area. The multiple side grooves, together with the second drainage channels, further guide the fluid in the main stress area quickly and discharge it to one side. At the same time, the contact area with the foundation is increased, the friction is increased, the risk of slipping when the foot steps is reduced, and slipping is avoided during walking. The effect is good. Attached Figure Description

[0018] Figure 1 This is a front view structural diagram of the shoe body of this utility model;

[0019] Figure 2 This is a schematic diagram of the first anti-slip protrusion structure of this utility model;

[0020] Figure 3 This is a schematic diagram of the second anti-slip protrusion structure of this utility model;

[0021] Figure 4 This is a schematic diagram of the triangular block connection structure of this utility model;

[0022] Figure 5 This is a schematic diagram of the triangular pyramid connection structure of this utility model.

[0023] In the diagram: 1. Shoe body; 2. Grip area; 21. Grip bump; 211. Triangular block; 22. Side groove; 3. Anti-slip area; 31. First anti-slip bump; 311. Diamond-shaped bump; 32. Second anti-slip bump; 321. Triangular bump; 4. Drainage area; 41. First drainage groove; 411. Triangular pyramid; 42. Second drainage groove. Detailed Implementation

[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0025] Example:

[0026] Please see Figures 1-5In this embodiment of the utility model, a multi-scenario grip sole includes a shoe body 1. The shoe body 1 includes a gripping area 2, an anti-slip area 3, and a drainage area 4. The gripping area 2 is disposed at the front end, rear end, and one side of the bottom of the shoe body 1, and the anti-slip area 3 is disposed on the other side of the bottom. The gripping area 2 and the anti-slip area 3 are disposed adjacent to each other. The gripping area 2 is used to provide gripping friction, and the anti-slip area 3 is used to provide dynamic friction and assist in drainage.

[0027] The drainage area 4 includes a first drainage channel 41 and a plurality of second drainage channels 42. The first drainage channel 41 and the plurality of second drainage channels 42 are connected. The first drainage channel 41 is located in the adjacent area of ​​the gripping area 2 and the anti-slip area 3 and extends through the gripping area 2 and the anti-slip area 3. The second drainage channels 42 are provided through the gripping area 2. The gripping area 2 includes a plurality of gripping protrusions 21 arranged at intervals. A plurality of side ditches 22 are opened on the plurality of gripping protrusions 21. The side ditches 22 are connected to the second drainage channels 42. The gaps between the plurality of gripping protrusions 21 are used to assist drainage. Both the second drainage channels 42 and the side ditches 22 are used to enhance drainage.

[0028] Specifically, the shoe body 1 of this utility model provides zoned anti-slip by dividing the gripping area 2 and the anti-slip area 3. The gripping area 2 has several gripping protrusions 21 to enhance the grip during starting or sudden stopping, ensuring effective power transmission and reducing the risk of slipping. The anti-slip area 3 further improves the anti-slip performance of the shoe body 1 in wet and slippery environments and enhances the overall stability. Multiple areas provide multiple points of friction, allowing the wearer to walk stably when facing wet and slippery road conditions. It is suitable for various usage scenarios and has good performance.

[0029] The first drainage channel 41 and multiple second drainage channels 42 in drainage area 4 are connected. When facing slippery road conditions, the multiple first drainage channels 41 and second drainage channels 42 work together to drain water, ensuring that the fluid is quickly discharged from both sides. Multiple side grooves 22 are opened on the gripping protrusions 21 in gripping area 2. When the foot steps, gripping area 2 is the main stress area. The multiple side grooves 22 work together with the second drainage channels 42 to further guide the fluid in the main stress area quickly and discharge it to one side. At the same time, the contact area with the foundation is increased, the friction is increased, the risk of slipping when the foot steps is reduced, and slipping is avoided during walking. The effect is good.

[0030] Preferred, such as Figure 1 As shown, the width of the first drainage trough 41 is greater than the width of the second drainage trough 42, and a number of triangular pyramids 411 are evenly distributed in the first drainage trough 41 and the second drainage trough 42.

[0031] Specifically, the first drainage channel 41 is used to quickly collect and disperse large areas of fluid from the bottom of the shoe body 1, with stronger drainage capacity, and can quickly drain the water accumulated at the bottom of the shoe body 1. The second drainage channel 42 assists in drainage, ensuring that the bottom surface of the shoe body 1 is in contact with the roadbed, improving friction and grip, and having better dynamic friction. The triangular cones 411 in the first drainage channel 41 and the second drainage channel 42 further enhance the drainage efficiency of the drainage channels, ensuring that the fluid can be guided to the sides of the shoe body 1 more smoothly and quickly, effectively avoiding the risk of slipping due to fluid accumulation, improving walking safety, and enabling the shoe body 1 to maintain good grip and stability in wet and slippery environments, ensuring the wearer's walking safety, while also increasing the wear resistance of the sole and extending the service life of the shoe.

[0032] Preferred, such as Figure 1 and Figure 5 As shown, the height of the triangular pyramid 411 is less than the depth of the first drainage trough 41 and the depth of the second drainage trough 42, and the spacing between the triangular pyramids 411 is equal.

[0033] Specifically, the lower triangular cone 411 does not protrude from the bottom surface of the first drainage groove 41 and the second drainage groove 42, ensuring that the fluid can fully contact and flow through the bottom of the drainage groove, further improving drainage efficiency. At the same time, the equally spaced width design between the triangular cones 411 ensures that the fluid can be evenly distributed when flowing through the drainage groove, further improving drainage efficiency and maximizing the walking safety of the shoe body 1 in wet and slippery environments.

[0034] Preferred, such as Figure 5 As shown, the triangular pyramid 411 is an equilateral triangular pyramid, and several triangular pyramids 411 are spaced apart to form a hexagon.

[0035] Specifically, the triangular cone 411 of the equilateral triangular pyramid allows each cone to evenly distribute the fluid pressure from the sole, reducing the impact of the fluid on the bottom of the drainage channel and extending the service life of the drainage channel. The hexagonal combination creates multiple small fluid channels inside the drainage channel, which can more effectively guide the fluid flow, reduce fluid accumulation and stagnation, and make it easier for the fluid to be squeezed out by the sole, thereby improving drainage efficiency.

[0036] Preferred, such as Figure 1 As shown, the side ditch 22 is wedge-shaped, and the opening angle of the side ditch 22 is 30°-60°, preferably 40° and 45°.

[0037] Specifically, the opening angle of the side ditch 22 is 30°-60° and is wedge-shaped, which can ensure smooth fluid discharge and avoid structural strength reduction caused by excessively large openings;

[0038] Furthermore, the preferred opening angles of the side ditch 22 are 40° and 45°, which can ensure drainage efficiency while taking into account the durability of the sole and the comfort of wearing, resulting in good performance.

[0039] Preferred, such as Figure 4 As shown, several triangular blocks 211 are connected to the gripping protrusion 21, and a triangular cavity is opened in the middle of the triangular block 211.

[0040] Specifically, the triangular chamber in the triangular block 211 further enhances functionality. This triangular chamber not only reduces the overall weight of the grip protrusion 21, making the shoe lighter to wear, but also increases the elasticity of the grip protrusion 21 in contact with the ground, improving the grip of the sole and the stability of walking. In addition, the structure of the triangular chamber also helps to disperse the reaction force of the ground during walking, reducing the impact on the foot and improving wearing comfort.

[0041] Preferred, such as Figure 1 , Figure 2 and Figure 3 As shown, the anti-slip area 3 includes a first anti-slip protrusion 31 and a second anti-slip protrusion 32. The first anti-slip protrusion 31 and the second anti-slip protrusion 32 are connected adjacent to each other at intervals. The first anti-slip protrusion 31 is located on the outer edge of the anti-slip area 3, and the second anti-slip protrusion 32 is located on the other side of the anti-slip area 3. Both the first anti-slip protrusion 31 and the second anti-slip protrusion 32 are hexagonal. The first anti-slip protrusion 31 and the second anti-slip protrusion 32 are arranged adjacent to each other at intervals. The gap between the first anti-slip protrusion 31 and the second anti-slip protrusion 32 is used to assist in drainage.

[0042] Specifically, the hexagonal first anti-slip protrusion 31 and second anti-slip protrusion 32 provide stable grip, and their unique shape helps to disperse pressure from the ground in multiple directions, enhancing stability during walking. In addition, the gap between the first anti-slip protrusion 31 and the second anti-slip protrusion 32 serves as a drainage channel, which can effectively drain water from the sole of the shoe quickly, keeping the sole dry and further improving the comfort and safety of wearing the shoe.

[0043] Preferred, such as Figure 2 and Figure 3 As shown, the first anti-slip protrusion 31 is connected to several rhomboid protrusions 311, and the second anti-slip protrusion 32 is connected to several triangular protrusions 321. Both the rhomboid protrusions 311 and the triangular protrusions 321 are connected to fish scale-shaped protrusions.

[0044] Specifically, the first anti-slip protrusion 31 is composed of three rhomboid protrusions 311. During use, the three rhomboid protrusions 311 exert force on each other, forming friction and enhancing dynamic friction, thereby preventing the outer edge of the shoe body 1 from slipping and thus preventing ankle sprains. The second anti-slip protrusion 32 is composed of six equilateral triangular protrusions 321. During use, the six equilateral triangular protrusions 321 exert force on each other, forming friction and enhancing dynamic friction. The larger area of ​​the second anti-slip protrusion 32 provides stable friction, preventing the entire shoe body 1 from slipping. It is suitable for wet and slippery road conditions and has a good effect. The fish scale-like protrusions on the rhomboid protrusions 311 and triangular protrusions 321 can further increase the friction between the bottom surface of the shoe body 1 and the ground. Especially on wet and slippery roads, the fish scale-like protrusions can effectively drain water and reduce the impact of water on friction, thereby providing more stable grip.

[0045] Furthermore, the fish-scale-like protrusions are made using a 3D textured process. This process creates a tiny bumpy structure on the surfaces of the rhomboid protrusions 311 and the triangular protrusions 321. This structure effectively prevents water from accumulating on wet surfaces, ensuring a high coefficient of friction between the bottom surface of the shoe body 1 and the ground. It provides excellent anti-slip properties even in rainy or wet conditions, greatly improving walking safety.

[0046] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and the inventive concept of the present utility model, should be included within the protection scope of the present utility model.

Claims

1. A multi-scenario grip sole, comprising a shoe body (1), characterized in that: The shoe body (1) includes a gripping area (2), an anti-slip area (3), and a drainage area (4). The gripping area (2) is located at the front end, the rear end, and one side of the bottom of the shoe body (1). The anti-slip area (3) is located on the other side of the bottom. The gripping area (2) and the anti-slip area (3) are arranged adjacent to each other. The gripping area (2) is used to provide gripping friction, and the anti-slip area (3) is used to provide dynamic friction and assist in drainage. The drainage area (4) includes a first drainage channel (41) and a plurality of second drainage channels (42). The first drainage channel (41) and the plurality of second drainage channels (42) are connected. The first drainage channel (41) is located in the adjacent area of ​​the gripping area (2) and the anti-slip area (3) and extends through the gripping area (2) and the anti-slip area (3). The second drainage channel (42) is provided through the gripping area (2). The gripping area (2) includes a plurality of spaced gripping protrusions (21). A plurality of side ditches (22) are opened on the plurality of gripping protrusions (21). The side ditches (22) are connected to the second drainage channels (42). The gaps between the plurality of gripping protrusions (21) are used to assist drainage. The second drainage channel (42) and the side ditches (22) are both used to enhance drainage.

2. The multi-scenario grip sole of claim 1, wherein: The width of the first drainage trough (41) is greater than the width of the second drainage trough (42), and a number of triangular pyramids (411) are evenly distributed in the first drainage trough (41) and the second drainage trough (42).

3. The multi-scenario grip sole of claim 2, wherein: The height of the triangular pyramid (411) is less than the depth of the first drainage trough (41) and the depth of the second drainage trough (42), and the spacing between the triangular pyramids (411) is equal.

4. The multi-scenario grip sole of claim 3, wherein: The triangular pyramid (411) is an equilateral triangular pyramid, and several of the triangular pyramids (411) are spaced apart to form a hexagon.

5. The multi-scenario grip sole according to claim 1, characterized in that: The side ditch (22) is wedge-shaped, and the opening angle of the side ditch (22) is 30°-60°.

6. The multi-scenario grip sole according to claim 5, characterized in that: The gripping protrusion (21) is connected to several triangular blocks (211), and a triangular cavity is formed in the middle of the triangular block (211).

7. The multi-scenario grip sole according to claim 1, characterized in that: The anti-slip area (3) includes a first anti-slip protrusion (31) and a second anti-slip protrusion (32). The first anti-slip protrusion (31) and the second anti-slip protrusion (32) are connected adjacent to each other at intervals. The first anti-slip protrusion (31) is located on the outer edge of the anti-slip area (3), and the second anti-slip protrusion (32) is located on the other side of the anti-slip area (3). The first anti-slip protrusion (31) and the second anti-slip protrusion (32) are both hexagonal. The first anti-slip protrusion (31) and the second anti-slip protrusion (32) are arranged adjacent to each other at intervals. The gap between the first anti-slip protrusion (31) and the second anti-slip protrusion (32) is used to assist in drainage.

8. The multi-scenario grip sole according to claim 7, characterized in that: The first anti-slip protrusion (31) is connected to several rhomboid protrusions (311), and the second anti-slip protrusion (32) is connected to several triangular protrusions (321). Both the rhomboid protrusions (311) and the triangular protrusions (321) are connected to fish scale-shaped protrusions.