KR101488964B1 - Window device with anion radiation structure - Google Patents

Abstract

The present invention relates to a door (10) comprising a door (11) and a door frame (12); A porous article (20) accommodated in a surface of the window (10) and having an anion emitting material (25); And protective means formed outwardly to support the porous article (20).
Thereby, it is used as a construction material, and the function of generating negative ions over a relatively long period of time is maintained, and the radiation that can be emitted together with the negative ions is reduced, thereby improving the safety of the human body.

Description

[0001] The present invention relates to a window device with an anion radiation structure,

The present invention relates to a window apparatus having an anion radiation structure, and more particularly, to a window apparatus having an anion radiation structure for imparting an anion effect to a building material.

In addition to air purification and sterilization functions, anion is usually known to promote ionization of minerals in blood, purifying blood and increasing resistance. Therefore, the use of negative ions is gradually spreading from household items such as bracelets and sanitary napkins to clothing, home appliances, automobiles, and construction.

Of these, reference can be made to Korean Registered Utility Model No. 0378127 (Prior Art 1) and Korean Registered Utility Model No. 0348526 (Prior Art 2), which are related to technology for utilizing negative ions in the construction field.

In the prior art 1, an aluminum foil is adhered to a lower side of a substrate by adhering a surface paper such as a printed board made of a synthetic resin which provides various patterns to the upper side of the substrate. The substrate is made of ceramic powder or activated carbon powder, And the surface of the raw material is mixed with at least one of ceramic powder, silver nano powder, or gold nano powder. As a result, an effect of emitting a large amount of negative ions and far infrared rays and minimizing the interlayer noise is expected.

The prior art document 2 includes a plate having a predetermined thickness, width and length; Coating means for forming a liquid coating film or sheet-like film attached to the surface of the plate material; The coating means may further comprise any functional nanomaterial which is at least one of far infrared rays and anion emission or antibacterial, antiseptic, antifungal, flame retardant, fireproof, deodorant, directional, fluorescent, harmful wave shielding or shielding. Accordingly, it is expected that the beneficial effect on the human body can be provided easily and easily without reducing or damaging it.

However, although the efficacy by far-infrared radiation can be expected according to the above-mentioned prior art documents, the efficacy due to anion emission is not expected to be expected in the building materials used for a long time.

1. Korean Registered Utility Model No. 0378127 "Functionalizing plate" (Open date: March 11, 2005) 2. Korean Utility Model Registration No. 0348526 entitled " Functional Nano-Coated Preparations "(Published on Apr. 28, 2004)

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above-mentioned problems of the prior art by providing a method for manufacturing a flat panel having an anion radiation structure for maintaining a function of generating negative ions for a relatively long period of time.

It is another object of the present invention to reduce the radiation that can be emitted with anions.

In order to achieve the above object, the present invention provides a door structure comprising: a window formed of a door and a door frame; A porous body accommodated in the surface of the window and having an anion emitting material; And protective means formed outward to support the porous body.

According to the detailed configuration of the present invention, the porous article is characterized by being selected from a fiber, a foamed resin, a ceramic, an activated carbon, a sponge, a hard rubber, and a MOF (Metal-Organic Framework).

According to the detailed construction of the present invention, the protective means is characterized in that a skin sheet having uniform micropores is used and is bonded to a window with an adhesive having an anionic radiation material.

According to the detailed configuration of the present invention, a radiation shielding material is further provided between the porous article and the protection means.

As a modification of the present invention, the window may further include emission promotion means for promoting the generation of negative ions in the porous body under the set conditions.

As described above, according to the present invention, it is possible to maintain the function of generating negative ions for a relatively long period of time while being used as a construction material, and reduce radiation that can be emitted together with negative ions, thereby improving safety for the human body.

1 is a perspective view showing a window according to the present invention;
2 is a diagram showing a state in which a protective means is installed in a window of Fig. 2. Fig.
3 is a cross-sectional view showing an example of installation of a porous body of a window according to the present invention
4 is a structural view showing an installation example of the emission promoting means of a window according to the present invention

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

The present invention is based on a window (10) composed of a door (11) and a door frame (12). The door (11) and the door frame (12) are generally formed into a rectangular structure combining a vertical member and a horizontal member. The window 10 has a plurality of concave-convex rails 15 for holding the doors 11 on the door frame 12 so as to be openable and closable while keeping the airtightness. The material of the window 10 is not limited to the wood, the aluminum alloy, and the resin of the high chassis.

According to the present invention, a porous body (20) having an anionic radiation material (25) is received on the surface of the window (10). The porous article 20 is accommodated by forming grooves on the surface facing the room in the vertical member of the window 10 and the horizontal member. The receiving grooves may be formed continuously or intermittently. The anion emitting material 25 continuously generates negative ions in a state of being attached on the porous article 20. The attachment of the anion emitting material 25 can be performed by an impregnation process using a liquid adhesive.

According to the detailed configuration of the present invention, the porous article 20 is selected from among fibers, foamed resins, ceramics, activated carbon, sponge, hard rubber, and MOF (Metal-Organic Framework). The porous article 20 uses a porous material having pores having a diameter ranging from 100 nm to 1 mm. Representative porous materials include fiber, foamed resin, activated carbon (activated carbon), and the like. Particularly, the activated carbon is relatively inexpensive and strong in adsorption, so that the adhesive force of the anion radiation material 25 can be maintained for a long time. A sponge, a hard rubber, or the like can be applied to the window 10 of relatively low cost. In addition, MOF is a porous hybrid with uniformly sized and shaped pores that are arranged very regularly.

At this time, the porous material 20 of the present invention may be a mixture of two or more of the above-mentioned porous materials. In terms of productivity, a simple laminated structure is preferable to reformation of the porous material through pulverization.

On the other hand, the anion radiation material 25 uses tourmaline, monazite, or the like which generates negative ions without friction or pressurization. Quartz porphyry, zeolite ore, zircon, zeolite, pegmatite, etc. can be added as a substitute. That is, in the case of some metals, it is difficult to generate anions by a conventional process, so that a mixed structure of a plurality of materials is not excluded. In any case, the anion radiation material 25 is used by crushing the pores of the porous article 20 into a particle size that does not block the pores.

Further, according to the present invention, a protective means is formed outward to support the porous article 20. The porous article 20 accommodated in the surface of the window 10 may be separated or separated by an external force during use. The protection means must be installed to support the porous body 20 on the door 11 and the door frame 12 and to permit the release of the anion radiation material 25. [

According to the detailed configuration of the present invention, the protective means is formed by using the skin sheet 40 having uniform micropores 45 and by using the adhesive 30 with the anion radiation material 25 to adhere to the window 10 . The skin sheet 40 uses a resin material having a pattern and color for decorating, and has fine pores 45 uniformly arranged so that the negative ions can pass therethrough. The adhesive 30 for bonding the skin sheet 40 is used by mixing the above-described anion emitting material 25.

Of course, the coating material may be applied instead of the skin sheet 40 as the protection means of the present invention. In this case, the above-described negative ion radiation material 25 is mixed with the coating material.

As shown in FIG. 3, in addition to forming the micropores 45 in the skin sheet 40, it is also possible to form deeper micropores 45 while the skin sheet 40 is attached to the window 10. In the latter case, the micropores 45 are communicated with the center of the porous article 20 having the anion radiation material 25.

On the other hand, as a modified example of the present invention, when the porous article 20 is composed of a plurality of layers, the physical properties of the protective means can be reduced or the protective means can be omitted. For example, a structure in which activated carbon impregnated with the anion radiation material 25 is laminated on the lower layer and MOF not impregnated with the anion radiation material 25 is laminated on the upper layer can be used. In this case, it is possible to omit the skin sheet 40 or the coating material, which is a protection means, or to install the skin sheet 40 in a very thin and porous state.

According to the detailed configuration of the present invention, a radiation shielding material 35 is further provided between the porous article 20 and the protection means. There is a controversy about the harmfulness of minerals that generate anions because they emit radiation in general although there is a difference in degree. The radiation shielding material 35 is pulverized or synthesized to have a nano size of 100 to 950 nm so as to increase the probability of collision with the radiation. Examples of the radiation shielding material 35 include iron, tungsten compounds, barium sulfate, gadolinium oxide (Gd ₂ SO ₃ ), and the like. On the other hand, lead, cadmium, etc., which are excellent in radiation shielding ability, are toxic and are excluded for use as a radiation plate. The radiation shielding material 35 is formed to have a thickness as thin as possible for facilitating the passage of negative ions.

As a modification of the present invention, the window (10) is further provided with emission promoting means (50) for promoting the generation of negative ions in the porous body (20) under the set conditions. The anion emitting material 25 of the porous article 20 is accompanied by fluctuation of anion living water depending on conditions such as pressure, temperature, humidity and voltage. The emission promoting means 50 arbitrarily or artificially imparts conditions corresponding to the physical properties of the anion radiation material 25. [

4, a vent hole is formed on the rail 15 of the window 10 as the simplest example of the emission facilitating means 50. As shown in Fig. A plurality of ventilation holes are formed in the rails 15 of the window 10 to reach the porous article 20. The air pressure is transmitted to the porous article 20 at the moment when the door 12 is engaged with the rail 15 in the process of opening and closing the door 11 to increase the number of generated negative ions. Such vent holes can be selected from angled, quadrangular, or trumpet types depending on the direction and cross-sectional shape of the flow path.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

10: window 11: door
12: door frame 15: rail
20: Porous article 25: Anion radiation material
30: adhesive 35: radiation shielding material
40: skin sheet 45: microporous
50: Emission promoting means

Claims (5)

A window 10 composed of a door 11 and a door frame 12;
A porous article (20) accommodated in a surface of the window (10) and having an anion emitting material (25); And
And protective means formed outward to support the porous article (20)
A radiation shielding material 35 is provided between the porous body 20 and the protection means,
Characterized in that the window (10) is provided with an emission promoting means (50) for promoting the generation of negative ions in the porous article (20) under at least one of the set pressure, temperature, humidity and voltage. The method according to claim 1,
Characterized in that the porous article (20) is selected from the group consisting of fiber, foamed resin, ceramic, activated carbon, sponge, hard rubber, and MOF (Metal-Organic Framework). The method according to claim 1,
Characterized in that the protective means comprises a skin sheet (40) with uniform micropores (45) and is bonded to the window (10) with an adhesive (30) having an anionic emissive material (25) Your window mechanism. delete delete

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