JP2019079714A - Planar heat generating cloth and manufacturing method thereof - Google Patents

Abstract

To provide a planar heat generating cloth capable of uniform heat generation even in a complicated shape, and can be used as a heat-generating element even when the cloth is cut into a free shape.SOLUTION: A planar heat-generating cloth includes a heat generating member 1 formed by impregnating a base material having continuous voids with a resin composition including a conductive material including carbon particles, metal particles, a metal oxide, and a conductive polymer, a first conductive cloth 2 laminated on one side of the heat generating member 1, and a second conductive cloth 3 laminated on the other side of the heat generating member.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a planar heat-generating fabric and a method for producing the same. More specifically, the present invention relates to a sheet-like heat-generating fabric that exhibits uniform heat build-up even with complicated shapes, and a method of manufacturing the same. Moreover, the planar heat-generating fabric of the present invention is characterized in that it can be used even if it is cut into a free shape.

  Conventionally, as a flexible planar heating element, it has an electrode (a cathode, an anode) made of metal or the like on a polymer film, and a relatively high electric resistance containing carbon particles etc. between the cathode and the anode. A heating element having a resin coating formed thereon has been used. However, when using conventional sheet-like heating elements in places that come in contact with the human body, such as clothes, chairs, and seats of vehicles, the use of a polymer film for the base causes problems of stuffiness and hardness. .

  It has been proposed to use a fabric as the base material as a method of solving the problems of the stuffiness and hardness of the planar heating element. For example, Patent Document 1 discloses a planar heating element in which an electrode portion and a heat generating portion are formed by printing and drying a conductive material and a resistor material in the form of ink on the surface of a base material. Patent Document 2 proposes a planar heating element including a heat generating portion formed of a fiber structure containing conductive fibers, and a conductive agent and a binder component as an electrode portion for energizing the heat generating portion. Further, according to Patent Document 3, a metal wire is sewn into an electroconductive sheet in which a resin containing an electroconductive powder is supported by a non-woven fabric, and the electroconductive sheet and the electrode are sandwiched by an insulating sheet. A planar heating element is disclosed.

  However, in the conventional planar heating element, an electrode is formed so as to sandwich the heat generating portion in the same plane with respect to the heat generating portion formed in a planar shape. That is, the direction in which the current flows when generating heat is the surface direction of the heat generating portion. In the case of such a planar heating element, if the shape of the heat generating portion is square, the distance between the electrodes becomes constant by providing the electrodes on two opposing sides, and uniform heat generation can be expected. On the other hand, when the shape of the heat generating portion is circular, it is difficult to obtain uniform heat generation even if the arrangement and shape of the electrodes are devised and formed. Moreover, even if it cut | judges in a free shape, the planar heating element which can be heated can not be obtained.

JP 2008-269914 A JP, 2013-191551, A JP 2007-184230 A

  The present invention provides a planar heat-generating fabric capable of uniform heat generation even in a complicated shape. In addition, the present invention provides a planar heat-generating fabric that can be used as a heat-generating element even when cut into a free shape.

  As a result of intensive investigations, the present inventors have found that, as long as the sheet-like heat generating fabric has a configuration in which current flows in the thickness direction, uniform heat generation can be obtained regardless of the shape, and the present invention is completed. It was up to you.

  That is, the planar heat-generating fabric of the present invention comprises a heat-generating member formed by impregnating a substrate having continuous voids with a resin composition containing a conductive material, and a first conductive layer laminated on one surface of the heat-generating member. It is a sheet-like heat generation cloth which has a sex cloth and the 2nd conductive cloth laminated on the other side of the heat generation member.

  It is preferable that the surface resistance value of the said heat-generating member is 100 ohms / square-60 k ohms / square.

  It is preferable that the surface resistance value of the said 1st conductive fabric and the said 2nd conductive fabric is 0.001 ohm / square-0.1 ohm / square.

  The conductive material is preferably a carbon particle, a metal particle, a metal oxide, or a conductive polymer.

  It is preferable that the said resin composition has a polyurethane resin and a urethane modified resin as a main component.

  In the method for producing a planar heat-generating fabric of the present invention, a substrate having continuous voids is impregnated with a resin composition containing a conductive material to obtain a heat-generating member, and one surface of the heat-generating member And laminating the second conductive fabric on the other surface of the heat generating member.

  According to the present invention, it is possible to obtain a sheet-like heat generating fabric which can obtain uniform heat generation even with a complicated shape. Moreover, even if it cut | disconnects in a free shape, the planar heat-generating cloth which can generate heat | fever is obtained.

It is sectional drawing which shows an example of the planar heating cloth of this invention. It is the photograph which image | photographed the heat-generation state of the planar heat-generating fabric of this invention. It is sectional drawing which shows an example of the planar heating cloth of this invention which has multiple heat-emitting part.

  The planar heat-generating fabric of the present invention has a heat-generating member in which a resin composition containing a conductive material is impregnated in a substrate having continuous voids. As a base material which has a continuous space | gap, the fabric etc. which are comprised from the foam which has an open cell, and various fibers are mentioned. Examples of foams having open cells include synthetic sponges made of synthetic resins such as urethane resins, melamine resins and synthetic rubbers, and natural sponges made of natural products such as sponges and natural rubbers. Among them, urethane resins and melamine resins are preferable because they are abundant in type and easy to obtain. As a method of manufacturing the foam which has an open cell using these resin materials, a foaming agent, mechanical stirring, a chemical reaction, etc. are mentioned.

  As fiber types constituting the fabric as a base material having continuous voids, synthetic fibers (polyamide, polyester, polyurethane, polyacrylic etc.), semi-synthetic fibers (acetate, triacetate etc.), regenerated fibers (rayon, cupra etc.) Natural fibers (cotton, hemp, wool, silk, etc.) are not particularly limited, but synthetic fibers are preferred from the viewpoint of strength and chemical resistance. Particularly preferred synthetic fibers include polyester, polyamide and the like. The form of the fibers may be monofilament yarn, multifilament yarn, spun yarn, covering yarn or the like. Examples of the form of the fabric include woven fabric (plain weave, twill weave, satin weave, etc.), knitted fabric (round knit, warp knit, etc.), non-woven fabric, and the like, and is not particularly limited.

  It is preferable that the thickness of the base material which has a continuous space | gap is 100 micrometers-1 mm. When the thickness of the substrate is in the range of 100 μm to 1 mm, sufficient heat buildup can be expressed. In addition, it is possible to obtain a sheet-like heat generating cloth with high flexibility.

  The heat-generating member in the present invention is configured by impregnating a resin composition containing a conductive material with respect to the base having the continuous void. That is, the resin composition containing the conductive material has penetrated into the continuous voids present inside the substrate. The resin composition is applied to fill the continuous voids of the substrate. Thereby, the heat generating member can obtain conductivity in the thickness direction. The heat-generating member of the present invention preferably has conductivity of 1 to 6,000 Ω · cm in the thickness direction.

  Examples of the conductive material contained in the resin composition include particulate materials made of a material having conductivity, such as carbon particles, metal particles, carbon nanotubes, metal oxides, and conductive polymers. Examples of metal particles include silver particles, copper particles, nickel particles, and aluminum particles. The particle diameter of the conductive material is preferably 0.1 μm to 10 μm. If the particle size is within this range, the conductive material is likely to penetrate into the continuous voids of the substrate. As a result, a heat generating member having uniform conductivity can be obtained.

  It is preferable that the content rate of the said electroconductive material in the said resin composition is 5 mass%-20 mass%. If the content of the conductive material is within this range, the above-described conductivity can be imparted to the heat-generating member.

  What disperse | distributed the said electroconductive material to the resin component is a resin composition used by this invention. Examples of the resin component used herein include synthetic resins such as acrylic resin, urethane resin, polyester resin, silicone resin, epoxy resin, melamine resin, and polyamine resin, and natural resins such as natural rubber, dammar and mastic.

  The resin composition of the present invention may contain, in addition to the conductive material and the resin component, a solvent and other additives. As the solvent, water, alcohol, ester and the like can be mentioned. Other additives include a dispersion stabilizer, a viscosity modifier, an antifoamer, and the like.

  In the present invention, the first conductive cloth and the second conductive cloth (both collectively and simply described as a conductive cloth) are respectively laminated on both surfaces of the heat-generating member and function as electrodes (FIG. 1). The conductive fabric may be a fabric woven and woven using conductive fibers. Alternatively, the fabric made of non-conductive fibers may be provided with conductivity by processing. Examples of the conductive fiber include carbon fiber, metal fiber and the like. Furthermore, fibers in which carbon particles and metal particles are mixed and fibers made of a conductive polymer material such as polyaniline, polythiophene and polypyrrole can be mentioned. Examples of processing for imparting conductivity to a fabric made of nonconductive fibers include metal deposition processing and metal plating processing. Among these, a conductive fabric in which metal plating is applied to a fabric made of non-conductive fibers is preferable in that a conductive fabric having an extremely low surface resistance can be obtained. A metal-plating process is beforehand performed to the nonelectroconductive fiber, and the electroconductive fabric formed using this is also mentioned as a preferable aspect.

  The non-conductive fibers constituting the fabric are not particularly limited, and synthetic fibers (polyamide, polyester, polyurethane, polyacrylic etc.), semi-synthetic fibers (acetate, triacetate etc.), regenerated fibers (rayon, cupra etc.), natural Fibers (cotton, hemp, wool, silk etc) can be used. Among them, synthetic fibers having high resistance to chemicals used in metal plating are preferable. In addition, polyester and polyamide are preferable in terms of strength and versatility.

  Examples of the metal used in the metal plating include at least one metal selected from the group consisting of copper, nickel, tin, silver and gold or an alloy thereof (for example, an alloy of copper and tin). Copper and silver are particularly preferred.

  The conductive fabric of the present invention preferably has a surface resistance value of 0.001 Ω / □ to 0.1 Ω / □. If the surface resistance value is within this range, it is possible to obtain a planar heat-generating fabric capable of uniform heat generation.

  A bonding member may be disposed at the boundary between the laminated heat generating member and the conductive cloth. As a joining member, a material with very low contact resistance is preferable. Specific examples of the bonding member include adhesives such as solder, conductive adhesive and anisotropic conductive adhesive, and so-called hot melt materials such as polyurethane, ethylene vinyl acetate and polyester. The contact resistance value is preferably 1 mΩ to 100 mΩ. If the contact resistance is within this range, the electrical connection between the heat-generating member and the conductive fabric becomes sufficient, and uniform and efficient heat generation becomes possible.

  In the present invention, as shown in FIG. 1, the first conductive fabric, the heat generating member, and the second conductive fabric are laminated in this order. It is preferable that the first conductive cloth, the heat-generating member, and the second conductive cloth have substantially the same shape and that their outlines overlap and be laminated so as not to protrude. According to this, it is possible to prevent the heat generation failure at the outer edge portion of the sheet-like heat generation fabric.

  In order to cause the sheet-like heat generating fabric of the present invention to generate heat, a voltage is applied to the first conductive fabric and the second conductive fabric from an external power source. Although the conducting wire for applying a voltage is connected to each conductive fabric, the method is not particularly limited. The wire may be sewn to the conductive fabric or may be adhered by a conductive adhesive. It may be connected using low temperature solder.

  Since the sheet-like heat generating fabric of the present invention is configured as a conductive cloth sandwiching the heat generating member from both sides thereof, current flows in the thickness direction of the sheet-like heat generating fabric. Therefore, the path of the current flow in each part of the sheet-like heat generating fabric has a constant length and a small variation. Therefore, uniform heat generation is possible. This effect is independent of the shape of the planar heat-generating fabric, and even if it is a complicated shape, uniform heat generation is possible. In addition, as long as the three-layer structure of the first conductive fabric / the heat generating member / the second conductive fabric is held, it can function as a planar heat generating fabric even if it is cut into a free shape.

  The method for producing a planar heat-generating fabric according to the present invention comprises the steps of: impregnating a substrate having a continuous void with a resin composition containing a conductive material to obtain a heat-generating member; And a step of laminating a conductive cloth, and a step of laminating a second conductive cloth on the other surface of the heat generating member.

  As a method of impregnating the resin composition containing a conductive material in a base material having a continuous void, a dip-nip method, a coating method, a spray method, an immersion method, a printing method and the like can be mentioned. The dip-nip method and the immersion method are preferred in that the resin composition can be uniformly applied to the internal voids of the substrate. After the base material is impregnated with the resin composition, the solvent can be removed by heating as required. Thus, the heat generating member in the present invention is obtained.

  As a method of laminating the first conductive fabric on one surface of the heat-generating member obtained in the above process, a method using an adhesive material can be mentioned. When the base material which comprises a heat-generation member is a material which has thermoplasticity, it can also be laminated | stacked by the method of what is called heat sealing which heats and fuses the surface of a heat-generation member, and superimposes a 1st conductive fabric. Moreover, when the resin composition used at the said process has adhesiveness, it can laminate | stack and adhere a 1st conductive fabric, without using an adhesive material in particular.

  The method of laminating the second conductive fabric on the other surface of the heat generating member is the same as the method of laminating the first conductive fabric.

  The planar heat-generating fabric of the present invention can be in other forms as long as it has the technical features. For example, a resin composition containing a conductive material may be applied in a pattern to a base material having continuous voids, and a heat generating portion in the heat generating member may be formed in a pattern (see FIG. 3). A first conductive cloth and a second conductive cloth covering the entire heat generating member are laminated on both sides of such a heat generating member. According to this, it is possible to generate heat uniformly in a pattern having a plurality of heat generation parts by only one pair of connections with the power supply.

EXAMPLES The present invention will be described by way of examples, but the present invention is not limited by these examples.
The evaluation method of various physical properties in this example is as follows.

<Heat buildup>
A lead is connected to each of the first conductive fabric and the second conductive fabric of the heat-generating fabric, voltage is applied, and the surface temperature of the planar heat-generating fabric is measured by infrared thermography (model FLIR C2 manufactured by FLIR SYSTEMS, Inc.) Observed. The surface temperature rise value when 9 V voltage is applied is measured with analysis software (FLIR Tools, manufactured by FLIR Systems), and the average value and standard deviation are calculated to evaluate heat generation and uniformity of heat generation. (See Figure 2).

<Surface resistance value, volume resistivity>
The surface resistance value of the heat generating member was measured with a resistivity meter (Loresta EP MCP-T360, manufactured by Mitsubishi Chemical Analytech Co., Ltd.). Further, the thickness of the heat generating member was measured by a digital thickness gauge, and the volume resistivity of the heat generating member was calculated from the product of the measured surface resistance value and the thickness of the heat generating member.

Example 1
A polyester knitted fabric with a thickness of 0.5 mm was prepared as a substrate having continuous voids. A resin composition containing carbon particles as a conductive material and containing a polyurethane resin as a main component (PUR120-1W, manufactured by Carbo-Therm Co., Ltd.) diluted 5 times with water is applied to the entire surface of the substrate by the immersion method. Granted. Subsequently, drying was performed at 100 ° C. for 30 minutes to obtain a heat generating member. The applied amount was 0.006 g / cm ² in dry weight. The surface resistance value of the heat generating member obtained was 1.5 kΩ / □, and the volume resistivity was 75 Ω · cm. Conductivity obtained by plating two metal layers of copper and silver on a polyester plain weave fabric (vertical: polyester wooly yarn 30d / 36f 189 / inch, horizontal: polyester wooly yarn 62d / 150f 120 / inch) Two pieces of the fabric were prepared. The surface resistance value of this conductive fabric was 0.02 Ω / □. This conductive fabric is stacked on one side of the heat-generating member via a hot melt sheet (Easelan SHM 101, manufactured by Ceddam Co., Ltd.) made of polyester-based polyurethane, and adhered by thermocompression bonding (130 ° C., 0.5 MPa, 30 sec). Stacked. Similarly, a conductive cloth was laminated on the other surface of the heat generating member to obtain a planar heat generating cloth of the present invention. The obtained sheet-like heat-generating fabric was cut into a square of 3 cm × 3 cm, and the heat generation was evaluated. As a result, the heat generation was highly uniform with an average of 35.3 K (Kelvin) and a standard deviation of 0.80.

Example 2
The heat-generating property was evaluated by cutting the sheet-like heat-generating fabric obtained in Example 1 into a star shape. As a result, it showed a highly uniform heat buildup with an average of 35.4 K and a standard deviation of 1.19.

[Example 3]
The heat-generating property was evaluated by cutting the sheet-like heat-generating fabric obtained in Example 1 into a circular shape. As a result, it showed a highly uniform heat buildup with an average of 35.3 K and a standard deviation of 0.67.

[Comparative example]
As a fabric, a polyester plain woven fabric having a weave density of 159 yarns / inch of warp composed of polyethylene terephthalate fiber (56 dtex / 72f), a weave density of weft of 120 yarns / inch, and air permeability of 38 cm ³ / cm ² · s was used. PUR120-1W was circularly coated on this fabric by screen printing. Subsequently, drying was performed at 100 ° C. for 30 minutes to form an exothermic film having a film thickness of 30 μm. Subsequently, opposing arc-shaped electrodes were formed in such a manner as to sandwich the above-mentioned circular heating film on the same plane, to obtain a planar heating cloth. The electrode was coated by screen printing using a resin composition (PE 873, manufactured by DuPont) containing silver particles as conductive particles. The heat generation property of the obtained planar heat-generating fabric was evaluated, and as a result, no uniformity was observed with an average of 33.1 K and a standard deviation of 8.89.

  The planar heat-generating fabric of the present invention can generate uniform heat even if it has a complicated shape. Moreover, it is a planar heating cloth which can be used as a heating element even if it is cut into a free shape. Such a sheet-like heat-generating fabric of the present invention has the effect of warming those which are in contact with each other as well as those which are close to each other by radiant heat, and can be used for clothing, industrial materials, medical / welfare devices, etc. It can be suitably used.

1: Heating member 2: First conductive fabric 3: Second conductive fabric 4: Base material

Claims (6)

  A heat generating member formed by impregnating a substrate having a continuous void with a resin composition containing a conductive material, a first conductive fabric laminated on one surface of the heat generating member, and the other of the heat generating member A planar heat-generating fabric having a second conductive fabric laminated on a surface.   The surface heating value of the said heat-generating member is 100 ohms / square-60 k ohms / square, The planar heat-generating fabric of Claim 1 characterized by the above-mentioned.   The planar heat-generating fabric according to claim 1 or 2, wherein the surface resistance value of the first conductive fabric and the second conductive fabric is 0.001 Ω / □ to 0.1 Ω / □. .   The sheet-like heat generating fabric according to any one of claims 1 to 3, wherein the conductive material is a carbon particle, a metal particle, a metal oxide, or a conductive polymer.   The sheet-like heat generating fabric according to any one of claims 1 to 3, wherein the resin composition contains a polyurethane resin and a urethane-modified resin as main components.   A step of impregnating a substrate having a continuous void with a resin composition containing a conductive material to obtain a heat generating member, a step of laminating a first conductive cloth on one surface of the heat generating member, and the heat generating member And laminating the second conductive fabric on the other side of the sheet.

Images