KR100477485B1 - A Volatile Organic Compounds Cleaner - Google Patents

Abstract

An object of the present invention is to provide a volatile organic compound removal device for quickly removing volatile organic compounds (VOC) and dust present in a high concentration in a room. .

According to the present invention, in the apparatus for removing volatile organic compounds, the air sucked through the suction port 111 formed on one side is discharged to the other side, and the heating means 113, the filter 140, and the lamps are disposed along the air stream therein. 160a, 160b, 160c and the case 110 with the photocatalytic reactors 170a and 170b installed therein, and the circulation duct 130 which guides the air discharged to the other side of the case 110 toward the inlet 111 of the case 110. And a discharge duct 190 communicated with the circulation duct 130 to discharge a part of the air flowing along the circulation duct 130, and installed in the case 110 or the circulation duct 130. It is characterized in that it comprises a blower 120 for blowing to flow along, and a damper 191 for adjusting the opening and closing degree of the discharge duct 190.

The volatile organic compound removal device of the present invention configured as described above discharges a part of the purified air while flowing along the case and discharges the remaining part to the room by refining the room, thereby improving cleanliness of the indoor air, and building and remodeling. By rapidly removing high concentrations of VOCs and dust present in buildings, repair spaces, and VOC sources, workers can be less likely to develop as work conditions improve.

Description

Volatile Organic Compounds Cleaner

The present invention relates to a device for removing contaminants and dust in a room, and in particular, to provide a volatile organic compound removal device for quickly removing harmful volatile organic compounds and dust.

Modern people spend 80-90% of their time indoors 24 hours a day. Therefore, if you live in a poor indoor environment for a long time, your health deteriorates. On the contrary, if you live for a long time in a comfortable indoor environment, you will be healthy. As the indoor environment has a great effect on health, a removal device for removing harmful components present in the indoor space has been developed.

Volatile Organic Compounds (VOCs, hereinafter referred to as 'VOC') are representative of these harmful components. The VOC is a substance that can cause cancer, and is regulated by the health care system and is an important air pollutant because it causes photochemical smog from an environmental point of view. Currently, regulations on airborne VOCs are being implemented in industrial areas, and indoor VOCs will be implemented in the near future.

Meanwhile, techniques for removing such VOCs are already commercially available in the water treatment field. Among commercially available VOC removal techniques, a technique using a titanium dioxide (TiO ₂ ) photocatalyst is already known.

However, since the concentration of VOC contained in general indoor air is low as several ppb, and a large amount of air must be processed quickly, it is difficult to purify indoor air using photocatalytic technology. In order to apply this photocatalyst technology to air purification, many basic researches have been conducted in laboratories. Currently, photocatalyst technology is used for the purpose of removing harmful gases, deodorizing, sterilization, etc. in combination with plasma technology.

On the other hand, in the field of construction, building materials that generate VOCs are used a lot, and the interior space is severely polluted by these building materials. In particular, newly constructed buildings have indoor VOC concentrations of several tens to hundreds of times higher than older buildings, and these VOCs are more lethal for children who are weaker than adults, so some people spend about two to three years after they are built rather than new ones. I prefer to live in old buildings.

In addition to these new buildings, special spaces such as VOC sources such as gas stations and laundries, remodeled buildings, and interior spaces under repair are very high at several ppm levels compared to regular indoor spaces. There is a need for a VOC removal device that effectively removes VOCs from indoor spaces. In addition, since a lot of dust is generated in the indoor construction site, dust along with VOC should be removed. Currently, air filters and electrostatic two-stage dust collectors are widely used to remove dust from indoor spaces.

However, the air filter and the electrostatic two-stage dust collector only perform the function of collecting dust and have a disadvantage of not removing the VOC.

The present invention has been proposed in order to solve the problems of the prior art as described above, and has a structure of a circulation system that removes VOC and dust together, in particular, redefines and discharges part of the purified air from which VOC is first removed. It is an object of the present invention to provide a volatile organic compound removal device configured to discharge only purified air at least once.

In the present invention for achieving the above object, in the volatile organic compound removal device, the air sucked through the suction port formed on one side to the other side and the heating means, the filter and the lamp and the photocatalytic reactor in accordance with the air flow therein A case having a case installed, a circulation duct for guiding the air discharged to the other side of the case toward an inlet of the case, an exhaust duct communicating with the circulation duct so as to discharge a portion of the air flowing along the circulation duct, and the case Or a blower installed in the circulation duct for blowing air to flow along the air flow, and a damper for adjusting the opening and closing degree of the discharge duct.

The inlet of the case of the present invention is located in the open end of the circulation duct, the air discharged from the case and the air flowing through the open end of the circulation duct is sucked.

Preferably, the apparatus for removing volatile organic compounds includes a temperature sensor positioned upstream of the lamp with respect to the air flow of the air, a controller for comparing and determining a temperature value and a set temperature value measured by the temperature sensor, and a determination result of the controller. And a transformer for controlling the generated heat of the heating means by adjusting the voltage applied to the heating means.

More preferably, the heating means is a heat transfer plate, and is fixed to the inner surface of the case along the air flow of the air.

The plurality of lamps and photocatalytic reactors of the present invention are located alternately along the air stream of the air.

Preferably, the lamp is an ultraviolet lamp, generates ultraviolet light of 250nm to 400nm wavelength, and has an ultraviolet output of 2.5W or more.

The photocatalytic reactor of the present invention includes a porous medium and a support for supporting the porous medium, wherein the porous medium is located upstream of the air stream.

Preferably, the porous medium is coated with a photocatalyst, which is a titanium oxide containing 70% or more of anatase.

More preferably, the photocatalytic reactor has a corrugated cross section, and the porous medium is a neutral filter or a hepa filter.

Preferably, the photocatalytic reactor has a corrugated cross section, and the porous medium is a metal mesh having a mesh number of 80 or more.

The support of the present invention is a metal mesh having a mesh number of 50 or less.

On the inner surface of the other end of the case of the present invention, an air flow distribution plate is formed along the air stream of the air.

Guide vanes are formed on the inner surface of the bent portion of the circulation duct of the present invention.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the volatile organic compound removal device according to the present invention will be described in detail.

1 is a schematic diagram of a VOC removal apparatus according to an embodiment of the present invention, Figure 2 is a detailed view of the photocatalyst shown in FIG.

As shown in FIG. 1 and FIG. 2, the VOC removing apparatus 100 includes a case 110 for discharging indoor air sucked through a suction port 111 formed at a front end to a rear end, and a rear end of the case 110. Is connected to the circulation duct 130 extending toward the inlet 111 of the case 110, the discharge duct communicating with the middle of the circulation duct 130 to discharge the air flowing along the circulation duct 130 to the room ( 190 and a blower 120 installed between the case 110 and the circulation duct 130 to blow air discharged to the rear end of the case 110 to the circulation duct 130 and the discharge duct 190. It includes a damper 191 for adjusting the opening and closing degree.

In the case 110, the heat transfer plate 113, the air filter 140, the temperature sensor 150, the lamp 160a, the first photocatalytic reactor 170a, the lamp 160b, and the front end of the case 110 may be disposed in the rear end direction. The second photocatalytic reactor 170b, the lamp 160c, and the air flow distribution plate 117 are sequentially installed, and the guide vane 133 is formed on the inner side of the bent portion of the circulation duct 130, and the case 110 The outside of the transformer 115 to adjust the temperature of the heat transfer plate 113 is installed. Such a VOC removal device 100 is preferably of a portable size to clean every corner of the indoor space.

Hereinafter, each component of the VOC removal device configured as described above will be described in more detail.

As shown in FIG. 1, the case 110 is a tube in which its front end gradually expands toward the rear from the suction port 111 and the rear end gradually becomes narrower. And, the rear end of the case 110 is connected to the circulation duct 130, the circulation duct 130 extends toward the inlet 111 of the case 110 so that the inlet 111 of the case 110 is the circulation duct ( 130 is formed to be located inside. That is, the front end portion of the case 110 is a structure in which the circulation duct 130 passes through the outer wall and is located inside the circulation duct 130. Therefore, when the blower 120 located between the case 110 and the circulation duct 130 is operated, air flows into the inlet 111 of the case 110, and at this time, the opening of the circulation duct 130 ( The purified air flowing along the indoor air and the circulation duct 130 introduced through the 131 flows into the inlet 111 of the case 110.

Air introduced into the inlet 111 of the case 110 is guided by the heat transfer plate 113 formed along the inner surface of the front end of the case 110 and flows to the rear of the case 110. At this time, the air guided by the heat transfer plate 113 that generates heat is preheated to a predetermined temperature of about 30 ℃ or more, and at the same time the heat transfer plate 113 is downstream of the heat transfer plate 113 in the rear, that is, the flow direction of air. It also serves to uniformly distribute the air flowing into the air filter 140 located, thereby maintaining the performance of the air filter 140 and the photocatalytic reactors 170a and 170b at a constant level. If the air flowing into the air filter 140 and the photocatalytic reactors 170a and 170b is deflected and introduced, the air filter 140 and the photocatalytic reactors 170a and 170b having a constant purification capability may also be partially deflected by the air. It will not be purified and will be discharged.

The air filter 140 located behind the heat transfer plate 113 filters the dust contained in the air. As the air filter 140, it is preferable to select and use a medium filter or a HEPA filter having a low pressure drop in the case of having the same flow rate. Do.

The air passing through the air filter 140 passes through the temperature sensor 150 and the temperature sensor 150 measures the temperature of the air. The temperature measured by the temperature sensor 150 is input to the control unit 152 as an electrical signal, and the control unit 152 compares the measured air temperature with the set point temperature, and when the measured temperature is lower or higher than the set point temperature, the transformer 115. ) To adjust the generated heat of the heat transfer plate (113). The reason for measuring the temperature of the air and controlling the temperature of the air to be similar to the setpoint temperature is to activate the removal of the VOC contained in the air.

The air passing through the temperature sensor 150 passes through the ultraviolet lamps 160a, 160b and 160c and the first and second photocatalytic reactors 170a and 170b. As shown in FIG. 1, the plurality of UV lamps 160a, 160b, and 160c each include a front of the first photocatalytic reactor 170a and a rear of the second photocatalytic reactor 170b and a first and second photocatalytic reactors. Located between 170a and 170b, respectively.

The ultraviolet lamps 160a, 160b, and 160c generate ultraviolet rays of 250 to 400 nm so that the VOC can be sufficiently decomposed by a photochemical reaction, and preferably have an ultraviolet output of 2.5 W or more.

Meanwhile, the first and second photocatalytic reactors 170a and 170b include a porous medium 173 and a support 175 for supporting the porous medium 173, and include titanium dioxide containing 70% or more of anatase. (TiO ₂ ) A photocatalyst is used.

The porous medium 173 has a corrugated cross section and is a media or mesh screen of an air filter having excellent permeability. In the case of an air filter media, a large amount of photocatalyst can be coated by widening a contact area. Preferably, the medium used for manufacturing the neutral performance filter or the HEPA filter filled with glass fibers irregularly is preferable, and in the case of a metal mesh, the mesh number is preferably 80 or more to have a sufficient surface area.

In addition, the support 175 preferably has a metal mesh structure having a mesh number of 50 or less so that the shape of the porous medium 173 is not deformed by the flow of air.

As shown in FIG. 2, the optimum contact area is determined by adjusting the bending interval G1 and the projection length L1 of the porous medium 173 according to the air treatment flow rate of the VOC removing apparatus 100. The gap G2 between the ultraviolet lamps and the gap L2 between the ultraviolet lamp and the porous medium 173 are adjusted according to the size of the total contact area of the medium 173.

The air passing through the first and second photocatalytic reactors 170a and 170b and the ultraviolet lamps 160a, 160b and 160c is uniformly formed along the airflow distribution plate 117 formed on the inner surface of the rear end of the case 110. 110) It is discharged to the rear end. The air flow in the case 110 is made by the blower 120 installed at the rear end of the case 110, and the air discharged to the rear end of the case 110 is the case 110 of the case 110 along the circulation duct 130. Flow to the tip.

The discharge duct 190 is formed in the middle of the circulation duct 130, the discharge duct 190 is opened and closed by the damper 191. The user rotates the damper 191 to adjust the opening and closing degree of the discharge duct 190, so that a part of the air flowing along the circulation duct 130 is discharged to the room. Meanwhile, some of the air is discharged into the room by the damper 191, and the other part flows to the inlet of the case 110 along the circulation duct 130 and flows back into the case 110 to be refined.

Since the circulation duct 130 extends from the rear end of the case 110 to the front end, the circulation duct 130 may be bent by interference with other objects, and the guide vane 133 is installed on the inner side of the bent portion to deflect airflow. Do not

As described in detail above, the VOC removal apparatus of the present invention discharges a part of the purified air while flowing along the case to the room and re-establishes the remaining part, thereby increasing the removal rate of VOC and dust contained in the inhaled air. Therefore, there is an advantage that the cleanliness of the indoor air can be improved in a short time.

In addition, the VOC removal device of the present invention by quickly removing the high concentration of VOC and dust present in new buildings, remodeling buildings, interior repair space, VOC discharge source, can prevent occupational diseases of workers according to the improvement of the working environment, working environment As the work progresses, the work progresses faster and the air can be shortened.

Although the technical idea of the VOC removal apparatus of the present invention has been described above with the accompanying drawings, this is illustrative of the best embodiment of the present invention and is not intended to limit the present invention.

1 is a schematic diagram of an indoor VOC (Volatile Organic Compounds) removal device according to an embodiment of the present invention,

FIG. 2 is a detailed view of the photocatalyst shown in FIG. 1.

  Explanation of symbols on the main parts of the drawings

100: VOC removal device 110: case

111: suction port 113: heat transfer plate

115: transformer 117: air distribution board

120: blower 130: circulation duct

131: opening 133: guide vane

140: air filter 150: temperature sensor

152: control unit 160a, 160b, 160c: ultraviolet lamp

170a, 170b: photocatalytic reactor 190: discharge duct

191: damper

Claims (13)

A case in which a heating means, a filter, a lamp, and a photocatalytic reactor are installed along the air flow in the air discharged to the other side through the suction port formed at one side; A circulation duct for directing the air discharged to the other side of the case toward the suction port of the case; An exhaust duct in communication with the circulation duct so as to discharge a portion of the air flowing along the circulation duct; A blower installed in the case or the circulation duct to blow air to flow along the air flow; Volatile organic compound removal device comprising a damper for adjusting the opening and closing of the discharge duct. The method of claim 1, The suction port of the case is located in the open end of the circulation duct, the air discharged from the case and the air flowing through the open end of the circulation duct is characterized in that the volatile organic compound removal device. The method according to claim 1 or 2, The volatile organic compound removal device is a temperature sensor which is located upstream of the lamp with respect to the air flow of the air, A control unit for comparing and determining a temperature value measured by the temperature sensor and a set temperature value; And a transformer for controlling the generated heat of the heating means by adjusting the voltage applied to the heating means according to the determination result of the controller. The method of claim 3, The heating means is a heat transfer plate, characterized in that fixed to the inner surface of the case along the air stream of the air volatile organic compound removal device. The method of claim 1, And a plurality of lamps and photocatalytic reactors, which are alternately positioned along the air stream of the air. The method according to claim 1 or 5, The lamp is an ultraviolet lamp, and generates a UV of 250nm to 400nm wavelength, the volatile organic compound removal device, characterized in that having an ultraviolet output of 2.5W or more. The method according to claim 1 or 5, The photocatalytic reactor includes a porous medium and a support for supporting the porous medium, wherein the porous medium is located upstream with respect to the air stream of the air. The method of claim 7, wherein Volatile organic compound removal apparatus, characterized in that the porous medium is coated with a photocatalyst, which is a titanium oxide containing more than 70% of anatase (anatase). The method of claim 8, The photocatalytic reactor has a corrugated cross section, and the porous medium is a neutral filter or a hepa filter, characterized in that the volatile organic compound removal device. The method of claim 8, The photocatalytic reactor has a corrugated cross section, and the porous medium is a volatile organic compound removing device, characterized in that the mesh number (mesh number) of 80 or more. The method of claim 7, wherein The support is a volatile organic compound removal device, characterized in that the mesh number (mesh number) of 50 or less. The method of claim 1, Volatile organic compound removal device, characterized in that the air flow distribution plate is formed along the air stream of the other end inner surface of the case. The method of claim 1, Volatile organic compound removing apparatus characterized in that the guide vane is formed on the inner surface of the bent portion of the circulation duct.