KR200295880Y1 - Electric floor using woven fabrics and non-woven fabric manufactured infrared basalt - Google Patents

Abstract

The present invention relates to an electric sheet using basalt fabrics and nonwoven fabrics in which far infrared rays are radiated. In the electric sheet generating heat by receiving electricity, a heating element generated by electricity supply and installed to surround the heating element are provided. A basalt nonwoven layer made of basalt fibres, and a basalt fabric layer overlaid on the basalt nonwoven layer and woven with basalt fibres, wherein the far infrared is radiated. By using the non-woven fabric has the effect of improving the far infrared radiation efficiency.

Description

Electric floor using woven fabrics and non-woven fabric manufactured infrared basalt}

The present invention relates to an electric field plate, and more particularly, to an electric field plate using a far infrared ray basalt fabric and a nonwoven fabric having improved far-infrared radiation efficiency by using a fabric and a non-woven fabric made of basalt fiber with far-infrared radiation.

In general, far infrared rays refer to electromagnetic waves having a wavelength in the range of 3 to 1000 μm. Such far infrared rays have excellent heat action and direct heat transfer and instantaneous heat transfer as compared to visible light, and thus, heating is performed quickly. Its large saving effect makes it widely used in dry heating, heat treatment, health care products and building interior materials. In particular, far-infrared rays with a wavelength in the range of 3 to 14 μm are known to be very effective for resonance and resonance of molecules constituting the living body by being absorbed by the human body, and are activated by molecular absorption of substances by resonance absorption. By strengthening the synthesis of all substances and enhancing the activity, it has the effect of thermotherapy to affect the action of enzymes, hormones and bioactive substances to promote metabolism.

Conventional electric wire or electric field plate configured to radiate far infrared rays has a structure which usually emits far infrared rays from the powder by coating a surface obtained by pulverizing loess or mineral, which is a far infrared ray emitting material, on the surface of fiber or the like, or synthesizing such powder It has a structure that emits far infrared rays by using the fiber prepared by mixing with the raw material to make the fiber, but because the amount of powder used is a small amount, the amount of far infrared rays emitted from it is insufficient, and the effect is not large. In addition, the processing of minerals takes a lot of time and labor, as well as the complicated manufacturing process, resulting in excessive manufacturing costs.

In addition, a conventional electric mat configured to radiate far infrared rays has a structure that radiates far infrared rays by processing minerals emitting far infrared rays to have a predetermined size and shape, arranging the minerals in a predetermined form, and then heating them using a heating wire. Or, by pulverizing the material that emits far infrared rays and mixing the powder with other materials and processing to have a certain shape, it has a structure that emits far infrared rays, but the manufacturing process is complicated and takes a lot of time and labor, and far infrared Since the radioactive material is arranged at regular intervals or locally, far infrared rays are also generated at regular intervals or locally, and far infrared rays are not evenly generated throughout the mat, and have problems such as heavy weight and bulkiness, making transportation and storage difficult.

In addition, the electric mat of another structure is configured to be used to crush the minerals in the form of coarse particles and pack them in a pack or to form a far-infrared radiation layer having a predetermined thickness with a mixture obtained by crushing the minerals. As the volume is increased, the heating part is increased, which is undesirable in terms of power consumption and transportation and storage, and has a problem in that the manufacturing process is complicated and requires a lot of time and labor.

The present invention is to solve the above problems, by using a fabric and non-woven fabric made of basalt fiber that is far-infrared radiation by far-infrared radiation by a large amount of far-infrared radiation to improve the effect of far-infrared radiation The purpose is to provide an electric field using basalt fabrics and nonwovens.

1 is a schematic configuration diagram showing the apparatus for producing basalt long fibers used in the present invention as a whole;

Figure 2 is an external perspective view of the electric plate according to the present invention as a whole;

3 is a partially cutaway perspective view of FIG. 2;

4 is a cross-sectional detail view of FIG. 2.

※ Explanation of symbols about main part of drawing ※

100: electric field plate 110: heating element

120: controller 130: basalt nonwoven layer

140: basalt fabric layer 150: electromagnetic shielding layer

160: sheath

The present invention as a technical configuration for achieving the above object, in the electric sheet to generate heat by receiving electricity, the heating element generated by the electricity supply, and the basalt fiber is installed so as to surround the heating element radiated far infrared rays The basalt non-woven fabric layer and a basalt fabric layer covered with the basalt nonwoven layer and woven basalt fibers woven with far-infrared radiation, characterized in that it comprises an electric sheet using a basalt fabric and a non-woven fabric with far-infrared radiation. .

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

First, the basalt fiber to be used in the present invention can be produced by the apparatus shown in the Republic of Korea Patent Application No. 2002-14449, which will be described briefly with reference to FIG.

Apparatus for producing basalt fiber is a crusher 20 for crushing the basalt 10, a silo 40 for storing and quantitatively storing the basalt crushed stone 12 pulverized in the crusher 20, and the silo 40 Melting furnace 50 is supplied with the basalt crushed stone 12 from), the burner 60 for heating and melting the basalt crushed stone 12 of the melting furnace 50, and the melt movement passage formed on one side of the melting furnace 50 The fiber forming machine 70 receives the molten basalt through 53 to form fibers, and a winding machine 86 for winding the basalt fibers discharged from the fiber forming machine 70. In addition, the apparatus further includes a heater 80 for heating and slowly cooling the fibers discharged from the fiber former 70. In addition, the apparatus further includes an applicator 82 for applying a surface treatment agent to the surface of the fibers discharged from the fiber former 70, and a dryer 84 for drying the fibers discharged from the applicator 82. do. In addition, the melt movement passage 53 is formed at one side of the melting furnace 50 is connected to the vertical wall 55 to overflow the basalt melt.

In order to manufacture basalt fibers using the basalt fiber manufacturing apparatus described above, the basalt is crushed into basalt crushed stone having a thickness of 20 mm or less, and the basalt crushed stone is melted at 1,440 ° C to 1,480 ° C. The basalt melted at was drawn while maintaining at 1,380 ° C. to 1,480 ° C., the fiber was gradually cooled to 960 ° C. to 1,150 ° C., a surface treatment agent was applied to the surface of the fiber, and the surface treatment agent applied to the fiber was dried. The basalt used above is composed of 47 to 56% by weight of SiO ₂ , 14 to 19% by weight of Al ₂ O ₃ , 7.0 to 13.5% by weight of FeO + Fe ₂ O ₃ , 8 to 11% by weight of CaO, and 3.5 to MgO. 10.0 wt%, K ₂ O + Na ₂ O 2.5 to 6.0 wt%, and TiO ₂ 2.0 wt% or less.

FIG. 2 is an external perspective view of the sheet of the present invention as a whole, and FIG. 3 is a partially cutaway perspective view of FIG. 2, and FIG. 4 is a detailed cross-sectional view of FIG. 2, wherein the electric plate 100 of the present invention is at a predetermined temperature. It has a heating element 110 that generates heat, and the heating element 110 may be composed of a conventional linear heating element or a planar heating element that is generated by electricity supply, such as nichrome wire, or may have a configuration in which the linear and planar heating elements are mixed. Of course, when considering only the aspect of heating the entire area of the electric plate 100 evenly, the planar heating element is more preferable than the linear heating element.

The heating element 110 is connected to a wire 114 having a plug 112, and the plug 112 is connected to a power source through an outlet (not shown). Of course, the temperature control function of the jangpan 100 with the blocking function of the current supplied to the heating layer 110 through the wire 114 to the connection portion, or other portions of the heating layer 110 and the wire 114. Controller 120 having a conventional structure.

The basalt nonwoven layer 130 and the basalt fabric layer 140 made of the basalt fibers are sequentially stacked on both sides or one side of the heating element 110.

The basalt nonwoven layer 130 is sufficient to have a conventional nonwoven fabric having no inter-directional directionality due to fiber entanglement, and is preferably manufactured to have an appropriate thickness or more to exert a predetermined cushion function.

The basalt fabric layer 140 is composed of a woven basalt continuous fiber, or basalt long fibers made by continuously manufacturing the basalt fibers.

In addition, it is preferable that the electric field plate 100 of the present invention has an electromagnetic wave shielding layer 150 formed by a generally known method, and the electromagnetic wave shielding layer 150 has an inner surface or basalt fabric layer of the basalt nonwoven layer 130. It is preferable to form by coating a conductive material on the inner surface of (140). Of course, the electromagnetic wave shielding layer 150 may be provided on both the upper and lower sides of the heating element 110, but is provided only on the upper side of the heating element 110 to prevent electromagnetic waves from propagating toward the user. It is preferable.

In addition, the electric field plate 100 of the present invention is wrapped by the outer shell 160, the outer shell 160 is the edge of the contour is sealed by sewing, when touched to the user's skin without any side effects It is good to be made of a material such as cotton which is excellent and absorbs sweat easily.

The operation of the present invention with the above configuration will be described.

The electric field plate of the present invention has a function as a commonly known field plate and can be used as an electric field.

In order to use the electric blanket 100, the electric blanket 100 is laid on the floor and the plug 112 is connected to an outlet to supply electricity.

The basalt nonwoven layer 130 and the basalt fabric layer 140 installed in the interior of the electric field plate 100 are heated while the heating element 110 is heated by the supplied electricity, and the basalt nonwoven layer 130 and the basalt fabric layer are heated. By continuously radiating a large amount of far-infrared at 140, the effect of health promotion is achieved by the effect of heating and the far-infrared poultice, ie disease prevention and blood circulation.

In addition, since the basalt nonwoven fabric layer 130 has a cushion function on its own, the user can feel the fluffy feeling at the same time without a separate blanket and can directly feel the heat and far-infrared jjimjil effect.

In addition, since the basalt nonwoven fabric layer 130 and the basalt fabric layer 140 constituting the electric field plate 100 of the present invention is made of basalt with a large amount of far-infrared radiation, far-infrared radiation effect is excellent.

In addition, by blocking the electromagnetic wave generated in the heating element 110 in the electromagnetic wave shielding layer 150 has a function that can double the far-infrared radiation effect.

In particular, the basalt nonwoven fabric layer 130 and the basalt fabric layer 140 surrounding the heating element 110 has a non-flammable and durable, it is possible to prevent the occurrence of fire in advance and has an effect of improving the life.

As described above, according to the electric field plate according to the present invention, the basaltic fabric layer and the basalt nonwoven fabric layer in which the far infrared rays are emitted are formed in a form that surrounds the heating element. Has an effect.

In addition, by blocking the electromagnetic wave generated in the heating element in the electromagnetic wave shielding layer has an effect that can double the far-infrared radiation effect.

In addition, the basalt nonwoven layer and the basalt fabric layer surrounding the heating element has the effect of preventing the occurrence of fire.

Claims (3)

In the electric field to generate heat by receiving electricity, A heating element that generates heat by electricity supply, A basalt nonwoven layer made of basalt fibers that are installed to surround the heating element and to which far infrared rays are radiated; The basalt fabric and the non-woven fabric, characterized in that it comprises a basalt fabric layer covered with the basalt nonwoven layer and woven from basalt fibers radiated far infrared rays. The electric field plate of claim 1, further comprising an electromagnetic wave shielding layer formed around the heating element to block electromagnetic waves generated by the heating element. According to claim 1 or 2, Far-infrared radiation is characterized in that it further comprises an outer skin covering the basaltic fabric layer made of a material that is excellent in touch and easy to absorb sweat when in contact with the user's skin Electric field using basalt fabrics and non-woven fabrics.