A type of antistatic shoe
By sewing conductive fibers into the soles of socks and insoles or outsoles to form a complete conductive path, the problem of static electricity buildup in socks is solved, achieving effective static electricity conduction and improved comfort.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 尤博爱
- Filing Date
- 2025-05-28
- Publication Date
- 2026-06-30
AI Technical Summary
Existing socks tend to accumulate static electricity after friction, which affects wearing comfort and attracts dust and fur. They also have poor anti-static properties.
Conductive fibers are sewn into the soles of socks and insoles or outsoles to form conductive paths, allowing static electricity to be conducted from the human body to the ground. This includes the design of conductive segments in the soles, insoles, and outsoles to ensure effective static electricity release under various wearing conditions.
It achieves effective conduction of static electricity under various wearing methods, eliminates the static electricity effect, improves wearing comfort and reduces dust adsorption, and has a wide range of applications.
Smart Images

Figure CN224420153U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of daily necessities technology, specifically to an anti-static shoe. Background Technology
[0002] Socks are essential daily necessities, and most common socks are made of ordinary materials such as cotton and polyester. Cotton and polyester have high insulation properties, but they easily accumulate electrical charge after friction. Especially in dry weather, socks with this charge attract dust, lint, and other contaminants, promoting bacterial growth and affecting comfort. Furthermore, prolonged friction between socks and skin or shoes can generate static electricity, resulting in poor anti-static properties. These drawbacks can cause considerable inconvenience. Summary of the Invention
[0003] To address the problems of socks attracting dust and fur due to their electrical charge, thus affecting wearing comfort, and the inconvenience caused by static electricity after wearing socks, this invention proposes an anti-static shoe that conducts static electricity to the ground, eliminating the static effect, and is suitable for various wearing methods.
[0004] To achieve the above objectives, the technical solution of this utility model is as follows:
[0005] An antistatic shoe includes antistatic socks, an insole, and a sole. The insole is sewn with conductive fiber filament two, which includes an upper conductive segment two, a lower conductive segment two, and a middle conductive segment two. The sole is sewn with conductive fiber filament three, which includes an upper conductive segment three, a lower conductive segment three, and a middle conductive segment three. The antistatic socks include a sole, at least at the forefoot and heel, with conductive fiber filament one woven in a mixed pattern. The conductive fiber filament one includes an upper conductive segment one, a lower conductive segment one, and a middle conductive segment one. An angle is formed between the lower conductive segment one of the sole and the upper conductive segment two of the insole, and between the lower conductive segment two of the insole and the upper conductive segment three of the sole.
[0006] Furthermore, the upper conductive segment is embedded in the inner surface of the sock sole, the lower conductive segment is embedded in the outer surface of the sock sole, and the upper conductive segment and the lower conductive segment are connected through the middle conductive segment.
[0007] Furthermore, the upper conductive segment two is sewn onto the upper surface of the insole, and the lower conductive segment two is sewn onto the lower surface of the insole. The upper conductive segment two and the lower conductive segment two are connected through the middle conductive segment two.
[0008] Furthermore, the upper conductive segment three is sewn onto the upper surface of the shoe sole, and a groove is formed on the lower surface of the shoe sole. The lower conductive segment three is sewn into the groove, and the upper conductive segment three and the lower conductive segment three are connected through the middle conductive segment three.
[0009] Furthermore, it also includes an insole, which has the same structure as the insole.
[0010] Furthermore, the conductive fiber filament one, conductive fiber filament two, and conductive fiber filament three have the same structure, and conductive fiber filament one is one or a combination of carbon fiber filament, silver fiber filament, and copper fiber filament.
[0011] Furthermore, the conductive fiber filament one, conductive fiber filament two, and conductive fiber filament three have the same structure, and conductive fiber filament one is a combination of one or more of the following: a yarn containing carbon fiber filaments, copper fiber filaments, or silver fiber filaments.
[0012] Furthermore, the lower conductive segment one of the sock sole and the upper conductive segment two of the insole, as well as the lower conductive segment two of the insole and the upper conductive segment three of the sole, all have an angle greater than 30°. This facilitates cross-contact between adjacent conductive segments when a person steps on them.
[0013] The beneficial effects of this utility model through the above technical solution are as follows:
[0014] The core of the antistatic socks provided by this utility model lies in the conductive fiber filaments woven on the sole, ensuring effective conduction of static electricity throughout the entire sole area. In barefoot situations, when the foot is in contact with the conductive fiber filaments woven on the sole, the static electricity is directly conducted to the ground and released, eliminating static electricity. In footwear situations, this utility model also provides antistatic shoes, which, when used in conjunction with the aforementioned antistatic socks, support various wearing methods such as barefoot-sock-ground, barefoot-sole-ground, barefoot-sock-sole-ground, barefoot-insoles-sole-ground, barefoot-sock-insoles-sole-ground, barefoot-sock-insole-sole-ground, and barefoot-sock-insoles-sole-ground. By establishing a complete conductive path from the human body to the ground, the generated static electricity is conducted to the ground, eliminating the static electricity effect. This design is highly practical and has a wide range of applications. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the antistatic socks in this utility model;
[0016] Figure 2 This is a schematic diagram of the sole of the antistatic socks in this utility model;
[0017] Figure 3 This is a cross-sectional view of the sole of the sock in this utility model;
[0018] Figure 4 This utility model Figure 3 Enlarged view of point A in the middle;
[0019] Figure 5 This is a schematic diagram of the insole or inner sole of the antistatic shoes in this utility model;
[0020] Figure 6 This is a schematic diagram of the lower surface of the sole of the antistatic shoe in this utility model;
[0021] Figure 7 This utility model Figure 6 Cross-sectional view of the BB section of the midsole.
[0022] The numbers in the attached diagram are:
[0023] 1. Sock sole; 2. Conductive fiber filament one; 21. Upper conductive segment one; 22. Lower conductive segment one; 23. Middle conductive segment one; 3. Insole; 4. Shoe sole; 5. Conductive fiber filament two; 51. Upper conductive segment two; 52. Lower conductive segment two; 53. Middle conductive segment two; 6. Conductive fiber filament three; 61. Upper conductive segment three; 62. Lower conductive segment three; 63. Middle conductive segment three; 7. Groove; 8. Insole. Detailed Implementation
[0024] The present invention will be further described below with reference to the accompanying drawings and specific embodiments: Example 1
[0025] like Figures 1-4 As shown, this embodiment provides an antistatic sock, including a sock sole 1, wherein conductive fiber filaments 2 are mixed and woven into the sock sole 1 at least at the forefoot and heel. In a barefoot scenario, after the foot is put on the antistatic sock, the sole of the foot comes into contact with the conductive fiber filaments 2 woven on the sock sole 1. Since the sock sole 1 is in direct contact with the ground, static electricity is directly conducted to the ground and released, thus eliminating static electricity.
[0026] In this embodiment, the conductive fiber filament 2 includes an upper conductive segment 21, a lower conductive segment 22, and a middle conductive segment 23. The upper conductive segment 21 is embedded in the inner surface of the sock sole 1, and the lower conductive segment 22 is embedded in the outer surface of the sock sole 1. The upper conductive segment 21 and the lower conductive segment 22 are connected through the middle conductive segment 23.
[0027] The antistatic socks provided by this utility model are designed based on common sock styles and conform to daily wearing habits; the conductive fiber filament 2 replaces some conventional yarns such as cotton and polyester, and can achieve functional upgrades without changing the existing production process, forming antistatic socks that combine conductivity and wearing comfort, and can be widely used in daily life.
[0028] The applicant would like to clarify that some of the existing antistatic shoes are work shoes worn in production workshops and advanced laboratories to reduce or eliminate the hazards of static electricity, and cannot be widely used in daily life; others have complex structures and use metal wires, resulting in poor wearing comfort.
[0029] This utility model also provides an antistatic shoe, including the aforementioned antistatic sock, such as... Figures 5-7 As shown, it also includes an insole 3 and a sole 4, wherein conductive fiber filament 2 5 is sewn onto the insole 3 and conductive fiber filament 3 6 is sewn onto the sole 4.
[0030] Specifically, the conductive fiber filament 5 includes an upper conductive segment 51, a lower conductive segment 52, and a middle conductive segment 53. The upper conductive segment 51 is sewn onto the upper surface of the insole 3, the lower conductive segment 52 is sewn onto the lower surface of the insole 3, and the upper conductive segment 51 and the lower conductive segment 52 are connected by the middle conductive segment 53. This structure ensures that the insole 3 effectively conducts static electricity.
[0031] In this invention, the conductive fiber filament 6 comprises an upper conductive segment 61, a lower conductive segment 62, and a middle conductive segment 63. The upper conductive segment 61 is sewn onto the upper surface of the sole 4, and a groove 7 is formed on the lower surface of the sole 4. The lower conductive segment 62 is sewn into the groove 7, and the upper conductive segment 61 and the lower conductive segment 62 are connected through the middle conductive segment 63. This structure ensures that the sole 4 effectively conducts static electricity. The groove 7 in the sole 4 not only provides good anti-slip performance but also reduces wear on the lower conductive segment 62.
[0032] Additionally, this includes the non-removable insole 8; please refer to [link / reference needed]. Figure 5 The insole 8 and the removable insole 3 have the same structure and will not appear on the same shoe model at the same time. The insole 8 and the insole 3 adopt the same structural design, which can effectively conduct static electricity whether stepping directly on the insole 3 or the insole 8.
[0033] In this embodiment, the conductive fiber filament 1 (2), conductive fiber filament 2 (5), and conductive fiber filament 3 (6) have the same structure. Conductive fiber filament 1 (2) is a combination of one or more of carbon fiber filaments, silver fiber filaments, and copper fiber filaments. The aforementioned carbon fiber filaments, silver fiber filaments, and copper fiber filaments combine conductivity and wearing comfort.
[0034] It is worth mentioning that the lower conductive segment 22 of the sock sole 1 and the upper conductive segment 51 of the insole 3, as well as the lower conductive segment 52 of the insole 3 and the upper conductive segment 61 of the sole 4, all have an angle greater than 30°. This structure facilitates cross-contact between adjacent conductive segments when a person steps on it, effectively establishing a complete conductive path from "human body - sock - insole - sole - ground".
[0035] In shoe-wearing scenarios, it supports multiple wearing methods, including barefoot-sole-ground, barefoot-sock-sole-ground, barefoot-insoles-sole-ground, barefoot-socks-insoles-sole-ground, and barefoot-socks-insoles-sole-ground. Specific application states are as follows:
[0036] The foot can be placed directly on the sole 4, so that the sole of the foot is in direct contact with the upper conductive segment 61 on the upper surface of the sole 4, and then the static electricity is conducted to the lower conductive segment 62 on the lower surface of the sole 4 through the middle conductive segment 63. The lower conductive segment 62 on the lower surface of the sole 4 directly releases the static electricity to the ground.
[0037] After putting on antistatic socks, the soles of the feet come into direct contact with the conductive fiber filaments 1-2 woven on the sock sole 1. Then, through the contact between the sock sole 1 and the shoe sole 4, static electricity is conducted to the upper conductive segment 61 on the upper surface of the shoe sole 4, and then through the middle conductive segment 63 to the lower conductive segment 62 on the lower surface of the shoe sole 4. The lower conductive segment 62 on the lower surface of the shoe sole 4 directly releases the static electricity to the ground.
[0038] The foot can be placed directly on the insole 8 of the shoe. Static electricity is conducted to the upper conductive segment 51 on the upper surface of the insole 8. Then, through the contact between the insole 8 and the sole 4, the static electricity is conducted from the lower conductive segment 52 on the lower surface of the insole 8 to the upper conductive segment 61 on the upper surface of the sole 4. Then, through the middle conductive segment 63, the static electricity is conducted to the lower conductive segment 62 on the lower surface of the sole 4. The lower conductive segment 62 on the lower surface of the sole 4 directly releases the static electricity to the ground.
[0039] After putting on anti-static socks, the soles of the feet come into direct contact with the conductive fiber filaments 1-2 woven on the sock sole 1. Then, through the contact between the sock sole 1 and the insole 8, the static electricity is conducted to the upper conductive segment 51 on the upper surface of the insole 8, and then through the middle conductive segment 53 to the lower conductive segment 52 on the lower surface of the insole 8. Then, through the contact between the insole 8 and the sole 4, the static electricity is conducted from the lower conductive segment 52 on the lower surface of the insole 8 to the upper conductive segment 61 on the upper surface of the sole 4, and then through the middle conductive segment 63 to the lower conductive segment 62 on the lower surface of the sole 4. The lower conductive segment 62 on the lower surface of the sole 4 directly releases the static electricity to the ground.
[0040] Alternatively, after putting on anti-static socks, the soles of the feet can directly contact the conductive fibers 1-2 woven on the sock sole 1. Then, through the contact between the sock sole 1 and the insole 3, static electricity is conducted to the upper conductive segment 51 on the upper surface of the insole 3, and then through the middle conductive segment 53 to the lower conductive segment 52 on the lower surface of the insole 3. Then, through the contact between the insole 3 and the sole 4, static electricity is conducted from the lower conductive segment 52 on the lower surface of the insole 3 to the upper conductive segment 61 on the upper surface of the sole 4, and then through the middle conductive segment 63 to the lower conductive segment 62 on the lower surface of the sole 4. The lower conductive segment 62 on the lower surface of the sole 4 directly releases the static electricity to the ground.
[0041] Through the above-mentioned combination methods, this utility model ultimately realizes a complete electrostatic transfer mode from the human foot to the ground, thereby avoiding the poor conductivity caused by the shoe being conductive while the insole is not, or the shoe being conductive while the sock is not, in some combinations. It is highly feasible and has a wide range of applications. Example 2
[0042] This embodiment is basically the same as Embodiment 1, and the similarities will not be repeated. The differences are as follows:
[0043] The conductive fiber filament 1 (2), conductive fiber filament 2 (5), and conductive fiber filament 3 (6) have the same structure. Conductive fiber filament 1 (2) is a yarn containing one or more of carbon fiber filaments, copper fiber filaments, or silver fiber filaments. This ensures effective static electricity conduction while further guaranteeing wearing comfort.
[0044] In summary, the key improvement of this invention lies in replacing some conventional yarns by weaving conductive fiber filaments into the sole of the sock. The conductive fiber filaments also run through the insole or shoe sole, thus changing the non-conductive properties of the socks and shoes to a conductive state. When the human body wears the antistatic socks and shoes provided by this invention, a complete conductive path is established from the human body to the ground. This is suitable for various wearing methods, allowing the generated static electricity to be conducted from the human body to the ground, eliminating the static electricity effect, and without affecting the original performance or function of the socks and insoles.
[0045] The embodiments and figures described above are merely preferred embodiments of this utility model and are not intended to limit the scope of implementation of this utility model. Therefore, all equivalent changes or modifications made to the structure, features and principles described in the patent claims of this utility model should be included within the scope of the patent application of this utility model.
Claims
1. An antistatic shoe comprising an antistatic sock, characterized by, It also includes an insole (3) and a sole (4), wherein the insole (3) is sewn with conductive fiber filament two (5), the conductive fiber filament two (5) including an upper conductive segment two (51), a lower conductive segment two (52) and a middle conductive segment two (53); the sole (4) is sewn with conductive fiber filament three (6), the conductive fiber filament three (6) including an upper conductive segment three (61), a lower conductive segment three (62) and a middle conductive segment three (63); the antistatic socks include a sock sole (1 The sock sole (1) is woven with conductive fiber filaments (2) at least at the forefoot and heel. The conductive fiber filaments (2) include an upper conductive segment (21), a lower conductive segment (22), and a middle conductive segment (23). The lower conductive segment (22) of the sock sole (1) and the upper conductive segment (51) of the insole (3) and the lower conductive segment (52) of the insole (3) and the upper conductive segment (61) of the sole (4) have an angle.
2. The anti-static shoe according to claim 1, wherein, The upper conductive segment (21) is embedded in the inner surface of the sock sole (1), and the lower conductive segment (22) is embedded in the outer surface of the sock sole (1). The upper conductive segment (21) and the lower conductive segment (22) are connected by the middle conductive segment (23).
3. The antistatic shoe according to claim 1, characterized in that, The upper conductive segment two (51) is sewn onto the upper surface of the insole (3), and the lower conductive segment two (52) is sewn onto the lower surface of the insole (3). The upper conductive segment two (51) and the lower conductive segment two (52) are connected by the middle conductive segment two (53).
4. The antistatic shoe according to claim 1, characterized in that, The upper conductive segment three (61) is sewn onto the upper surface of the sole (4), and a groove (7) is provided on the lower surface of the sole (4). The lower conductive segment three (62) is sewn into the groove (7), and the upper conductive segment three (61) and the lower conductive segment three (62) are connected through the middle conductive segment three (63).
5. An antistatic shoe according to claim 3, characterized in that, It also includes the insole (8), which has the same structure as the insole (3).
6. The antistatic shoe according to claim 1, characterized in that, The conductive fiber filament 1 (2), conductive fiber filament 2 (5) and conductive fiber filament 3 (6) have the same structure. The conductive fiber filament 1 (2) is a combination of one or more of carbon fiber filament, silver fiber filament and copper fiber filament.
7. The antistatic shoe according to claim 1, characterized in that, The conductive fiber filament 1 (2), conductive fiber filament 2 (5) and conductive fiber filament 3 (6) have the same structure. The conductive fiber filament 1 (2) is a combination of one or more of the following: a yarn containing carbon fiber filament, copper fiber filament or silver fiber filament.
8. An antistatic shoe according to claim 1, characterized in that, The lower conductive segment 1 (22) of the sock sole (1) and the upper conductive segment 2 (51) of the insole (3) and the lower conductive segment 2 (52) of the insole (3) and the upper conductive segment 3 (61) of the sole (4) have an angle greater than 30°.