KR20160035818A - Photocatalyst device - Google Patents

Abstract

The photocatalyst device (100) of the present invention comprises: a body (110) with a fixing unit (111) formed to be fixated on a case (210, 300) of an air conditioner (1000) for a vehicle; a light source unit (120) which comprises an LED (121), a substrate (122) where the LED (121) is fixated, and a first radiation fin (123) in the shape of a plate placed on one side of the substrate (122) having the LED (121) in the direction of the air flow, which irradiates ultraviolet light, and which is fixated onto the body (110); and a catalyst unit (130) for making a photocatalyst reaction by the light irradiated by the light source unit (120) to generate a hyperoxic radical. In other words, since there is the first radiation fin (123) in the shape of a plate placed in the direction of irradiation of light inside the body (110) and the direction of air flow, the heat generated from the LED (121) can be effectively discharged to provide the continuous sterilization and deodorization performance. Here, the first radiation fin (123) is formed in an area excluding the area where the LED (121) irradiates light to the catalyst unit (130), and does not interfere with the irradiation of light by the LED (121) to the catalyst unit (130) but secures the radiation performance of the LED (121).

Description

[0001] PHOTOCATALYST DEVICE [0002]

The present invention relates to a photocatalyst apparatus, more particularly, to a photocatalyst apparatus that purifies air introduced into an air conditioning case, sterilizes and deodorizes an evaporator, efficiently dissipates heat generated from the photocatalyst apparatus, To a photocatalyst apparatus.

An air conditioner for a vehicle includes an evaporator for cooling the inside of the air conditioner case, an evaporator for cooling the inside of the air conditioner case, an evaporator for cooling the inside of the air conditioner case, A heater core for the heating action, and air blown or heated by the evaporator or the heater core are selectively blown to respective portions of the vehicle interior using a blowing mode switching door.

On the other hand, not only the vehicle penetration rate is continuously increased but also the time in which the user is inside the vehicle is increasing, so research for maintaining the comfort inside the vehicle is continuing. However, since the interior of the vehicle is narrow and airtight and is susceptible to contamination, contamination of the interior of the vehicle is further increased due to fine dust and various pollutants in the city, and recently, a vehicle air purification apparatus for purifying indoor air of a vehicle has been developed .

As one example, Japanese Patent Application No. 2549032 (May 30, 1997), which was previously filed, discloses a cooling apparatus having a deodorizer for an automobile. 1 is a cross-sectional view showing a conventional cooling apparatus with a deodorizer for an automobile.

1, a conventional air conditioner with a deodorizer for an automobile is provided with an outside air inlet 21 and an inside air inlet 22 in a body 20, and an outside air inlet 21 and an inside air inlet 22 And an intake door 23 for selectively opening and closing is rotatably provided. An actuator 30 is connected to the pivot shaft of the intake door 23 and is controlled by the control means 31. A blower 25 for blowing the air introduced from the inside and outside air intake ports 21 and 22 to the downstream side is provided on the downstream side of the intake door 23 and the blower 25 is connected to the fan 32 and the fan 32 And a motor 33 for rotating the motor. On the downstream side of the blower 25, an evaporator 26 is installed and cools the air by exchanging heat with air passing therethrough. The air passage 28 on the downstream side of the evaporator 26 is provided with a photocatalytic filter 27 for generating active oxygen by irradiation with a long wavelength light. The photocatalytic filter 27 generates active oxygen by irradiation of the ultraviolet lamp 29, and the active oxygen oxidizes and decomposes the substance causing the odor to a very low concentration oxidizable compound. The ultraviolet lamp 29 is disposed between the evaporator 26 and the photocatalytic filter 27. The downstream side of the photocatalytic filter 27 is provided with a metal catalyst filter 34 for removing ozone contained in the flowing air. Reference numeral 35 denotes a temperature sensor, 36 denotes a sensor for sensing the odor level, 37 denotes a fan switch, and 24 denotes an air outlet.

However, in the conventional air conditioner with a deodorizer for automobiles, since the ultraviolet lamp 29 used as a light source of photocatalyst contains mercury therein, mercury is harmful to the human body and can not be applied to vehicles due to various environmental requirements There was a problem. In addition, the photocatalytic filter 27 is installed downstream of the evaporator 26 to adsorb and deodorize the odor generated in the evaporator 26, thereby causing a problem in that the filter must be replaced due to a decrease in the amount of dust overflow. In addition, the conventional cooling apparatus with a deodorizer for an automobile has a problem that the ultraviolet lamp 29 and the photocatalytic filter 27 are separate components, resulting in deterioration in assemblability.

Japanese Patent Publication No. 2549032 (May 30, 1997)

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide an air conditioner, an air conditioner, an air conditioner, an air conditioner, And to provide a photocatalyst device capable of continuously maintaining sterilizing and deodorizing performance by radiating heat.

The photocatalytic device of the present invention comprises: a body having a fixing part fixed to a case of a vehicle air conditioner; A light source unit that emits ultraviolet (UV) light and includes a first heat dissipation fin in a plate shape parallel to an air flow direction on one side of the substrate on which the LED is mounted; And a catalyst part for generating a photocatalytic reaction by the light irradiated by the light source part and generating oxygen radicals. That is, since the plate-shaped first radiating fins are arranged parallel to the air flow direction in the light irradiation direction inside the body, the heat generated from the LEDs can be effectively discharged, and the sterilizing and deodorizing performance can be continuously maintained.

At this time, the first radiating fins are formed in a region except for the region where the LED irradiates light to the catalyst portion, so that heat dissipation performance of the LED can be ensured without obstructing the LED irradiating the catalyst portion with light.

The body includes a supporting portion for supporting the LED substrate, an inclined portion formed to be inclined so as to be wider in the light irradiation direction of the light source portion from the supporting portion, and a slope portion projecting inward from the inner periphery of the slope portion to support the catalyst portion And a catalyst portion accommodating portion extending from the step portion to fix the catalyst portion. The catalyst portion accommodating portion can be fixed to the case of the air conditioner through the fixing portion, so that the mounting is easy.

In addition, the light source unit may include a second radiating fin on the opposite side of the substrate on which the LED is mounted, and a hollow portion may be formed in the body to hollow the predetermined region of the support portion so that the second radiating fin is inserted and protruded to the outside. have. The second radiating fins can effectively dissipate heat generated in the photocatalyst device together with the first radiating fins.

Accordingly, the photocatalyst apparatus of the present invention is capable of sterilizing and deodorizing the evaporator, efficiently dissipating heat generated in the photocatalyst apparatus, and continuously maintaining the sterilizing and deodorizing performance by purifying the air introduced into the air conditioning case There are advantages.

1 is a cross-sectional view showing a conventional cooling apparatus with a deodorizer for an automobile.
2 and 3 are a perspective view and a cross-sectional view of the photocatalytic device according to the present invention.
4 is a perspective view of a first radiating fin of a photocatalytic device according to the present invention.
5 and 6 are another cross-sectional view of the photocatalytic device according to the present invention and a perspective view of a first radiating fin.
7 is another sectional view of the photocatalytic device according to the present invention.
8 is a view showing a catalyst part of a photocatalytic device according to the present invention.
9 and 10 are a schematic view and a perspective view of a vehicle air conditioning system equipped with a photocatalytic device according to the present invention.

Hereinafter, the photocatalyst 100 of the present invention having the above-described characteristics will be described in detail with reference to the accompanying drawings.

4 is a perspective view of the first radiating fin 123 of the photocatalyst apparatus 100 according to the present invention, and FIGS. 5 and 6 are views showing a first embodiment of the photocatalytic device 100 according to the present invention. FIGS. 2 and 3 are a perspective view and a cross- 7 is a cross-sectional view of another embodiment of the photocatalytic device 100 according to the present invention. FIG. 8 is a cross-sectional view of the photocatalytic device 100 according to the present invention. 9 and 10 are a schematic view and a perspective view showing the automotive air conditioner 1000 equipped with the photocatalytic device 100 according to the present invention.

The photocatalyst 100 of the present invention includes a body 110, a light source 120, and a catalyst unit 130.

The body 110 supports the light source unit 120 and the catalytic unit 130 and is fixed to the cases 210 and 300 (the air conditioning case 300 or the air blowing case 210) of the air conditioner 1000 And is fixed to the cases 210 and 300 of the air conditioner 1000 for a vehicle.

The body 110 includes a support portion 112, an inclined portion 113, a step portion 114, and a catalyst portion receiving portion 115.

The supporting part 112 is a part for supporting the substrate 122 of the light source part 120 and the inclined part 113 extends from the supporting part 112 toward the step part 114 The light irradiated from the light source unit 120 mounted on the support unit 112 is guided to the catalyst unit 130 and is concentrated on the catalyst unit 130 to increase the amount of the catalytic reaction . As a result, the amount of oxygen radicals generated increases, and the sterilization and deodorizing effect can be increased. The catalytic part accommodating part 115 is a part where the catalytic part 130 is provided and the air inside the cases 210 and 300 of the automotive air conditioner 1000 is connected to the catalytic part 130 So as to be guided. Particularly, one surface of the catalytic portion 130 (the opposite surface of the supporting portion 112) is formed to be exposed to the inside of the case 210, 300. At this time, the catalyst part receiving part 115 can be slidingly coupled to the catalyst part 130 so that the catalyst part 130 can be detached easily so that the mounting and checking of the catalyst part 130 can be facilitated.

The light source unit 120 is fixed to the body 110 and emits ultraviolet light. The light source unit 120 includes a light emitting diode (LED) 121, a substrate 122 on which the LED 121 is fixed And a first heat radiation fin 123 in the form of a plate parallel to the air flow direction on one side of the substrate 122 provided with the LED 121. In Fig. 4, the air flow direction is indicated by an arrow.

The LED 121 irradiates UVA (Ultra Violet-A) light or UVV (Ultra Violet-C) light having a wavelength of 400 nm or less and solves the problem of mercury use which has been a problem in conventional mercury lamps, Effective light irradiation is possible. In this case, UVA is advantageous in cost because it is relatively inexpensive and effectively activates the photocatalytic reaction of the photocatalyst carrier. In addition, UVC is relatively expensive but can act to activate the photocatalytic reaction, and at the same time, perform sterilizing function on its own to improve sterilization efficiency. The light source unit 120 may include one LED 121 or two or more LEDs 121 corresponding to the size of the catalyst unit 130. Of course, when two or more of the LEDs 121 are provided, all the LEDs 121 that emit UVA (Ultra Violet-A) and UVC (Ultra Violet-C) may be provided.

Meanwhile, it is very important that the light source 120 emits heat generated from the LED 121 and the substrate 122 to maintain a high light amount. Accordingly, the first radiating fins 123 are provided to increase the heat radiation performance, and are formed in a plate shape parallel to the air flow direction on one side of the substrate 122 provided with the LED 121. The inclined portion 113 of the body 110 is provided between the one side of the substrate 122 having the LED 121 inside the body 110 and the catalyst portion 130, There is a region irradiated with light by the first radiating fin 123, and the first radiating fin 123 radiates heat through the air flowing in the region. At this time, the first radiating fins 123 are formed in a plate shape parallel to the air flow direction inside the case 210, 300 of the air conditioner 1000 of the automobile, and the light from the LED 121 to the catalyst part 130 To form an area excluding the irradiated area. The first heat radiating fin 123 shown in FIGS. 3 and 4 has a central region where the LED 121 is provided in the left and right direction (air flow direction) of the drawing, the fin is not protruded, An example is shown in which heat can be easily emitted without blocking the light emitted from the LED 121. 5 and 6 illustrate two examples of the LED 121 formed in the left and right direction of the drawing and an example in which the first radiating fins 123 are tilted downward as they are away from the two LEDs 121 Respectively. In the photocatalytic module of the present invention, the shape of the first radiating fin 123 is not limited to that shown in the drawing, and the LED 121 may be freely formed in a region other than a region irradiated with light by the catalyst portion 130 .

The light source unit 120 includes a second heat dissipation fin 124 on the opposite side of the substrate 122 on which the LED 121 is provided and the body 110 has a second heat dissipation fin 124 inserted therein, A hollow portion 112a in which a certain region of the support portion 112 is hollow may be formed. That is, the second radiating fins 124 are formed on the opposite side of the substrate 122 on which the first radiating fins 123 and the LEDs 121 are provided and emit heat together with the first radiating fins 123 .

The photocatalyst 100 of the present invention can effectively dissipate the heat generated from the LED 121 by providing the first radiating fin 123 and the second radiating fin 124 to maintain the light quantity characteristic of the LED 121 high And can increase the durability, so that sterilization and deodorization performance can be maintained continuously.

The first radiating fins 123 and the second radiating fins 124 are formed in close contact with both sides of the substrate 122 to fix the substrate 122 to the supporting portion 112 of the body 110 It may be concluded at once.

The catalytic unit 130 generates photocatalytic reaction by the light irradiated by the light source unit 120 and generates oxygen radicals. The catalytic unit 130 generates a photocatalytic reaction by the light irradiated from the light source unit 120 and oxidizes the excess oxygen radical generated in the photocatalytic reaction to remove the pollutant introduced into the air conditioning case 300 , Fungi in the evaporator (410), various contaminants and odors. More specifically, when the light emitted from the light source unit 120 is absorbed by the photocatalyst, electrons of a valence band (VB) filled with electrons absorb the light energy, and a conduction band (CB) ). Hole, the empty electron spot of the valence band, oxidizes the water molecules on the surface, and the oxidized water molecules form OH radicals. In addition, an excited electron, excited by a conduction band, reacts with oxygen to produce a strong oxidizing oxygen radical.

The catalyst unit 130 may include a carrier 131 and a coating layer 132 coated with the carrier 131 by coating a catalyst liquefied in a gel form by adding a co-catalyst and an acidic additive. have. 8). The support body 131 may be formed of various structures including a mesh, and may be made of a material having metal or elastic characteristics.

As the catalyst, titanium oxide particles having a particle size of 10 nanometers to 60 nanometers are formed, and the surface area value of the titanium oxide particles is formed to be 330 m ² / g or more. More specifically, titanium oxide (TiO ₂ ) used as a photocatalyst receives ultraviolet rays of 400 nm or less to generate oxygen radicals, and the produced oxygen radicals decompose organic substances into safe water and carbon dioxide. The titanium oxide is nanoparticles, and a large amount of oxygen radicals can be produced even by using a light source having a relatively weak ultraviolet wavelength. Therefore, it has excellent decomposing ability of organic matter, has persistent durability and stability against environmental change, and has a semi-permanent effect. In addition, a large amount of oxygen radical can remove various substances such as odors, bacteria and the like as well as organic substances. Since the catalytic portion 130 has a surface area value of nanoparticulate titanium oxide of 330 m ² / g or more, the number of particles that receive light energy per area is much larger than that of ordinary titanium oxide, .

At this time, the co-catalyst may be alumina. In this case, the supporting force of the catalytic portion 130 can be further improved and the fixing ability of the carrier 131 can be increased.

An example of the manufacturing process of the catalyst part 130 is as follows. After titanium oxide is granulated at a high temperature of 10 to 60 nanometers through a calcination and a room temperature drying process, a catalyst composed of alumina is added Process liquid. Thereafter, the liquid phase is secondarily processed in accordance with the intended use, is carried on the carrier 131, and is fixed to the carrier 131 through the secondary drying and firing process.

The photocatalyst 100 of the present invention is a structure for generating oxygen radicals by photocatalytic reaction using the light source unit 120 and the catalytic unit 130. The photocatalyst apparatus 100 has a structure for adsorbing and deodorizing polluted air containing a conventional odor There is an advantage that it is almost semi-permanently usable through the type selection of the carrier or the appropriate ON / OFF control of the light source unit 120. [

The photocatalyst 100 of the present invention is fixed to the air blowing case 210 or the air conditioning case 300 of the automotive air conditioner 1000 by the fixing portion 111 of the body 110 to clean do. At this time, it is preferable that the photocatalyst apparatus 100 of the present invention is provided on the front side of the evaporator 410 provided inside the air conditioner 1000 to sterilize and deodorize the evaporator 410.

The vehicle air conditioning system 1000 will be briefly described. (See Figs. 9 and 10)

The vehicle air conditioner 1000 includes an air blowing device 200 including an inlet duct, an inside / outside switching door 213, a fan 214 and a ventilation case 210, And an air conditioning case 300 in which the components for controlling the air conditioner 300 are incorporated.

The inflow duct is formed with an inflow inlet 211 and an inflow inlet 212, respectively. The inside air inlet 211 communicates with the inside of the vehicle, and the outside air inlet 212 communicates with the outside of the vehicle, so that outside air flows into the outside air inlet 212.

The inside / outside switching door 213 is provided inside the inlet duct to open / close the inside air inlet 211 and the outside air inlet 212. The inside / outside switching door 213 is operated in accordance with the setting of the vehicle occupant to control the outside air or the inside air to be selectively introduced.

The fan 214 forcibly blows air or outside air.

The air blowing case 210 has one side connected to the inlet duct and the other side connected to the inlet side of the air conditioning case 300, and a fan 214 is provided inside. More specifically, the air blowing case 210 includes a fan mounting portion connected to the inlet duct to mount the fan 214, and a connection portion 210 extending from the periphery of the fan mounting portion and connected to the inlet side of the air conditioning case 300. [ .

The air conditioning case 300 is connected to an air inlet and an air blowing case 210 so that air is introduced into the air conditioning case 300. An evaporator 410 and a heater core 420 are provided in the air conditioning case 300, And is supplied to the passenger compartment through a plurality of vents 310. In this case, generally, the evaporator 410 is cooled by the cooling of the refrigerant, and the heater core 420 heats the heated air. The air conditioning case 300 is provided with a temperature control door 320 for determining the degree of the air passing through the evaporator 410 through the heater core 420. In other words, the temperature control door 320 adjusts the opening degree of the air passage through which the air passed through the evaporator 410 passes through the heater core 420 and the air passage not passing through the heater core 420. The ventilation case 300 is formed with a vent 310 through which the temperature-controlled air is evaporated by the evaporator 410 and the heater core 420 to the interior of the vehicle. The vent 310 includes a face vent 310, a defrost vent 310, and a floor vent 310. The face vent 310 discharges air to the front side (front seat) of the vehicle interior. The defrost vent 310 discharges air toward the windshield of the vehicle interior, and the floor vent 310 The face vent 310, the defrost vent 310, and the floor vent 310 are adjusted in opening through respective mode doors 310d.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: photocatalyst device
110: Body
111:
112: Support part 112a:
113:
114: step portion 115: catalyst portion accommodating portion
120: Light source
121: LED 122: substrate
123: the first radiating fin
124: the second radiating fin
130:
131: Carrier 132: Coating layer
200: blower
210: air blowing case
211: Air inlet port 212: Outer air inlet
213: internal / external switching door 214: blowing fan
300: Air conditioning case
310: vent 310d: mode door
320: Temperature control door
410: Evaporator
420: heater core
1000: Car air conditioner

Claims (4)

A body having a fixing part fixed to a case of the air conditioner of the vehicle;
A light source unit that emits ultraviolet (UV) light and includes a first heat dissipation fin in a plate shape parallel to an air flow direction on one side of the substrate on which the LED is mounted;
And a catalyst part for generating a radical of oxygen by causing a photocatalytic reaction by the light irradiated by the light source part.
The method according to claim 1,
The body includes a supporting portion for supporting the LED substrate, an inclined portion formed to be inclined so as to be wider in the light irradiation direction of the light source portion from the supporting portion, and a step portion projecting inward from the inner periphery of the inclined portion, And a catalyst portion accommodating portion extending from the step portion to fix the catalyst portion.
3. The method of claim 2,
Wherein the first radiating fin is formed in a region of the LED except for a region irradiated with light by the catalyst portion.
The method according to claim 1,
Wherein the light source unit includes a second radiating fin on an opposite side of the substrate having the LED,
Wherein the body is formed with a hollow portion in which a predetermined region of the support portion is hollow so that the second radiating fin is inserted and protruded to the outside.

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