KR100876213B1 - Sheet for automobile interior containing far-infrared radiation silicate mineral and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a sheet for automobile interiors containing far-infrared radiation silicate minerals and a method for producing the same.

Sheet for automobile interior containing far-infrared radiation silicate mineral of this invention is a nonwoven fabric on both sides of a polyurethane layer; Glass fiber layer; In the far-infrared radiator, a reinforcing scrim prepared by laminating a far-infrared radiation layer containing a far-infrared radiation silicate mineral that emits a wavelength of 7 to 20 μm is bonded, and the sheet for automobile interior materials of the present invention is a polyethylene resin contained in a far-infrared radiation layer. Implemented by fusion bonding method by heating, and due to far-infrared radiation silicate mineral containing far-infrared emission, long-term operation, fatigue and tension relief effect, air purification, blood circulation, harmful bacteria or fungus Anti-dwelling efficacy can be achieved. Furthermore, the sheet for automobile interior containing the far-infrared radiation silicate mineral of this invention can be usefully utilized for a headliner, a headrest, a door trim, a rear self, a trunk mat, a carmat, and a bonnet liner among automotive interior materials.

Description

SHEET FOR AUTOMOBILE INTERIOR CONTAINING SILICATE MINERALS RADIATING FAR INFRARED RAY AND MANUFACTURING METHOD THEREOF}

1 is a schematic diagram of a method for producing a sheet for automobile interior containing far-infrared radiation silicate mineral according to the present invention.

※ Explanation of code about main part of drawing ※

1: nonwoven fabric 21: glass fiber raw material

22: cutting roller 23: crushed glass fiber

31: high density polyethylene powder (HDPE) 32: far infrared radiation silicate mineral powder

33: distribution roller 41: heating plate

42: compression roller 43: cooling plate

5: finished product

The present invention relates to a sheet for automobile interiors containing far-infrared radiation silicate minerals and a method for manufacturing the same. More specifically, the present invention provides a non-woven fabric on both sides of a polyurethane layer; Glass fiber layer; The reinforcing scrim prepared by stacking the far-infrared radiation silicate mineral containing 7-20 nm wavelength of the far-infrared radiation emitter is bonded by an adhesive film, and due to the far-infrared emission due to the containing of the far-infrared radiation silicate mineral, The present invention relates to a seat for automobile interior materials and a method of manufacturing the same that maximize the far infrared radiation effect.

Humans use oxygen to produce carbon dioxide, which inevitably involves acidification of the blood.

Surprisingly, to prevent this acidification process, the body automatically generates a preliminary alkaline substance to regulate the acidified blood to keep the blood slightly alkaline. However, due to deterioration of metabolic rate due to aging, the ability to produce preliminary alkaline substances gradually decreases, resulting in a loss of balance in the body and acidification of blood. At this time, the calcium component in the bone acts as a substitute for the preliminary alkaline substance.

However, calcium is also absorbed well during the growth phase, but when the growth stops, it is not absorbed well. Also, the calcium deficiency phenomenon causes osteoporosis. In addition, in order to prevent acidification, the neutralized substance produced by calcium is not discharged by sweat or urine, which causes another problem. The viscosity is increased, making the blood sticky, which slows down the blood.

Thus, the neutralized substance adheres to the blood vessel wall, lipid peroxide, that is, saturated fat adheres to it, and protein, especially cholesterol, adheres to it, thereby stiffening the blood vessel wall and narrowing blood vessels, resulting in hypertension, adult disease, and metabolic activity. Cause disease.

In addition, in the case of active oxygen necessarily accompanied by blood acidification, not only the immune system but also DNA is destroyed, making energy metabolism in the cell impossible and inhibiting protein synthesis. For this reason, active oxygen breaks down enzymes, causes imbalance in the endocrine system, lowers physiological metabolism of the human body, and easily infects viruses and bacteria, causing disease.

Healthy human body is more than 70% water, 30% of the nutritional substances, minerals, vitamins, etc. combined. This body balance maintains 30% of the nutrients as the cells age, but reduces water and instead begins to accumulate oil. Cell oil is blocked by the oil, and wrinkles are caught on the skin.

At this time, the cell membrane is generally a double reticulum consisting of a phospholipid component, the reticulum is too fine so that the general water particles are large, do not enter well, very small particles of 20nm or less can enter. Therefore, the lack of moisture in the cells, the general nutrients or oxygen deficiency occurs because of the large molecules of blood, the passage of lipid membranes becomes smaller and the space occupied by oil is filled with oil .

Many reports on disease research have been focused on the effects of 30% of the substances on the human body. More than 70% of water was regarded as only a component of blood, and water was used as an intracellular carrier. Research on the role or role of DNA or enzymes or physiological metabolism is insufficient.

In other words, in order to sufficiently supply intracellular nutrition and oxygen, water molecules of blood must be made very small, and a substance capable of smoothly supplying water to cells by strengthening the movement of moisture is needed.

Accordingly, Korean Patent No. 208878 discloses a method for producing silicate minerals (granite, quartzite, kaolin, etc.) using a hydrothermal alteration vibration crushing method for producing a far-infrared radiation (radiative) silicate mineral having a wavelength of 7-20 μm. Looking at the manufacturing method in detail, the silicate minerals (granite, quartzite, kaolin, etc.) proceed in the order of mining → immersion and heat treatment in a cyclical repetition → pulverization → packaging, and the mined silicate minerals Crush it and immerse it in water to feed about 5-10% of water, and take it out, heat it to 200 ~ 400 ℃, and then immerse it in water again and inject about 5 ~ 10% of water, and pick it up at 200 ~ 400 ℃. The hydrothermal deformed zone is produced by expanding the rock structure line (breaking gap) by heating at least -50 times. In addition, the production method can produce a fine powder having a far infrared radiation (copy) function in the 7 ~ 20㎛ wavelength.

Recently, the far-infrared radiation silicate mineral powder prepared by the manufacturing method is widely used under the trade name of ACTIVA, and the far-infrared radiation silicate mineral can easily transport nutrients and oxygen from blood vessels into cells.

In general, sunlight can take hundreds of thousands of minutes to pass through 1 cm of water. In this short time, water molecules make 170 rotations of incidence, translation, stretching, and rotation. If it transmits far infrared rays, it is amplified by pi times, or 3.14 times, and activated about 540 times, which is called a piwater or frequency.

On the other hand, permeation of far-infrared radiation silicate minerals causes the movement of 1,200 times much stronger than Pywater, making it about 2.2 times stronger than Pywater.

More than 200 water movements in the process to remove the lipid peroxide (saturated fat), cholesterol and the like attached to the wall of the blood vessels become hard, making the narrowed blood vessels smooth and wide, allowing blood to easily pass through the cell membrane.

Water is a collection of hundreds of thousands of water molecules, a space is created between the water molecules and gas is present in the space. When the far-infrared radiation silicate mineral is added thereto, the water molecules are broken into small amounts of 1 / 20,000 in an instant, so that there is no space for the gas to remain, the gas is blown away and the heavy metal is ground down. That is, these small water molecules can easily pass through the cell membrane and can easily attract nutrients or oxygen into the cell.

In addition, the far-infrared radiation silicate mineral appears to be about 125 times higher than the general antioxidant in terms of the active oxygen capacity, which means that it prevents the action of active oxygen 125 times. In addition, in terms of the amount of free radical reduction, it appears to be about 8.5 times higher [ORAC test], which means that the ability to return harmful free radicals to healthy oxygen is more than 8.5 times. Thus, far-infrared radiation silicate minerals prevent cell membrane destruction of immune cells, thereby preventing the functioning of immune cells and making the immune system work normally.

The enzyme does not act alone, but acts within a constant wavelength of 7-20 μm. Said wavelength is a wavelength contained in far infrared rays among sunlight, and far infrared rays activates the metabolism of a human body in the wavelength of the narrow region of the wavelength (live light wave) of the 7-20 micrometers range among the wavelengths of 4-11,000 micrometers area | region. The growth light waves resonate and resonate when they meet the same wavelength. In the case of the human body, cells collide with each other, become more intense, and destroy even intracellular molecular structures. However, before the change to the heat energy causes the self-heating phenomenon to maintain the body temperature of 36.5 ~ 37 ℃, and some of the energy to activate the enzyme. At this time, about 52% of the heat energy is used in the body, and 48% is released to the body.

As described above, when far-infrared radiation is emitted to the human body consisting of 70% or more moisture, it penetrates 80 times deeper than normal heat up to 4-5 cm in the skin, and shakes the cells finely 12,000 times in 60 seconds. It activates the cell tissue through. Wastewater and toxic substances are discharged by the effect obtained by releasing heat energy through such cellular action, and promote blood circulation by decomposing thrombi. In particular, since the far-infrared radiation silicate mineral has a far-infrared radiation function in the range of 7 to 20 µm, as described above, since it affects the activation of the enzyme, its range of application is gradually expanding.

Nonwoven fabrics made by interwoven synthetic fibers short fibers and / or long fibers without needle weaving, such as needle punching, are widely used in various fields, and in particular, due to their light weight, Widely used in interior materials and mats.

In general, interior parts and mats made of non-woven fabrics are installed in various parts of an automobile, and in particular, the sound absorption and sound insulation effect is excellent, and functions to decorate the exterior more beautifully. Such interior materials are used for interior mats and floors and floors and floors of car interiors and doors, as well as for rear shelves and trunk floors.

The conventional structure of the interior material is usually resin-treated on the back side of the nonwoven fabric by spraying or dipping the acrylic binder onto the back side of the nonwoven fabric made of a material having soundproofing and heat resistance. Has been used. However, such a conventional interior material provides excellent effects in terms of sound insulation and heat resistance, but does not have antibacterial and deodorizing functions, and after a long time of use, the nonwoven fabric itself becomes odorous, and various dusts are deposited therein. When the humidity in the air is high, there is a problem such that odor is generated due to the growth of microorganisms.

Accordingly, the present inventors adopt the far-infrared radiation silicate mineral, which has been proven to be effective due to the far-infrared radiation, as a new material and add it to a vehicle interior manufacturing process that has not been applied yet. By confirming, the present invention was completed by providing an automobile interior material which can realize the effect of reducing fatigue and tension, as well as air purification, promoting blood circulation, and preventing harmful bacteria and molds.

An object of the present invention is to provide a sheet for automobile interior containing a far-infrared radiation silicate mineral and a manufacturing method thereof.

Another object of the present invention is to provide an automotive interior material using a sheet for automotive interior materials containing the far-infrared radiation silicate mineral.

In order to achieve the above object, the present invention, both sides of the polyurethane layer, non-woven; Glass fiber layer; Provided is a sheet for automobile interiors in which a reinforcing scrim manufactured by stacking a far-infrared radiation layer containing a far-infrared radiation silicate mineral that emits a wavelength of 7 to 20 μm among far-infrared radiators is bonded by an adhesive film.

The far-infrared radiation layer is formed by applying a mixed powder composed of high density polyethylene powder and far-infrared radiation silicate mineral, and the high density polyethylene powder is applied in a range of 10 g to 200 g per 1 m 2 of the coated surface. In addition, the far-infrared radiation silicate mineral is characterized in that it contains 1.0 to 10.0% by weight of the high-density polyethylene powder.

Sheet for automobile interior of the present invention is implemented by the melt adhesive method of the polyethylene resin contained in the far-infrared radiation layer heat.

The far-infrared radiation silicate mineral used in the present invention has a particle size of 0.1 to 42 µm and is a weakly alkaline particle having a pH of 7.3 to 9.0.

The present invention also provides a method for manufacturing a sheet for automobile interior containing far-infrared radiation silicate mineral. More specifically, after the pulverized glass fiber is applied to the nonwoven fabric, a glass fiber layer is prepared, and a mixed powder made of high density polyethylene powder and far-infrared radiation silicate mineral is continuously applied to the glass fiber layer to prepare a far-infrared radiation layer. It is heated to 300 ° C and interlayer bonding, passing through the compression roller and cooled to prepare a reinforcement scrim, and consists of adhering the reinforcement scrim with an adhesive film on both sides of the polyurethane layer.

The high density polyethylene powder is preferably applied in a range of 10 g to 200 g per 1 m 2 of the coated surface, and the far-infrared radiation silicate mineral contains 1.0 to 10.0% by weight of the high density polyethylene powder. More preferred far-infrared radiation silicate mineral content is 3.5% by weight of the high density polyethylene powder.

The far-infrared radiation silicate mineral used in the present invention contains 65 to 80% by weight of aluminum silicate salt and 20 to 35% by weight of natural mineral components containing calcium, magnesium, titanium and sodium.

The far-infrared radiation silicate mineral emits 7 to 20 µm of the far-infrared emitter, has a particle size of 0.1 to 42 µm, and is a weakly alkaline particle having a pH of 7.3 to 9.0.

Furthermore, the present invention is an automotive interior material applicable to any one selected from the group consisting of headliner, headrest, door trim, rear self, trunk mat, car mat and bonnet liner To provide.

Hereinafter will be described in detail with reference to the manufacturing method of the sheet for automobile interior containing far-infrared radiation silicate mineral of the present invention.

The present invention 1) to prepare a glass fiber layer by applying a glass fiber pulverized in 2.5 to 5.5 cm size on a nonwoven fabric,

2) to produce a far-infrared radiation layer by applying a mixed powder composed of polyethylene powder and the far-infrared radiation silicate mineral prepared by the hydrothermal vibration crushing method to the glass fiber layer,

3) After the far-infrared radiation layer is prepared, it is heated to 150 to 300 ℃ to melt the high-density polyethylene powder interlayer bonding, passing through a compression roller and cooled to prepare a reinforcing scrim,

4) It provides a method for producing a sheet for automobile interior containing far-infrared radiation silicate mineral consisting of adhering the reinforcement scrim with an adhesive film on both sides of the polyurethane layer, and winding the finished product.

The glass fiber layer of step 1) is used for the purpose of providing the rigidity of the product, in the manufacturing method of the sheet for automotive interior containing the far-infrared radiation silicate mineral of the present invention of Figure 1 , the glass fiber raw material 21 is a cutting roller While passing through 22, the glass fibers 23 crushed to a size of 2.5 to 5.5 cm are applied to at least one side of the nonwoven fabric 1 conveyed on the conveyor belt.

In this case, the coating amount may vary depending on the conditions or speed of the raw material and the machine, but the amount of the glass fiber is not boiled on the nonwoven fabric. At this time, the application means is to uniformly coat the amount of the pulverized raw material placed on the nonwoven fabric by using a conventional method such as spray, knife or ROLL knife from the nozzle connected to the hopper.

At this time, the glass fiber layer is preferably formed in 0.2 to 1.0mm, for the uniform glass fiber layer, the glass fiber should be crushed to 2.5 to 5.5cm size. At this time, if the glass fiber is less than 2.5cm, the rigidity is weak and the expected rigidity cannot be obtained. If the glass fiber exceeds 5.5cm, the void formation between particles is large and there is also a problem in the rigidity.

In the process of step 1), after the glass fiber layer is formed on one side of the nonwoven fabric 1, the mixed powder consisting of the high density polyethylene powder 31 and the far-infrared radiation silicate mineral 32 produced by the hydrothermal vibration crushing method is distributed roller ( Step 2) is carried out to apply via 33) to produce a far infrared ray emitting layer.

The high density polyethylene powder 31 is commonly used for the purpose of adhering the nonwoven fabric with the glass fiber layer prepared in step 1). At this time, the high-density polyethylene powder is preferably used to select uniform particles in the size of 77 to 220㎛, the preferred coating amount is to apply 10g to 200g per 1 m 2 coated surface.

At this time, if it is less than 10 g per 1 m <2> of coating surfaces, there exists a problem with adhesiveness, and when it exceeds 200 g, the possibility of impregnation and bleeding on a nonwoven fabric is large, and it is unpreferable.

Therefore, the present invention by adding the far-infrared radiation silicate mineral to the high-density polyethylene powder, to reduce fatigue and tension caused by far-infrared emission to the interior of the automobile interior finished products, and to purify the air, promote blood circulation, harmful bacteria or fungi It is characterized by providing an prevention effect.

Far-infrared radiation silicate mineral used in the present invention is a silicate mineral (granite, quartzite, kaolin, etc.) of the Republic of Korea Patent No. 208878 by using a hydrothermal alteration vibration crushing method, the wavelength of far infrared radiation (radiation) silicate It is manufactured by the manufacturing method. More specifically, the far-infrared radiation silicate mineral used in the present invention was analyzed by the KS L 3128 method using a CS analyzer under the conditions of 20-21 ° C. and 45-49% RH [Korea Ceramic Industry Research Institute], It is as Table 1 below.

Test Analysis Items Test analysis result Test Analysis Items Test analysis result SiO ₂ (% by weight) 65.1 P ₂ O ₅ (% by weight) 0.10 Al ₂ O ₃ (wt%) 13.7 Ba (wt%) 0.09 Na ₂ O (% by weight) 3.67 Cr (% by weight) 0.01 Fe ₂ O ₃ (% by weight) 4.07 Sn (% by weight) <0.001 CaO (% by weight) 3.63 Zn (% by weight) 0.01 MgO (% by weight) 1.65 Sr (wt%) 0.04 K ₂ O (% by weight) 3.53 Ga (% by weight) 0.01 TiO ₂ (% by weight) 0.43 V (% by weight) 0.03 Zr (wt%) 0.003 Rb (wt%) <0.001 MnO (% by weight) <0.001 Y (% by weight) 0.001 SO ₃ (% by weight) Remaining volume (CS analyzer)

Far-infrared radiation silicate mineral used in the present invention contains 65 to 80% by weight of aluminum silicate salt, 20 to 35% by weight of natural mineral components containing calcium, magnesium, titanium and sodium, In the manufacturing process by, may contain trace elements such as germanium, gold, cobalt component.

The far-infrared radiation silicate mineral used in the present invention is a weakly alkaline fine particle that emits a wavelength of 7 to 20 µm, has a particle size of 0.1 to 42 µm, and has a pH of 7.3 to 9.0 in the far infrared emitter.

At this time, if the particle size of the far-infrared radiation silicate mineral is less than 0.1 mu m, it is not easy to work due to agglomeration between particles, and if it exceeds 42 mu m, there is a problem because the surface thickness becomes thick during coating film formation.

In addition, since the far-infrared radiation silicate mineral used in the present invention is a weak alkaline of pH 7.3 to 9.0, there is an effect of improving the thermal efficiency of the sub-material (powder) according to the material.

At this time, the far-infrared radiation silicate mineral contains 1.0 to 10.0% by weight of the high density polyethylene powder, and more preferably contains 3.5% by weight of the high density polyethylene powder used. If the content of far-infrared radiation silicate mineral is less than 1.0% by weight of the high density polyethylene powder, the amount of far-infrared emission is not preferable because the measured value is weak, and if it exceeds 10.0%, there is no problem depending on the characteristics according to the applied material.

Step 3) after the far-infrared radiation layer is manufactured, heated to 150 to 300 ℃ in the heating plate 41 while passing through the sealed chamber, then passed through the compression roller 42 and to 5 to 10 ℃ in the cooling plate 43 It cools and forms a coating film and manufactures a reinforcement scrim.

This step may apply the heating and cooling conditions to be carried out in the manufacture of conventional automotive interior materials.

Preferably the temperature of the heating plate is carried out at 150 ℃ or more, more preferably by heating to 150 to 300 ℃, non-woven fabric continuously formed by melting the high-density polyethylene powder of the thermoplastic resin contained in the far-infrared radiation layer to have fluidity; Glass fiber layer; And to increase the adhesion between the far-infrared radiation layer, to facilitate the formation of a coating film.

Thereafter, the compression roller 42 is manufactured in a sheet shape, and the temperature of the cooling plate 43 is maintained at 5 to 10 ° C., and the elapsed time may vary depending on the degree of curing of the previous step.

4) The reinforcing scrim prepared in the step is bonded to both sides of the polyurethane layer with an adhesive film, the finished product is wound up.

Sheet for automobile interior of the present invention, both sides of the polyurethane layer, non-woven fabric; Glass fiber layer; A reinforcing scrim bonded by a reinforcing scrim manufactured by stacking a far-infrared radiation layer containing a far-infrared radiation silicate mineral that emits a wavelength of 7 to 20 μm among the far-infrared radiators.

The detailed description of the far-infrared radiation silicate mineral used in the present invention is the same as that described in the preparation method.

That is, the sheet for automotive interior materials of the present invention emits a wavelength of 7 to 20 ㎛ in the far infrared emitter, has a particle size of 0.1 to 42 ㎛, and contains a far-infrared radiation silicate mineral which is a weakly alkaline particle having a pH of 7.3 to 9.0 In addition, it can provide the effect of reducing fatigue and tension caused by far-infrared ray emission in car interior materials, purifying air, promoting blood circulation in human body, and preventing harmful bacteria or mold habitat.

For the sheet for automobile interior of the present invention, the radiation energy (W / m 2) and the emissivity (%) of 4 to 20 μm were measured based on a black body using an infrared spectrometer at 180 ° C. using the KFIA-FI-1005 test method. Measured. At this time, when the emissivity of the black body was 4 at 4 to 20 µm, the emissivity of the far-infrared radiation silicate mineral (activa) itself of the present invention was 0.927%. Table 2 shows the results of measuring the far-infrared characteristics [Korea Far Infrared Association], and the far-infrared characteristics were measured by the same method for the sheet manufactured without containing the far-infrared radiation silicate mineral.

 Radiation dose measuring range (4 ~ 20㎛) Radiation energy measured amount (W / ㎡ · ㎛, 180 ℃) Far Infrared Radiation Silicate Mineral Free Sheet 0.826% 1.67 × 10 ³ Far Infrared Radiation Silicate Mineral Containing Sheet 0.881% 1.78 × 10 ³

In general, far infrared rays in the 7 to 20㎛ wavelength range resonantly resonates with the cells to affect the growth of the cells, and are called growth light waves. The higher the radiation energy and the radiation amount in the wavelength range, the more beneficial to the living being. Thus, from the results of Table 2, in the case of the sheet for automobile interior containing the far-infrared radiation silicate mineral of the present invention, the radiation amount and the radiation energy measurement amount increased in the wavelength range of 4 to 20㎛ than the non-containing.

The seat for automobile interior of the present invention can be used as a vehicle interior, more preferably a group consisting of a head liner (head liner), head rest (head rest), door trim, rear self, trunk mat, car mat and bonnet liner It can be used as any material selected from.

As described above, the present invention is a far-infrared radiation silicate that emits a wavelength of 7 to 20㎛ in a high-density polyethylene powder, which is a thermoplastic resin used to promote adhesion between the layers in a sheet for automotive interior consisting of a nonwoven fabric and a glass fiber layer. Car interior seats that contain minerals to maintain interlayer adhesion and maximize far-infrared effects, and head liners, head rests, door trims, rear-shelves, trunk mats, carmats or bonnets using them Provided are automotive interiors that are applicable to liners.

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, and such modifications and modifications are within the scope of the appended claims.

Claims (12)

On both sides of the polyurethane layer, Non-woven; Glass fiber layer; Sheet for automobile interior containing far-infrared radiation silicate mineral, characterized in that the reinforcing scrim manufactured by stacking the far-infrared radiation layer containing the far-infrared radiation silicate mineral emitting 7 to 20 탆 wavelength among the far-infrared radiator is bonded by an adhesive film. . The sheet for automobile interiors according to claim 1, wherein the far-infrared radiation layer is formed by applying a mixed powder made of high density polyethylene powder and far-infrared radiation silicate mineral. The vehicle interior sheet containing the far-infrared radiation silicate mineral according to claim 2, wherein the high-density polyethylene powder is coated in an amount of 10 g to 200 g per 1 m 2 of the coated surface. The vehicle interior sheet containing the far-infrared radiation silicate mineral according to claim 2, wherein the far-infrared radiation silicate mineral is contained in an amount of 1.0 to 10.0% by weight of the high density polyethylene powder. The vehicle interior sheet containing the far-infrared radiation silicate mineral, characterized in that the polyethylene resin contained in the far-infrared radiation layer is implemented by heat fusion bonding method. The sheet for automobile interiors according to claim 1, wherein the far-infrared radiation silicate mineral has a particle size of 0.1 to 42 µm and is a weakly alkaline particle having a pH of 7.3 to 9.0. A glass fiber layer is prepared by applying pulverized glass fibers to a nonwoven fabric, and a continuous powder is applied to the glass fiber layer by applying a mixed powder composed of high density polyethylene powder and far-infrared radiation silicate mineral, and then heated to 150 to 300 ° C. Dissolving the high density polyethylene powder to form an interlayer, passing through a compression roller and cooling to prepare a reinforcing scrim, A method for manufacturing a sheet for automobile interiors comprising the far-infrared radiation silicate mineral of claim 1, wherein the reinforcing scrim is attached to both sides of the polyurethane layer with an adhesive film. The method of manufacturing a sheet for automobile interior materials containing the far-infrared radiation silicate mineral according to claim 7, wherein the high density polyethylene powder is applied per 1 m 2 of the coated surface. The method of manufacturing a sheet for automobile interior materials containing the far-infrared radiation silicate mineral according to claim 7, wherein the far-infrared radiation silicate mineral contains 1.0 to 10.0% by weight of the high density polyethylene powder. 8. The far-infrared radiation silicate mineral contains 65 to 80% by weight of an aluminum silicate salt and 20 to 35% by weight of a natural mineral component containing calcium, magnesium, titanium and sodium. Method for producing a sheet for automotive interior containing the far-infrared radiation silicate mineral. 8. The far-infrared radiation according to claim 7, wherein the far-infrared radiation silicate mineral emits 7-20 탆 wavelength in the far-infrared emitter, has a particle size of 0.1-42 탆, and is about alkaline particles having a pH of 7.3-9.0. A method for producing a sheet for automobile interior containing silicate mineral. The interior material sheet for automobiles containing the far-infrared radiation silicate mineral of claim 1 is applied to any one selected from the group consisting of headliners, headrests, door trims, rear-shelves, trunk mats, carmats and bonnet liners. Automotive interior materials.

Images