KR102437543B1 - Ethylene removal device with no ozone remaining and Ethylene removal Method using the same - Google Patents

Abstract

The present invention provides an ozone lamp photocatalytic reaction unit that reacts and removes high concentration ethylene with ozone after introducing air into it, a zeolite filter unit that blocks low concentration ethylene, an activated carbon ozone filter unit that blocks residual ozone, fine concentration It is sequentially connected to the potassium permanganate reaction unit that removes the ethylene of Ozone is removed by the ozone removal filter, and the remaining low-concentration ethylene is completely removed with a zeolite filter and potassium permanganate aqueous solution, and ozone is blocked to the outside so that subtropical fruits and vegetables stored in low-temperature storage warehouses can be stored stably for a long period of time. In addition, it prevents damage to the user's body by ozone.

Description

Ethylene removal device with no ozone remaining and Ethylene removal Method using the same

The present invention relates to an ethylene removal device in which ozone does not remain and a method for removing ethylene using the same.

Ethylene is a type of plant hormone and is a natural hormone also called fruit maturation hormone or stress hormone.

In the 1800s, a phenomenon of early browning and falling of leaves was observed due to a gas leak from a gas pipe, and after that, it was found that the cause of early maturation was ethylene.

Ethylene is not only expressed in the living body of plants, but can also be produced industrially, but as a plant hormone, ethylene has the characteristic of being expressed in the living body of most plants. In particular, it is known to be widely expressed in tropical plants such as mango, banana, orange, and apple, and is also called a stress hormone because it is actively produced by factors that stress plants, such as drought, lack of oxygen, and cold weather.

Currently, due to global warming, domestic cultivation of fruits such as figs, passionfruits, tangerines, mandarin oranges, and king jujubes is increasing due to global warming.

Ethylene generated from subtropical fruits and vegetables when stored in a cold storage warehouse of subtropical fruits and vegetables that generate a lot of ethylene can cause side effects that damage the stored fruits if the concentration is excessively increased in a closed place. are removing

In the conventional ethylene removal device, an ozone generator using plasma or a photocatalyst is provided as a freshness maintainer.

The conventional ethylene removal device through an ozone generator using plasma or a photocatalyst has a problem of exposing ozone to a user and causing damage to the human body.

In addition, the conventional ethylene removal device through an ozone generator using plasma or photocatalyst may cause damage to fruits and vegetables in storage. became

The reaction between ozone and ethylene does not occur actively at low temperatures, and the state where ozone and ethylene coexist is maintained. However, when a freshness retainer is used in a low temperature storage, ethylene is not effectively decomposed and only the ozone concentration is increased.

Korean Patent Registration No. 10-1974994 'Ethylene Removal Device' (April 26, 2019, registered)

To solve the problem of the present invention, in order to improve the ozone leakage problem and effectively remove ethylene at a concentration of 1 ppm or less even at low temperatures, the amount of ethylene in hundreds of ppm is lowered to about 10 ppm using a photocatalytic reaction, and the remaining ozone is effectively blocked by the ozone cut-off filter unit. and to provide an ozone-free ethylene removal device that completely removes residual ethylene with a concentration of 10 ppm or less using an oxidizing agent to block the leakage of ozone to the outside, and an ethylene removal method using the same.

The ethylene removal device in which ozone does not remain according to an embodiment of the present invention removes ozone from the ethylene removal filter unit for removing and discharging ethylene after introducing air into the interior, and from the air removed from the ethylene removal filter unit. It characterized in that it comprises a pump for passing the ozone removal filter unit, the air through the filter unit for removing ethylene and the ozone removal filter unit.

The ethylene removal device in which ozone does not remain according to an embodiment of the present invention introduces air inside through an air inlet on one side, removes ethylene, and discharges it to an air outlet on the other side, and the filter unit for removing ethylene , The ozone removal filter unit, further comprising a housing unit for removing ethylene installed therein, wherein the filter unit for removing ethylene includes an ozone lamp and a photocatalyst member located inside the housing unit for removing ethylene, the ozone The removal filter unit may be an activated carbon filter.

In the present invention, the filter unit for removing ethylene further includes a zeolite filter member and a potassium permanganate filter member positioned in the housing for removing ethylene, wherein the ozone removal filter unit is located between the zeolite filter member and the potassium permanganate filter member It may be an activated carbon filter.

In the present invention, the photocatalyst member, the zeolite filter member, the ozone removal filter member, the potassium permanganate filter member, and the pump may be located in the order of the air inlet to the air outlet in the housing for removing ethylene in the present invention.

In the present invention, the ethylene removal filter unit has a photocatalyst coating layer located on the inner surface, a UV lamp for ozone is located inside, and a first ethylene removal casing coated with a heat insulating material on the outside, and air is introduced into the first ethylene removal casing a first air hose member; and a second air hose member for discharging air in the first ethylene removal casing and introducing it into the ozone removal filter unit, wherein the ozone removal filter unit includes an ozone removal casing to which the second air hose member is connected, and the ozone removal and a third air hose member for discharging the activated carbon filter layer located in the casing and the air in the ozone removal casing to the outside, wherein the filter for ethylene removal includes the third air hose member inserted thereinto and the third air hose It may further include a fourth air hose member for discharging the air of the second ethylene removal casing and the second ethylene removal casing air is introduced to the inside through the member and potassium permanganate aqueous solution is located therein.

In the present invention, a zeolite filter including a plurality of porous zeolite grains may be positioned within the first ethylene removal casing and the ozone removal casing.

In the present invention, one end of the second air hose member is inserted into the zeolite filter, and a pneumatic silencer capable of reducing the noise of air pressure by dispersing air is located at one end, and the third air hose member has one end A pneumatic silencer capable of reducing the noise of pneumatic pressure by dispersing air at one end of which the side is inserted into the activated carbon filter layer may be located.

In the present invention, the pump may be positioned to be connected to the first air hose member to allow air to pass through the aqueous potassium permanganate solution.

The ethylene removal device in which ozone does not remain according to an embodiment of the present invention further includes a control unit for controlling the operation of the pump and the UV lamp for ozone, wherein the control unit maintains the ozone lamp in an off state. The pump is operated for a preset time, and after turning off the pump, the ozone lamp is operated for a preset time and then turned off and then the pump is operated again for a preset time while repeating the process of removing air from the filter for removing ethylene It may be discharged to the outside through the unit and the ozone removal filter unit.

The ethylene removal method according to an embodiment of the present invention includes an ozone lamp photocatalytic reaction step of removing high concentration ethylene by reacting with ozone, and a first low concentration first low concentration ethylene in which the low concentration ethylene is adsorbed and removed through the zeolite filter unit in the ozone lamp photocatalytic reaction step Ethylene removal step, ozone removal step of removing ozone remaining in the air by passing through an activated carbon filter after the first low concentration ethylene removal step, and second low concentration ethylene removal step of removing low concentration ethylene remaining after the ozone removal step with an aqueous potassium permanganate solution It is characterized in that it comprises a step.

The present invention removes ethylene from the air using a photocatalytic reaction and effectively blocks ozone with an ozone blocking filter unit to remove ethylene and also blocks the outflow of ozone to the outside. It has the effect of preventing damage to the user's body due to ozone.

1 is a schematic diagram showing an embodiment of an ethylene removal device in which ozone does not remain according to the present invention.
Figure 2 is a schematic view showing another embodiment of the ethylene removal device does not remain ozone according to the present invention.
Figure 3 is a schematic view showing another embodiment of the ethylene removal device does not remain ozone according to the present invention.
4 is a view showing an example of installing another embodiment of the ethylene removal device in which ozone does not remain according to the present invention in the storage.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art to which the present invention pertains can easily carry out the present invention.

However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. Throughout the specification, like reference numerals are assigned to similar parts.

1 is a schematic diagram showing an embodiment of an ethylene removal device in which ozone does not remain according to the present invention.

An embodiment of an ethylene removal device in which ozone does not remain according to the present invention will be described in detail below with reference to FIG. 1 .

One embodiment of the ethylene removal device in which ozone does not remain according to the present invention is an ethylene removal device in which ozone does not remain in accordance with an embodiment of the present invention, which removes ethylene after introducing air into the interior for ethylene removal The filter unit 100, the ozone removal filter unit 200 for removing ozone from the air removed from the ethylene removal filter unit 100, and the air filter unit 100 for removing ethylene and the ozone removal filter unit 200 It includes a pump 300 to pass through.

The ethylene removal device in which ozone does not remain removes ethylene after introducing air therein, and the ethylene removal filter unit 100 and the ozone removal filter unit 200 are installed inside the housing unit 400 for removing ethylene. ) is further included.

In the housing unit 400 for removing ethylene, an air inlet 410 for introducing air into the inside is located on one side, and an air outlet 420 for discharging air from which ethylene has been removed is located on the other side.

The air inlet 410 is an open space to allow air to be introduced into the interior, and the air outlet is an open space through which air can be discharged.

A pump 300 for sucking air into the housing unit 400 for removing ethylene and discharging it to the outside of the housing unit 400 for removing ethylene is located inside the housing unit 400 for removing ethylene.

The pump 300 may be located in the air discharge unit 420 to finally discharge the air in a state in which ethylene and ozone are removed from the inside of the housing unit 400 for removing ethylene.

The filter unit 100 for removing ethylene includes an ozone lamp 110 and a photocatalyst member positioned inside the housing unit 400 for removing ethylene, and the ozone lamp 110 is a housing unit 400 for removing ethylene with a photocatalytic effect. ) to remove ethylene contained in the air introduced into the

The ozone lamp 110 is a UV-C lamp as an example of an ultraviolet lamp, and it is pointed out that it can be variously modified and implemented as a known lamp that generates ozone by a photocatalytic effect.

The photocatalyst member 120 is positioned in the housing unit 400 for removing ethylene, and the photocatalyst member 120 is a TiO ₂ photocatalyst as an example, and in addition to the photocatalytic effect, it is variously transformed into a known photocatalyst that generates ozone. It should be noted that this can be implemented.

The photocatalyst member 120 is provided as a photocatalyst coating layer part 121 on the inner surface of the housing part 400 for removing ethylene and is positioned to surround the ozone lamp 110 .

The photocatalyst member 120 is provided as a coating layer on the inner surface of the housing unit 400 for removing ethylene so that the light generated from the ozone lamp 110 can be evenly irradiated, thereby increasing the ozone generation efficiency and improving the ethylene removal efficiency. can do it

The ozone removal filter unit 200 is positioned on the side of the air discharge unit 420 inside the housing unit 400 for removing ethylene to remove ozone remaining in the discharged air.

The ozone removal filter unit 200 is an activated carbon filter as an example, and the first ozone removal filter member 210 positioned on the side of the air discharge unit 420 in the housing unit 400 for removing ethylene, ethylene removal It may include a second ozone removal filter member 220 located on the side of the air inlet 410 in the interior of the housing 400 for.

The photocatalyst coating layer part 121 surrounding the ozone lamp 110 is positioned on the inner surface of the housing part 400 for removing ethylene, and a second ozone removal filter member is disposed between the photocatalyst coating layer part 121 and the air inlet part 410 . 220 is positioned, and the first ozone removal filter member 210 is positioned between the photocatalyst coating layer part 121 and the air exhaust part 420 .

The first ozone removal filter member 210 and the second ozone removal filter member 220 are each an activated carbon filter as an example.

The activated carbon filter is a filter having excellent efficiency in removing ozone, and may be variously modified and implemented using a known filter capable of removing ozone.

As an example, the filter unit 100 for removing ethylene further includes a zeolite filter member 130 or a potassium permanganate filter member 140 positioned in the housing unit 400 for removing ethylene.

That is, the filter unit 100 for removing ethylene further includes a zeolite filter member 130 and a potassium permanganate filter member 140 to adjust the ethylene concentration in the air to 1 ppm or less, which is a recommended concentration of ethylene in the air.

The zeolite filter member 130 adsorbs and removes ethylene with a filter layer in which porous zeolite grains are laminated.

When ethylene at a concentration of 2% (20,000 ppm) passes through the zeolite filter member 130 in which porous zeolite particles are stacked to about 6 cm, ethylene in the air is adsorbed to and removed from the porous zeolite particles, so that the ethylene concentration in the air is 1 ppm or less.

Potassium permanganate has a high oxidation number of +7 for Mn ions, so it is easy to accept electrons and is a powerful oxidizing agent that oxidizes by taking electrons from other molecules.

Potassium permanganate is an oxidizing agent that effectively lowers the concentration of ethylene.

An embodiment of the ethylene removal device in which ozone does not remain according to the present invention is a zeolite filter member 130, a first ozone removal filter member 210 and a pump 300 between the photocatalytic filter member and the air discharge unit 420. A potassium permanganate filter member 140 is positioned therebetween.

The ozone removal filter unit 200 , that is, the first ozone removal filter member 210 is located between the zeolite filter member 130 and the potassium permanganate filter member 140 , and finally air is discharged through the air discharge unit 420 . When discharged, it effectively removes ozone contained in the air.

In addition, an embodiment of the ethylene removal device in which ozone does not remain according to the present invention primarily removes ethylene from the air through ozone generated by the photocatalytic effect, and then uses the zeolite filter member 130 to secondarily remove ethylene from the air. After removing ozone with the first ozone removal filter member 210 , ethylene in the air is tertiarily removed through the oxidation action of the potassium permanganate filter member 140 , and the ethylene discharged through the air discharge unit 420 . The concentration can be greatly reduced to 1ppm or less, and the removal efficiency of ethylene contained in the air is maximized.

In addition, the pump 300 is located in the air discharge unit 420 from which air is finally discharged, so that air from which all impurities in the air are removed passes through, durability can be stably maintained for a long time.

Figure 2 is a schematic diagram showing another embodiment of the ethylene removal device does not remain ozone according to the present invention.

Referring to FIG. 2 , an air intake duct 430 for sucking air is connected to the air inlet 410 of the ethylene removal housing 400 , and the air intake duct 430 has air A check valve unit 440 for maintaining the flow may be located.

That is, another embodiment of the ethylene removal device in which ozone does not remain according to the present invention is the air intake duct 430 connected to the air inlet 410 of the ethylene removal housing 400, the air intake duct It is located in the portion 430 and further includes a check valve portion 440 for moving the air in one direction.

Another embodiment of the ethylene removal device in which ozone does not remain according to the present invention can prevent an accident in which the air sucked into the housing 400 for removing ethylene is reversed due to an external factor and the ethylene is not removed and discharged. have.

In addition, another embodiment of the ethylene removal device in which ozone does not remain according to the present invention may further include a duct unit 450 for discharging air connected to the air discharging unit 420, and the pump 300 is air discharging. It is located on the inside of the duct portion 450 for.

The pump 300 is located in the duct part 450 for discharging air from which air is finally discharged, so that durability can be stably maintained, and convenience can be secured during maintenance work.

In addition, the pump 300 is located in the duct part 450 for air discharge, the zeolite filter part located inside the housing part 400 for removing ethylene, the ozone removal filter part 200, the potassium permanganate filter member 140. Improves the convenience of replacing filters such as

On the other hand, Figure 3 is a schematic diagram showing another embodiment of the ethylene removal device in which ozone does not remain according to the present invention, Figure 4 is a storage storage of another embodiment of the ethylene removal device in which ozone does not remain according to the present invention. It is a diagram showing an example installed inside.

Another embodiment of the ethylene removal device in which ozone does not remain according to the present invention will be described in detail below with reference to FIGS. 3 and 4 .

In the filter unit 100 for removing ethylene, a photocatalyst coating unit 151 is located on the inner surface, an ultraviolet lamp 152 for ozone is located inside the first ethylene removal casing, and the outside is coated with a heat insulating material 153 . (150), the first air hose member 160 for introducing air into the first ethylene removal casing 150, and the agent for discharging the air in the first ethylene removal casing 150 and introducing it into the ozone removal filter unit 200 2 It includes an air hose member (170).

In addition, the ozone removal filter unit 200 includes an ozone removal casing 230 to which the second air hose member 170 is connected, an activated carbon filter layer 240 positioned in the ozone removal casing 230 , and an ozone removal casing 230 . and a third air hose member 250 for discharging the internal air to the outside.

In addition, a zeolite filter 500 including a plurality of porous zeolite grains, respectively, may be positioned in the first ethylene removal casing 150 and the ozone removal casing 230 .

The zeolite filter 500 in the ozone removal casing 230 is positioned on the upper side of the activated carbon filter layer 240 .

The porous zeolite grains are removed by adsorbing ethylene in the air, and the concentration of ethylene in the air can be greatly reduced to 1 ppm or less.

The second air hose member 170 has one end side inserted into the zeolite filter 500, and a pneumatic silencer 600 capable of effectively dispersing air to one end to reduce the noise of the air pressure may be located.

The third air hose member 250 has one end side inserted into the activated carbon filter layer 240 , and a pneumatic silencer 600 capable of reducing the noise of air pressure may be positioned at one end.

In the filter unit 100 for removing ethylene, the third air hose member 250 is inserted therein, air is introduced into the inside through the third air hose member 250, and the potassium permanganate aqueous solution is located therein to remove the second ethylene. The casing 180 and the second ethylene removal casing 180 may further include a fourth air hose member 190 for discharging the air to the outside.

The other end of the third air hose member 250 is located in the potassium permanganate aqueous solution 181, and an air pressure silencer 600 capable of reducing the noise of air pressure by effectively dispersing air at the other end may be located.

The pump 300 is positioned to be connected to the first air hose member 160 so that air can pass through the potassium permanganate aqueous solution 181 .

The pump 300 introduces air into the first ethylene removal casing 150 through the air hose member so that the air flows through the first ethylene removal casing 150 , the ozone removal casing 230 , and the second ethylene removal casing 180 . to pass sequentially.

The air may finally pass through the potassium permanganate aqueous solution 181 and be discharged to the outside through the fourth air hose member 190 in a state in which the fine remaining ethylene is completely removed.

That is, the first ethylene removal casing 150 removes ethylene in the air through the photocatalytic effect and the zeolite filter 500, and the ozone removal casing 230 removes ethylene in the air through the zeolite filter 500 once more and , the activated carbon filter layer 240 removes ozone contained in the air.

And, the second ethylene removal casing 180 is to completely remove the ethylene contained in the air as the air is discharged into the potassium permanganate aqueous solution 181 stored therein.

Although not shown, the ethylene removal device in which ozone does not remain according to the present invention further includes a control unit (not shown) for controlling the operation of the pump 300 and the ultraviolet lamp 152 for ozone.

The control unit may alternately operate the pump 300 and the ultraviolet lamp 152 for ozone to improve ethylene removal efficiency.

In more detail, the control unit operates the pump 300 for a preset time with the ozone UV lamp 152 turned off, and operates the ozone UV lamp 152 for a preset time after turning off the pump 300 . After turning off and repeating the process of operating the pump 300 for a preset time, the air passes through the ethylene removal filter unit 100 and the ozone removal filter unit 200 and is discharged to the outside.

The control unit alternately operates the pump 300 and the ozone UV lamp 152 for a preset period of time, for example, for 10 minutes, so that the air stays sufficiently within the ethylene removal filter unit 100 and the ozone removal filter unit 200 . After effectively removing ethylene and ozone generated while removing ethylene, the air is finally discharged.

The control unit alternately operates the pump 300 and the UV lamp 152 for ozone for a preset time, so that when the UV lamp 152 for ozone is operated, the temperature of the reaction unit increases to decompose the high concentration of ethylene, and the pump 300 is operated Ozone remaining through the ozone removal filter unit 200 can be removed, and the remaining low concentration of ethylene can be completely made into the zeolite filter 500 and the potassium permanganate aqueous solution 181 .

The fourth air hose member 190 extends from the storage 10 to the vicinity of the ventilation fan 20 for the storage that introduces air into the storage and blows it, and finally the air from which ethylene is removed is transferred to the storage through the ventilation fan for the storage. Make sure it spreads evenly throughout.

An embodiment of the method for removing ethylene according to the present invention is an ozone lamp photocatalytic reaction step for removing high concentration ethylene by reacting with ozone, and a first low concentration first low concentration ethylene to be adsorbed and removed by passing the low concentration ethylene through the zeolite filter unit in the ozone lamp photocatalytic reaction step After the ethylene removal step, the first low concentration ethylene removal step, an ozone removal step in which the ozone remaining in the air is removed by passing an activated carbon filter, and the second low concentration ethylene removal step in which the low concentration ethylene remaining after the ozone removal step is removed with an aqueous potassium permanganate solution includes steps.

In the present invention, the replacement cycle of potassium permanganate aqueous solution is 100 times longer than when ethylene is removed with only potassium permanganate aqueous solution by completely removing low concentration ethylene with a zeolite filter and potassium permanganate aqueous solution after removing high concentration ethylene by reacting ozone with photocatalytic effect. It can be increased, and ozone is also removed.

The present invention removes ethylene using a photocatalytic reaction and effectively blocks ozone with an ozone blocking filter unit to remove ethylene and also blocks the outflow of ozone to the outside so that subtropical fruits and vegetables stored in low-temperature storage warehouses, etc., can be stored stably for a long period of time. In addition, it is possible to prevent damage to the user's body due to ozone.

Although the preferred embodiment of the present invention has been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also provided. is within the scope of the

100: filter unit for removing ethylene 110: ozone lamp
120: photocatalyst member 121: photocatalyst coating layer part
130: zeolite filter member 140: potassium permanganate filter member
150: first ethylene removal casing 151: photocatalyst coating part
152: UV lamp for ozone 153: insulation coating
160: first air hose member 170: second air hose member
180: second ethylene removal casing 181: potassium permanganate aqueous solution
190: fourth air hose member
200: ozone removal filter unit 210: first ozone removal filter member
220: second ozone removal filter member 230: ozone removal casing
240: activated carbon filter layer 250: third air hose member
300: pump 400: housing for ethylene removal
410: air inlet 420: air outlet
430: air intake duct part 440: check valve part
450: duct for air exhaust 500: zeolite filter
600: pneumatic silencer

Claims (10)

A UV lamp for ozone is disposed inside the photocatalyst coating layer and the outside is covered with a heat insulating material, a first air hose member for introducing air into the first ethylene removal casing, and within the first ethylene removal casing A filter unit for removing ethylene that includes a second air hose member for discharging air, and removing ethylene after introducing air into the interior;
and an ozone removal casing to which the second air hose member is connected, an activated carbon filter layer positioned within the ozone removal casing, and a third air hose member for discharging air in the ozone removal casing to the outside, in the filter unit for removing ethylene an ozone removal filter that removes ozone from the removed air; and
A pump that passes air through the filter unit for removing ethylene and the filter unit for removing ozone
includes,
The filter unit for removing ethylene,
Further comprising a second ethylene removal casing into which the third air hose member is inserted and an aqueous potassium permanganate solution is located therein, and a fourth air hose member for discharging the air of the second ethylene removal casing to the outside
Ethylene removal device that does not leave ozone. In claim 1,
After introducing air into the interior, ethylene is removed and discharged to the other side of the air outlet, and the filter unit for removing ethylene, the filter unit for removing ozone, and a housing unit for removing ethylene in which the pump is installed.
The ozone removal filter unit is an activated carbon filter
Ethylene removal device that does not leave ozone. In claim 2,
The filter unit for removing ethylene further includes a zeolite filter member and a potassium permanganate filter member positioned in the housing unit for removing ethylene,
The ozone removal filter unit is an activated carbon filter positioned between the zeolite filter member and the potassium permanganate filter member
Ethylene removal device that does not leave ozone. In claim 3,
The photocatalyst member of the photocatalyst coating layer, the zeolite filter member, the ozone removal filter unit, the potassium permanganate filter member, and the pump are located in the order of the photocatalyst coating layer from the air inlet to the air outlet in the ethylene removal housing unit
Ethylene removal device that does not leave ozone. delete In claim 1,
In the first ethylene removal casing and the ozone removal casing, a zeolite filter including a plurality of porous zeolite grains, respectively, is positioned
Ethylene removal device that does not leave ozone. In claim 6,
The second air hose member has one end side inserted into the zeolite filter, and a pneumatic silencer capable of reducing the noise of air pressure by dispersing air at one end is located,
The third air hose member has one end of which is inserted into the activated carbon filter layer and a pneumatic silencer capable of reducing the noise of air pressure by dispersing air at one end is located.
Ethylene removal device that does not leave ozone. In claim 1,
The pump is positioned to be connected to the first air hose member so that air can pass through the aqueous potassium permanganate solution.
Ethylene removal device that does not leave ozone. In claim 1,
Further comprising a control unit for controlling the operation of the pump and the ultraviolet lamp for ozone,
The control unit operates the pump for a preset time with the UV lamp for ozone turned off, turns off the pump, operates the UV lamp for ozone for a preset time, and turns off the pump again for a preset time While repeating the operation during
Ethylene removal device that does not leave ozone. To remove ethylene using an ethylene removal device in which ozone does not remain as defined in any one of claims 1 to 4, 6 to 9,
ozone lamp photocatalytic reaction step of removing high concentration of ethylene by reacting with ozone;
a first low-concentration ethylene removal step of adsorbing and removing ethylene, which has been low-concentrated in the ozone lamp photocatalytic reaction step, through a zeolite filter unit;
an ozone removal step of removing ozone remaining in the air after the first low concentration ethylene removal step through an activated carbon filter; and
A second low-concentration ethylene removal step of removing the low-concentration ethylene remaining after the ozone removal step with an aqueous potassium permanganate solution;
Ethylene removal method.

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