KR100298046B1 - Far Infrared Radial Fiber Fabric Manufacturing Equipment And Manufacturing Method - Google Patents

Abstract

The present invention relates to a device for producing far-infrared radial fiber fabrics, and a method for manufacturing the same. In particular, in the manufacture of various clothes, cushions, sheets, a far-infrared radiation coating material obtained by mixing an appropriate amount of ocher, pine needles, wormwood, and bioceramic with an oily or aqueous adhesive Applying and fixing in the form of unevenness only on the whole or one side of the fabric used, and contact with various clothes, cushions, and sheets made of this fabric can promote blood circulation of the human body and obtain therapeutic effects such as neuralgia, arthralgia and back pain Of course, it can prevent the occurrence of allergic skin diseases, block electromagnetic waves and water veins, remove the poison in the human body through the generation of purification and degrading power, freshness due to the smell of herbal medicine and It is to improve freshness through the lack of oxygen supply.

Description

Far Infrared Radial Fiber Fabric Manufacturing Apparatus and Manufacturing Method Thereof

The present invention relates to a far-infrared radial fiber fabric manufacturing apparatus and a method for manufacturing the same, and more particularly, to a variety of clothes, cushions, sheets of the far-infrared radiation coating material obtained by mixing an appropriate amount of ocher and pine needles, mugwort and bioceramic to an oily or aqueous adhesive It is applied to the whole fabric used for manufacturing or in the form of unevenness, and when it comes into contact with various clothes, cushions, and sheets made of this fabric, it promotes blood circulation of the human body, thereby treating the effects of neuralgia, joint pain and low back pain. It can of course prevent the occurrence of allergic skin diseases, block the electromagnetic waves and water veins, remove the poison in the human body through the generation of purification and degrading power, It is invented to enhance the freshness through the freshness and the smoothness of oxygen supply.

In general, various textile papers used as textile fabrics are fabric processed using yarn, spinning, twisted yarn, etc., and most of the textile papers used in the manufacture of various garments are mechanical, durable, hygienic, and decorative. And sensory performance.

However, such a fabric is not only to maintain the beauty through coloring and various designs, there is a problem such as allergic skin diseases caused by static electricity, and also can not block the electromagnetic waves and water veins, and thus prevent damage There are problems such as not being able to.

On the other hand, in loess and bio-ceramic, far-infrared rays are radiated, so when they are brought close to the human body, the physiological action of the cells is actively performed, and harmful substances are released due to the generation of thermal energy, which has a photoelectric effect. Decomposition is generated to perform the function of removing the poison present in the human body, and also performs the function of blocking electromagnetic waves and water veins.

In this case, the far infrared rays are a kind of electromagnetic waves, and all materials emit infrared rays while generating heat above the absolute temperature (-273 ° C. 0 ° C. K).

In addition, far-infrared rays are less likely to reflect or scatter particles in the atmosphere than ultraviolet rays or visible rays, so they penetrate the air well and are well absorbed by the target object, thereby providing electrical resonance and self-heating to molecules of the object. It is also raised.

In addition, the far-infrared rays radiated from ocher and bio-ceramic have the effect of activating energy generating molecules by resonance absorption phenomenon caused by the vibration of radiation penetration force molecules. There is a photoelectric effect to emit harmful substances by generating a.

In addition, it is excellent in purifying and degrading power, and has various effects such as neutralizing toxicity and enhancing sleep effect.

Nevertheless, in the past, devices and methods have not been developed that can apply such loess or bioceramic to textile fabrics used for weaving clothes, cushions and sheets.

The present invention has been made in order to solve the above problems, the fiber used in the manufacture of various clothes, cushions and sheets of far-infrared radiation coating material mixed with an appropriate amount of ocher and pine needles, mugwort and bioceramic to an oily or aqueous adhesive It can be applied to the whole fabric or in the form of irregularities on its surface to promote blood circulation and metabolism of the human body, and can also obtain therapeutic effects such as neuralgia, arthralgia and low back pain. Not only can it prevent, but also it can block electromagnetic waves and water veins, it can remove poisons in the human body through the generation of purification and decomposing power, and maintain fresh environment all the time through the odor and oxygen supply of herbal medicine The purpose of the present invention is to provide a far-infrared radial garment fabric manufacturing apparatus and a method of manufacturing the same. The.

An object of the present invention described above, the coating unit for applying the far-infrared radiation coating material by mixing an appropriate amount of ocher and pine needles, mugwort and bioceramic to the oily or aqueous adhesive on the whole or the surface of the fiber fabric transported at a predetermined speed; A hot wind generator that heats outside air and blows it to a drying unit; A drying unit for drying the far-infrared radiation coating material through the hot air blown from the hot air generator to fix the fiber to the fabric; A far-infrared radiation coating material can be achieved by constructing a winding portion for winding up the applied and dried fiber fabric.

Therefore, far-infrared rays are generated from the fiber fabrics used in the manufacture of clothing, cushions, sheets, etc., as well as the smell of the herbal medicines, which promotes blood circulation and metabolism of the human body, thereby obtaining therapeutic effects such as neuralgia, arthralgia, and back pain. It can of course prevent the occurrence of allergic skin diseases, block electromagnetic waves and water veins, remove the poison in the human body through the generation of purification and degrading power, and supply the smell and oxygen of herbal medicine The willingness to maintain a fresh environment all the time.

1 is a schematic structural diagram according to an embodiment of the device of the present invention;

Figure 2 is a cross-sectional plan view of the main portion cut in accordance with an embodiment of the present invention.

Figure 3 is an enlarged side view of the applicator of the embodiment of the present invention.

4 is a schematic structural diagram according to another embodiment of the device of the present invention;

* Explanation of symbols for main parts of the drawings

1: Fiber Fabric Supply Part 2: Heating Roller

3: coating part 4: drying part

5: hot air generator 6: winding part

7: press roller 8: fiber fabric

9: coating material 10: control part

31: cylinder 32: electromagnetically modified nozzle

33: coating roller 41: rectangular box body

42,43: Inlet and Outlet 44,61: Children Roller

45: warmth distribution plate 46: warmth exhaust hole

47: pipe connection 51: suction pipe

52: warmth discharge pipe 53: boiler

54: blower 62: winding roller

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows a schematic block diagram according to an embodiment of the device of the present invention, Figure 2 shows a cutaway plan cross-sectional view according to an embodiment of the device of the present invention, Figure 3 is an embodiment of the device of the present invention An enlarged side view of the coating part is shown.

According to this, the fiber fabric supply unit (1) for rotatably placing the fiber fabric (8) rolled in a roll form having a predetermined width and diameter to be supplied sequentially from the front end portion;

A heating roller (2) for laying down the woolen present on the surface of the fiber fabric (8) supplied from the fiber fabric supply unit (1) by thermal pressure;

Coating material 31 having a predetermined volume and installed at regular intervals at the bottom of the cylinder 31 and opened and closed at regular time intervals in response to a signal output from the controller 10 and contained in the cylinder 31. It is provided with several electromagnetically modified nozzles (32) for discharging a predetermined amount (9), and is installed above the fiber fabric feed path to discharge the coating material (9) in the form of dots on the surface of the fiber fabric (8). An applicator 3;

The fiber fabric 8 is formed at the both ends of the rectangular box-shaped body portion 41 rotated 90 [deg.] To the right, and the outlets 42 and 43 are formed therein so as to move in the flat state of the fiber fabric. While installing several idler rollers 44 in the horizontal direction, at the bottom of the idler rollers 44 is provided with a warm air distribution plate 45 having several warmer discharge holes 46 and a hot air generator below. Far-infrared radiation through the hot air blown from the hot air generator (5) is installed in the rear portion of the applicator (3) having a configuration in which the pipe connector (47) connected to the warm air discharge pipe (52) A drying unit 4 for drying the coating material 9 and fixing it to the fiber fabric 8;

A suction pipe 51 for guiding the outside air, a warmer discharge pipe 52 installed between the main body portion and the pipe connector 47 of the drying unit 4, a boiler 53 using gas as a fuel, and air A hot air generator (5) having a blower (54) for forcibly suctioning and blowing the air and forcing the outside air to be forced into the drying unit (4);

It is provided with the elasticity adjusting means of the fiber fabric (8), several idle rollers (61) and winding rollers (62), and are installed at the rear of the drying unit (4), and the far-infrared radiation coating material (9) is applied and dried. It is characterized by consisting of a winding portion 6 for winding the fiber fabric (8).

In addition, Figure 4 shows a schematic configuration diagram according to another embodiment of the present invention, according to this, the fiber fabric 8, which has a predetermined width and diameter and is wound in a roll form, is rotatably placed in order from the leading end thereof. A fiber fabric supply unit 1 for supplying;

A fiber fabric having a cylinder 31 having a volume in which a predetermined volume of the coating material 9 can be stored, and an application roller 33 installed at the bottom of the cylinder 31 and supplied into the cylinder 31. An applicator 3 which coats the coating material with the whole of (8);

A pair of pressing rollers 7 for pressing the coating material 9 which is randomly buried while passing through the coating part 3 to have a predetermined thickness on the upper and lower surfaces of the fiber fabric 8;

The fiber fabric 8 is formed at the both ends of the rectangular box-shaped body portion 41 rotated 90 [deg.] To the right, and the outlets 42 and 43 are formed therein so as to move in the flat state of the fiber fabric. While installing several idler rollers 44 in the horizontal direction, at the bottom of the idler rollers 44 is provided with a warm air distribution plate 45 having several warmer discharge holes 46 and a hot air generator below. Far-infrared radiation through the hot air blown from the hot air generator (5) is installed in the rear portion of the applicator (3) having a configuration in which the pipe connector (47) connected to the warm air discharge pipe (52) A drying unit 4 for drying the coating material 9 to fix the upper and lower surfaces of the fiber fabric 8;

A suction pipe 51 for guiding the outside air, a warmer discharge pipe 52 installed between the main body portion and the pipe connector 47 of the drying unit 4, a boiler 53 using gas as a fuel, and air A hot air generator (5) having a blower (54) for forcibly suctioning and blowing the air and forcing the outside air to be forced into the drying unit (4);

It is provided with the elasticity adjusting means of the fiber fabric (8), several idle rollers (61) and winding rollers (62), and are installed at the rear of the drying unit (4), and the far-infrared radiation coating material (9) is applied and dried. It is characterized by consisting of a winding portion 6 for winding the fiber fabric 8 in the form of a roll.

On the other hand, one embodiment of the method of the present invention comprises: a woolen laying step of laying down the woolen on the fiber fabric (8) supplied from the fiber fabric supply unit (1) by thermal pressure;

A coating material application step of applying the coating material 9 in the form of dots on the upper surface of the moving fiber fabric with a constant moving speed in a state in which the cows are laid down;

A drying step of drying and fixing the coating material 9 applied in the form of dots on the fiber fabric 8 by forcibly blowing hot air;

It is characterized in that the far-infrared radiation coating material (9) is made of a winding process for winding the fiber fabric (8) which is applied and dried and discharged.

At this time, the coating material 9 is used by mixing the appropriate amount of ocher and pine needles, mugwort and bioceramic to the oily or aqueous adhesive, in one embodiment of the method of the present invention, the oily adhesive per yard of the fiber fabric (8) 10 l of ocher 30g, pine needles 15g, mugwort 15g, bioceramic 30g is mixed or used in 10l of water water-based adhesive 40g, ocher 30g, pine needles 15g, mugwort 15g, bioceramic 30g.

In addition, another embodiment of the method of the present invention, the coating step of burying the coating material (9) in the whole fiber fabric (8) supplied at a constant moving speed from the fiber fabric supply unit (1);

A coating amount pressurizing step of pressing the coating material 9 randomly buried on the fiber fabric 8 to a predetermined pressure to have a predetermined thickness on the upper and lower surfaces of the fiber fabric 8;

A drying step of drying and fixing the coating material 9 applied to the whole of the fiber fabric 8 by forcibly blowing hot air;

The far-infrared radiation coating material 9 is applied and dried, and is characterized in that the winding step of winding the fiber fabric 8 discharged in the form of a roll.

The coating material (9) used in this embodiment is produced by mixing 20 l of ocher, 30 g of pine needles, 30 g of wormwood, 60 g of bioceramic to 20 l of an oily adhesive per yard of the fiber fabric 8, or aqueous 20 l of water. 80g adhesive, 60g ocher, 30g pine needles, wormwood 30g, the ratio of bioceramic 60g is produced and used.

The present invention as described above can be largely divided into two, the first is the coating material (9) made by mixing the appropriate amount of ocher and pine needles, mugwort and bioceramic to oily or aqueous adhesive only on the surface of the fiber fabric (8) It is to apply in the form of spots, and the second is to apply the coating material (9) to a predetermined thickness throughout the fiber fabric.

In the first embodiment, in order to apply the coating material 9 to the surface of the fiber fabric 8 in the form of dots, the coating part 3 is provided with a predetermined volume of the cylinder 31 and several electron valves at the bottom of the cylinder 31. The nozzles 32 are formed in a configuration in which the hairs are present on the fiber fabric 8 so that the coating material 9 is applied in the form of dots on the fiber fabric 8 in which the hairs are present. In this case, the dot shapes are not kept as they are due to the hairs formed on all the fiber fabrics 8.

Therefore, in this case, a heating roller 2 is installed between the fiber fabric supply unit 1 and the application unit 3 to form a wool present on the surface of the fiber fabric 8 supplied from the fiber fabric supply unit 1. Let it lie down by heat pressurization.

Of course, in the case of applying the coating material 9 to the entire fiber fabric 8 as in the second case, it is not necessary to lay the wool of the fiber fabric, so the installation of the heating roller is omitted.

However, in the case of the second embodiment, unlike the first embodiment, so that the coating material 9 can be applied to the entire fiber fabric 8, it is locked in the cylinder 31 of the applicator 3 and exits to the outside. Therefore, even if the coating material 9 is smeared all over by the application roller 33 in the cylinder 31, the thickness is not constant, so that between the application portion 3 and the drying portion 4 (i.e., , A pair of pressure rollers 7 are installed on the discharge part of the applicator 3 to squeeze through the applicator 3 to press the coating material 9 that is randomly buried at a constant pressure. The upper and lower surfaces of the fiber fabric 8 allows the coating material 9 to be applied to a predetermined thickness.

Meanwhile, in the first embodiment, the electromagnetically modified nozzles 32 installed on the bottom surface of the cylinder 31 of the coating unit 3 are opened and closed at predetermined time intervals in response to output signals of the controller 10 output at predetermined time intervals. The coating material 9 contained in the cylinder 31 is discharged by a predetermined amount on the upper surface of the fiber fabric 8 moving at a constant speed to form a point shape.

Of course, in the first case, the coating material 9 is applied to the fiber fabric 8 in the form of dots, so the amount of the coating material 9 required per yard of the fiber fabric 8 is 30 l of ocher to 10 l of an oily adhesive. 15g of pine needles, 15g of mugwort and 30g of bioceramic, or 10g of water, 40g of aqueous adhesive, 30g of ocher, 30g of pine needles, 15g of mugwort, 15g of bioceramic, and 30g of bioceramic. 8) It is applied to the whole, or in this case, the coating material 9, which is randomly buried through the pressure roller 7, is squeezed out so as to be applied to a certain thickness on the upper and lower surfaces of the fiber fabric 8, which is twice as large as that of the first case. If it is positive.

That is, when the coating material 9 is applied to the entire fiber fabric 8, the amount of the coating material 9 required per yard of the fiber fabric 8 is 60 g of yellow soil, 30 g of pine needles, 30 g of mugwort, and bioceramic in 20 l of an oil-based adhesive. What is necessary is just to mix in the ratio of 60g, or the amount which mixed in 20 liters of water with the ratio of 80g of aqueous adhesives, 60g of yellow soil, 30g of pine needles, 30g of wormwood, and 60g of bioceramic.

In addition, as described above, the coating material 9 applied throughout the point form or the whole is still in a viscous state, and passes through the drying unit 4 to fix it on the fiber fabric 8.

At this time, the drying unit 4 is used in common in both embodiments of the present invention, the "[" character has a shape rotated 90 degrees to the right and both ends of the fiber fabric 8 can be entered and discharged The fiber fabric 8 being transported in the body portion 41 by installing a plurality of idle rollers 44 at regular intervals in the quadrangular body 41 having the inlet and outlet holes 42 and 43 formed thereon. In order to maintain this flat state, a warm air distribution plate 45 having a plurality of warm air discharge holes 46 is installed at the bottom of the idle roller 44 so that the hot air blowing from the hot air generator 5 is maintained. It is supplied to the body part 41 through the warmth discharge hole 46 of the warmth blower plate 45 so that the coating material 9 on the fiber fabric 8 can be dried well, and the body part 41 At the bottom of the pipe can be connected to the hot air discharge pipe 52 of the hot air generator (5) by installing a pipe connector (47) Make sure

In addition, the hot air generator (5) is also commonly used in both embodiments of the present invention, the suction pipe 51 for inducing outside air, and the warm air discharge pipe for sending the heated air to the drying unit ( 52), a boiler 53 using gas as a fuel, and a blower 54 for forcibly drawing and blowing air, forcing the outside air to be heated in the hot air generator 5 and into the drying unit 4. The hot air at the time of blowing is to have about 90 ℃-110 ℃ to shorten the solidification time of the coating material (9) applied to the fiber fabric (8).

In addition, the winding part 6 is also commonly used in both embodiments of the present invention, which is not shown in order to wind up the fiber fabric 8 having the far-infrared radiation coating material 9 applied and dried in a roll form. However, as the fiber fabric 8 is continuously wound, elastic adjustment means for automatically changing elasticity in response to changes in diameter and elasticity during movement, and several idle rollers 61 and winding rollers 62 are provided. do.

On the other hand, the efficacy of ocher and ceramics of ocher and pine needles, mugwort and bioceramic used in the production of the coating material 9 of the present invention is as described above, pine needles have a strong bactericidal power and expand the peripheral nerve to increase hormone secretion It not only plays a role in relieving stress and recovers from fatigue, but also has the effect of treating neuralgia and rheumatism and strengthening the heart.

In addition, mugwort has a treatment effect such as bruises, neuralgia, joint pain, skin disease, jaundice and liver disease, as well as hemostatic effect, and has the effect of preventing numbness or chilling of the hands and feet.

Therefore, in the present invention, by using an appropriate amount of ocher and pine needles, mugwort and bioceramic as a coating material it can be expected to produce the effects generated from these coated fabrics.

As described above, according to the present invention, the far-infrared radiation coating material in which an appropriate amount of ocher, pine needles, wormwood and bioceramic are mixed with an oily or aqueous adhesive is applied to the whole fabric used for manufacturing various clothes, cushions and sheets, or the like. Or by applying irregularities on the surface, it can promote blood circulation and metabolism of the human body, as well as obtain a therapeutic effect such as neuralgia, joint pain and back pain, and also prevent the occurrence of allergic skin diseases. Not only can it block electromagnetic waves and water veins, it can also remove poisons in the human body through the generation of purification and degrading power, and it can maintain fresh surroundings all the time through the odor and oxygen supply of herbal medicine. It is such a very useful invention.

Claims (8)

A fiber fabric supply unit (1) for placing the fiber fabric (8) rolled in a roll shape having a predetermined width and diameter in a rotatable manner and feeding the fiber fabric (8) sequentially from the front end portion; A heating roller (2) for laying down the woolen present on the surface of the fiber fabric (8) supplied from the fiber fabric supply unit (1) by thermal pressure; Coating material 31 having a predetermined volume and installed at regular intervals at the bottom of the cylinder 31 and opened and closed at regular time intervals in response to a signal output from the controller 10 and contained in the cylinder 31. It is provided with several electromagnetically modified nozzles (32) for discharging a predetermined amount (9), and is installed above the fiber fabric feed path to discharge the coating material (9) in the form of dots on the surface of the fiber fabric (8). An applicator 3; On both ends of the rectangular box-shaped body part 41, several idle rollers 44 are formed in the transverse direction to form the fiber fabric 8 inlet and outlet ports 42 and 43 therein and to be moved in a flat state of the fiber fabric. At the same time, the warmth distribution plate 45 having a plurality of warmth exhaust holes 46 is installed at the bottom of the idle roller 44 and connected to the warmth exhaust pipe 52 of the hot air generator 5 at the lower portion thereof. It has a configuration in which the tubular connector 47 is installed and is installed in the rear portion of the applicator 3 to dry the far-infrared radiation coating material 9 through the hot air blown from the hot air generator 5 to produce a fiber fabric 8. A drying unit 4 which is fixed to); A suction pipe 51 for guiding the outside air, a warmer discharge pipe 52 installed between the main body portion and the pipe connector 47 of the drying unit 4, a boiler 53 using gas as a fuel, and air A hot air generator (5) having a blower (54) for forcibly suctioning and blowing the air and forcing the outside air to be forced into the drying unit (4); It is provided with the elasticity adjusting means of the fiber fabric (8), several idle rollers (61) and winding rollers (62), and are installed at the rear of the drying unit (4), and the far-infrared radiation coating material (9) is applied and dried. Far-infrared radiation fiber manufacturing apparatus, characterized in that consisting of a winding portion (6) for winding the fiber fabric (8). A fiber fabric supply unit (1) which has a predetermined width and diameter and is arranged to be rotatable and to supply the fiber fabric (8) wound in a roll form from a leading end portion thereof; A fiber fabric having a cylinder 31 having a volume in which a predetermined volume of the coating material 9 can be stored, and an application roller 33 installed at the bottom of the cylinder 31 and supplied into the cylinder 31. An applicator 3 which coats the coating material with the whole of (8); A pair of pressing rollers 7 for pressing the coating material 9 which is randomly buried while passing through the coating part 3 to have a predetermined thickness on the upper and lower surfaces of the fiber fabric 8; On both ends of the rectangular box-shaped body part 41, several idle rollers 44 are formed in the transverse direction to form the fiber fabric 8 inlet and outlet ports 42 and 43 therein and to be moved in a flat state of the fiber fabric. At the same time, the warmth distribution plate 45 having a plurality of warmth exhaust holes 46 is installed at the bottom of the idle roller 44 and connected to the warmth exhaust pipe 52 of the hot air generator 5 at the lower portion thereof. It has a configuration in which the tubular connector 47 is installed and is installed in the rear portion of the applicator 3 to dry the far-infrared radiation coating material 9 through the hot air blown from the hot air generator 5 to produce a fiber fabric 8. A drying unit 4 for fixing the upper and lower surfaces of the upper and lower surfaces thereof; A suction pipe 51 for guiding the outside air, a warmer discharge pipe 52 installed between the main body portion and the pipe connector 47 of the drying unit 4, a boiler 53 using gas as a fuel, and air A hot air generator (5) having a blower (54) for forcibly suctioning and blowing the air and forcing the outside air to be forced into the drying unit (4); It is provided with the elasticity adjusting means of the fiber fabric (8), several idle rollers (61) and winding rollers (62), and are installed at the rear of the drying unit (4), and the far-infrared radiation coating material (9) is applied and dried. Far-infrared radial fiber fabric manufacturing apparatus, characterized in that consisting of a winding portion (6) for winding the fiber fabric (8) in the form of a roll. A woolen lying down process of laying down the woolen yarn on the fiber fabric 8 supplied from the fiber fabric feeder 1 through heat pressurization; A coating material application step of applying the coating material 9 in the form of dots on the upper surface of the moving fiber fabric with a constant moving speed in a state in which the cows are laid down; A drying step of drying and fixing the coating material 9 applied in the form of dots on the fiber fabric 8 by forcibly blowing hot air; A method for producing a far-infrared radial fiber fabric, characterized in that it comprises a winding-up step of winding up the fiber fabric (8) from which the far-infrared radiation coating material (9) is applied and dried. The method according to claim 3, wherein the coating material 9 is far infrared ray radial fiber fabrics, characterized in that the mixture of oily adhesive per 10 yards of fiber fabric (8) in the ratio of 30g ocher 30g, pine needles 15g, mugwort 15g, bioceramic 30g Way. The far-infrared radial type according to claim 3, wherein the coating material 9 is mixed with 10 l of water per yard of the fiber fabric 8 in an amount of 40 g of aqueous adhesive, 30 g of ocher, 15 g of pine needles, 15 g of mugwort, and 30 g of bioceramic. Fiber Fabric Manufacturing Method. An application step of burying the coating material 9 in the entire fiber fabric 8 supplied at a constant moving speed from the fiber fabric supply unit 1; A coating amount pressurizing step of pressing the coating material 9 randomly buried on the fiber fabric 8 to a predetermined pressure to have a predetermined thickness on the upper and lower surfaces of the fiber fabric 8; A drying step of drying and fixing the coating material 9 applied to the whole of the fiber fabric 8 by forcibly blowing hot air; A method for producing a far-infrared radial fiber fabric, comprising a winding-up step of winding a fiber fabric (8) discharged by applying and drying the far-infrared radiation coating material (9) in a roll form. The method of claim 6, wherein the coating material (9) is produced in the far-infrared radial fiber fabrics, characterized in that 20 l of oil-based adhesive per yard of the fiber fabric (8) mixed in the ratio of 60g ocher, 30g, wormwood 30g, 60g bioceramic Way. The far-infrared radial type according to claim 6, wherein the coating material (9) is mixed with 20 l of water per yard of the fiber fabric (8) in an amount of 80 g of aqueous adhesive, 60 g of ocher, 30 g of pine needles, 30 g of mugwort, and 60 g of bioceramic. Fiber Fabric Manufacturing Method.