KR19990040886U - German floor applied floorboard material - Google Patents

Abstract

The present invention relates to a flooring material for ondol, and an organic germanium compound, an inorganic germanium compound, or a mixture containing the same, which is a far-infrared emitter in an ondol flooring material comprising a plywood layer, an adhesive layer, a surface veneer layer, and an ultraviolet curing coating layer. It is related with the flooring material for ondol which contained in an adhesive bond layer and an ultraviolet cured coating layer, and had a high far-infrared radiation effect.

Description

German floor applied floorboard material

The present invention relates to flooring materials for ondol, and more particularly to flooring materials for ondol containing an organic germanium compound, an inorganic germanium compound or a mixture containing them.

The flooring material for ondol is installed on the ondol and requires dimensional stability in construction and use. Generally, the plywood layer, adhesive layer, surface veneer layer, and ultraviolet curing coating layer (hereinafter referred to as coating layer) Has a structure.

The unique function of the flooring material can be referred to as the decoration and finishing of the floor surface, but as the standard of living has recently improved, various functions such as weather resistance, heat resistance, chemical resistance, as well as wear resistance, scratch resistance, etc., in addition to the inherent functions have been improved. The functional flooring material which I had is released.

Flooring materials with far-infrared radiation are also available, including ocher and elvan. However, in fact, the flooring material produced using this kind of raw material as a far infrared ray emitter is far lower in far infrared radiation function than the flooring material containing germanium compound.

Accordingly, the present invention provides an ondol flooring material having a high far-infrared radiation effect by containing an organic germanium compound, an inorganic germanium compound, or a mixture containing the same, in the adhesive floor and the coating layer of the flooring material for an on-floor flooring material. To provide.

1 is a manufacturing process diagram of the flooring material for ondol of the present invention.

Figure 2 is a cross-sectional view of the flooring material for ondol of the present invention.

(Explanation of symbols in the main part of the drawing)

10: plywood layer 20: adhesive layer

30: surface veneer layer 40: undercoat

50: middle layer 60: top layer

70: top layer

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

1 is a manufacturing process diagram of the flooring material for the flooring of the present invention is prepared first plywood layer 10 for durability and dimensional stability. 7.5 mm is preferable for the thickness of the plywood layer 10, and it is used by humidifying so that a moisture content may be 10% or less.

Melamine resin-based adhesive containing a germanium compound, which is a far-infrared emitter, is applied to the entire upper surface of the plywood layer 10 at about 11 to 15 g / ft ² to form an adhesive layer 20. In this case, the germanium compound may be an organic germanium compound, an inorganic germanium compound, or a mixture containing them. Moreover, it is preferable to adjust content of this germanium compound in the range which does not interfere with the adhesive force of an adhesive agent, and about 2 weight% is suitable.

The surface veneer layer 30 having a thickness of about 0.5 mm, which gives a natural realism and a beautiful appearance effect to the adhesive layer 20 formed as described above, is inlaid and bonded by thermal pressure.

Next, as a first cutting process, first, the surface of the surface veneer layer 30 is polished by using 120 to 180 times of abrasive paper, and then the surface of the polished surface is coated with snow and then dried. At this time, the snow covering is to adjust the surface of the surface veneer layer 30 before forming the coating layer, that is, the urethane resin-based snow filler is applied to the surface veneer layer 30 using a reverse roll coater. And fill and smooth the conduits of the surface veneer to prevent the paint of the coating layer from penetrating into the surface veneer layer 30 or to prevent staining due to such infiltration. 30) increase the compatibility, ie adhesion between.

After the snow filling process, the coating layer is formed on the surface veneer layer 30. In the present invention, the coating layer is formed from below, the lower coat layer 40, the middle coat layer 50, the top coat layer 60, and the top coat layer 70. It consists of four layers.

First, the undercoat layer 40 is formed to fix and stabilize the fibers of the surface veneer and to increase the adhesion between the surface veneer layer 30 and the coating layer. The undercoat is obtained by applying a urethane acrylate resin paint using a roll coater and then curing it by passing an ultraviolet lamp. At this time, the coating contains a germanium compound. As in the adhesive layer 20, an organic germanium compound, an inorganic germanium compound, or a mixture containing the same may be used, and the same may be applied to the intermediate and upper coating layers below. It is preferable to adjust content of a germanium compound in the range which does not change glossiness or a color, and about 3-7 weight% is suitable.

After the undercoat 40 is formed, the intermediate layer 50 is formed to fill the conduit hole still present so that the smooth top coat layer 60 is formed. In addition, the urethane acrylate resin paint is applied using a roll coater, and then cured by passing through an ultraviolet lamp to form a middle layer 50. At this time, the content of the germanium compound is preferably about 2 to 6% by weight.

After the intermediate layer 50 is formed in this way, the surface is polished using 240 to 280 abrasive papers and subjected to secondary cutting.

Thereafter, a top coat layer 60 for beautiful luster is formed. The urethane acrylate resin paint is applied by using a roll coater, and then cured by passing through an ultraviolet lamp as in the undercoat 40 and the interlayer 50, thereby forming a top coat 60. At this time, the content of the germanium compound About 4-8 weight% of silver is suitable.

Finally, after coating the urethane acrylate resin-based paint containing no germanium compound to the top coat layer 60, it is also cured by passing through an ultraviolet lamp to form the top layer 70, thereby completing the flooring material for the ondol of the present invention. .

Figure 2 is a cross-sectional view of the flooring flooring material for flooring manufactured according to such a manufacturing process from the bottom, plywood layer 10, adhesive layer 20, surface veneer layer 30, the undercoat layer 40, the middle layer 50 The top layer 60 and the top layer 70 are stacked in this order. In addition to the double adhesive layer 20, the germanium compound is contained in one of the four layers of the lower coat layer 40, the middle coat layer 50, and the upper coat layer 60 or two or more layers.

In this way, the flooring material for the ondol which consists of the plywood layer 10, the adhesive layer 20, the surface veneer layer 30, the undercoat layer 40, the intermediate layer 50, the top coat layer 60 and the top layer 70 The far-infrared radiation effect of the germanium compound, which is a far-infrared radiator, is included in one or two or more layers of the four layers of the adhesive layer 20, the underlayer 40, the middle layer 50, and the top coat layer 60. It is possible to obtain a flooring material for ondol having.

In this case, the far-infrared radiation effect can be seen as an infrared emissivity measured by a Fourier transform infrared spectrometer (FT-IR Spectrometer of Midac, USA), which is a conventional ondol flooring material generally manufactured in the far-infrared region of the wavelength range of 5 to 20㎛. While showing an emissivity of 83 to 85%, it can be seen that the flooring material for ondol according to the present invention shows a high emissivity of 90% or more.

Due to the high far-infrared radiation effect of the flooring material for the ondol can also be expected to heat, improve blood circulation, recover from fatigue and relieve adult diseases, thus providing a better living space.

The germanium compound, which is a far-infrared emitter, has an antimicrobial effect in addition to the far-infrared radiation effect, and improves wear resistance when using a gemstone containing an inorganic germanium compound.

Claims (2)

In the flooring material for underfloor consisting of the plywood layer 10, the adhesive layer 20, the surface veneer layer 30, the undercoat layer 40, the middle layer 50, the top coat layer 60 and the top layer 70 The floor covering material for ondol, comprising an infrared ray radiator contained in one or two or more of four layers of the adhesive layer 20, the undercoat layer 40, the intermediate layer 50, and the upper coat layer 60. The floor covering for ondol according to claim 1, wherein the far-infrared emitter is an organic germanium compound, an inorganic germanium compound or a mixture containing them.