A 3D mesh fabric with built-in anti-slip properties
By weaving an hook-and-loop layer onto the upper surface of the 3D mesh fabric, the problem of unstable connection between traditional 3D mesh fabric and textile fabric is solved, achieving higher friction and connectivity, and preventing slippage.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- JIANGSU SIMU NEW TEXTILE TECH CO LTD
- Filing Date
- 2026-04-30
- Publication Date
- 2026-06-30
AI Technical Summary
Traditional 3D mesh fabrics have a smooth surface and low friction, making it difficult to form a stable connection and hook-and-loop fastener with other textiles, and they are prone to slippage.
A hook and loop layer is woven into the upper surface of the 3D mesh fabric. The hook and loop layer is formed by yarns, which increases friction to improve stability and connectivity.
It enhances the friction between the 3D mesh and the woven fabric, improves stability and connectivity, and prevents slippage.
Smart Images

Figure CN122304101A_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of 3D mesh fabric, and in particular to a 3D mesh fabric with its own anti-slip properties. Background Technology
[0002] 3D mesh fabric specifically refers to elastic fabric with a stable three-dimensional spatial structure formed by polymer monofilament as the main raw material through a three-dimensional weaving process. Because it has the physical properties of vertical cushioning, high resilience, overall breathability and washability, 3D mesh fabric is often used as a removable anti-slip mat in conjunction with carpets and other textiles to protect the floor and improve the feel underfoot, and the carpets and other textiles on the top of the mat can be easily removed and machine washed.
[0003] Traditional 3D mesh fabrics typically only require cushioning through their three-dimensional mesh structure; however, the surface of such mesh fabrics is often smooth or a single woven plane. When used in conjunction with other textiles, the friction between its surface and the back of the textile is small, making it difficult to form a stable connection and hook and loop fastener by relying solely on natural adhesion or simple planar contact between the two. Summary of the Invention
[0004] In order to improve the problems existing in the above-mentioned technologies, this application provides a 3D mesh fabric with its own anti-slip properties.
[0005] This application provides a 3D mesh fabric with built-in anti-slip properties, using the following technical solution: A 3D mesh fabric with built-in anti-slip properties includes: a 3D mesh fabric body, which is composed of an upper layer, a middle layer and a lower layer and is woven together to form a 3D mesh fabric body. The top of the upper layer is provided with an hook and loop layer, which is formed of yarn.
[0006] By adopting the above technical solution, the 3D mesh fabric woven with the yarn of this application can form an hook and loop layer on the upper surface of the 3D mesh fabric. Thus, when the 3D mesh fabric is used with the textile fabric, the friction between the 3D mesh fabric and other textile fabrics can be increased by setting the hook and loop layer, so as to improve stability, connection and hook and loop performance and prevent slippage.
[0007] Optionally, the yarn includes: a core and hook and loop fasteners, wherein the hook and loop fasteners are woven or twisted together with the core to form a yarn, and the hook and loop fasteners are laid along the length direction of the core and extend in the width direction.
[0008] By adopting the above technical solution, when the yarn is used to weave 3D mesh fabric, the hook and loop fastener can form a hook and loop layer on the surface of the 3D mesh fabric. Through the hook and loop layer, when the 3D mesh fabric is used with the textile fabric, the friction between the 3D mesh fabric and other textile fabrics can be increased, thereby improving stability, connection and hook and loop performance and making it less likely to slip off.
[0009] Optionally, the hook and loop fasteners are arranged regularly along the length of the wire core.
[0010] By adopting the above technical solution, the yarn has a high overall aesthetic appeal and is easy to maintain.
[0011] Optionally, the hook and loop fasteners are arranged irregularly along the length of the wire core.
[0012] By adopting the above technical solution, the yarn has a fluffy and three-dimensional overall appearance. Although it lacks a strong sense of order, it has a strong sense of artistry. Furthermore, due to the disorderly arrangement of the hook and loop fasteners, the hook and loop layer can almost cover the surface of the 3D mesh fabric. As a result, when the 3D mesh fabric is used with the textile fabric, the friction between the 3D mesh fabric and other textile fabrics can be further increased, thereby improving stability, connection and hook and loop performance and making it less prone to slippage.
[0013] Optionally, the hook and loop fastener is flocked onto the core along the length of the core.
[0014] By adopting the above technical solution, when the yarn is used to weave 3D mesh fabric, the hook and loop fastener can form a hook and loop layer on the surface of the 3D mesh fabric. Since the hook and loop fastener completely covers the core, the hook and loop layer completely covers the surface of the 3D mesh fabric. Therefore, when the 3D mesh fabric is combined with other textile fabrics, the friction between the 3D mesh fabric and the textile fabric can be further increased to improve stability, connection and hook and loop performance and prevent slippage.
[0015] Optionally, a protrusion may be provided at the end of the hook and loop fastener or on the upper layer.
[0016] By adopting the above technical solution, when using this yarn to weave 3D mesh fabric, the hook and loop thread can form a hook and loop layer on the surface of the 3D mesh fabric, and the protrusion is located on the hook and loop layer; in this way, when the 3D mesh fabric is combined with other textile fabrics, the protrusion can hook and loop into the pile or loop of the textile fabric to increase the connectivity and hook and loop performance.
[0017] Optionally, the ends of any two of the hook and loop wires may be fixedly connected to each other to form a coil.
[0018] By adopting the above technical solution, when using this yarn to weave 3D mesh fabric, the hook and loop thread can form a hook and loop layer on the surface of the 3D mesh fabric. When the 3D mesh fabric is combined with other textile fabrics, the pile or loops on the textile fabric can be hooked into the hook and loop layer to increase the connectivity and hook and loop performance.
[0019] In summary, this application includes at least one of the following beneficial effects: 1. The 3D mesh fabric woven using the yarn of this application can form an hook and loop layer on the upper surface of the 3D mesh fabric. When the 3D mesh fabric is used with the textile fabric, the friction between the 3D mesh fabric and other textile fabrics can be increased by setting the hook and loop layer, so as to improve stability, connection and hook and loop performance and prevent slippage.
[0020] 2. When using this yarn to weave 3D mesh fabric, the hook and loop thread can form a hook and loop layer on the surface of the 3D mesh fabric, and the protrusion is located on the hook and loop layer; in this way, when the 3D mesh fabric is combined with other textile fabrics, the protrusion can hook into the pile or loop of the textile fabric to increase the connection and hook and loop performance.
[0021] 3. When using this yarn to weave 3D mesh fabric, the hook and loop thread can form a hook and loop layer on the surface of the 3D mesh fabric. When the 3D mesh fabric is combined with other textile fabrics, the pile or loops on the textile fabric can be hooked into the hook and loop layer to increase the connectivity and hook and loop performance. Attached Figure Description
[0022] Figure 1 This is a structural schematic diagram according to Embodiment 1 of this application; Figure 2 This is a schematic diagram of the yarn structure according to Embodiment 1 of this application; Figure 3 This is a structural schematic diagram according to Embodiment 2 of this application; Figure 4 This is a structural schematic diagram according to Embodiment 3 of this application; Figure 5 This is a structural schematic diagram according to Embodiment 4 of this application; Figure 6 This is a structural schematic diagram according to Embodiment 4 of this application; Figure 7 This is a structural schematic diagram according to Embodiment 5 of this application; Figure 8 This is a structural schematic diagram according to Embodiment 5 of this application; Figure 9 This is a structural schematic diagram according to Embodiment Six of this application.
[0023] In the diagram: 1. Core yarn; 2. Hook and loop fastener; 3. Protrusion; 4. Coil; 5. 3D mesh fabric body; 6. Yarn; 7. Upper layer; 8. Middle layer; 9. Lower layer; 10. Hook and loop fastener layer; 11. Anti-slip layer. Detailed Implementation
[0024] This application provides a 3D mesh fabric with built-in anti-slip properties. Example
[0025] See Figure 1 and Figure 2A 3D mesh fabric with anti-slip properties includes: a 3D mesh fabric body 5, which is composed of an upper layer 7, a middle layer 8 and a lower layer 9 and is woven together. The top of the upper layer 7 is provided with a hook and loop fastener 10, which is formed simultaneously when the upper layer 7 is woven and is not formed by subsequent processing; and the hook and loop fastener 10 is formed by yarn 6.
[0026] The yarn 6 includes a core 1 and hook and loop fasteners 2, which are interconnected with the core 1, and the hook and loop layer 10 is formed by the hook and loop fasteners 2. In this embodiment, the hook and loop fasteners 2 are not limited to being processed by processes such as interlacing, weaving, air deformation, cutting, flocking, napping, and brushing to form a whole; in this embodiment, the core 1 and the hook and loop fasteners 2 can also be integrally formed and sprayed out by a spinneret, and the specific spraying structure can be determined according to the shape of the spray holes on the spinneret.
[0027] See Figure 1 and Figure 2 In the embodiments of this application, the core 1 and the hook and loop fastener 2 can be made of chemical fibers, natural fibers, etc., but are not limited to chemical fibers and natural fibers. The core 1 and the hook and loop fastener 2 can be made of any material according to specific needs.
[0028] See Figure 1 and Figure 2 The hook and loop fasteners 2 are arranged regularly along the length of the core 1. For example, two hook and loop fasteners 2 are symmetrically arranged with the axis of the core 1 as the center, along the length of the core 1 and on the same horizontal line, which is similar to centipede legs. The yarn has a high overall aesthetic appeal and is easy to care for. When the yarn is used to weave 3D mesh fabric, the hook and loop fasteners 2 can form a hook and loop layer 10 on the surface of the 3D mesh fabric. With the setting of the hook and loop layer 10, when the 3D mesh fabric is used with the textile fabric, the friction between the 3D mesh fabric and other textile fabrics can be increased, so as to improve stability, connection and hook and loop performance and prevent slippage.
[0029] See Figure 1 and Figure 2 Regardless of the type of yarn used in the above-mentioned processes such as interlacing, weaving, air deformation, cut pile, flocking, napping and brushing, the 3D mesh fabric formed by weaving not only retains the structure of the 3D mesh fabric to ensure that the 3D mesh fabric continues to maintain its breathability and washability, but also the surface of the 3D mesh fabric will have good skin-friendliness, so that when people's skin comes into contact with it, they can feel comfortable and not irritate their skin.
[0030] See Figure 1Furthermore, an anti-slip layer 11 is provided at the bottom of the lower layer 9. In this embodiment, the anti-slip layer 11 can be made of materials such as plastic, hot melt adhesive, rubber, latex, etc. (as well as rubber-like materials, woven fabrics of gel-like filaments made of any polymer), thereby increasing the friction between the lower layer 9 and other surfaces such as the ground, sofa surface, or mattress surface to achieve an anti-slip effect and improve the anti-slip performance.
[0031] The working principle of Example 1 is as follows: When the yarn is used to weave 3D mesh fabric, the hook and loop fastener 2 can form a hook and loop layer on the surface of the 3D mesh fabric. Through the hook and loop layer, when the 3D mesh fabric is combined with other textile fabrics, the friction between the 3D mesh fabric and the textile fabric can be increased, so as to improve stability, connection and hook and loop performance and prevent slippage. Example
[0032] See Figure 3 The difference between this embodiment and Embodiment 2 is that the hook and loop fasteners 2 are irregularly arranged along the length of the core 1, that is, the hook and loop fasteners 2 are arranged randomly and disorderly along the length of the core 1. The yarn as a whole is fluffy and three-dimensional. Although it does not have a strong sense of order, it has a strong sense of artistry. Since the attached figure is a simplified structural diagram, the actual arrangement of the hook and loop fasteners 2 is more dense. When using this yarn to weave 3D mesh fabric, the hook and loop fasteners 2 can form a hook and loop layer 10 on the surface of the 3D mesh fabric. And because of the random arrangement of the hook and loop fasteners 2, the hook and loop layer can almost cover a large area of the surface of the 3D mesh fabric. Thus, when the 3D mesh fabric is combined with the textile fabric, the friction between the 3D mesh fabric and other textile fabrics can be further increased to improve stability, connection and hook and loop performance and prevent slippage.
[0033] The working principle of Example 2 is as follows: When the yarn is used to weave 3D mesh fabric, the hook and loop fastener 2 can form a hook and loop layer 10 on the surface of the 3D mesh fabric. Due to the disordered arrangement of the hook and loop fastener 2, the hook and loop layer 10 can cover almost a large area of the surface of the 3D mesh fabric. As a result, when the 3D mesh fabric is used with the textile fabric, the friction between the 3D mesh fabric and other textile fabrics can be further increased, so as to improve stability, connection and hook and loop performance and prevent slippage. Example
[0034] See Figure 4The difference between this embodiment and Embodiment 1 is that the hook and loop fasteners 2 are flocked along the length of the core 1, meaning there are many hook and loop fasteners 2, and they are densely arranged, thus achieving the effect of wrapping the core 1. That is, it is equivalent to a layer of hook and loop fasteners 2 being wrapped around the core 1. In this embodiment, the hook and loop fasteners can be wrapped regularly or irregularly. The yarn as a whole has both aesthetic appeal and a fluffy three-dimensional feel. When using this yarn to weave 3D mesh fabric, the hook and loop fasteners 2 can form a hook and loop layer 10 on the surface of the 3D mesh fabric. Since the hook and loop fasteners 2 completely wrap the core 1, the hook and loop layer 10 completely covers the surface of the 3D mesh fabric. Therefore, when the 3D mesh fabric is combined with other textile fabrics, the friction between the 3D mesh fabric and the textile fabric can be further increased to improve stability, connection and hook and loop performance and prevent slippage. The working principle of Example 3 is as follows: When the yarn is used to weave 3D mesh fabric, the hook and loop fastener 2 can form a hook and loop layer 10 on the surface of the 3D mesh fabric. Since the hook and loop fastener 2 completely covers the core 1, the hook and loop layer 10 completely covers the surface of the 3D mesh fabric. Therefore, when the 3D mesh fabric is combined with other textile fabrics, the friction between the 3D mesh fabric and the textile fabric can be further increased to improve stability, connection and hook and loop performance and prevent slippage. Example
[0035] See Figure 5 and Figure 6 The difference between this embodiment and Embodiments 1 and 2 is that a protrusion 3 is provided at the end of the hook and loop fastener 2 away from the core 1 or on the top wall of the upper layer 7. After the hook and loop fastener 2 is connected to the core 1, part or all of the hook and loop fastener 2 can be sintered or melted by temperature at the end of the hook and loop fastener 2 away from the core 1 to form the protrusion 3; or after the 3D mesh fabric body 5 is woven, the top wall of the upper layer 7 can be sintered or melted by temperature to form the protrusion 3. When the yarn is used to weave 3D mesh fabric, the hook and loop thread 2 can form a hook and loop layer 10 on the surface of the 3D mesh fabric, and the protrusion 3 is located on the hook and loop layer 10. In this way, when the 3D mesh fabric is combined with other textile fabrics, the protrusion 3 can hook into the pile or loop of the textile fabric to increase the connection. As a result, the friction between the 3D mesh fabric and the textile fabric can be further increased to improve the stability, connection and hook and loop performance and prevent slippage.
[0036] The working principle of Example 4 is as follows: When the yarn is used to weave 3D mesh fabric, the hook and loop thread 2 can form a hook and loop layer 10 on the surface of the 3D mesh fabric, and the protrusion 3 is located on the hook and loop layer 10. In this way, when the 3D mesh fabric is combined with other textile fabrics, the protrusion 3 can hook into the pile or loop of the textile fabric to increase the connection. As a result, the friction between the 3D mesh fabric and the textile fabric can be further increased to improve stability, connection and hook and loop performance and prevent slippage. Example
[0037] See Figure 7 and Figure 8 The difference between this embodiment and Embodiments 1 and 2 is that the ends of any two hook and loop fasteners 2 are fixedly connected to each other. In this embodiment, it is not necessary to connect all two hook and loop fasteners 2, only some of them need to be fixedly connected. After the ends of two hook and loop fasteners 2 are fixedly connected to each other, the two hook and loop fasteners 2 can form a coil 4.
[0038] In this embodiment, after the two hook and loop fasteners 2 can form a coil 4, a protrusion 3 can be formed by sintering or melting at a temperature on the coil 4, or after the 3D mesh fabric body 5 is woven, the top wall of the upper layer 7 can be sintered or melted at a temperature to form a protrusion 3; thereby better cooperating with the textile fabric and improving the adhesion between the two.
[0039] When the yarn is used to weave 3D mesh fabric, the hook and loop thread 2 can form a hook and loop layer 10 on the surface of the 3D mesh fabric. When the 3D mesh fabric is combined with other textile fabrics, the pile or loops on the textile fabric can be hooked into the loops 4 on the hook and loop layer 10, and the protrusions 3 on the loops 4 can also be hooked into the loops of the textile fabric to increase the connectivity. As a result, the friction between the 3D mesh fabric and the textile fabric can be further increased to improve stability, connectivity and hook and loop performance and prevent slippage.
[0040] The working principle of Example 5 is as follows: When the yarn is used to weave 3D mesh fabric, the hook and loop thread 2 can form a hook and loop layer 10 on the surface of the 3D mesh fabric. When the 3D mesh fabric is combined with other textile fabrics, the pile on the textile fabric can hook into the loop 4 on the hook and loop layer 10 to increase the connectivity. As a result, the friction between the 3D mesh fabric and the textile fabric can be further increased to improve stability, connectivity and hook and loop performance and prevent slippage. Example
[0041] See Figure 9 The difference between this embodiment and embodiment one is that the hook and loop fastener 2 is no longer connected to the core 1, but only the core 1 is used; the surface of the core 1 is roughened or brushed to form a layer of fluff, i.e., hook and loop layer 10. In this way, the use of hook and loop fastener 2 is reduced, thereby saving materials and simplifying the connection steps between the core 1 and the hook and loop fastener 2, so as to improve efficiency.
[0042] In this embodiment, after the surface of the core 1 is roughened or brushed, the core 1 can also be sintered or melted at a temperature to form protrusions 3, or after the 3D mesh body 5 is woven, the top wall of the upper layer 7 can be sintered or melted at a temperature to form protrusions 3; thereby better cooperating with the textile fabric and improving the adhesion between the two.
[0043] The working principle of Example 6 is as follows: By performing operations such as brushing or sanding on the surface of the wire core 1, a layer of fluff can be formed on the surface of the wire core 1, namely the hook and loop layer 10.
[0044] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.
Claims
1. A 3D mesh fabric with built-in anti-slip properties, characterized in that, include: The 3D mesh fabric body (5) is composed of an upper layer (7), a middle layer (8) and a lower layer (9) and is woven together. The top of the upper layer (7) is provided with a hook and loop layer (10) and the hook and loop layer (10) is formed of yarn (6).
2. The 3D mesh fabric with anti-slip properties according to claim 1, characterized in that, The yarn (6) includes a core (1) and hook and loop fasteners (2), which are woven or twisted together with the core (1) to form the yarn (6). The hook and loop fasteners (2) are laid along the length direction of the core (1) and extend in the width direction.
3. The 3D mesh fabric with anti-slip properties according to claim 2, characterized in that, The hook and loop fastener (2) is arranged regularly along the length direction of the core (1).
4. The 3D mesh fabric with anti-slip properties according to claim 2, characterized in that, The hook and loop fastener (2) is irregularly arranged along the length of the core (1).
5. The 3D mesh fabric with anti-slip properties according to claim 2, characterized in that, The hook and loop fastener (2) is flocked onto the core (1) along the length direction of the core (1).
6. The 3D mesh fabric with anti-slip properties according to claim 3 or 4, characterized in that, The end of the hook and loop fastener (2) or the upper layer (7) is provided with a protrusion (3).
7. The 3D mesh fabric with anti-slip properties according to claim 3 or 4, characterized in that, The ends of any two hook and loop wires (2) are fixedly connected to each other to form a coil (4).