KR101553665B1 - Activated carbon filter module, purificating and neutralizing apparatus for hazardous gas - Google Patents

Abstract

The present invention relates to an activated carbon filter module for decomposing and adsorbing harmful substances in the air using activated carbon coated with a photocatalyst, and a harmful gas purifying and neutralizing device having the activated carbon filter module. The activated carbon filter module according to the present invention comprises a case having an inlet for introducing air, a discharge port for discharging air, and an activated carbon filling chamber provided between the inlet and the outlet, a case filled in the activated carbon filling chamber and coated with a photocatalyst on the activated carbon pellet A light irradiation unit provided in the activated carbon filling chamber for irradiating light to a plurality of photocatalyst activated carbons; and a plurality of photocatalyst activated carbons provided in the activated carbon filling chamber for supporting the light irradiation unit and supplying power to the light irradiation unit Support pillars. The light irradiation unit has a plurality of lamps for generating light, a support bar to which the plurality of lamps are coupled to the outer surface, and a light-transmissive cover for surrounding the plurality of lamps and the support bar.

Description

TECHNICAL FIELD [0001] The present invention relates to an activated carbon filter module, and to a purifying and neutralizing apparatus for a hazardous gas,

The present invention relates to an activated carbon filter module, and more particularly, to an activated carbon filter module for decomposing and adsorbing harmful substances in the air using a photocatalyst-coated activated carbon, and a harmful gas purifying and neutralizing device having the activated carbon filter module.

In general, the conventional harmful gas purifying and neutralizing apparatus has been provided as a fixed-type large-scale facility mainly in a thermal power plant, a waste incineration plant, a large-scale combustion gas generating plant, a semiconductor manufacturing plant using a dry etching process.

Generally, these devices can be roughly divided into dry and wet devices, and the dry type device for cleaning harmful gas has a dust collecting and damping device using high voltage and an incinerator device and a filter device for pyrolyzing harmful components. In addition to the above facilities, the wet type facilities for harmful gas purification and purification include harmful component collection facilities, neutralization facilities, wastewater treatment facilities and filter facilities.

However, most of these devices are suitable for outdoor large-scale combustion gas harmful gas purification and / or neutralization equipment which processes harmful gas generated from a combustion furnace or an incinerator or harmful gas generated from a dry etching process facility and directly discharges it to the outside air , It is not suitable to manufacture and use small-sized movable type or stand type having independent form.

On the other hand, although air cleaners and air cleaners which have been recently introduced for domestic use are small indoor units of a portable type or a stand type having an independent form, they are intended to be used for the purpose of purifying indoor air in a residential space such as a home or office And is essentially independent of harmful gas purification and neutralization processes. These household air purifiers and air purifiers have the functions of electric dust collection and dust removal as main functions, and have microbial sterilization function by using negative ion ozone generation, direction, deodorization or deodorization, UV lamp or silver nanofilter. These are intended to make the indoor air in the home or office comfortable, but they are not enough to purify and neutralize harmful or toxic gases when considering its structure and functions.

Korean Utility Model Registration No. 20-0392308 Korean Patent Registration No. 10-0778360

The present applicant has found that it is possible to effectively and efficiently apply harmful gases such as volatile organic compounds, odors, or fumes generated during research work or product production in a laboratory or a laboratory, a semiconductor or chemical production plant or a hospital, And has developed a room-use harmful gas purifying and neutralizing device for purifying and neutralizing. The harmful gas purifying and neutralizing apparatus developed by the applicant of the present application is disclosed in Korean Registered Patent No. 0941666 (registered on Mar. 02, 03, 2010), and various studies are currently under way to improve the harmful gas purification and neutralization efficiency.

SUMMARY OF THE INVENTION It is an object of the present invention to improve the decomposition and adsorption removal efficiency of harmful substances in the air by using a photocatalyst-coated activated carbon and a light irradiation unit for irradiating light thereto And a harmful gas purifying and neutralizing device having the activated carbon filter module.

According to an aspect of the present invention, there is provided an activated carbon filter module comprising: a casing having an inlet for air inflow, an outlet for air exhaust, and an activated carbon filling chamber provided between the inlet and the outlet; A plurality of photocatalyst activated carbons formed by coating activated carbon pellets with a photocatalyst, a plurality of lamps installed in the activated carbon filling chamber for irradiating light to the plurality of photocatalyst activated carbons and generating light, and a plurality of lamps And a support column for supporting the light irradiation unit and supplying power to the light irradiation unit, wherein the supporting pillars are provided on the support pillars, .

The light-transmissive cover may be provided with a plurality of through holes for discharging heat generated from the plurality of lamps to the outside.

A connector is provided at an end of the light irradiation unit. The support column is provided with a socket through which the connector can be electrically connected, and the light irradiation unit can be detachably coupled to the support column.

The activated carbon filter module according to the present invention comprises a first net disposed inside the discharge surface formed with the discharge port of the case to cover the discharge port and passing air therethrough to prevent the photocatalyst activated carbon from escaping to the discharge port, And a second net disposed inside the inflow surface formed with the inflow port of the case to allow air to pass therethrough and prevent the photocatalyst activated carbon from escaping to the inflow port.

The photocatalyst coated on the activated carbon may be a visible light-responsive photocatalyst.

The visible light responsive photocatalyst may be titanium dioxide doped with fluorine or titanium dioxide doped with fluorine and nitrogen simultaneously.

Wherein the support column includes a fixed body fixed to the case and a rotating body rotatably coupled to the fixed body in an electrically connected state with the fixed body, And to the rotating body.

According to another aspect of the present invention, there is provided a harmful gas purifying and neutralizing apparatus comprising: a main body having an inlet port and an outlet port; An activated carbon filter module disposed downstream of the pre-filter in the main body; and a blower installed between the inlet port and the exhaust port for forcedly flowing air inside the main body, The activated carbon filter module may include a case having an inlet for air inflow, an outlet for air exhaust, and an activated carbon filling chamber provided between the inlet and the outlet, and a photocatalyst coated on the activated carbon pellet A plurality of photocatalyst activated carbon, and a plurality of photocatalyst activated carbon A light irradiating unit installed in the activated carbon filling chamber for irradiating light, having a plurality of lamps for generating light, a support bar for coupling the plurality of lamps to the outer surface, and a light-transmissible cover for enclosing the plurality of lamps and the support bar; And a supporting column installed in the activated carbon filling chamber for supporting the irradiation unit and supplying power to the irradiation unit.

The activated carbon filter module according to the present invention is characterized in that the activated carbon pellets of the activated photocatalytic activated carbon charged in the activated carbon filling chamber between the inlet and the exhaust outlet adsorb and remove noxious gases and harmful substances in the air and the photocatalyst coated on the activated carbon pellets is irradiated with light And sterilize and sterilize harmful substances in the air. Therefore, the noxious gas in the air can be effectively purified and neutralized.

In addition, the activated carbon filter module according to the present invention can irradiate light uniformly to a plurality of photocatalytic activated carbons charged in the activated carbon filling chamber by being installed inside the case so that a plurality of light irradiation units are embedded in the plurality of photocatalytic activated carbons. Therefore, the overall photoactive efficiency of the photocatalyst activated carbon filled in the activated carbon filling chamber can be improved, and the air purification and sterilization efficiency can be further improved.

In addition, the activated carbon filter module according to the present invention has a structure in which a plurality of light irradiation units are detachably coupled to support pillars provided for power supply inside the case, so that the light irradiation unit can be easily installed and separated, When a problem occurs in the irradiation unit, the replacement work or the repair work for the light irradiation unit can be easily performed.

In addition, the activated carbon filter module according to the present invention uses photocatalytic activated carbon coated with activated carbon pellets of titanium dioxide modified to react even in the visible light region, so that the photocatalytic activated carbon can exhibit optical resolving power even in the visible light region. Therefore, the light irradiation unit for irradiating light to the photocatalyst activated carbon can be constituted by a low-cost lamp having low-power characteristics such as LED, and can be manufactured at low cost.

1 is a front view showing a harmful gas purifying and neutralizing apparatus according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view of the activated carbon filter module of the harmful gas purifying and neutralizing apparatus shown in FIG. 1. FIG.
3 is a side cross-sectional view showing the activated carbon filter module of the harmful gas purifying and neutralizing apparatus shown in FIG.
4 is a perspective view showing a light irradiation unit and a supporting column of the activated carbon filter module shown in Figs. 2 and 3. Fig.
5 is a graph showing the UV-visible light absorbance of modified titanium dioxide used in the production of the activated carbon of the activated carbon filter module according to the present invention by UV-visible diffuse reflectance spectrophotometer (UV-DRS) .
6 is an exploded perspective view illustrating an activated carbon filter module according to another embodiment of the present invention.
7 is a side sectional view showing an activated carbon filter module according to another embodiment of the present invention.

Hereinafter, an activated carbon filter module according to the present invention and a harmful gas purifying and neutralizing device having the same will be described in detail with reference to the accompanying drawings.

In describing the present invention, the sizes and shapes of the components shown in the drawings may be exaggerated or simplified for clarity and convenience of explanation. In addition, the terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. These terms are to be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the contents throughout the present specification.

FIG. 1 is a front view showing a harmful gas purifying and neutralizing apparatus according to an embodiment of the present invention, FIG. 2 is an exploded perspective view showing an activated carbon filter module of the harmful gas purifying and neutralizing apparatus shown in FIG. 1, FIG. 4 is a perspective view showing a light irradiation unit and a supporting column of the activated carbon filter module shown in FIG. 2 and FIG. 3. FIG. 4 is a side sectional view showing the activated carbon filter module of the harmful gas purifying and neutralizing apparatus shown in FIG.

1, a harmful gas purifying and neutralizing apparatus 10 according to an embodiment of the present invention includes a main body 11 having an intake port 12 and an exhaust port 13, The blower 17, and the activated carbon filter module 20, which are disposed in the flow path from the exhaust port 13 to the exhaust port 13. A pair of the activated carbon filter modules 20 are disposed with the blower 17 therebetween. The blower 17 is for forcibly flowing air between the intake port 12 and the exhaust port 13. When the blower 17 is operated, the outside air is sucked into the main body 11 through the intake port 12, The filter 15 and the plurality of activated carbon filter modules 20 are sequentially passed through and purified, and then discharged to the outside through the exhaust port 13. The activated carbon filter modules 20 disposed on the upper and lower portions of the blower 17 have the same structure.

The pre-filter 15 is a pretreatment filter for filtering foreign matter such as dust contained in the sucked air to reduce the load of the activated carbon filter module 20. [ The prefilter 15 may be a nonwoven filter of a reusable polyvinylchloride (PVC), polyethylene (PE), or polypropylene (PP) fiber, or a porous sponge filter as a filter known in the art, Filters, and the like can be used.

2 and 3, the activated carbon filter module 20 includes a case 21, a plurality of photocatalyst activated carbon 30 filled in the case 21, and a plurality of photocatalyst activated carbon 30, A plurality of light irradiation units 33 provided inside the case 21 for irradiating the plurality of light irradiation units 33 and a support column 40 provided inside the case 21 for supporting the plurality of light irradiation units 33 . The activated carbon filter module 20 adsorbs and removes noxious gases and harmful substances in the air that has passed through the pre-filter 15, and exhibits sterilization and sterilization functions.

The case 21 includes a case body 22 having an activated carbon filling chamber 23 filled with a plurality of photocatalyst activated carbons 30 and one side opened, a case cover 27 covering an open upper surface of the case body 22, . The case body 22 includes a discharge surface 24 in which a plurality of discharge ports 25 are formed and a fence 26 disposed around the edge of the discharge surface 24. The case cover 27 has an inflow surface 28 in which a plurality of inflow ports 29 are formed. The air that has passed through the prefilter 15 in the state where the plurality of photocatalyst activated carbon 30 is filled in the activated carbon filling chamber 23 and the case cover 27 is coupled to the case body 22 is introduced into the inlet port Flows into the activated carbon filling chamber 23 through the opening 29 and then passes through the gap between the plurality of photocatalyst activated carbon 30 and escapes to the outlet 25 of the case body 22.

The first net 31 is disposed inside the discharge surface 24 in order to prevent the photocatalyst activated carbon 30 charged in the activated carbon filling chamber 23 from escaping to the outside through the discharge port 25. The first net 31 has a structure having a plurality of vents such as a nonwoven fabric that covers the discharge port 25 so that the photocatalyst activated carbon 30 can pass through the discharge port 25 while preventing air from passing through. A second net 32 is provided inside the inflow surface 28 of the case cover 27 to prevent the photocatalyst activated carbon 30 charged in the activated carbon filling chamber 23 from escaping to the outside through the inflow opening 29 . The second net 32 has a structure having a plurality of vents such as a nonwoven fabric which covers the inlet 29 so that the photocatalyst activated carbon 30 can pass through the inlet 29 without passing through.

The plurality of photocatalyst activated carbons 30 are formed by coating a photocatalyst on the surface of activated carbon pellets of a predetermined size, and purify air flowing into the activated carbon filling chamber 23. That is, the activated carbon pellets constituting the photocatalyst activated carbon 30 adsorb and remove harmful gases and harmful substances in the air, and the photocatalyst coated on the activated carbon pellets is irradiated with light from the light irradiation unit 33, do.

As is well known, a photocatalyst is a substance that catalyzes a chemical reaction by changing the chemical state of a surface when light such as visible light or ultraviolet light is irradiated. When light is irradiated on the surface of the photocatalyst, a radical material such as a hydroxy radical or a superoxide anion is generated. The radical material thus produced functions to remove, sterilize and sterilize various harmful substances. Representative examples of the photocatalyst include titanium dioxide (TiO ₂ ), tin oxide (SnO ₂ ), iron oxide (Fe ₂ O ₃ ), tungsten oxide (WO ₃ ), zinc oxide (ZnO) and cadmium sulfide (CdS).

As the photocatalyst constituting the photocatalyst activated carbon 30 according to the present invention, various kinds of photocatalyst materials as described above can be used, but it is preferable to use titanium dioxide (TiO ₂ ) capable of photo activation in visible light. In particular, a high photocatalytic efficiency can be achieved by coating the activated carbon pellets with titanium dioxide (TiO ₂ ) doped with a plurality of non-metallic ions to form the photocatalyst activated carbon 30. A specific method for producing such a photocatalyst activated carbon 30 will be described later.

2 to 4, the light irradiation unit 33 irradiates a plurality of photocatalyst activated carbons 30, which are provided in a plurality of activated carbon filling chambers 23 and filled in the activated carbon filling chamber 23, Thereby photo-activating the photocatalyst of the photocatalyst activated carbon 30. The light irradiation unit 33 includes a plurality of lamps 34 for generating light, a support bar 35 for supporting the plurality of lamps 34, a plurality of lamps 34, And a light-transmissive cover 36.

As the lamp 34, various kinds of materials capable of irradiating visible light or ultraviolet light capable of photoactivating the photocatalyst of the photocatalyst activated carbon 30 may be used. The lamps 34 are arranged on the outer surface of the support bar 35 in plural. One end of the support bar 35 is coupled to the support column 40. A power supply path (not shown) for supplying power is provided inside the support bar 35 and a plurality of lamps 34 are operated by receiving power from the power supply path inside the support bar 35.

The supporting bar 35 may include a material having excellent thermal conductivity so as to dissipate heat generated from the lamp 34. The heat generated in the lamp 34 is transmitted to the support column 40 through the support bar 35 and the heat transmitted to the support column 40 is transferred to the activated carbon filling chamber 23, the problem of the lamp 34 being overheated can be reduced. At one end of the support bar 35, a connector 37 having a connector pin 38 is provided.

The light-transmissible cover 36 is made of a transparent or translucent material through which the light generated from the lamp 34 can be transmitted and covers the plurality of lamps 34 so that the photocatalyst activated carbon 30 contacts the lamp 34 It prevents you. The light-transmissive cover 36 is coupled to the support bar 35 while surrounding the support bar 35 to which the plurality of lamps 34 are coupled. The light-transmissive cover 36 is provided with a plurality of through-holes 39 for emitting heat generated by a plurality of lamps 34 disposed therein. The plurality of through holes 39 are provided in the light transmissible cover 36 so that the air passing through the activated carbon filling chamber 23 is introduced into the light transmissive cover 36 to thereby enhance the cooling efficiency of the lamp 34 have. In the figure, the light-transmissive cover 36 is shown coupled to the support bar 35 and coupled to the support column 40 together with the support bar 35, The support bar 35 may be wrapped around the support column 40 by being separated from the support bar 35 regardless of the support bar 35.

The light irradiation unit 33 irradiates a plurality of photocatalyst activated carbons 30 filled in the activated carbon filling chamber 23 in a state where a plurality of the photocatalyst active carbons 30 are coupled to the supporting columns 40 and embedded in the plurality of photocatalyst active carbons 30 Thereby improving the efficiency of air purification and sterilization by the plurality of photocatalyst activated carbon (30). Although four rectangular light irradiation units 33 are shown as being installed at the same height on the support posts 40 in the figure, the shape, number of installation, and installation positions of the light irradiation unit 33 can be variously changed .

A plurality of sockets 41 for coupling the light irradiation unit 33 and power supply paths for supplying power to these sockets 41 are formed in the support columns 40 supporting the plurality of light irradiation units 33 Not shown). The power supply path of the support column 40 is connected to a cable 44 to which a connector 45 is coupled at one end. The portion of the cable 44 where the connector 45 is engaged is exposed to the outside of the case body 22 and the remaining portion of the cable 44 is embedded in the discharge surface 24 of the case body 22, 40). The external power supplied through the cable 44 can be provided to the plurality of lamps 34 through the power supply path and the socket 41 of the support column 40 and the power supply path of the support bar 35. [ Of course, the external power supply structure for the lamp 34 may be variously changed, and a battery may be installed in the case 21 to receive power from a battery having a plurality of light irradiation units 33 have.

The socket 41 is provided in the coupling groove 42 formed on the outer surface of the support column 40 so that the end of the light irradiation unit 33 can be inserted and inserted into the socket 41, A pin engagement hole 43 into which the pin 38 can be inserted is provided. The light irradiation unit 33 is detachably coupled to the support column 40 and electrically connected to the socket 41. [ When the light irradiation unit 33 is detachably coupled to the support column 40, if the light irradiation unit 33 has a problem, the light irradiation unit 33 having a problem can be easily replaced or repaired .

In the present invention, the concrete structure of the case 21 constituting the activated carbon filter module 20, the light irradiation unit 33, and the support column 40 is not limited to the illustrated ones, and may be variously changed . For example, the case 21 has a structure in which the case cover 27 is detachably coupled to the case body 22, the inflow surface 28 is integrally provided at one end of the fence 26, And the discharge surface 24 may be integrally formed. The lamp 34 of the light irradiation unit 33 may be of various types such as an LED that generates visible light depending on the type of the photocatalyst of the photocatalyst activated carbon 30 or an ultraviolet lamp that generates ultraviolet rays.

Hereinafter, a method for manufacturing the activated carbon 30 of the activated carbon filter module 20 according to the present invention will be described.

Any known photocatalyst may be used as the photocatalyst constituting the photocatalyst activated carbon 30 coated on the activated carbon pellets in the present invention. Specific examples include titanium dioxide (TiO ₂ ), tin oxide (SnO ₂ ), iron oxide (Fe ₂ O ₃ ), tungsten oxide (WO ₃ ), zinc oxide (ZnO), cadmium sulfide (CdS) . ≪ / RTI > Of these various types of photocatalysts, TiO ₂ has no emission of harmful substances during photodegradation, can be used semi-permanently, and exhibits optical resolution without being dependent on specific substances. Therefore, in the present invention, as a photocatalyst coated on activated carbon pellets Most preferred.

When titanium dioxide is used as the photocatalyst, titanium dioxide has a high band gap of 3.2 eV and reacts only in the ultraviolet region having a wavelength shorter than 387.5 nm. Therefore, in order to increase the photodegradation efficiency and to maximize the utilization value of titanium dioxide as a photocatalyst, it is preferable to use titanium dioxide which is modified to react even in the visible light region.

In the present invention, as a method of modifying titanium dioxide so as to exhibit photolytic ability even in the visible light region, a method of doping fluorine to titanium dioxide or simultaneously doping fluorine and nitrogen to titanium dioxide can be used. When fluorine and nitrogen are doped into titanium dioxide, the band gap energy of titanium dioxide is lowered, and titanium dioxide exhibits photolytic ability even in the visible region.

Hereinafter, a method of coating titanium dioxide on activated carbon pellets, a method of doping titanium dioxide with fluorine, nitrogen, etc. will be described in detail.

First, the activated carbon pellets coated with titanium dioxide can be obtained by dissolving a titanium dioxide precursor in a solvent, sufficiently supporting the activated carbon pellets in the prepared titanium dioxide precursor solution, and then heat-treating the activated carbon pellets.

In addition, coating the activated carbon pellets with titanium dioxide modified to exhibit photolytic ability even in the visible light region can be accomplished by the following method.

First method: Doped  Activated carbon pellets coated with titanium dioxide of  Produce

(1) a first step of dissolving a titanium dioxide precursor in a solvent;

(2) a second step of supporting activated carbon pellets in the solution prepared through the first step

(3) a third step of heat treating the activated carbon pellets through the second step;

(4) The fourth step of reacting activated carbon pellets subjected to the heat treatment process of the third step with fluorine gas.

Method 2: Fluorine and nitrogen simultaneously Doped  Activated carbon pellets coated with titanium dioxide of  Produce

(I) a step of dissolving a compound containing a titanium dioxide precursor and nitrogen in a solvent;

(Ii) step ii) carrying the activated carbon pellets in the solution prepared through step i)

(Iii) a step iii) heat-treating the activated carbon pellet through the process of the step ii);

(Iv) an iv step of reacting activated carbon pellets subjected to the heat treatment in step iii) with fluorine gas.

The heat treatment in the third and the third step is preferably performed at a temperature of 100 to 500 ° C. for 0.1 to 1 hour. When the heat treatment temperature and time are less than the lower limit, sufficient heat treatment such as the presence of a residual solvent is not performed If the heat treatment temperature and time exceed the upper limit value, the structure of the activated carbon may be deformed, which is not preferable.

It is preferable that the reaction with the fluorine gas in the fourth step and the fourth step is carried out at a pressure of 0.1 to 3 bar for 0.1 to 1 hour. If the pressure and time of the fluorine gas are less than the lower limit There is a possibility that the effect of reducing the band gap of titanium dioxide can not be sufficiently achieved because the fluorine functional group is not sufficiently doped and if the pressure and time of the fluorine gas exceed the upper limit value, The resolution may be rather lowered.

The optical resolving power of the titanium dioxide in which fluorine is introduced or the titanium dioxide in which fluorine and nitrogen are simultaneously introduced as described above can be confirmed through the graph shown in Fig. FIG. 5 shows UV-visible light absorbance measured by a UV-visible Diffuse Reflectance Spectrophotometer (UV-DRS). In FIG. 5 (a), titanium tetraisopropoxide ( Titanium tetraisopropoxide was dissolved in 28.4 g of the solution, and the activated carbon pellet was immersed in the solution for 3 minutes and then heat-treated at 300 ° C for 30 minutes. (B) Titanium tetra isopropoxide was dissolved in the solution, and the activated carbon pellet was immersed in the solution for 3 minutes, then heat-treated at 300 ° C for 30 minutes, and activated carbon pellets were reacted with fluorine gas for 10 minutes under a pressure of 1 bar of fluorine gas , (c) is dissolved isopropanol (isopropanol) 100ml of titanium tetraisopropoxide in (titanium tetra isopropoxide) and 28.4g urea (NH ₂ CONH ₂₎ 5g, and then, to the solution After the Christmas pellets supported for 3 minutes, the sample was heat treated at 300 ℃ 30 minutes, and 10 minutes at a pressure of 1 bar reacting fluorine gas to activated carbon pellets and fluorine gas. As can be seen from FIG. 5, the sample (a) coated with titanium dioxide coated with neither fluorine nor nitrogen showed no activity in a visible light range of 400 nm or more, and a sample coated with fluorine-doped titanium dioxide (b ) And the sample coated with titanium dioxide coated with fluorine and nitrogen (c) showed activity not only in the ultraviolet region but also in the visible region.

The activated carbon filter module 20 according to the present invention can prevent the activated carbon pellets of the photocatalyst activated carbon 30 charged in the activated carbon filling chamber 23 between the inlet 29 and the outlet 25 from being exposed to noxious gas The photocatalyst coated on the activated carbon pellets is irradiated with light from the light irradiation unit 33 to sterilize and sterilize harmful substances in the air. Therefore, the noxious gas in the air can be effectively purified and neutralized.

The activated carbon filter module 20 according to the present invention is also provided with a plurality of activated charcoal filter modules 20 installed inside the case 21 so that a plurality of light irradiation units 33 are embedded in the plurality of photocatalyst activated carbon 30, The light can be uniformly irradiated to the photocatalyst activated carbon 30. Therefore, the overall photoactive efficiency of the photocatalyst activated carbon 30 filled in the activated carbon filling chamber 23 can be increased, and the air purification and sterilization efficiency can be further improved.

The activated carbon filter module 20 according to the present invention has a structure in which a plurality of light irradiation units 33 are simply and removably coupled to the support columns 40. This facilitates installation and separation of the light irradiation units 33 Do. Therefore, when a problem arises in the light irradiation unit 33, replacement or repair work for the light irradiation unit 33 can be easily performed.

Further, the activated carbon filter module 20 according to the present invention uses the photocatalyst active carbon 30 coated with activated carbon pellets of titanium dioxide modified to react even in the visible light region, so that the photocatalytic activated carbon 30 can exhibit optical resolution even in the visible region have. Therefore, the light irradiation unit 33 for irradiating the photocatalyst activated carbon 30 with light can be formed of a low-cost lamp having low-power characteristics such as LED, and can be manufactured at low cost.

FIG. 6 is an exploded perspective view illustrating an activated carbon filter module according to another embodiment of the present invention, and FIG. 7 is a side cross-sectional view illustrating an activated carbon filter module according to another embodiment of the present invention.

The activated carbon filter module 50 shown in FIGS. 6 and 7 is different from the activated carbon filter module 20 according to the embodiment of the present invention in that the number of the light irradiation units 33 and the number of the activated carbon filling chambers 23 The structure of the support pillars 51 is somewhat different, and the rest of the structure is the same. The concrete structure of the case 21 and the light irradiation unit 33 is the same as described above.

The supporting column 51 includes a fixed body 52 fixed to the case body 22 and a rotating body 53 rotatably coupled to the fixed body 52. The fixed body 52 and the rotating body 53, the bearings 54 are interposed. A plurality of sockets 41 (see Fig. 4) are provided in each of the fixed body 52 and the rotating body 53 and a plurality of light irradiation units 33 are electrically connected to the fixed body 52 and the rotating body 53 Respectively. The combined structure of the light irradiation unit 33 and the fixing member 52 and the combined structure of the light irradiation unit 33 and the rotating body 53 are the same as the combination structure of the light irradiation unit 33 and the base column 40 same.

The power supply structure of the support pillars 51 to the fixed body 52 is the same as that of the activated carbon filter module 20 described above. In other words, a power supply path (not shown) for supplying power to the plurality of sockets 41 is provided in the fixed body 52. The power supply path includes a cable 44 to which the connector 45 is coupled, And is electrically connected. The rotating body 53 can rotate while being electrically connected to the fixing body 52. [ Accordingly, the rotating body 53 can receive electric power supplied to the fixing body 52 and transmit power to the plurality of light irradiation units 33 coupled thereto. The coupling structure of the fixing body 52 and the rotating body 53 can be implemented by various methods such as a method using a rotary joint.

In the activated carbon filter module 50 according to another embodiment of the present invention, a plurality of light irradiation units 33 are arranged in a double layer structure in the activated carbon filling chamber 23, . ≪ / RTI > The rotating body 53 is rotatably coupled to the fixed body 52 so that the rotating body 53 is rotated to couple the light irradiating unit 33 coupled to the fixed body 52 and the rotating body 53 It is possible to more uniformly irradiate the plurality of photocatalyst activated carbons 30 filled in the activated carbon filling chamber 23 with the arrangement angle of the irradiated light irradiation unit 33. [

Although one rotating body 53 is shown as being rotatably coupled to the fixed body 52 of the supporting column 51 in the drawing, the number of the rotating bodies 53 can be variously changed. The plurality of light irradiation units 33 may be arranged in a three-layer or more multi-layer arrangement structure in addition to the two-layer arrangement structure as shown in FIG.

The embodiments of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art can improve and modify the technical idea of the present invention in various forms. Accordingly, such improvements and modifications will fall within the scope of the present invention as long as they are obvious to those skilled in the art.

10: Noxious gas purifying and neutralizing device 11:
12: inlet port 13: exhaust port
15: prefilter 17: blower
20, 50: Activated carbon filter unit 21: Case
22: Case body 23: Activated carbon filling chamber
24: exhaust surface 25: exhaust port
26: Fence 27: Case Cover
28: inlet surface 29: inlet
30: photocatalyst activated carbon 31, 32: first and second nets
33: light irradiation unit 34: lamp
35: support bar 36: light transmissive cover
37, 45: connector 38: connector pin
39: through holes 40, 51: support posts
41: Socket 44: Cable
52: Fixture 53: Rotor
54: Bearings

Claims (9)

A case having an inlet for air inflow, an outlet for air exhaust, and an activated carbon filling chamber provided between the inlet and the outlet;
A plurality of photocatalytic activated carbon filled in the activated carbon filling chamber and coated with a photocatalyst on activated carbon pellets;
A plurality of lamps provided in the activated carbon filling chamber for irradiating light to the plurality of photocatalyst activated carbons, the plurality of lamps generating light, the supporting bars to which the plurality of lamps are coupled to the outer surface, A light irradiation unit having a transparent cover; And
And a support column installed in the activated carbon filling chamber to support the light irradiation unit and supply power to the light irradiation unit,
Wherein the light-transmitting cover is provided with a plurality of through holes for discharging heat generated from the plurality of lamps to the outside.
delete The method according to claim 1,
Wherein a connector is provided at an end of the light irradiation unit, a socket is provided on the support column so that the connector can be electrically connected thereto, and the light irradiation unit is detachably coupled to the support column. .
The method according to claim 1,
A first net disposed inside the discharge surface formed with the discharge port of the case to cover the discharge port and passing air therethrough to prevent the photocatalyst activated carbon from escaping to the discharge port; And
And a second net disposed inside the inflow surface formed with the inflow port of the case so as to cover the inflow port and passing air therethrough to prevent the photocatalyst activated carbon from escaping to the inflow port, .
The method according to claim 1,
Wherein the photocatalyst coated on the photocatalyst activated carbon is a visible light-responsive photocatalyst.
6. The method of claim 5,
Wherein the visible light responsive photocatalyst is fluorine-doped titanium dioxide.
6. The method of claim 5,
Wherein the visible light responsive photocatalyst is titanium dioxide doped with fluorine and nitrogen at the same time.
The method according to claim 1,
Wherein the supporting column includes a fixed body fixed to the case and a rotating body rotatably coupled to the fixed body while maintaining an electrically connected state with the fixed body,
Wherein a plurality of the light irradiation units are coupled to both the stationary body and the rotating body.
A main body having an intake port and an exhaust port;
A pre-filter disposed between the intake port and the exhaust port in the main body to filter out foreign matter contained in the air sucked through the inlet port;
An activated carbon filter module disposed downstream of the pre-filter in the main body; And
And a blower installed between the intake port and the exhaust port for forcedly flowing air inside the main body,
The activated carbon filter module includes:
A case having an inlet for air inflow, an outlet for air exhaust, and an activated carbon filling chamber provided between the inlet and the outlet,
A plurality of photocatalytic activated carbon filled in the activated carbon filling chamber and coated with a photocatalyst on activated carbon pellets,
A plurality of lamps provided in the activated carbon filling chamber for irradiating light to the plurality of photocatalyst activated carbons, the plurality of lamps generating light, the supporting bars to which the plurality of lamps are coupled to the outer surface, A light irradiation unit having a transparent cover, and
And a supporting column installed in the activated carbon filling chamber for supporting the light irradiation unit and supplying power to the light irradiation unit,
Wherein the light-permeable cover is provided with a plurality of through holes for discharging heat generated from the plurality of lamps to the outside.

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