TWM572306U - Fabric with multilayer hot press lamination structure having far infrared - Google Patents

Abstract

The present invention discloses a fabric having a far infrared multi-layer thermo-compression bonding (Tech-Mix) structure, which includes, in order from top to bottom, a first cloth layer, a first far infrared ceramic material layer, and a TPU gas permeable film. a layer, a second far infrared ceramic material layer, and a second cloth layer. The first cloth layer, the first far infrared ceramic material layer, the TPU gas permeable film layer, the second far infrared ceramic material layer, and the second layer are sequentially laminated by a multi-layer hot press bonding technique The fabric layer is thermocompression bonded to a fabric having a far infrared multi-layer thermocompression bonding (Tech-Mix) structure.

Description

Cloth with far infrared multi-layer thermocompression bonding structure

This creation is a fabric with a far-infrared multi-layer thermocompression bonding (Tech-Mix) structure, especially a method in which far-infrared ceramic powder is pressed into the fabric interlayer by thermocompression bonding technology to achieve permanent infrared rays. The multilayer heat-pressing structure of the cloth.

Infrared rays are a kind of radiation in the sun's rays, which is different from the rainbow in the sky after the rain; infrared rays are invisible light, which is the light that the human eye can't see. Infrared was discovered two hundred years ago by German scientist Hacher. The research was concentrated in the field of physics, and it was not until the 1970s that it gradually developed into medical and preventive health care. The far-infrared expert research further converts the energy of the far-infrared FIR physical wave, the physical wave energy resonance relationship between the applied substance and the physiological system, stimulates the physiological function and promotes the health of the body, and achieves the purpose of prevention and health care.

In addition, far-infrared rays transmit light directly in the same way as visible light. When applied to the human body, resonance and warmth are generated, and metabolism can be promoted, and blood circulation can be improved. The far-infrared fiber made of high-tech technology mixed ceramic powder and fiber raw material is used in special health care products such as knee pads, wrist protectors and neck protectors. Recently, international manufacturers have applied it to underwear, pants and socks. Coats and other apparel products, and cross the sports and leisure market.

However, most of the far-infrared fabrics that are commonly used in the market are woven with far-infrared ray or powder, but it is easy to gradually reduce the function of far-infrared rays due to the repeated use of the cloth or the increase in the number of washings. Or the powder falls off, losing the original far-infrared function of the fabric. Therefore, the present invention creates a fabric with a far-infrared multi-layer thermocompression bonding structure, and presses the far-infrared ceramic powder to the fabric clip by an original multi-layer thermocompression bonding technique. Among the layers, the function of gradually reducing the far-infrared function is gradually reduced, and the function of far-infrared rays is continuously maintained in the fabric.

The main purpose of the present invention is to provide a fabric having a far-infrared multi-layer thermocompression bonding structure, wherein the far-infrared ceramic powder is pressed into the fabric by a thermocompression bonding technique to achieve a fabric having a permanent infrared ray. purpose.

In order to achieve the above object, the present invention provides a cloth having a far infrared multi-layer thermocompression bonding structure, comprising: a first cloth layer, a first far infrared ceramic material layer, a TPU gas permeable film layer, and a first a layer of two far infrared ceramic materials and a second cloth layer. The first far-infrared ceramic material layer is disposed below the first cloth layer, and the TPU gas-permeable film layer is disposed below the first far-infrared ceramic material layer, and the second far-infrared ceramic material layer is disposed The second cloth layer is disposed below the second far-infrared ceramic material layer below the TPU gas permeable film layer. The first cloth layer, the first far-infrared ceramic material layer, the TPU gas permeable film layer, the second far-infrared ceramic material layer, and the second cloth layer are hot-pressed by sequentially conforming to a thermocompression bonding condition. The way is one.

In one embodiment, the first cloth layer and the second cloth layer are made of one of cotton, linen, nylon, polyester fiber, and elastic fiber, respectively.

In one embodiment, the hot pressing conditions include: 1. the pressing temperature range is 140 to 170 ° C; 2. the pressing time is 15 to 25 seconds; and 3. the hot pressing pressure is 2 to 5 kg/cm ² .

In one embodiment, the main material content of the first far-infrared ceramic material layer and the second far-infrared ceramic material layer respectively include: a resin, a foam stabilizer, a thickener, a bridging agent, and A ceramic powder (with far infrared function).

In one embodiment, the resin coating liquid is formulated as follows: Appearance: slightly viscous and translucent liquid; composition: polyester type water-based resin; ionic: anion; solid content: 40.0±1.5%; pH: 7.5 ± 1.0; organic solvent: acetone (less than 1%); and stability: stored at 5 ~ 40 ° C for at least 6 months.

In one embodiment, the resin is: 100 g; the foam stabilizer is: 2-5 g; the thickener is 1.0 to 2.0 g; the bridging agent is 3.0 to 5.0 g; the ceramic powder system It is: 10.0~20.0g.

In one embodiment, the TPU gas permeable film layer has a melting temperature range of 70 to 120 ° C.

1‧‧‧cloth with far-infrared multi-layer thermocompression bonding structure

11‧‧‧First fabric layer

12‧‧‧First far infrared ceramic material layer

13‧‧‧TPU breathable film layer

14‧‧‧Second far infrared ceramic material layer

15‧‧‧Second cloth layer

Figure 1 is a partial cross-sectional enlarged view of a cloth having a far infrared multi-layer thermocompression bonding structure.

In order to more clearly describe the fabric of the far-infrared multi-layer thermocompression bonding structure proposed by the present invention, the following will be described in detail in conjunction with the drawings.

Referring to FIG. 1 , FIG. 1 is an enlarged partial cross-sectional view of a fabric having a far infrared multi-layer thermocompression bonding (Tech-Mix) structure. The cloth 1 having the far-infrared multi-layer thermocompression bonding structure comprises: a first cloth layer 11, a first far-infrared ceramic material layer 12, a TPU gas-permeable film layer 13, and a second far-infrared ceramic. A material layer 14 and a second cloth layer 15.

In the fabric embodiment of the present invention, the first fabric layer 11 and the second fabric layer 15 are made of cotton, linen, nylon, polyester fiber, and elastic fiber. one. The first far-infrared ceramic material layer 12 and the second far-infrared ceramic material layer 14 respectively comprise a predetermined ratio: a resin, a foam stabilizer, a thickener, a bridging agent, and a ceramic powder. (With far infrared function).

In the present invention, the TPU gas permeable film layer 13 is coated with a solvent-based resin (wet microporous type) between the first far-infrared ceramic material layer 12 and the second far-infrared ceramic material layer 14, respectively, and The formulation of the resin coating liquid is as follows: Appearance: slightly viscous and translucent liquid; composition: polyester type water-based resin; ionic: anion; solid content: 40.0 ± 1.5% by weight; pH: 7.5 ± 1.0; organic solvent: acetone (less than 1% by weight); and stability: 5 to 40 ° C for at least 6 months.

Further adding the appropriate foam stabilizer to the resin, stirring at a high speed to make the foam ratio 3 to 5 times, adding the thickener and the bridging agent, and finally adding the ceramic powder (having a far infrared ray function) and continuously stirring at a high speed. After the coating, that is, the main material content of the first far-infrared ceramic material layer 12 and the second far-infrared ceramic material layer 14, respectively, the respective reference formula ratios are as follows: 1. Resin: 100 g; 2. Foam Stabilizer: 2~5g; 3. Thickener (as required): 1.0~2.0g; 4. Bridging agent: 3.0~5.0g; and 5. Ceramic powder: 10.0~20.0g.

That is, the first far-infrared ceramic material layer 12 and the second far-infrared ceramic material layer 14 are water-based glues formed by mixing a predetermined ratio of the resin and the ceramic powder. Type of adhesive, in order to adjust its variable degree of width (width / amount of glue), and heat and static electricity do not affect product stability, and further apply it to the TPU breathable film layer 13 and the lower two Between the surface and the first cloth layer 11 and the second cloth layer 15, the first cloth layer 11, the first far infrared ceramic material layer 12, and the TPU are sequentially ventilated by the thermocompression bonding method. The film layer 13, the second far-infrared ceramic material layer 14, and the second cloth layer 15 are combined into one, and the cloth 1 having a far-infrared multi-layer thermocompression bonding structure integrally formed by heat pressing is integrated.

The TPU gas permeable film layer 13 is a gas permeable film composed of a thermoplastic plastic TPU (Thermoplastic polyurethane), and the TPU gas permeable film is processed by calendering, casting, film blowing, coating, etc. In addition to environmental protection and non-toxicity, the film has excellent high tensile strength, wear resistance, tortuosity, acid and alkali resistance, superior weather resistance, etc. It is a non-toxic environmentally friendly material and a polymer. Elastomer, with wear-resistance, tensile strength, high temperature resistance, low temperature resistance and no cracking, can be applied to footwear, sporting goods, ready-to-wear, medical, leather bags, inflatable toys, mountaineering products, bicycles.. Etc., in response to the world's environmental awareness to replace PVC (PolyVinyl Chloride), its use is extensive, has been a large number use.

In the embodiment of the cloth having the far-infrared multi-layer heat-pressing bonding structure, the hot pressing process must match the melting temperature requirement of the TPU gas permeable film layer 13 between 70 and 120 ° C, and The hot pressing condition includes: 1. the pressing temperature range is 140~170 ° C; 2. the pressing time is 15~25 seconds; and 3. the hot pressing pressure is 2~5 kg/cm2.

In other words, the TPU gas permeable film layer 13 can pass through the first far infrared ceramic material layer 12 and the second far infrared ceramic material layer 14 and the first cloth layer 11 respectively under the condition of the thermal compression bonding. The second cloth layer 15 is subjected to hot press fusion to achieve a perfect perfect bonding, thereby ensuring that the far infrared ray ceramic powder can be uniformly distributed in the cloth by the method of hot pressing bonding, and the length can be avoided. Time use or the disadvantage of reduced far infrared ray performance caused by washing.

In summary, the fabric 1 having the far infrared multi-layer thermocompression bonding structure comprises: a first cloth layer 11, a first far infrared ceramic material layer 12, a TPU gas permeable film layer 13, and a second The far infrared ceramic material layer 14 and a second cloth layer 15. The first far-infrared ceramic material layer 12 is disposed under the first cloth layer 11, and the TPU gas-permeable film 13 is disposed below the first far-infrared ceramic material layer 12, the second far-infrared ceramic The material layer 14 is disposed below the TPU gas permeable film layer 13, and the second cloth layer 15 is disposed below the second far infrared ceramic material layer 14. The first cloth layer 11, the first far infrared ceramic material layer 12, the TPU gas permeable film layer 13, the second far infrared ceramic material layer 14, and the second cloth are sequentially arranged by conforming to a thermocompression bonding condition. The layer 15 combines five layers into one by hot pressing technology, and the far-infrared effect is continuously preserved in the fabric interlayer of the multi-layer structure, and the far-infrared effect is not reduced by long-term use or by washing the cloth.

The embodiments described above are not intended to limit the scope of application of the present invention. The scope of protection of the present invention should be based on the technical spirit defined by the content of the patent application scope of the present invention and the scope thereof. That is to say, the equal changes and modifications made by Dafan in accordance with the scope of application for patent creation will not lose the essence of this creation, nor will it deviate from the spirit and scope of this creation, so it should be regarded as the further implementation of this creation.

Claims (7)

A fabric having a far infrared multi-layer thermocompression bonding structure, comprising: a first cloth layer; a first far infrared ceramic material layer disposed under the first cloth layer; a TPU gas permeable film layer, The second far infrared ceramic material layer is disposed under the TPU gas permeable film layer; and a second cloth layer is disposed at the second side. a layer below the infrared ceramic material layer; wherein the first cloth layer, the first far infrared ceramic material layer, the TPU gas permeable film layer, the second far infrared ceramic material layer, and the second cloth layer are sequentially arranged It is a combination of hot pressing methods. The fabric of the far-infrared multi-layer thermocompression bonding structure according to the first aspect of the invention, wherein the material of the first fabric layer and the second fabric layer are cotton, linen, nylon, polyester fiber, respectively. And one of the elastic fibers. The fabric having the far-infrared multi-layer thermocompression bonding structure according to claim 1, wherein the hot pressing condition of the hot pressing method comprises: 1. the pressing temperature range is 140 to 170 ° C; The pressing time is 15~25 seconds; and 3. The hot pressing pressure is 2~5kg/cm ² . The fabric of the far-infrared multi-layer thermocompression bonding structure according to claim 1, wherein the main material content of the first far-infrared ceramic material layer and the second far-infrared ceramic material layer respectively comprise: A resin, a foam stabilizer, a thickener, a bridging agent, and a ceramic powder having a far infrared function. The fabric having the far-infrared multi-layer thermocompression bonding structure according to claim 4, wherein the resin is formulated as a slightly viscous translucent liquid, and is composed of a polyester resin, ionic. It is an anion with a solid content of 40.0 ± 1.5% by weight, a pH of 7.5 ± 1.0, and an organic solvent containing acetone of less than 1%. The fabric having the far-infrared multi-layer thermocompression bonding structure according to claim 4, wherein the resin is: 100 g; the foam stabilizer is: 2 to 5 g; and the thickener is 1.0. ~2.0g; the bridging agent system is: 3.0~5.0g; the ceramic powder system is: 10.0~20.0g. The fabric having the far-infrared multi-layer thermocompression bonding structure according to claim 1, wherein the TPU gas permeable film layer has a melting temperature range of 70 to 120 °C.