JPH0219571A - Heat-retentive cloth - Google Patents

Abstract

PURPOSE:To obtain the title cloth capable of raising cloth temperature by laminating the surface of a cloth containing a near infrared ray-absorptive substance capable of absorbing rays falling within the specified wavelength range with a resin or film containing a substance of specific infrared emissivity. CONSTITUTION:The objective cloth can be obtained by laminating the surface of a cloth made of fiber incorporated with a near infrared ray-absorptive substance capable of absorbing rays falling within the wavelength range 700-2,000mum with a resin or film containing a substance >=0.4 in infrared emissivity (e.g. siliconium) (e.g. moisture-permeable film of polyurethane resin).

Description

[Detailed description of the invention] (Industrial application field) The present invention relates to a heat retaining fabric.

(Prior art) Conventionally, fabrics such as knitted fabrics and non-woven fabrics have been made by increasing the thickness of the fabric itself in order to improve its heat retention properties, and by raising the surface of the fabric to increase the air content of the fabric. It was known.

However, since these fabrics are thick, they have disadvantages such as being heavy and being bulky due to raised naps, and their uses are limited. On the other hand, there are known methods of increasing heat retention by coating a fabric with a resin or laminating a film. These methods lower the breathability of the fabric to reduce heat loss due to convection and increase heat retention.

Furthermore, resins and films containing metal powders such as aluminum have also been used. In addition to lowering breathability, this method uses the property of metal powder to have a high reflectivity against radiant heat from the body to increase heat retention inside clothing.

Furthermore, in the combination of resin or film and metal powder, ceramic powder is also used instead of the metal powder. In this case, the radiant heat from the body of the ceramic powder (
It is thought to be a heat retention method that utilizes radioactivity (far infrared, etc.).

Thermal properties such as radioactivity are determined by the composition of the ceramic itself, and ceramics with high radiation characteristics are generally selected.

However, when fabrics coated or laminated with these metal powders and ceramics are used on the inside of clothing, the resin containing these metal powders and ceramics can only utilize radiant heat from the human body. There are limits to its heat retention.

(Object of the Invention) An object of the present invention is to provide a heat-retaining fabric that can actively store heat such as solar radiation from the surface of the fabric and more efficiently radiate heat into the inside of clothing. be.

(Structure of the Invention) The present invention provides a resin containing a substance with an infrared emissivity of 0.4 or more on the surface of a fabric containing a near-infrared absorbing substance having an absorption ability in a wavelength range of 700 millimicrons to 2000 millimicrons. Alternatively, it is a heat-retaining fabric characterized by being laminated with films.

Near-infrared absorbing substances having absorption ability in the wavelength region of 700 mμ to 2000 mμ used in the present invention include anthoraquinone compounds and naphthalocyanine compounds.

Metal complex compounds are effectively used.

In order to obtain a fabric containing such a near-infrared absorbing substance, the following steps can be taken: (1) After blending the near-infrared absorbing substance with a synthetic fiber polymer, it is made into fibers by a conventional method, and this fiber is used in whole or in part. It is obtained by weaving and knitting in the usual way, and dyeing and finishing as necessary.

(2) It is obtained by immersing a fabric in water or a solvent containing the near-infrared absorbing material and adsorbing it.

In this case, the adsorption treatment may be performed simultaneously with normal dyeing, or before or after dyeing.

In the case of fabrics containing thermoplastic synthetic fibers, instead of adsorption treatment in water or a solvent, it is also possible to perform adsorption using a combination of padding treatment and heat treatment.

(2) This is a method in which the material is adsorbed by thread or linear treatment, and then dyed and processed in the same manner as in (2) using fabrics and pears in the usual manner.

The present invention provides these fabrics with an infrared emissive substance.The substances used in the present invention with an infrared emissivity of 0.4 or more include silicon oxide and silicon oxide.

Metal oxides such as titanium oxide, silicon carbide.

Metal carbides such as silicon carbide, titanium oxide, various ceramics, etc. can be used alone or in combination. Also,
To apply these infrared emitting substances to fabrics containing near-infrared absorbing substances, coating methods and film lamination methods are used, but urethane-based resins are used for such coatings and film laminations. Resins and acrylic resins are commonly used.

Infrared emitting substances can be blended with the resin in the case of resin coatings, pre-blended with the film-making resin and placed in the film layer in the case of film laminates, or blended with the adhesive and placed in the adhesive layer. Should I put it in?
More preferably, it can be included in both the film layer and the adhesive layer.

In addition, when used for general clothing, especially resin layers,
The film layer preferably has good moisture permeability from the viewpoint of wearing comfort.

(Action of the invention) When the fabric obtained by the present invention is used outdoors under sunlight with a large amount of near-infrared rays, the temperature of the fabric increases first due to the influence of the near-infrared absorbing substance. As the temperature of the fabric increases, the temperature of the resin layer or the film layer increases, heat radiation from the ceramic increases, and the temperature of the back surface of the fabric increases.

The fabric of the present invention can be used as an excellent clothing material that has both heat-absorbing and heat-radiating properties by utilizing such properties. Furthermore, when the fabric of the present invention is used as a material for a futon with padding or as a clothing member with batting, the heat retention property is further increased by combining the excellent heat storage effect of the batting.

The fabric of the present invention can be used not only for ordinary dyeing, but also for various treatments such as water repellency, electric shock treatment, dark dyeing, etc. as necessary, and can be used as outdoor clothing. In such cases, it is particularly desirable to improve waterproofness by water-impregnation treatment. Hereinafter, the present invention will be explained in detail with reference to Examples.

(Example 1) A plain weave fabric using polyester false twisted yarn (75 denier/72 filaments) for the warp and weft was fabricated with a warp density of 1.
87/3.79 (Im, weft richness 140/3.
790, and the woven fabric was relaxed and scoured in a conventional manner, and then dry-set to obtain a base fabric.

Next, IRQ-750 was added to the base fabric as a near-infrared absorbing material.
(Maximum absorption wavelength is 700 millimicrons, manufactured by Nippon Kayaku Co., Ltd.)
Using a 30% aqueous dispersion, process with a dyeing machine so that 4% of the weight of the base fabric adheres (temperature 130℃ x time 60 minutes)
I did it.

After drying the obtained treated fabric (green), a fluorine-based water grinding agent (
A wansui process was performed using a padding method using a 5% aqueous solution of Asahi Guard AG 710 (manufactured by Asahi Glass Co., Ltd.). Furthermore, compression processing is performed using a thermal calendar at a temperature of 160°C to obtain a raw fabric.

A moisture permeable film made using a polyurethane resin shown in Table 1 was laminated onto the raw fabric using an adhesive having a composition shown in Table 2 to obtain a fabric of the present invention.

For comparison, IRQ-750 was used instead of IRQ-750 on the base fabric.
Deeper Blue K is a disperse dye that does not have a maximum absorption wavelength in the wavelength range of 0 mm to 2000 mm.
(manufactured by Ciba Geigy) Diamond Blue ACE (
(Manufactured by Mitsubishi Chemical Industries, Ltd.), Diamondx Yellow ACE
(manufactured by Mitsubishi Kasei Corporation), each at 0.5% based on the weight of the fabric,
A film having the composition shown in Table 1 was applied to a dyed base fabric that was dyed using 0.14% and 0.24% to the same hue density as the original fabric, and subjected to water repellent treatment and calender treatment in the same way as the original fabric. A fabric of Comparative Example 1 was obtained using the adhesive shown in Table 2.

Furthermore, for comparison, a film using the resin composition shown in Table 1 with the silicon carbide powder removed was used for the raw fabric, and a film using the adhesive resin composition shown in Table 2 with the silicon carbide powder removed was used as the base fabric. The fabric of Comparative Example 2 was obtained by laminating with an adhesive.

Table 1 Resin composition for film making Lisbon 3314 Lisbon Assister 5D-17 Additive Np, 10 Isopropyl alcohol Toluene Silicon carbide powder 100 parts (manufactured by Dainippon Ink Co., Ltd.) 3.3 parts (horn) 0.5 parts (/7 ) 12 parts, 12 parts, 13 parts (manufactured by Nihon Shinkinzoku Co., Ltd.) After irradiation for 10 minutes, the temperature of the back surface of each fabric was actually measured by contacting it with the surface using a temperature sensor. Table 3 shows the results.

Table 3 Table 2 Adhesive resin composition Lisbon 4260 Crisbon 4070 Soltex CL-45 Accel T Toluene dimethyl formaldehyde silicon carbide powder 50 parts (manufactured by Dainippon Ink Co., Ltd.) 50 parts (11) 15 parts (J/ ) 1.5 parts ()I) 70 parts, 10 parts, 5 parts (manufactured by Nippon Shinkinzoku Co., Ltd.) Furthermore, using the raw cloth without film lamination as Comparative Example 3, a sunlight lamp D 400 manufactured by Toshiba ■, which has a wavelength distribution close to that of sunlight, was used. Of course, the one according to Example 1 using
It is also superior to those containing either a near-infrared absorbing substance or an infrared emitting substance (Comparative Example 1 and Comparative Example 2).

(Example 2) The fabric of the present invention produced by the method shown in Example 1 was used for geodetic measurements, and the filling was Isaac ID-80k (manufactured by Yojin ■).
(Example 2) and Comparative Example 1 for comparison.
For geodetic measurements, a fabric made of a special fabric was used for geodetic measurements, and the fabric used in Example 2 (Comparative Example 5) was used as the filling, and the fabric was left under sunlight for 60 minutes, during which time the temperature of the filling was measured using a temperature sensor. It was measured using

The measured temperature was 43° C. for Example 2 and 35° C. for Comparative Example 5, indicating that the futon using the fabric of the present invention had excellent heat absorbing properties.

Claims (1)

[Claims] A resin or film containing a substance with an infrared emissivity of 0.4 or more is laminated on the surface of a fabric containing a near-infrared absorbing substance that has an absorption ability in the wavelength range of 700 mm to 2000 mm. A heat-retaining fabric characterized by