KR20020029533A - manufacturing process far-infrared pad - Google Patents

Abstract

PURPOSE: A method for preparing a far-infrared radiation pad is provided to absorb outer impact, to improve safety of a residual and to increase smoothness of human metabolism by the far-infrared light and anions discharged from jade, loess and/or bio-stones. CONSTITUTION: The method comprises: admixing 20wt.% stone powders, 70wt.% of E.V.A., 2wt.% of cross-linking agent, 4wt.% of zinc promotor and 4wt.% of activating agent in an emulsion form; introducing the emulsion into a shaped mold; and compression-molding the emulsion to form a desired size and form of the pad. Alternatively, The admixture is made of 20wt.% of loess powders, 70wt.% of E.V.A., 2wt.% of cross-linking agent, 4wt.% of zinc promotor and 4wt.% of activation agent. The loess powders are substituted with jade and/or bio-stone powders in a substantially same amount. The produced pad(1) is located under a plywood(2) and attached to the plywood with an adhesive.

Description

Manufacturing method of far infrared pad {manufacturing process far-infrared pad}

The present invention relates to a method for manufacturing a far-infrared pad, which is used by bonding to a building interior material such as flooring or wall material, far-infrared material such as lava stone, loess, jade, ganban stone and Ethylene Vinyl Acetate (hereinafter referred to as EVA), a crosslinking agent. , The zincation accelerator and the activator are mixed at a predetermined ratio to pour the emulsion mixture into a mold of a predetermined size and press-molded to a desired thickness and size.

Building interior materials made of a combination of a number of plywood, such as flooring and wall materials of the prior art has been installed directly on cement floors, walls, ceilings, etc. containing a lot of moisture.

However, the building interior material formed by the combination of the plywood as described above has a low thermal insulation effect, so even after construction, the cool air leaks from the cement of the floor, wall, ceiling, etc. In addition, over time, moisture is generated on the bottom surface of the building interior materials constructed by the temperature difference due to the cold discharged from the cement and the heating heat of the exterior of the building interior materials, thereby creating a favorable atmosphere for the breeding of bacteria or fungi. People with disease in the system adversely affects health, and various insects have been inhabited, and it is very dirty for hygiene. Especially, the building interior material used as flooring material has no buffering effect, so the touch is hard and children and the elderly If you slip and fall unexpectedly There was a problem such as a big accident may occur.

The present invention has been made to solve the problems of the prior art, the technical problem is to be used to adhere to one side of the building interior materials such as plywood is provided with an elastic force and the shock can be absorbed, replace only parts It can be provided for each piece of building interior material to be replaced, and it can prevent direct harm by blocking cold air that is harmful to the human body. Also, it can be applied to the human body by the action of far-infrared rays generated from lava stone, loess, jade and elvan rock, which are used as main materials. To produce a far-infrared pad that provides a beneficial effect, heat insulation, deodorizing effect.

1 is a cross-sectional view of an embodiment using the far-infrared pad manufactured by the present invention.

Figure 2 is a bottom perspective view of an embodiment using a far infrared pad made by the present invention.

<Description of the symbols for the main parts of the drawings>

1: Far Infrared Pad 2: Plywood

4: adhesive

Referring to the manufacturing method of the far infrared pad according to the present invention as described above in detail.

First, 20% by weight of lava stone powder, which is pulverized to 200 mesh or more, 70% by weight of EVA, 2% by weight of crosslinking agent, 4% by weight of zincation promoter, and 4% by weight of activator, and then the mixture in emulsion state Pour an appropriate amount into the mold of the mold and compression molding to a desired size and thickness.

The adhesive is applied to one side of the far-infrared pad manufactured as described above, and then attached to the bottom of the building interior material such as plywood.

The built-in building material with the far-infrared pad manufactured as described above has its own elasticity due to EVA used as the material of the far-infrared pad, so it can absorb external shocks, and also due to the far-infrared rays and negative ions emitted from the lava stone, The metabolism of the smooth, and the insulation and deodorizing action is provided.

In another embodiment, instead of lava stone powder in the mixture of the far-infrared pad, yellow clay powder, jade powder, ganban stone powder, 20% by weight of EVA, 70% by weight of crosslinking agent, 4% by weight of zincation accelerator, 4% by weight of activator are mixed. Thereafter, the mixture in the emulsion state is poured into a mold of a predetermined size and pressed to a desired size and thickness to produce a far-infrared pad for building interior materials.

When the far-infrared pad manufactured according to the present invention is attached to the bottom of the building interior material and installed on the floor, wall, or ceiling, the impact of external shock is absorbed by the elastic force of the far-infrared pad itself, thereby improving the safety of residents. Far-infrared rays and anions emitted from ocher, jade, and elvan are provided with various useful effects such as smoothing the metabolism of the human body and insulating and deodorizing effects.

Claims (4)

After mixing 20% by weight of lava powder, 70% by weight of EVA, 2% by weight of crosslinking agent, 4% by weight of zincation accelerator, and 4% by weight of activator, the emulsion mixture is poured into a mold of a predetermined size to a desired size and thickness. A method for producing a far-infrared pad, which is formed by compression molding. According to claim 1, wherein a mixture of 20% by weight ocher, 70% by weight of EVA, 2% by weight of crosslinking agent, 4% by weight of zincation accelerator, and 4% by weight of activator is poured into a mold of a predetermined size to a desired size and thickness. Far infrared pad manufacturing method characterized in that the compression molding. The method of claim 1, wherein a mixture of 20% by weight of jade powder, 70% by weight of EVA, 2% by weight of crosslinking agent, 4% by weight of zincation accelerator, and 4% by weight of activator is poured into a mold of a predetermined size and pressed into a desired size and thickness. Method for producing a far-infrared pad, characterized in that formed by molding. The method according to claim 1, wherein a mixture of 20% by weight of barnstone powder, 70% by weight of EVA, 2% by weight of crosslinking agent, 4% by weight of zincation accelerator, and 4% by weight of activator is poured into a mold of a predetermined size to a desired size and thickness. Far infrared pad manufacturing method characterized in that the compression molding.