Anti-skid and wear-resistant sole structure

By incorporating abrasion-resistant plates, anti-slip blocks, and anti-slip particles into the sole, combined with a support layer and a cushioning layer, the problem of insufficient abrasion resistance and anti-slip properties of the sole is solved, thereby improving the durability and comfort of the sole.

CN224402997UActive Publication Date: 2026-06-26RUIAN JINZITA SHOES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
RUIAN JINZITA SHOES CO LTD
Filing Date
2025-05-09
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing shoe soles lack sufficient abrasion resistance and slip resistance in high-wear areas, resulting in a shortened lifespan and affecting comfort and practicality.

Method used

The design employs a lower and upper abrasion-resistant plate to distribute wear, combined with TPU anti-slip blocks and rubber anti-slip particles to increase the contact area. It also features a TPU foam support layer and a gel cushioning layer to enhance the abrasion resistance and anti-slip properties of the sole, and extends its service life through abrasion-resistant rubber material.

Benefits of technology

It effectively extends the lifespan of shoe soles, improves anti-slip performance, reduces wear, enhances comfort and stability, and reduces fatigue.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses an anti -skidding wear -resisting shoe sole structure belongs to the shoe sole technical field, including the shoe sole, the heel position of shoe sole bottom adhesive connection has lower wear -resisting piece, and the shoe sole bottom metatarsal adhesive connection has upper wear -resisting piece, and the inside of shoe sole is provided with the recess, the lower surface of shoe sole adhesive connection has the anti -skid strip, and the lower surface of shoe sole adhesive connection has lower wear -resisting block, the lower surface of shoe sole adhesive connection upper wear -resisting block, the lower surface of shoe sole adhesive connection has the anti -skid block, and the anti -skid block is in the lower surface of shoe sole equal interval distribution, and the anti -skid block is TPU material composition, the lower surface of shoe sole adhesive connection has the anti -skid granule, and the anti -skid granule in the lower surface of shoe sole equal interval distribution, this anti -skidding wear -resisting shoe sole structure, through setting lower wear -resisting piece and upper wear -resisting piece, effectively dispersed the wear degree of shoe sole whole, and lower wear -resisting piece and upper wear -resisting piece can be targeted in easy wear area Additional protection, prolongs the service life of shoe sole.
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Description

Technical Field

[0001] This utility model relates to the field of shoe sole technology, specifically to a non-slip and wear-resistant shoe sole structure. Background Technology

[0002] The sole is the bottom of a shoe, directly contacting the ground or other surfaces. The design and materials of the sole are crucial to the shoe's comfort, durability, and functionality. A key factor for the sole is its slip resistance and abrasion resistance; however, existing soles have relatively poor abrasion resistance, especially in areas where the heel and forefoot bear significant weight. Over time, this wears down the sole, significantly reducing its slip resistance. Furthermore, as a wearable item, comfort during use is also paramount.

[0003] To overcome the above-mentioned defects, the prior art (Chinese patent application number CN202322789874.7, application date 2023-10-18) provides a wear-resistant and anti-slip sole structure, including a sole body and an edge. The bottom of the sole body is provided with a wear-resistant and anti-slip layer. Wear-resistant blocks are installed in both the forefoot and heel areas of the wear-resistant and anti-slip layer. Several anti-slip particles are embedded in the wear-resistant blocks, which play an anti-slip and wear-resistant role in the two areas with heavy force, effectively preventing the bottom of the sole body from being worn and extending the service life of the shoe. Anti-slip plates are fixedly installed on both sides of the bottom of the arch area, further enhancing the anti-slip effect of this utility model. The support layer is equipped with a support air cushion and air bladder, which has good elasticity and can play a role in cushioning and shock absorption. A cushioning layer is heat-pressed and bonded to the top of the support layer, which also plays a cushioning role. Both can improve the comfort of the user during use.

[0004] When the wearer walks, the forefoot and heel of the shoe sole have a large contact area with the ground, and this wear and tear is accelerated during exercise. The aforementioned device cannot improve the wear resistance of the sole during use, leading to accelerated wear, reduced lifespan, and decreased practicality. Utility Model Content

[0005] The purpose of this invention is to provide a non-slip and wear-resistant shoe sole structure to solve the problem mentioned in the background art that the wear resistance of the shoe sole cannot be improved, which leads to accelerated wear of the shoe sole, reduced service life of the shoe sole, and reduced practicality of the shoe sole.

[0006] To achieve the above objectives, this utility model provides the following technical solution: a non-slip and wear-resistant shoe sole structure, including a shoe sole, wherein a lower wear-resistant sheet is bonded to the heel of the shoe sole, and an upper wear-resistant sheet is bonded to the forefoot of the shoe sole, and a groove is provided inside the shoe sole; a non-slip strip is bonded to the lower surface of the shoe sole, and a lower wear-resistant block is bonded to the lower surface of the shoe sole; and an upper wear-resistant block is bonded to the lower surface of the shoe sole.

[0007] The above structural design effectively distributes the overall wear of the sole by using a lower abrasion plate and the sole itself. The lower abrasion plate can also provide additional protection in areas prone to wear, extending the lifespan of the sole.

[0008] Preferably, the lower surface of the shoe sole is bonded with anti-slip blocks, which are evenly distributed on the lower surface of the shoe sole and are made of TPU material.

[0009] The above structural design, through the installation of anti-slip blocks, allows the TPU anti-slip blocks to automatically adjust the contact area and shape according to the unevenness of the ground when the sole of the shoe comes into contact with the ground, thus closely adhering to the ground and generating greater friction to effectively prevent slipping.

[0010] Preferably, anti-slip particles are bonded to the lower surface of the shoe sole, and the anti-slip particles are evenly distributed on the lower surface of the shoe sole, and the anti-slip particles are made of rubber.

[0011] The above structural design, through the inclusion of anti-slip particles, increases the contact area between the sole and the ground, thereby generating greater friction and improving the anti-slip performance of the shoe. Furthermore, the rubber anti-slip particles are not easily worn away, maintaining a good anti-slip effect for a long time, extending the service life of the sole, and reducing the decline in anti-slip performance caused by the wear of the anti-slip particles.

[0012] Preferably, the lower surface of the shoe sole is stitched with a connecting layer, which is made of hot melt adhesive, and a support layer is stitched with the lower surface of the connecting layer, which is made of TPU foam.

[0013] The above structural design, through the setting of connecting and supporting layers, effectively prevents the supporting layer from falling off the sole during daily use, ensuring the stability and integrity of the sole structure. In addition, the cushioning effect of PU foam material can effectively reduce the pressure on the feet, provide comfortable support for the feet, reduce fatigue, and also help protect joints and reduce damage to the body caused by prolonged walking or exercise.

[0014] Preferably, a buffer layer is stitched to the lower surface of the support layer, and the buffer layer is composed of a gel material.

[0015] The above structural design, by setting a cushioning layer of gel material, can efficiently convert impact energy into its own internal energy, greatly reducing the vibration transmitted to the feet. This not only improves the wearing experience but also enhances the feeling of walking or exercising to a certain extent, making people more relaxed and comfortable.

[0016] Preferably, the lower surface of the buffer layer is stitched with an anti-slip layer, and the anti-slip layer is composed of a thermoplastic elastomer material.

[0017] The above structural design, by setting a non-slip layer made of thermoplastic elastomer material, can effectively increase the friction between the sole and the ground, thereby reducing the risk of slipping. At the same time, the TPE non-slip layer can maintain a good non-slip effect, providing reliable safety for walking.

[0018] Preferably, a wear-resistant layer is stitched to the lower surface of the anti-slip layer, and the wear-resistant layer is composed of wear-resistant rubber material. Furthermore, an adhesive layer is stitched to the lower surface of the wear-resistant layer, and the adhesive layer is composed of sponge material.

[0019] The above structural design, through the setting of the wear-resistant layer and the bonding layer, the wear-resistant rubber material can effectively resist friction and wear, significantly extending the service life of the sole, and the bonding layer can closely fit the contour of the foot, providing a full-body comfortable wrapping feeling for the foot, effectively relieving the pressure between the foot and the sole, reducing the fatigue caused by walking or standing for a long time, and making the wearing experience more comfortable and free.

[0020] Compared with the prior art, the beneficial effects of this utility model are: the anti-slip and wear-resistant shoe sole structure adopts a novel structural design, the specific details of which are as follows:

[0021] (1) The anti-slip and wear-resistant sole structure effectively disperses the overall wear of the sole through the setting of the lower wear-resistant plate and the upper wear-resistant plate, and the lower wear-resistant plate and the upper wear-resistant plate can provide additional protection in the wear-prone areas, extending the service life of the sole.

[0022] Furthermore, increasing the contact area between the sole and the ground generates friction, thus improving the shoe's anti-slip performance.

[0023] (2) The anti-slip and wear-resistant sole structure, through the setting of wear-resistant layer and bonding layer, the wear-resistant rubber material wear-resistant layer can effectively resist friction loss and significantly extend the service life of the sole, and the bonding layer can closely fit the contour of the foot, providing a comprehensive comfortable wrapping feeling for the foot.

[0024] Furthermore, it effectively relieves pressure between the feet and the soles of the shoes, reducing fatigue caused by prolonged walking or standing.

[0025] (3) The anti-slip and wear-resistant sole structure, through the setting of the connecting layer and the support layer, effectively prevents the support layer from falling off the sole during daily use, ensuring the stability and integrity of the sole structure, and the cushioning effect of the TPU foam material can effectively reduce the pressure on the feet. Attached Figure Description

[0026] Figure 1 This is a schematic diagram of the connection structure between the shoe sole and the lower abrasion-resistant plate of this utility model;

[0027] Figure 2This is a schematic diagram of the sole and upper abrasion-resistant plate structure of this utility model;

[0028] Figure 3 This is a schematic diagram of the connection structure between the anti-slip block and the anti-slip particles of this utility model;

[0029] Figure 4 This is a schematic diagram of the connection structure between the shoe sole and the anti-slip strip of this utility model;

[0030] Figure 5 This is a schematic diagram of the connection structure between the connecting layer and the support layer of this utility model;

[0031] Figure 6 This is a schematic diagram of the connection structure between the buffer layer and the anti-slip layer of this utility model;

[0032] Figure 7 This is a schematic diagram of the connection structure between the bonding layer and the wear-resistant layer of this utility model.

[0033] In the diagram: 1. Outsole; 2. Groove; 3. Lower abrasion-resistant plate; 4. Upper abrasion-resistant plate; 5. Anti-slip block; 6. Anti-slip particles; 7. Lower abrasion-resistant block; 8. Anti-slip strip; 9. Upper abrasion-resistant block; 10. Connecting layer; 11. Supporting layer; 12. Buffer layer; 13. Anti-slip layer; 14. Abrasion-resistant layer; 15. Adhesive layer. Detailed Implementation

[0034] 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.

[0035] Example 1: By setting, such as Figures 1-3 As shown: It includes a sole 1, a lower abrasion-resistant sheet 3 is bonded to the heel of the bottom of the sole 1, and an upper abrasion-resistant sheet 4 is bonded to the forefoot of the bottom of the sole 1. The sole 1 has a groove 2 inside. The lower surface of the sole 1 has an anti-slip strip 8 bonded to it, a lower abrasion-resistant block 7 bonded to it, and an upper abrasion-resistant block 9 bonded to it.

[0036] When the wearer walks, the sole 1 provides stable support for the wearer's feet and effectively distributes pressure, allowing the foot to maintain balance when standing and walking. At the same time, the abrasion plate 3 installed on the sole 1 effectively distributes the overall wear of the sole 1 and can provide additional protection in areas prone to wear, extending the service life of the sole 1 and ensuring the durability of the sole 1 in key areas, thereby improving the overall abrasion resistance of the sole 1.

[0037] In Example 2, unlike Example 1, the anti-slip slider 5, anti-slip particles 6, and connecting layer 10 increase the contact area between the sole 1 and the ground. Figures 4-5 As shown: Anti-slip blocks 5 are bonded to the lower surface of the sole 1, and the anti-slip blocks 5 are evenly distributed on the lower surface of the sole 1. The anti-slip blocks 5 are made of TPU material. Anti-slip particles 6 are bonded to the lower surface of the sole 1, and the anti-slip particles 6 are evenly distributed on the lower surface of the sole 1. The anti-slip particles 6 are made of rubber material. A connecting layer 10 is sewn to the lower surface of the sole 1. The connecting layer 10 is made of hot melt adhesive material. A support layer 11 is sewn to the lower surface of the connecting layer 10. The support layer 11 is made of TPU foam material. A cushioning layer 12 is sewn to the lower surface of the support layer 11. The cushioning layer 12 is made of gel material.

[0038] When the sole 1 contacts the ground, the TPU anti-slip block 5 can automatically adjust the contact area and shape according to the unevenness of the ground, closely conforming to the ground, thereby generating greater friction and effectively preventing slipping. The anti-slip particles 6 increase the contact area between the sole 1 and the ground, thereby generating greater friction and effectively preventing slipping. Furthermore, the rubber anti-slip particles 6 are not easily worn away, maintaining a good anti-slip effect for a long time, extending the service life of the sole 1, and reducing the decline in anti-slip performance caused by the wear of the anti-slip particles 6.

[0039] In Example 3, unlike Example 2, the use of the bonding layer 15, anti-slip layer 13, and abrasion-resistant layer 14 extends the lifespan of the shoes. Figures 6-7 As shown: The lower surface of the buffer layer 12 is stitched with an anti-slip layer 13, which is made of thermoplastic elastomer material. The lower surface of the anti-slip layer 13 is stitched with a wear-resistant layer 14, which is made of wear-resistant rubber material. The lower surface of the wear-resistant layer 14 is stitched with an adhesive layer 15, which is made of sponge material.

[0040] With the addition of the wear-resistant layer 14 and the bonding layer 15, the wear-resistant rubber layer 14 can effectively resist this frictional wear, significantly extending the service life of the sole 1. The bonding layer 15 can closely conform to the contour of the foot, providing a comprehensive and comfortable wrapping feel for the foot. It can effectively relieve the pressure between the foot and the sole 1, reduce fatigue caused by walking or standing for a long time, and make the wearing experience more comfortable and free.

[0041] The above is the entire working process of the device, and all contents not described in detail in this specification are existing technologies known to those skilled in the art.

[0042] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A non-slip and wear-resistant shoe sole structure, comprising a shoe sole (1), wherein a lower wear-resistant sheet (3) is bonded to the heel position of the bottom of the shoe sole (1), and an upper wear-resistant sheet (4) is bonded to the forefoot position of the bottom of the shoe sole (1), and a groove (2) is provided inside the shoe sole (1). Its features are: The lower surface of the sole (1) is bonded with an anti-slip strip (8), and the lower surface of the sole (1) is bonded with a wear-resistant block (7). The abrasion-resistant block (9) is bonded to the lower surface of the sole (1).

2. A slip-resistant, wear-resistant shoe sole structure according to claim 1, characterized in that: The lower surface of the sole (1) is bonded with anti-slip blocks (5), and the anti-slip blocks (5) are evenly distributed on the lower surface of the sole (1), and the anti-slip blocks (5) are made of TPU material.

3. A slip-resistant, wear-resistant shoe sole structure according to claim 2, characterized in that: The lower surface of the sole (1) is bonded with anti-slip particles (6), and the anti-slip particles (6) are evenly distributed on the lower surface of the sole (1), and the anti-slip particles (6) are made of rubber.

4. A slip-resistant, wear-resistant shoe sole structure according to claim 3, characterized in that: The lower surface of the sole (1) is stitched with a connecting layer (10), which is made of hot melt adhesive material, and the lower surface of the connecting layer (10) is stitched with a support layer (11), which is made of TPU foam material.

5. The anti-slip and wear-resistant shoe sole structure according to claim 4, characterized in that: The lower surface of the support layer (11) is stitched with a buffer layer (12), and the buffer layer (12) is composed of gel material.

6. The anti-slip and wear-resistant shoe sole structure according to claim 5, characterized in that: The lower surface of the buffer layer (12) is stitched with an anti-slip layer (13), and the anti-slip layer (13) is composed of thermoplastic elastomer material.

7. The anti-slip and wear-resistant shoe sole structure according to claim 6, characterized in that: The anti-slip layer (13) has a wear-resistant layer (14) sewn onto its lower surface. The wear-resistant layer (14) is made of wear-resistant rubber material. The wear-resistant layer (14) has an adhesive layer (15) sewn onto its lower surface. The adhesive layer (15) is made of sponge material.