Antibacterial flocked fabric
By using an antibacterial fiber yarn-woven base layer and a breathable pore design in the flocked fabric, the problem of bacterial growth caused by moisture inside clothing is solved, thus improving antibacterial properties and service life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHISHI LIANCHENG FLOCK COATING CO LTD
- Filing Date
- 2025-07-25
- Publication Date
- 2026-06-19
Smart Images

Figure CN224375098U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of flocked fabric technology, specifically to an antibacterial flocked fabric. Background Technology
[0002] Flocked fabric is a type of fabric with a velvety effect, formed by implanting short-fiber flocks onto a base fabric. It typically consists of a base fabric, an adhesive applied to the base fabric, and flock fibers fixed to the base fabric by the adhesive. During the forming process, adhesive is applied to the base fabric, and the flock fibers are implanted into the base fabric through an electrostatic field or mechanical vibration, allowing them to adhere and be fixed by the adhesive. Subsequently, the adhesive is cured, and any excess flock fibers that have not been properly adhered are cleaned up, resulting in flocked fabric. Flocked fabric has a beautiful appearance, a textured and high-end feel, and a soft and comfortable touch, playing an important role in various fields such as clothing, home furnishings, packaging, handicrafts, and industry.
[0003] Although the existing technologies mentioned above can solve the corresponding technical problems, they still have certain drawbacks: when existing flocked fabrics are used on the lining of clothing, the flocked fabric will come into direct contact with the human body. Therefore, the moisture generated by the human body during the wearing process can easily adhere to the flocked fabric. After wearing it for a period of time, it is easy for bacteria to multiply, requiring frequent washing. However, washing can easily cause the flocked fabric to shed fibers, affecting the service life of the flocked fabric. Utility Model Content
[0004] The purpose of this invention is to address the shortcomings and deficiencies of existing technologies by providing an antibacterial flocked fabric that prevents moisture and dries quickly.
[0005] To achieve the above objectives, the present invention adopts the following technical solution: an antibacterial flocked fabric, comprising a base fabric layer woven from antibacterial fiber yarns and an adhesive layer with multiple breathable holes adhered and fixed to the upper surface of the base fabric layer, wherein a flocked fiber layer is adhered and fixed to the adhesive layer.
[0006] A further improvement is that the base fabric layer includes an upper base fabric layer and a lower base fabric layer, a cavity layer is formed between the upper base fabric layer and the lower base fabric layer, and a support protrusion formed by sewing antibacterial fiber yarn is provided between the upper base fabric layer and the lower base fabric layer.
[0007] A further improvement is that the upper base fabric layer is integrally formed with vent holes that extend downwards, pass through the cavity layer, and penetrate the lower base fabric layer.
[0008] A further improvement is that the cavity layer is integrally formed with an air-collecting cavity at the corresponding position of the air vent.
[0009] A further improvement is that a mesh binding layer is sewn and fixed between the upper and lower base fabric layers at the edge of the cavity layer.
[0010] After adopting the above technical solution, the beneficial effects of this utility model are as follows: When this utility model is used, the antibacterial properties of the fabric are greatly improved by sewing the base fabric layer with antibacterial fiber yarn. At the same time, the base fabric layer is divided into an upper base fabric layer and a lower base fabric layer. The cavity layer formed inside it can contain the humid and hot air generated by the body when wearing it, and allow it to dissipate outward through the lower base fabric layer and the binding layer. Combined with the ventilation holes formed on the upper and lower base fabric layers, the humid and hot air can be quickly dissipated, thereby preventing the wearing surface from being damp and stuffy, making it less likely for bacteria to multiply in large quantities, and effectively improving the antibacterial properties of the flocked fabric. Attached Figure Description
[0011] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0012] Figure 1 This is a structural schematic diagram of the front cross-section of the antibacterial flocked fabric of this utility model;
[0013] Figure 2 This is a structural schematic diagram of the front cross-section of the base fabric layer of this utility model;
[0014] Figure 3 This is a top view of the cross-section of the base fabric layer of this utility model located at the cavity layer position. Detailed Implementation
[0015] The present invention will now be further described in conjunction with the accompanying drawings and specific embodiments.
[0016] See Figure 1-3As shown, the technical solution adopted in this specific embodiment is: an antibacterial flocked fabric, comprising a base fabric layer 1 woven from antibacterial fiber yarns and an adhesive layer 2 with multiple breathable holes adhered and fixed to the upper surface of the base fabric layer 1. The base fabric layer 1 includes an upper base fabric layer 111 and a lower base fabric layer 112, with a cavity layer 13 formed between the upper base fabric layer 111 and the lower base fabric layer 112. A support formed by sewing antibacterial fiber yarns is provided between the upper base fabric layer 111 and the lower base fabric layer 112. The protrusion 14 has a pile fiber layer 3 adhered and fixed on the adhesive layer 2. In use, the base fabric layer 1 is first formed. The base fabric layer 1 is woven with antibacterial fiber yarn, which can be Teflon antibacterial yarn, providing good antibacterial effects and additional properties such as UV blocking. The upper base fabric layer 111 and the lower base fabric layer 112 are formed by weaving the antibacterial fiber yarn. The forming support protrusion 14 is then sewn onto the lower base fabric layer 112. This can be achieved through a knitting process. The yarn is stacked to form the supporting protrusion 14. Then, the upper base fabric layer 111 is placed on the lower base fabric layer 112, and the top of the sewing protrusion 14 is sewn to the upper base fabric layer 111. At this time, under the support of the sewing protrusion 14, a cavity layer 13 is formed between the upper base fabric layer 111 and the lower base fabric layer 112. When worn, the base fabric layer 1, which is formed by sewing antibacterial fiber yarn, greatly improves the overall antibacterial properties of the fabric. At the same time, the base fabric layer 1 is divided into the upper base fabric layer 111 and the lower base fabric layer 112. The cavity layer 13 formed inside it can contain the humid and hot air generated by the body when worn, and allow it to diffuse outward through the lower base fabric layer 112 and the edge of the cavity layer 13. Compared with traditional fabrics of the same thickness, the cavity layer 13 can effectively absorb humid and hot air and increase the speed of humid and hot air diffusion outward, thereby preventing the wearing surface from being damp and stuffy, making it less likely for bacteria to multiply in large quantities, and effectively improving the antibacterial properties of the flocked fabric.
[0017] The upper base fabric layer 111 has an integrally formed vent hole 12 that extends downward and passes through the cavity layer 13 and penetrates the lower base fabric layer 112. The vent hole 12 can be formed by punching, which helps to further increase the speed at which hot and humid air is discharged from the base fabric layer 1, making it less likely for hot and humid air to accumulate on the base fabric layer 1, further improving the dehumidification and heat dissipation effect and the effect of preventing bacterial growth.
[0018] The cavity layer 13 is integrally formed with an air collecting cavity 15 at the corresponding position of the vent hole 12. The air collecting cavity is formed by cutting the lower base fabric layer 112 and the upper base fabric layer 111 at the corresponding position of the vent hole 12. This helps to further increase the amount of humid and hot air that the cavity layer 13 can hold and shorten the stroke of the vent hole 12. At the same time, when there is a lot of humid and hot air, some of the humid and hot air can be introduced into the cavity layer 13 through the air collecting cavity 15 to further accelerate the discharge of humid and hot air, so that the humid and hot air can be discharged to the outside more quickly.
[0019] A mesh edging layer 16 is sewn and fixed between the upper base fabric layer 111 and the lower base fabric layer 112 at the edge of the cavity layer 13. It is preferred to use a lockstitch technique to sew it together, which helps to seal the edge of the cavity layer 13 and prevent foreign objects from entering. At the same time, the numerous through holes formed on the mesh edging layer 16 ensure the effect of venting hot and humid air.
[0020] The working principle of this utility model is as follows: First, a base fabric layer 1 is formed. This base fabric layer 1 is woven with antibacterial fiber yarn, such as Teflon antibacterial yarn, which has good antibacterial effects and additional properties such as blocking ultraviolet rays. The upper base fabric layer 111 and the lower base fabric layer 112 are formed by weaving the antibacterial fiber yarn. A forming support protrusion 14 is then sewn onto the lower base fabric layer 112. Next, the upper base fabric layer 111 is placed over the lower base fabric layer 112, and the top of the sewn protrusion 14 is sewn to the upper base fabric layer 111. At this point, under the support of the sewn protrusion 14, the upper base fabric layer 111 and the lower base fabric layer 112... A cavity layer 13 is formed between 112. When worn, the base fabric layer 1, which is formed by sewing antibacterial fiber yarn, greatly improves the overall antibacterial properties of the fabric. At the same time, the base fabric layer 1 is divided into an upper base fabric layer 111 and a lower base fabric layer 112. The cavity layer 13 formed inside it can contain the humid and hot air generated by the body when worn, and allow it to dissipate outward through the lower base fabric layer 112 and the edge of the cavity layer 13. Compared with traditional fabrics of the same thickness, the cavity layer 13 can effectively absorb humid and hot air and increase the speed of humid and hot air dissipation, thereby preventing the wearing surface from being damp and stuffy, making it less likely for bacteria to multiply in large quantities, and effectively improving the antibacterial properties of the flocked fabric.
[0021] This utility model aims to protect the structure of the product. The model numbers of the components are not the focus of this utility model's protection, as they are common technology. Any component on the market that can achieve the functions described above can be used as an option. Therefore, the model numbers and other parameters of the components are not described in detail in this utility model. The contribution of this utility model lies in the scientific combination of the various components.
[0022] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions provided are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of protection of this utility model as defined by the appended claims and their equivalents. Any aspects of this utility model not detailed herein are well-known to those skilled in the art.
Claims
1. An antibacterial flocked fabric, characterized by: It includes a base fabric layer (1) woven from antibacterial fiber yarn and an adhesive layer (2) with multiple breathable holes adhered to the upper surface of the base fabric layer (1), wherein a pile fiber layer (3) is adhered to the adhesive layer (2).
2. The anti-microbial flocked fabric according to claim 1, wherein: The base fabric layer (1) includes an upper base fabric layer (111) and a lower base fabric layer (112), a cavity layer (13) is formed between the upper base fabric layer (111) and the lower base fabric layer (112), and a support protrusion (14) formed by sewing antibacterial fiber yarn is provided between the upper base fabric layer (111) and the lower base fabric layer (112).
3. The antibacterial flocked fabric according to claim 2, characterized in that: The upper base fabric layer (111) has an integrally formed air vent (12) that extends downward and passes through the cavity layer (13) and penetrates the lower base fabric layer (112).
4. The antibacterial flocked fabric according to claim 3, characterized in that: The cavity layer (13) is integrally formed with an air-collecting cavity (15) at the corresponding position of the air vent (12).
5. The antibacterial flocked fabric according to claim 2, characterized in that: A mesh binding layer (16) is sewn and fixed between the upper base fabric layer (111) and the lower base fabric layer (112) at the edge of the cavity layer (13).