KR101409449B1 - Visible lay lighting apparatus for air conditioning - Google Patents

Abstract

The present invention relates to a visible light lamp for air purification.
A visible light lamp for air purification according to the present invention is a lamp including a heat generating mechanism composed of a socket or a ballast, comprising: a light source for generating a visible light; A thermal contact portion formed adjacent to a distance of 0.1 to 10 cm from the light source and adjacent to any one of the heat generating mechanisms within a distance of 1 to 10 cm; And a photocatalyst thin film layer formed of titanium dioxide and optically excited in a visible light region, the photocatalyst thin film layer being bonded to the thermal contact portion with a binder.
According to the present invention, a photocatalytic thin film layer containing titanium dioxide which causes a photocatalytic reaction is formed on one side of a luminaire, and the photocatalytic thin film layer is formed of a material containing nitrogen as a doping component and is optically excited in a visible light region It is possible to sterilize bacteria contained in the room air and remove harmful substances. In particular, the photocatalyst thin film layer is a region adjacent to a heat generating mechanism such as a socket, a ballast, It is possible to increase the air movement at the point where the photocatalytic reaction occurs so that the air having the photocatalytic reaction can be actively moved without being stagnant in one place, A heat insulating case provided with a heat insulating material on the outside, The air temperature and the sterilization effect can be improved by guiding the flow of air by increasing the temperature of the air around the portion and forming a plurality of first guide holes in the portion, The second contact hole is formed on the outer side of the reflector to increase the atmospheric activity according to the temperature difference between the heat contact portion and the other portion and the thermal contact portion is formed of a sheet material which is detachably attached to the reflector, It is possible to replace the photocatalyst thin film layer without replacing the photocatalyst thin film layer.

Description

Technical Field [0001] The present invention relates to a lighting apparatus for air purification,

More particularly, the present invention relates to a photocatalytic thin film layer made of titanium dioxide as a main ingredient, and more particularly, to a photocatalytic thin film layer for air purifying use, which is capable of photoexciting in a visible light region other than ultraviolet light, .

There are various types of direct and indirect lighting fixtures, but if you look at the lighting fixtures by installation location, you can see the living room (ward), kitchen etc. where the person lives, the lighting lamp of the house for raising livestock, , Food storage (low-temperature) and high-intensity lamps are used only as the original lighting means. Also, the ultraviolet sterilizers used in living space are exposed to ultraviolet lamps and the indoor air is converted into the sterilizing power range of ultraviolet sterilizing lamp In particular, the ultraviolet rays emitted from the ultraviolet sterilizing lamp are in contact with the human body, and ultraviolet rays are brought into contact with the human body, thereby causing the occurrence of dermatitis (cancer) and the like The problem was also great.

Such conventional and indirect lighting fixtures are composed of direct or indirect lighting fixtures, reflectors (lamps), lamps, ballasts, etc., and other effects other than lighting can not be anticipated, so that special insect lamps or ultraviolet sterilization lamps are exposed And sterilization are installed in the living space.

As an example, there is a separate ultraviolet sterilization device in the living room (patient's room) where a person lives, a restaurant or a kitchen that treats food, a low-temperature storage room that stores food, and a vinyl house that grows vegetables. In another example, insecticidal lamps or sterilizing lamps made of ultraviolet sterilization lamps have been installed in indoor or housing buildings where people live in the summer season.

In addition, in general, when a luminaire is used for a long time, a variety of substances are adsorbed on the body of the lamp, the cover, or the reflector, so that the color is yellowed and the beauty is deteriorated.

Furthermore, the discoloration of the luminaire cover also reduces the light transmittance somewhat.

Such surface discoloration proceeds over a long period of time. When these luminaire bodies, luminaire covers or lamp shades are once discolored, they are not easy to clean. Once discolored, it is not easy to recover the original color.

Therefore, when the luminaire body, the cover, and the lamp shade are used for a long period of time, they will remain yellowish discolored in most cases and will be damaged.

A technique capable of solving these problems is disclosed in Korean Patent Laid-Open Publication No. 10-2006-0133681 (Patent Document 1), which discloses a titanium dioxide thin film which is sensitive to visible light and a method for producing the same. To accelerate and inject nitrogen ions; And a step of heat-treating the titanium dioxide thin film into which the nitrogen ions are implanted, as a doping component, and a method of manufacturing the same.

The titanium dioxide thin film having the bandgap adjusted bandgap can perform the photocatalyst function not only in the ultraviolet ray but also in the visible light region, thereby functioning as a photocatalyst under the light source that generates visible light, thereby purifying water, preventing fogging, .

Therefore, the improved titanium dioxide thin film can be applied to general luminaires to obtain effects such as indoor and air pollution purification.

However, such a theoretical expectation does not show substantial air purification effect in the ordinary room.

The reason is that the flow of air is not active in the room, so that the air of purified or sterilized air is less moved in the place where the titanium dioxide thin film is located, and as a result, only the effect of preventing the discoloration of the surface of the lamp shade is obtained.

KR 10-2006-0133681 (December 27, 2006)

A photocatalyst thin film layer containing titanium dioxide, which causes a photocatalytic reaction, is formed on one side of a luminaire. The photocatalyst thin film layer is formed of a titanium dioxide Nitrogen is doped as a doping component and is optically excited in the visible light region, thereby having a light effect through visible light and at the same time sterilizing bacteria contained in the indoor air and removing harmful substances.

Particularly, the photocatalyst thin film layer is formed in a thermal contact area adjacent to a heat generating mechanism such as a socket, a stabilizer, and the like, which is usually included in a luminaire, so that air movement at a point where a photocatalytic reaction occurs is increased, So that the air purification and disinfection effect of the entire room can be obtained.

Particularly, a heat insulating case provided with a heat insulating material outside the heat generating mechanism is provided to raise and raise the temperature of the air around the thermal contact portion, and by forming a plurality of first guide holes in this portion, air flow is guided, .

A second guide hole is formed on the outer side of the reflector to increase the atmospheric activity according to the temperature difference between the heat contact portion and the other portion.

In addition, the heat-contacting portion is formed of a sheet material that is detachably attached to the reflector so that only the photocatalyst thin film layer can be used without replacing the entire luminaire.

In order to solve the above-described problems, the present invention provides a luminaire including a heat generating mechanism including a socket and a ballast, the luminaire comprising: a light source for generating visible light; A thermal contact portion formed adjacent to a distance of 0.1 to 10 cm from the light source and adjacent to any one of the heat generating mechanisms within a distance of 1 to 10 cm; And a photocatalyst thin film layer formed of titanium dioxide and optically excited in a visible light region, the photocatalyst thin film layer being bonded to the thermal contact portion with a binder.

At this time, a heat insulating case for shielding a heat generating mechanism is formed outside the heat generating mechanism, a receiving part for receiving a heat generating mechanism is formed inside, a heat insulating material is provided on a wall surface of the heat insulating case, And the formed heat-contact portion is formed with a first guide hole at a portion in contact with the accommodating portion.

Further, the lamp is provided with a reflector, a thermal contact portion is formed on the center side of the reflector, and a second guide hole is formed on the outside of the reflector.

In addition, the photocatalyst thin film layer is characterized in that nitrogen is contained as a doping component.

Further, the thermal contact portion is a sheet material which is detachably attached to the reflector.

According to the present invention, a photocatalytic thin film layer containing titanium dioxide which causes a photocatalytic reaction is formed on one side of a luminaire, and the photocatalytic thin film layer is formed of a material containing nitrogen as a doping component and is optically excited in a visible light region It is possible to sterilize the bacteria contained in the indoor air and remove the harmful substances while having a lighting effect through the visible light.

Particularly, the photocatalyst thin film layer is formed in a thermal contact area adjacent to a heat generating mechanism such as a socket, a stabilizer, and the like, which is usually included in a luminaire, so that air movement at a point where a photocatalytic reaction occurs is increased, So that the air purification and disinfecting effect of the entire room can be obtained.

Particularly, a heat insulating case provided with a heat insulating material outside the heat generating mechanism is provided to raise and raise the temperature of the air around the thermal contact portion, and by forming a plurality of first guide holes in this portion, air flow is guided, Can be further improved.

A second guide hole is formed on the outer side of the reflector to increase the atmospheric activity according to the temperature difference between the heat contact portion and the other portion.

In addition, the heat-contacting portion is formed of a sheet material that is detachably attached to the reflector so that only the photocatalyst thin film layer can be used without replacing the entire luminaire.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exploded perspective view showing an embodiment of a visible light lamp for air purification of the present invention. FIG.
2 is a sectional view showing an embodiment of a visible light lamp for air purification according to the present invention.
3 is a sectional view showing still another embodiment of the visible light lamp for air purification of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a visible light lamp for air purification according to the present invention will be described in detail with reference to the accompanying drawings.

The lighting fixture of the present invention can be applied to various lighting fixtures such as general fluorescent lamps, incandescent lamps, and LED lamps. In such a lighting fixture, a heat generation phenomenon occurs in a socket or a ballast. In the present invention, It will be referred to as a mechanism 14.

Further, the heat generating mechanism 14 is not limited to the socket or the ballast as long as it generates heat in the luminaire.

In the present invention, the lamp, which is the light source 11, generates visible light. In the case of the ultraviolet lamp, it is not only harmful to the human body but also difficult to use as a lighting apparatus.

The thermal contact portion 20 is formed adjacent to the light source 11 within a distance of 0.1 to 10 cm and is located adjacent to the heat generating mechanism 14 within a distance of 1 to 10 cm.

1, the lighting apparatus includes a case 10 at the uppermost stage, a lamp and a ballast as a light source 11 are installed inside the lamp, and a lamp support 13 for supporting the lamp is installed have.

In addition, a reflector 12 is installed inside the case 10 so that the lamp can be exposed to the outside.

In such a configuration, the thermal contact 20 will correspond to the rectangular space of the bottom of the reflector 12 adjacent to the lamp, adjacent to the ballast as shown.

At this time, it is preferable that the thermal contact portion 20 is as close as possible to the light source 11 and the heat generating mechanism 14, and it is difficult to induce substantial air movement when the distance is 10 cm or more.

The photocatalyst thin film layer 30 is bonded to the thermal contact portion 20 with a binder and includes titanium dioxide, but is optically excited in a visible light region.

At this time, various known oil or inorganic binders for bonding titanium dioxide to the thermal contact portion 20 can be applied to the binder. Examples thereof include silica, an aqueous emulsion binder, and a resin binder.

When light having a certain level of energy or more is applied to the surface of a catalyst material such as zinc oxide, titanium oxide, or tin oxide, electrons are transferred to the surface of the particles and holes are generated.

The holes thus formed react with oxygen or water in the air to form a strong oxidizing compound (OH radical) dmf, which sterilizes bacteria on the surface of the catalyst and controls harmful substances. This is called a photocatalytic reaction.

When the light is absorbed, the photocatalyst shows the function of decomposing the harmful substances on the surface. It is used for the low temperature environment such as air, water quality and soil purification, and the oxidation and reduction power of the photocatalyst is very high. When used, it exhibits excellent antibacterial and deodorizing properties, and is used as a self-cleaning glass to prevent the surface from being dirty by itself because the photocatalyst decomposes contaminants attached to the surface.

The above-described Patent Document 1 discloses a photocatalyst thin film containing nitrogen as a doping component by accelerating and injecting nitrogen ions into a titanium dioxide thin film and heat-treating the thin titanium dioxide thin film. It is known that the photocatalyst functions also in a visible light region.

Or an oxide such as zinc oxide, platinum oxide, or magnesium oxide may be used as a doping component to produce titanium dioxide and photoexcited in an ultraviolet ray region.

When the visible light is generated from the light source 11 at the bottom of the reflector hatch, the light travels to the buzzard and the photocatalyst thin film layer 30 formed on the surface of the heat contact portion 20, which is a part of the reflector 12, .

As a result, bacteria in the air are sterilized by the photocatalytic reaction at the portion contacting with the photocatalytic film layer 30, and the contaminants can be purified.

Particularly, as shown in FIG. 2, air is heated in the heat generating mechanism 14 positioned adjacent to the upper side of the heat-contacting portion 20 and in a portion where the heat generated in the lamp is located close to the air, The air that has not been sterilized and purified is newly brought into contact with the photocatalyst thin film layer 30 due to the active movement of the air due to the temperature difference, so that the photocatalytic reaction can be caused.

At this time, the movement of the air is further activated, and the air cleaning efficiency can be improved by guiding the movement of the air.

Specifically, as shown in FIG. 3, a heat insulating case 40 for shielding the heat generating mechanism 14 is formed outside the heat generating mechanism 14, And a heat insulating material 41 may be provided on a wall surface of the heat insulating case 40. [

This is to make the air movement more active by keeping the temperature on the side of the heat contact portion 20 high.

At this time, a first guide hole 50 may be formed in a portion of the thermal contact portion 20 formed with the photocatalytic film layer 30 in contact with the receiving portion 42.

This is because the stabilizer or the like is usually installed on the upper side of the reflector 12 to be shielded from the reflector 12 so that the heat of the stabilizer is transmitted to the lower side. So that the heat of the accommodating portion 42 is more easily transmitted to the lower side so that the temperature of the air on the side of the thermal contact portion 20 is further raised to activate the atmospheric movement.

However, since the reflector 12 has a shape in which the outer periphery thereof is curved downward as shown in the figure, the heated and activated air has a tendency to be directed upward, so that even when the air is activated, Lt; / RTI >

In order to solve this problem, when the thermal contact portion 20 is formed on the center side of the reflector 12, a second guide hole 60 may be formed on the outer side of the reflector.

In this case, since the heated air of the central side thermal contact portion 20 is moved upward through the second guide hole 60, the air is circulated up and down with respect to the reflector 12, The air beneath the reflector 12 is moved upward so that the air beneath the reflector 12 moves up to the upper side of the thermal contact portion 20 Air purification by the photocatalytic reaction can be performed.

Although not shown in the above-described configuration, the thermal contact portion 20 can be formed of a sheet material that can be detachably attached to the reflector 12 by bolts, adhesive sheets, or the like.

In this case, when the function of the photocatalytic film layer 30 is deteriorated, the air purification performance can be maintained by replacing the photocatalytic film layer 30 only without replacing the luminaire. When the arrangement of the stabilizers or the arrangement of the light sources 11 is changed, 30 can be moved correspondingly.

INDUSTRIAL APPLICABILITY The visible light luminaires for air purification of the present invention can be applied to various luminaires for generating visible light such as general fluorescent lamps, incandescent lamps, LEDs, and halogen lamps.

In addition, since the visible light lamp for air purification of the present invention utilizes titanium dioxide, it has functions not only for air purification but also sterilization, deodorization, antibacterial, etc. according to the photocatalyst.

10: Case 11: Light source
12: Reflecting shade 13: Lamp support
14: heat generating device 20: thermal contact
30: photocatalyst thin film layer 40:
41: Insulation material 42:
50: first guide hole 60: second guide hole

Claims (5)

And a heat generating mechanism (14) made of any one of a lamp, a socket, and a ballast,
A light source 11 for generating visible light;
A thermal contact portion 20 formed adjacent to the light source 11 within a distance of 0.1 to 10 cm and adjacent to any one of the heat generating mechanisms 14 within a distance of 1 to 10 cm;
And a photocatalyst thin film layer (30) which is bonded to the thermal contact part (20) by a binder and is made of titanium dioxide and is optically excited in a visible light region,
The photocatalytic film layer 30 contains nitrogen as a doping component,
Characterized in that the heat-contacting portion (20) is a sheet material which is detachably attached to the reflector (12)
Visible light luminaires for air purification.
delete delete The method according to claim 1,
A heat insulating case 40 for shielding the heat generating mechanism 14 is formed outside the heat generating mechanism 14 and a receiving portion 42 for receiving the heat generating mechanism 14 is formed inside, A heat insulating material 41 is provided on the wall surface of the case 40,
Wherein the first contact hole (50) is formed in a portion of the heat contact portion (20) where the photocatalytic thin film layer (30) is formed and in contact with the accommodating portion (42)
Visible light luminaires for air purification.
5. The method of claim 4,
The lighting fixture is provided with a reflector 12, and a heat contact portion 20 is formed at the center of the reflector 12,
And a second guide hole (60) is formed on the outer side of the reflection plate.
Visible light luminaires for air purification.

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