KR102627472B1 - Carbon dioxide reduction device - Google Patents

Abstract

In the present invention, in order to collect fine dust, ultrafine dust, and oil vapor first and remove carbon monoxide and carbon dioxide at the rear end, mist is sprayed between a porous rotating plate and a fixed plate in the sedimentation tank to allow fine dust and oil vapor to settle, and OH is added to the reaction tank at the rear end. It relates to a carbon dioxide reduction device that generates mist containing radicals and converts carbon monoxide and carbon dioxide into hydrogen carbonate.
For this purpose, one embodiment of the present invention consists of an exhaust hood installed in a workplace, a settling tank connected to the exhaust hood and a duct, and a reaction tank connected to the settling tank and an exhaust fan; The sedimentation tank is provided with a first inlet pipe connected to the duct and a first outflow pipe connected to the exhaust fan, and the first inlet pipe turns water supplied at high pressure from a circulation pump into mist. The injection key is provided with a first capillary frame; Inside the first inlet pipe, a multi-stage hollow fixed plate is provided, and a porous rotating plate rotated by the exhausted wind is provided between each of the fixed plates, so that fine dust and oil vapor adhere to the mist and turn into droplets, and then turn into droplets in the sedimentation tank. Allows it to flow down; The reaction tank is provided with a second inlet pipe connected to the exhaust fan and a second outlet pipe for discharging air into the atmosphere; The second inlet pipe is provided with a second capillary frame connected to the (+) electrode of the high voltage generator, and the inside of the second inlet pipe is connected to the (-) electrode of the high voltage generator to correspond to the second capillary frame. An electrode plate is provided, and when the water supplied from the constant pressure pump changes into mist containing OH radicals through electrostatic spraying in the second capillary frame and is sprayed into the second inlet pipe, carbon monoxide and carbon dioxide in the exhausted air are converted into hydrogen carbonate. There is a characteristic that caused the transformation.

Description

Carbon dioxide reduction device

The present invention relates to a carbon dioxide reduction device, and more specifically, to allow fine dust, oil vapor, carbon monoxide, and carbon dioxide generated in a workplace to pass through a settling tank and a reaction tank, wherein mist is sprayed between a porous rotating plate and a fixed plate into the settling tank to remove fine dust and It relates to a carbon dioxide reduction device that causes oil vapor to precipitate and generates mist containing OH radicals in the reaction tank to convert carbon monoxide and carbon dioxide into hydrogen carbonate.

In general, when cutting or welding metal in a kitchen or industrial site, a lot of fine dust, ultrafine dust, oil vapor, carbon monoxide, and carbon dioxide are generated. Since these fine dust and harmful gases enter the lungs through the worker's respiratory system, working for a long period of time can cause lung disease. To improve this working environment, exhaust hoods are installed or fresh air is supplied, but since oil vapor, carbon dioxide, and fine dust generated in the workplace cannot be substantially removed, they are released into the atmosphere as is.

Carbon dioxide is one of the major greenhouse gases that traps heat in the Earth's atmosphere. Increasing levels of CO2 and other greenhouse gases are causing global warming and climate change, which can have numerous harmful effects, including increased global temperatures, severe heat waves, altered weather patterns, and melting polar ice caps. Efforts to mitigate the negative impacts of CO2 emissions require switching to renewable energy sources, improving energy efficiency, and implementing carbon capture and abatement technologies.

Most air purification systems using water spray water toward fine dust or allow fine dust to be adsorbed on the surface of the water. Because fine dust in the air easily sticks to water, the removal efficiency of fine dust is high. In addition, a method of spraying water into the inhaled air using an ultrasonic oscillator to adsorb and remove fine dust is also used.

Previous patent publication No. 10-2009-0087560 consists of a main body having a humidifier, a dehumidifier, and an air purifier. Water is sprayed into the room with an ultrasonic vibrator of the humidifier, and indoor air with increased humidity flows into the main body and is then dehumidified. It is structured so that fine dust in the indoor air is collected in the process of removing moisture through condensation as it passes through the secondary thermoelectric element. However, the existing patent has the disadvantage of increasing indoor humidity because it is a humidification method that sprays water directly into the room, and although it can remove fine dust, it does not have the function of actually removing carbon dioxide, so the working environment does not improve.

Previous patent No. 2284715 proposed an air purification device using electrostatic water spray that can remove fine dust in an environmentally friendly manner without frequent filter replacement using an electrostatic spraying method that sprays charged fine droplets. However, since it does not include technology to turn fine droplets into mist, the OH radicals generated during the electrostatic spraying process are not sufficiently contained in the fine droplets. Therefore, the effect of converting the chemical structure of carbon dioxide using OH radicals is reduced. In particular, oil vapor generated during work in the kitchen or factory is generated together with carbon dioxide, so if these oil vapor and carbon dioxide are not separated and removed, the efficiency may be further reduced. There was one downside.

<Prior art research literature>

Document 1: Publication Patent No. 10-2009-0087560

Document 2: Registered Patent No. 2284715

Document 3: Registered Patent No. 2569244

The present invention was developed in consideration of conventional problems. The purpose of the present invention is to collect fine dust, ultrafine dust, and oil vapor first and to remove carbon monoxide and carbon dioxide at the rear, by spraying mist between a porous rotating plate and a fixed plate in the sedimentation tank. The aim is to provide a carbon dioxide reduction device that allows fine dust and oil vapor to settle and generates mist containing OH radicals in a rear reaction tank to convert carbon monoxide and carbon dioxide into hydrogen carbonate.

For this purpose, one embodiment of the present invention consists of an exhaust hood installed in a workplace, a settling tank connected to the exhaust hood and a duct, and a reaction tank connected to the settling tank and an exhaust fan; The sedimentation tank is provided with a first inlet pipe connected to the duct and a first outflow pipe connected to the exhaust fan, and the first inlet pipe turns water supplied at high pressure from a circulation pump into mist. The injection key is provided with a first capillary frame; Inside the first inlet pipe, a multi-stage hollow fixed plate is provided, and a porous rotating plate rotated by the exhausted wind is provided between each of the fixed plates, so that fine dust and oil vapor adhere to the mist and turn into droplets, and then turn into droplets in the sedimentation tank. Allows it to flow down; The reaction tank is provided with a second inlet pipe connected to the exhaust fan and a second outlet pipe for discharging air into the atmosphere; The second inlet pipe is provided with a second capillary frame connected to the (+) electrode of the high voltage generator, and the inside of the second inlet pipe is connected to the (-) electrode of the high voltage generator to correspond to the second capillary frame. An electrode plate is provided, and when the water supplied from the constant pressure pump changes into mist containing OH radicals through electrostatic spraying in the second capillary frame and is sprayed into the second inlet pipe, carbon monoxide and carbon dioxide in the exhausted air are converted into hydrogen carbonate. There is a characteristic that caused the transformation.

According to the present invention, fine dust, ultrafine dust, oil vapor, carbon monoxide, and carbon dioxide generated in kitchens or factories are removed step by step as they pass through a precipitation tank and a reaction tank. In the sedimentation tank, fixed plates and porous rotating plates are installed alternately in multiple stages, and water is changed into micrometer-scale mist and sprayed from the upper capillary frame, so fine dust, ultrafine dust, and oil vapor adhere to the mist and settle. In addition, since the reaction tank installed at the rear is equipped with an electrostatic spray type capillary frame, OH radicals collide with carbon monoxide and carbon dioxide while mixed with the mist. At this time, carbon dioxide is removed because OH radicals and water react with carbon monoxide and carbon dioxide and are converted into hydrogen carbonate.

Therefore, users who use reduction devices can receive carbon taxes through carbon trading, and there are advantages such as lowering the concentration of carbon dioxide in the atmosphere because carbon dioxide can be captured. In addition, it can effectively remove carbon dioxide when installed in the kitchen of schools, military bases, and large catering facilities, or in workplaces that emit fugitive dust and carbon emissions, and has the advantage of convenient management as it does not require a replaceable filter air purifier.

1 is an overall conceptual diagram of a reduction device according to an embodiment of the present invention.
Figure 2 is a schematic diagram of a sedimentation tank of an abatement device according to an embodiment of the present invention.
Figure 3 is a schematic diagram of the reaction tank of the reduction device of one embodiment of the present invention
Figure 4 is a schematic diagram of the hydraulic eliminator of the reduction device in one embodiment of the present invention
Figure 5 is a schematic diagram of the exhaust hood of the reduction device in one embodiment of the present invention.

1 to 5, the reduction device of one embodiment of the present invention includes an exhaust hood 10 installed in a workplace where fine dust, ultrafine dust, oil vapor, carbon monoxide, and carbon dioxide are generated; A sedimentation tank (20) that removes fine dust, ultrafine dust, and oil vapor; And it consists of a reaction tank 30 that removes carbon monoxide and carbon dioxide. The sedimentation tank 20 is provided with a first inlet pipe 21 and a first outlet pipe 22 at the top, and the first inflow pipe 21 and the exhaust hood 10 are connected by a duct 13. . In addition, the reaction tank 30 is provided with a second inlet pipe 31 and a second outlet pipe 32 at the top, and an exhaust fan 14 between the first outlet pipe 22 and the second inlet pipe 31. ) is connected so that harmful gases and oil vapor pass through the precipitation tank 20 and the reaction tank 30, are adsorbed and removed through the exhaust hood 10, and are then released into the atmosphere.

The exhaust hood 10 is composed of a box-shaped hollow body, the upper center of which is connected to the duct 13, and the front lower portion is open. And the open portion is divided into a plurality of spaces through partitions 11 placed horizontally at equal intervals, and each partition 11 extends into the interior of the exhaust hood 10 and is then bent vertically to form the exhaust hood 10. It extends to the center of (10) and divides the interior of the exhaust hood (10) at equal intervals. In addition, the tip of each of the partitions 11 exposed to the outside of the exhaust hood 10 is bent into a semi-circular arc and then closes to the lower part of the other partition 11 directly above to form an exhaust port 12. Therefore, since the exhaust port 12 is narrower than the gap between each of the partition plates 11 inside the exhaust hood 10, air is sucked into the exhaust hood 10 by the Venturi effect, thereby reducing exhaust efficiency. improves

The first inlet pipe 21 of the settling tank 20 is provided with a first capillary frame 23 on the outside, and each capillary tube 23a of the first capillary frame 23 is inside the first inflow pipe 21. The water at the bottom of the sedimentation tank 20 is supplied at high pressure to the first capillary frame 23 through the circulation pump 24. Accordingly, the high-pressure water supplied into the first capillary frame 23 passes through each capillary tube 23a, changes into micrometer- or nanometer-sized mist, and is sprayed into the first inlet pipe 21. And inside the first inlet pipe 21, a plurality of fixing plates 25 and rotating plates 26 are alternately provided in multiple stages toward the lower part of the first capillary frame 23, and each rotating plate 26 has a central rotating axis ( 26a), and the upper end of the rotating shaft 26a is provided with rotating blades 26b. In addition, each of the fixing plates 25 has an outer circumferential surface in close contact with the inner wall of the first inlet pipe 21 and is hollow in the center so that the rotation shaft 26a passes through it.

Additionally, each of the rotating plates 26 is composed of a perforated plate with a plurality of holes drilled therein. Therefore, when fine dust and harmful gases from the workplace enter the first inlet pipe 21 due to the operation of the exhaust fan 14, fine dust and ultrafine dust are adsorbed to the mist generated in the first capillary frame 23. do. And the mist to which these fine dusts are adsorbed collides with the surface in the process of passing through the fixed plate 25 and the rotating plate 26 step by step and changes into the form of droplets, and the oil vapor passes through the fixed plate 25 and the rotating plate 26. ) and is absorbed into the droplet, then flows down to the bottom of the sedimentation tank 20 and settles in water. In addition, since the indoor air is sucked into the first inlet pipe 21 during the exhaust process, the rotary blade 26b rotates, thereby rotating the rotary plate 26. Therefore, it helps the mist and oil vapor change into droplets during the collision process with the rotating plate 26. In addition, since the water in the sedimentation tank 20 continues to circulate to the first inlet pipe 21 through the circulation pump 24, it is replaced with fresh, uncontaminated water after operating for a certain period of time.

In addition, the first outflow pipe 22 is equipped with a cylindrical metal wire filter 27, which serves to filter out contaminated mist that has not changed into droplets as it passes through the fixed plate 25 and the rotating plate 26. Mist contaminated with fine dust and oil vapor changes into droplets in the process of colliding with the surface of the metal wire filter 27 and flows down to the bottom of the settling tank 20.

The second inlet pipe 31 of the reaction tank 30 is equipped with a second capillary frame 33 on the outer wall, and a plurality of capillaries 33a provided in the second capillary frame 33 are used to feed the second inflow pipe 31. It protrudes into the tube 31. In addition, the second capillary frame 33 is connected to the (+) electrode of the high voltage generator 34, and the inside of the second inlet pipe 31 is an electrode plate connected to the (-) electrode of the high voltage generator 34. (34a) is provided so that electrostatic spraying occurs between these capillaries (33a) and the electrode plate (34a) through corona discharge.

Electrostatic spraying is accomplished by setting the high voltage to be applied to the electrodes (the second capillary frame 33 and the ground electrode plate 34a), setting the distance between both electrodes, and setting the pressure. When the above conditions are set to the set values, the capillary ( Water passing through 33a) at high pressure creates a Taylor cone at the end of the capillary tube 33a, and then the water particles are broken into small pieces, enabling electrostatic spraying in the form of Taylor jet (jet injection). As the mist generated through electrostatic spraying passes through the electromagnetic field formed by corona discharge, OH radicals are trapped in the mist, and the mist with OH radicals adheres to the electrode plate 34a and changes into the form of droplets (water droplets). It collects at the bottom of the rear reaction tank (30). The mist containing OH radicals is released in the process of colliding with the electrode plate 34a. At this time, carbon monoxide and carbon dioxide in the exhaust gas passing through here are converted into hydrogen carbonate (H2CO3), so even if released into the atmosphere, carbon emissions are emitted. This does not occur. This can be expressed in an equation as follows:

CO + OH → CO2 + H

CO2 + OH → HCO3 → H2CO3

In addition, the second capillary frame 33 is directly connected to the water pipe through a static pressure pump 35 and a water pressure controller 36 consisting of a diaphragm pump. When tap water of a certain pressure (1.5 to 3.5 kg/cm2) is supplied directly to the suction part of the constant pressure pump 35, the water pressure at the pump discharge part slightly changes, affecting the generation of OH radicals. Therefore, the water pressure controller 36 serves to keep the pressure at the discharge part of the constant pressure pump 35 constant. The water pressure controller 36 has a built-in valve operated by a spring 36a and adjusts the water pressure by changing the elasticity of the spring 36a in the process of loosening and tightening the control bolt 36b.

In addition, the second outflow pipe 32 is equipped with a cylindrical metal wire filter 37, which serves to filter the mist generated from the second capillary frame 33. In the process of converting carbon monoxide and carbon dioxide into hydrogen carbonate, some of the mist changes into the form of droplets in the process of colliding with the surface of the metal wire filter 37 and flows down to the bottom of the settling tank 20, so that the mist is not discharged to the outside air. No.

In the reduction device of one embodiment of the present invention configured in this way, when the exhaust fan 14 is operated, fine dust and various harmful gases flowing in through the exhaust hood 10 are removed while passing through the settling tank 20 and the reaction tank 30, and the human body Since only harmless hydrogen carbonate is emitted, it has the advantage of contributing to carbon neutrality.

The exhaust hood 10 is installed in the kitchen of schools, military bases, and large catering facilities, and has the characteristic of being installed behind the cooking worker rather than directly above the cooking facility. Therefore, harmful gases, oil vapor, and fine dust generated during the cooking process are discharged backwards rather than toward the cook, so the cook does not inhale these gases and dust, which is beneficial to health. In particular, the exhaust port 12 of the exhaust hood 10 is installed in multiple stages and has a narrower spacing than the internal diaphragm 11, showing the venturi effect. As the flow path narrows, the speed of the fluid increases, allowing more active exhaust. there is.

In addition, the water supplied at high pressure from the circulation pump 24 changes into mist in each capillary tube 23a of the first capillary tube frame 23 and is sprayed into the first inlet pipe 21. At this time, fine particles in the discharged air are sprayed into mist. Dust, ultrafine dust, and oil vapor stick to the mist. Then, as it passes through the fixed plate 25 and the rotating plate 26 in multiple stages, it changes into droplets and is included in the water at the bottom of the sedimentation tank 20. In addition, since water continues to circulate through the circulation pump 24, when the concentration of water becomes cloudy, the device is stopped and replaced with clean water. And the air from which fine dust and oil vapor, etc. have been removed while passing through the first inlet pipe 21, collides with the metal wire filter 27 while passing through the first outflow pipe 22. At this time, the mist changes into the form of droplets and flows. As it comes down, it additionally removes fine dust and oil vapor.

Additionally, harmful gases are removed from the air flowing into the second inlet pipe 31 through electrostatic spraying of the second capillary frame 33. That is, the second capillary frame 33 generates mist in an electrostatic manner, and when a high voltage is applied to the second capillary frame 33 and the electrode plate 34a through the high voltage generator 34, water is generated in micro and nanoscale. It is sprayed as a small mist. Electrostatic spraying is accomplished by setting the high voltage to be applied to the electrode, setting the distance between both electrodes, and adjusting the water pressure inside the capillary (33a). When the above conditions are set to the set values, the water passing through the capillary (33a) is ) A Taylor cone is created at the discharge end, and the water particles are then broken into small pieces, enabling electrostatic spraying in the form of Taylor jet (jet injection).

When polluted air is passed through the mist generated through electrostatic spraying, fine dust, carbon monoxide, and carbon dioxide are absorbed into the charged mist. Afterwards, the mist that reaches the electrode plate (34ㅁ) changes into the form of droplets (water droplets). In this process, OH radicals contained in the mist convert carbon monoxide and carbon dioxide into hydrogen carbonate. The mist that has not changed into droplets collides with the metal wire filter 37 while passing through the second outflow pipe 32, changes into droplets, and flows down into the reaction tank 30. Therefore, the exhaust air is discharged with fine dust and harmful gases removed, thereby lowering the carbon concentration in the atmosphere.

10: exhaust hood 20: sedimentation tank
21: first inlet pipe 22: first outflow pipe
23: first capillary frame 24: circulation pump
25: fixed plate 26: rotating plate
30: reaction tank 31: second inlet pipe
32: second outflow pipe 33: second capillary frame
34: high voltage generator 34a: electrode plate
35: constant pressure pump 36: water pressure controller

Claims (4)

It consists of an exhaust hood installed in the workplace, a settling tank connected to the exhaust hood and a duct, and a reaction tank connected to the settling tank and an exhaust fan;
The sedimentation tank is provided with a first inlet pipe connected to the duct and a first outflow pipe connected to the exhaust fan, and the first inlet pipe turns water supplied at high pressure from a circulation pump into mist. The injection key is provided with a first capillary frame;
Inside the first inlet pipe, a multi-stage hollow fixed plate is provided, and a porous rotating plate rotated by the exhausted wind is provided between each of the fixed plates, so that fine dust and oil vapor adhere to the mist and turn into droplets, and then turn into droplets in the sedimentation tank. Allows it to flow down;
The reaction tank is provided with a second inlet pipe connected to the exhaust fan and a second outlet pipe for discharging air into the atmosphere;
The second inlet pipe is provided with a second capillary frame connected to the (+) electrode of the high voltage generator, and the inside of the second inlet pipe is connected to the (-) electrode of the high voltage generator to correspond to the second capillary frame. An electrode plate is provided, and when the water supplied from the constant pressure pump changes into mist containing OH radicals through electrostatic spraying in the second capillary frame and is sprayed into the second inlet pipe, carbon monoxide and carbon dioxide in the exhausted air are converted into hydrogen carbonate. A carbon dioxide reduction device characterized by conversion. According to claim 1,
A carbon dioxide reduction device characterized in that metal wire filters are built into the first outflow pipe and the second outflow pipe to form droplets of mist in the exhausted air and flow them into the precipitation tank and the reaction tank. According to claim 1,
Each of the rotating plates built into the first inlet pipe is connected through a rotating shaft penetrating each of the fixed plates, and a rotating blade rotated by exhaust wind is provided at the top of the rotating shaft to rotate the rotating shaft. Carbon dioxide reduction device. According to claim 1,
The positive pressure pump is connected to a direct supply of tap water;
A carbon dioxide reduction device, characterized in that a water pressure regulator is provided at the discharge port of the constant pressure pump to maintain the pressure of the tap water constant by adjusting the elasticity of the spring.