KR20220035721A - An air sterilizer using a photo plasma technology - Google Patents

Abstract

The present invention relates to an air sterilizer using light plasma, and more specifically, to an air sterilizer that decomposes air using a VUV lamp that generates light plasma to sterilize and purify harmful gases, viruses, bacteria, odors, etc.
In the air sterilizer using optical plasma according to the present invention, air passes inside the optical plasma generator in the form of a vortex, and ultraviolet rays of the optical plasma generator pass through the interior of the optical plasma generator to the extent of total reflection, so that the OH radicals of the optical plasma generator The generation efficiency has been greatly improved compared to before, resulting in excellent air purification and sterilization effects.
In addition, in the present invention, since the optical plasma generator generates ultraviolet wavelengths in the range of 180 nm to 400 nm, OH radicals, ozone generation, and ozone decomposition can be performed by the same optical plasma generator, thereby reducing the required number of optical plasma generators. It works.
In addition, the present invention has the effect of reducing the operating noise of the air sterilizer due to the operation of the fan or air inflow and outflow by providing a low-noise exhaust part that reduces noise and a vibration-proof stand to attenuate vibration.

Description

An air sterilizer using a photo plasma technology}

The present invention relates to an air sterilizer using light plasma, and more specifically, to sterilize and purify harmful gases, viruses, bacteria, harmful bacteria, odors, etc. by decomposing the air using a VUV (Vacuum Ultra Violet) lamp that generates plasma. This is about an air sterilizer.

In general, various air purification devices are used in homes or industrial sites. For example, air purifiers are used in industrial sites to remove various harmful substances and dust, and air purifiers are also used in each home to maintain a clean environment. Air conditioners, fan heaters, vacuum cleaners, etc. also purify the air. Various filters for purification are installed.

In addition, in the case of indoors where very clean air quality is desired, such as in sterile rooms or laboratories, filter-type air sterilizers are used to remove pathogenic bacteria or fine dust floating in the indoor air.

As filters for these air sterilizers, HEPA (High Efficiency Particulate Arrestor) filters or electrostatic filters of the electrostatic dust collection method are usually used.

However, when using only a filter, the removal efficiency for fine dust is excellent and a significant portion of bacteria attached to particles can be removed by filtering, but it is difficult to sterilize the bacteria themselves and strict sterilization standards are required. There was a problem that there were limits to realizing efficiency.

Moreover, as the need for sterilization of viruses contained in the air has recently increased due to the COVID-19 virus epidemic, the need for air purification devices that can not only remove fine particles but also sterilize bacteria or viruses is increasing.

For this purpose, a device that generates ozone to sterilize microorganisms in the air has been used. Although a certain degree of sterilization effect can be expected when using such a device, there are concerns about reactions such as oxidation and corrosion, especially when people stay indoors. There is a problem that makes it difficult to use.

In particular, when using ozone, special care must be taken when using it because unreacted ozone is actually harmful to the human body, and there is a problem that it is difficult to maintain a pleasant indoor environment because ozone causes a unique odor.

In order to solve the above problems, an air sterilization device using an ultraviolet (UV) lamp has been proposed. Using an ultraviolet (UV) lamp can solve various problems in chemical sterilization, but there is a problem in that a sufficient sterilization process cannot be achieved due to the limited number of bacteria and viruses that can be sterilized within the ultraviolet wavelength range.

In order to solve this problem, as a prior art, Korean Patent Publication No. 10-2011-0061426, as shown in FIG. 1, includes an ozone generator 20 in which a plurality of ultraviolet lamps that generate ozone are installed, and an ozone removal device. An air purification device including an ozone removal unit 30 including a plurality of ultraviolet lamps is disclosed.

In the prior art, the sucked air is passed through the ozone generator 20 to generate ozone and discharged to the outside. In order to remove unreacted ozone in the outside air, the outside air is again sucked in and passed through the ozone remover 30. to remove residual ozone.

However, the prior art has the disadvantage of increasing the number of installed ultraviolet lamps and increasing electrical energy consumption because ozone generation and ozone removal are performed using separate ultraviolet lamps.

In addition, the prior art has the disadvantage of low ozone generation efficiency because the ozone generator uses a plurality of ultraviolet lamps to generate a large amount of ozone, and uses a plurality of fans for air inflow and outflow, so there is a very high risk of noise and vibration. There is a problem that there is no response to the failure of the ultraviolet lamp, and there are concerns about high concentrations of unreacted ozone being spread into the space when the ozone removal unit fails.

Therefore, there is a need to develop a newer and more advanced air sterilizer that can improve the above-mentioned problems.

Prior art: Korean Patent Publication No. 10-2011-0061426 (published on June 9, 2011)

In order to solve the above problems, the present invention aims to provide an air sterilizer that has excellent air purification and sterilization effects by efficiently generating a small amount of ozone and OH radicals in an optical plasma generator.

In addition, the present invention aims to provide an air sterilizer using optical plasma in which ozone generation and ozone decomposition are performed by the same optical plasma generator, thereby reducing the required number of optical plasma generators.

Another technical object of the present invention is to provide an air sterilizer using optical plasma that can reduce noise and vibration generated during the operation of the air sterilizer.

In addition, the present invention aims to provide an air sterilizer using light plasma that detects whether a malfunction or abnormality occurs in the light plasma generator or fan, and prevents the dispersion of contaminated air or bacteria due to abnormal operation of the air sterilizer.

An air sterilizer using light plasma of the present invention according to one embodiment includes a main body 100;

An optical plasma generator 200, a VUV lamp driver 300, and an LCD/fan control unit 400 installed inside the main body 100;

A low noise exhaust unit 500 installed on the upper part of the main body 100;

It includes a dust-proof stand 700 installed below the main body 100,

The optical plasma generator 200 includes an optical plasma case 210 and a VUV lamp 220 installed therein,

The VUV lamp driver 300 includes a power and drive circuit 310 and a timer 330,

A characteristic feature is that a vortex forming unit 600 that generates a vortex flow is installed on the side where air flows into the optical plasma generating unit 200.

In addition, the low-noise discharge unit 500 of the present invention has an absorption chamber 520, and a plurality of sound insulation plates 530 are disposed inside the absorption chamber 520, and the vortex forming unit 600 has a plurality of vortex blades. It is characterized by having (620).

In addition, the dustproof stand 700 of the present invention

fixing bolt (710);

A dust-proof washer 720 pressed by the fixing bolt 710;

Anti-vibration rubber pads (730, 740) fastened to the main body (100) by the fixing bolt (710) and having different elastic moduli;

and a sound-absorbing material 750 disposed inside the anti-vibration rubber pads 730 and 740, wherein a protrusion 760 is formed on the anti-vibration rubber pad 730 and a groove 770 on the anti-vibration rubber pad 740. It is characterized by this formation.

In addition, the present invention is characterized in that a suction fan 610 is installed in the lower part of the main body 100 and an exhaust fan 510 is installed in the upper part of the main body 100.

In the air sterilizer using optical plasma according to the present invention, air passes inside the optical plasma generator in the form of a vortex, and ultraviolet rays of the optical plasma generator pass through the interior of the optical plasma generator to the extent of total reflection, so that the OH radicals of the optical plasma generator The generation efficiency has been greatly improved compared to before, resulting in excellent air purification and sterilization effects.

In addition, in the present invention, the optical plasma generator generates ultraviolet wavelengths in the range of 100 nm to 400 nm, and especially emits vacuum ultraviolet rays in the 100 nm to 200 nm vacuum ultraviolet wavelength range, so that the optical plasma generator has the same OH radical and ozone generation and ozone decomposition effects. This has the effect of lowering the ozone concentration of indoor air to a level that is harmless to the human body and reducing the number of optical plasma generators required.

In addition, the present invention has the effect of reducing the operating noise of the air sterilizer due to the operation of the fan or air inflow and outflow by providing a low-noise exhaust part that reduces noise and a vibration-proof stand to attenuate vibration.

In addition, the present invention has the effect of preventing the dispersion of contaminated air or bacteria due to abnormal operation of the air sterilizer by detecting whether a malfunction or abnormality occurs in the optical plasma generator or fan, etc. using a separate sensor.

1 is an exploded perspective view of a prior art air purifier.
Figure 2 is a perspective view of an air sterilizer using light plasma of the present invention.
Figure 3 is a diagram of the internal opening of the air sterilizer using the light plasma of the present invention.
Figure 4 is a diagram showing an electrical circuit diagram related to the VUV lamp of the air sterilizer using light plasma of the present invention.
Figure 5 is a diagram of the optical plasma generator of the air sterilizer using the optical plasma of the present invention.
Figure 6 is a diagram showing a dust-proof stand of an air sterilizer using light plasma of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. The present invention may be subject to various changes and may have various forms, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Referring to Figures 2 and 3, an air sterilizer using light plasma according to an embodiment of the present invention includes a main body 100; A photoplasma generator 200, a VUV lamp driver 300, and an LCD/fan control unit 400 installed inside the main body 100; A low noise exhaust unit 500 installed on the upper part of the main body 100; It includes a dust-proof stand 700 installed below the main body 100.

In addition, an LCD display unit 120, a fan control knob 130, and a power button 140 are disposed on one side of the outside of the main body 100 of the present invention, and an intake port 110 for sucking in external air is formed at the bottom of one side. do.

When describing the photoplasma generator 200 of the present invention with reference to FIG. 4, the photoplasma generator 200 includes a photoplasma case 210 and a VUV lamp 220 installed therein, A vortex forming unit 600 that generates a vortex flow is installed on the side where air flows into the optical plasma generating unit 200.

In the present invention, the VUV lamp 220 irradiates ultraviolet light in the wavelength range of 100 nm to 400 nm. In particular, it emits vacuum ultraviolet rays in the form of optical plasma in the vacuum ultraviolet wavelength range corresponding to 100 nm to 200 nm, thereby damaging the sucked indoor air and moisture and 1. A secondary reaction occurs to generate OH radicals and ozone.

Although other types of radicals may be generated in the VUV lamp 220 of the present invention, the VUV lamp 220 of the present invention generates VUV by adjusting the vacuum gas composition in the lamp that generates light plasma or coating the lamp tube with a light wavelength control layer. The ultraviolet wavelength band of the lamp 220 can be focused on a band around 180 nm, which is a wavelength advantageous for generating OH radicals.

OH radicals are harmless to the human body and have an oxidation rate about 2,000 times faster than ozone, demonstrating powerful sterilization, deodorization, and disinfection properties. Therefore, activated compounds (phenol, resorcinol, salicylate) in the inhaled air are removed through a strong oxidation effect. , it can sterilize and purify by reacting with microorganisms, bacteria, and contaminants.

In particular, OH radicals have a higher electrochemical oxidation potential than ozone, so they decompose existing ozone while also removing organic pollutants that react slowly with molecular ozone, such as aliphatic acids, aldehydes, ketones, and aromatic hydrocarbons distributed in the inhaled air. It can be removed through a secondary reaction that reacts more rapidly and extensively with the OH radical non-selectively.

In particular, in the secondary reaction, OH radicals react with organic contaminants, creating a chain reaction that continuously generates new OH radicals, which can continuously produce sterilization and purification effects. For example, most organic chemical products mixed with air are oxidized by OH ^- radicals, aliphatic molecules provide RO ₂ ^- radicals that can initiate various reactions, the reaction of RO ₂ ^- radicals is fast and H atoms New carbon radicals are continuously generated by splitting or intramolecular movement. The sterilizing and purifying action of the intake air can be continuously maintained by the continuous generation of OH radicals, such as the reaction cycle of intramolecular movement of H atoms, generation of new RO ₂ ^- radicals, conversion to corresponding RO ₂ ^- radicals, etc. there is.

Through the primary and secondary reactions generated by the light plasma effect of the VUV lamp 220 of the present invention, it can demonstrate faster sterilization and decomposition ability than a general UVC sterilization lamp, and can achieve faster sterilization and decomposition ability than ozone (O3). It can be performed.

In particular, through the secondary reaction of the VUV lamp (220), not only ozone decomposition but also the chain generation effect of other OH radicals triggered by ozone decomposition can demonstrate faster sterilization and decomposition ability than general UVC sterilization lamps or ozone (O ₃ ). It can lower the indoor concentration of ozone, which is harmful to the human body, and can exert stronger sterilizing power than ozone while using less energy.

In the photoplasma generator 200 of the present invention, the photoplasma case 210 is coated so that the inside of the ultraviolet rays of the VUV lamp 220 is totally reflected, and the photocatalyst 230 is inside to increase the generation efficiency of OH radicals. It is desirable to be placed in . The photocatalyst 230 includes metals and/or metal oxides such as noble metals, aluminum oxide, titanium dioxide, silicon oxide, and mixtures thereof.

Additionally, in one embodiment of the present invention, a vortex forming unit 600 that generates a vortex flow is installed on the side where air flows into the photoplasma generating unit 200. The vortex forming unit 600 of the present invention allows the indoor air flowing into the vortex forming unit 600 by the suction fan 610 for sucking indoor air into the optical plasma case 210 while forming a swirling flow. It is provided with a plurality of vortex wings (620).

In this way, the air swirl flow introduced into the photoplasma case 210 increases the reaction path to react with ultraviolet rays emitted from the VUV lamp 220, thereby increasing the reaction time between ultraviolet rays and indoor air, resulting in a first reaction. The amount of OH radicals generated increases, and the generation of OH radicals generated in secondary reactions also increases, so air purification efficiency can be significantly improved.

In addition, since the ultraviolet rays of the VUV lamp 220 are totally reflected inside the photoplasma case 210, the ultraviolet ray reflection path becomes very long, so the reaction path between the inhaled swirling flow and the ultraviolet rays is greatly improved, thereby increasing the OH of the primary and secondary reactions. The generation of radicals further increases.

As described above, the photoplasma generator 200 of the present invention significantly improves the amount of OH radicals generated by the swirling action of the intake air, the total ultraviolet reflection action of the VUV lamp 220, and the action of the photocatalyst 230, thereby improving the sterilization and purification effects compared to the conventional one. It can be significantly improved compared to the UV sterilizing lamp, and also has the effect of reducing the required number of VUV lamps 220.

In addition, the photoplasma generator 200 of the present invention is equipped with an ultraviolet ray sensor 250 to measure the ultraviolet ray intensity of the VUV lamp 220 and transmits it to the VUV lamp driver 300, which will be described later.

Next, the VUV lamp driver 300 of the present invention will be described with reference to FIGS. 3 and 4. The VUV lamp driver 300 is characterized by including a power and drive circuit 310 and a timer 320.

In particular, the VUV lamp driver 300 monitors the ultraviolet ray detection signal from the ultraviolet ray sensor 250 of the photoplasma generator 200 and displays it on the LCD display 120, and then emits ultraviolet rays due to long-term use or failure of the VUV lamp 220. When it stops or decreases below a certain level, this situation is notified to the user through the LCD display unit 120 or a separate alarm device.

In addition, the VUV lamp driver 300 is equipped with a timer 320 that accumulates and measures the operation time since the VUV lamp 220 was first mounted, and displays the operation time of the VUV lamp 220 on the LCD display unit 120. If the operating time of the VUV lamp 220 is longer than the design life of the VUV lamp 220, the user is notified of this through the LCD display unit 120 or a separate alarm device.

The VUV lamp driver 300 of the present invention is equipped with an ultraviolet sensor 250 and a timer 330, thereby preventing contaminated air from entering the room without being sterilized or purified due to a malfunction or abnormality of the VUV lamp 220. It has the effect of preventing this.

In addition, the present invention has a separate pollution detection sensor that measures air pollution and can display it on the LCD display unit 120, and the VUV lamp driver 300 adjusts the ultraviolet ray intensity of the VUV lamp 220 to allow the user to You can achieve the desired level of purification.

3, the low noise exhaust unit 500 of the present invention is described. The low noise exhaust unit 500 is provided with an absorption chamber 520 and a plurality of sound insulation plates 530 are disposed inside the absorption chamber 520. An exhaust fan 510 is installed on the side where air flows from the absorption chamber 520.

In the present invention, the air that has been sterilized and purified by passing through the photoplasma generator 200 is discharged to the outside by the discharge fan 510, and is generally discharged to the outside through the discharge fan 510 itself or the air flow discharged by the discharge fan. This causes noise and vibration.

In the present invention, in order to prevent such noise and vibration, the exhaust fan 510 is fixed to the main body 100 by a fixing bolt 511 through a dustproof washer 512 to attenuate the vibration of the exhaust fan and also to prevent air flow. In order to reduce noise, a plurality of sound insulating plates 530 are arranged in a zigzag manner inside the low noise discharge section 500, and a sound absorbing material is attached to the inner wall of the low noise discharge section 500 or the sound insulating plate 530 to form a low noise discharge section 500. The air flowing into the air consumes flow energy as it zigzags between the sound insulation plates 530, and the flow noise is absorbed by the sound absorbing material, thereby reducing the noise and vibration of the air discharged through the outlet 550 of the low-noise discharge unit 500. This can be greatly reduced.

In addition, a vibration sensor is added near where the exhaust fan 510 is installed to detect vibration caused by the exhaust fan and transmits it to the LCD/fan control unit 400, and the fan control unit 400 discharges the vibration when it is determined that the vibration is above a certain level. The rotation speed of the fan 510 can be reduced and this information can be displayed on the LCD display unit 120. In addition, like the discharge fan 510, the suction fan 610 can detect abnormal operation through a vibration sensor and display it on the LCD display unit 120.

In the present invention, the suction fan 610 is fixed to the main body 100 by a fixing bolt 511 with an anti-vibration washer 512 interposed to attenuate the vibration of the discharge fan.

In addition, in the present invention, the rotation speeds of the suction fan 610 and the exhaust fan 510 are each controlled by the fan control knob 130, and the fan speed is increased by turning the fan control knob 130 clockwise and counterclockwise. Turn in the direction to reduce the fan speed and turn the fan control knob (130) until a “click” sound is heard to stop the fan.

Furthermore, an air flow sensor is installed near the suction fan 610 and the exhaust fan 510 to detect the air flow rate of the suction fan 610 and the exhaust fan 510 and transmits it to the LCD/fan control unit 400. If the air flow rate is determined to be below a certain level, this information can be displayed on the LCD display unit 120.

In addition, the user is provided with a separate input means to set the rotation speed of the suction fan 610 and the discharge fan 510, so that the LCD/fan control unit 400 operates the suction fan 610 and the exhaust fan 510 according to the user's set speed. The rotation speed of the exhaust fan 510 can be controlled, and when the user sets the intake volume or exhaust volume using a separate input means, the LCD/fan control unit 400 controls the intake fan 610 based on the sensor measurement value of the air flow sensor. ) and the rotation speed of the discharge fan 510 can be controlled.

In addition, in the present invention, a temperature sensor is placed on the driving motor of the suction fan 610 and the exhaust fan 510 to measure the temperature of each fan driving motor and transmits the temperature to the LCD/fan control unit 400 to adjust the temperature of the driving motor. If it is determined to be above a certain level, it is determined that the driving motor is overheated, this information is displayed on the LCD display unit 120, and the user can be notified through an alarm device.

This vibration sensor, temperature sensor, and flow sensor prevents contaminated air from entering the room without sterilization and purification due to a malfunction or abnormality of the suction fan 610 and exhaust fan 510. There is.

Next, the vibration isolation stand 700 of the present invention will be described with reference to FIG. 6. The anti-vibration stand 700 of the present invention includes a fixing bolt 710; A dust-proof washer 720 pressed by the fixing bolt 710; Anti-vibration rubber pads (730, 740) fastened to the main body (100) by the fixing bolt (710) and having different elastic moduli; and a sound-absorbing material 750 disposed inside the anti-vibration rubber pads 730 and 740, wherein a protrusion 760 is formed on the anti-vibration rubber pad 730 and a groove 770 on the anti-vibration rubber pad 740. It is characterized by this formation.

The vibration isolation stand 700 of the present invention not only attenuates vibration caused by the suction fan 610 and the exhaust fan 510, but also has the effect of preventing external vibration from being transmitted to the air sterilizer.

In particular, the anti-vibration stand 700 of the present invention generates a pressing force that presses the anti-vibration rubber pads 730 and 740 by the fastening force with which the fixing bolt 710 fastens the anti-vibration rubber pads 730 and 740 to the main body. When the anti-vibration rubber pads 730 and 740 are pressed, the anti-vibration frequency range changes according to the pressing force, and the transmission of vibration from the air sterilizer itself or from the outside can be controlled by the fastening force of the fixing bolt 710.

In addition, in the vibration-proof stand 700 of the present invention, vibration-proof rubber pads 730 and 740 with different elastic coefficients are stacked and pressed, so the vibration-proof frequency range can be adjusted by adjusting the elastic coefficients of the vibration-proof rubber pads 730 and 740. .

Therefore, the vibration isolation stand 700 of the present invention can adjust the vibration isolation frequency range by adjusting the fastening force of the fixing bolt 710 and the elastic coefficient of the vibration isolation rubber pads 730 and 740, so that it has the effect of attenuating vibration in a wide frequency range. there is.

In addition, a protrusion 760 is formed on one side of the anti-vibration rubber pads 730 and 740 of the present invention, and a groove 770 is formed on the other side, so that when the anti-vibration rubber pads 730 and 740 are stacked, the protrusion 760 forms a groove ( It is easy to assemble by inserting it into the 770), and also allows the laminated anti-vibration rubber pads 730 and 740 to maintain their laminated state without slipping.

In addition, the anti-vibration rubber pads 730 and 740 of the present invention can further attenuate vibration by having a sound absorbing material 750 therein.

In this way, in the air sterilizer according to the present invention, air passes inside the optical plasma generator in the form of a vortex, and ultraviolet rays of the optical plasma generator pass through the interior of the optical plasma generator to the extent of total reflection, thereby generating OH radicals in the optical plasma generator. Efficiency has been significantly improved compared to before, providing excellent air purification and sterilization effects.

In addition, in the present invention, since the optical plasma generator generates ultraviolet wavelengths in the range of 180 nm to 400 nm, OH radicals, ozone generation, and ozone decomposition can be performed by the same optical plasma generator, thereby reducing the ozone concentration in indoor air to a level that is harmless to the human body. This has the effect of reducing the number of optical plasma generators required.

In addition, the present invention has the effect of reducing the operating noise of the air sterilizer due to the operation of the fan or air inflow and outflow by providing a low-noise exhaust part that reduces noise and a vibration-proof stand to attenuate vibration.

Although the present invention has been described in detail through specific examples, this is for detailed explanation of the present invention, and the present invention is not limited thereto, and may be understood by those skilled in the art within the technical spirit of the present invention. It is clear that it can be modified or improved.

100: main body 110: intake port
120: LCD display 130: Fan control knob
140: Power button 150: Power connector
200: Optical plasma generator 210: Optical plasma case
220: VUV lamp 230: photocatalyst
250: UV sensor
300: VUV lamp driver 310: Power supply and driving circuit
320: Timer
400: LCD/fan control
500: low noise exhaust unit 510: exhaust fan
511: fixing bolt 512: dustproof washer
520: Absorption chamber 530: Sound insulation plate
540: Bulkhead 550: Outlet
560: Sound absorbing material
600: Vortex forming part 610: Suction fan
620: Vortex wings
700: Anti-vibration stand 710: Fixing bolt
720: Anti-vibration washer 730, 740: Anti-vibration rubber pad
750: Sound-absorbing material 760: Protrusion
770: Home

Claims (6)

main body (100);
A photoplasma generator 200, a VUV lamp driver 300, and an LCD/fan control unit 400 installed inside the main body 100;
A low noise exhaust unit 500 installed on the upper part of the main body 100;
It includes a dust-proof stand 700 installed below the main body 100,
The photoplasma generator 200 includes a photoplasma case 210 and a VUV lamp 220 installed therein,
The VUV lamp driver 300 is characterized in that it includes a power and drive circuit 310 and a timer 320.
Air sterilizer using light plasma. The air sterilizer using light plasma according to claim 1, wherein the low noise discharge unit 500 has an absorption chamber 520 and a plurality of sound insulation plates 530 are disposed inside the absorption chamber 520. The method according to claim 2, wherein a vortex forming unit 600 that generates a vortex flow is installed on the side where air flows into the optical plasma generating unit 200, and the vortex forming unit 600 includes a plurality of vortex blades 620. An air sterilizer using light plasma, characterized by having a. The method of claim 3, wherein the anti-vibration stand (700) is
fixing bolt (710);
A dust-proof washer 720 pressed by the fixing bolt 710;
Anti-vibration rubber pads (730, 740) fastened to the main body (100) by the fixing bolt (710) and having different elastic moduli;
It includes a sound-absorbing material 750 disposed inside the vibration-proof rubber pads 730 and 740,
A protrusion 760 is formed on the anti-vibration rubber pad 730,
Characterized in that a groove 770 is formed in the vibration-proof rubber pad 740,
Air sterilizer using light plasma. The method according to claim 4, wherein a suction fan 610 is installed at the lower part of the main body 100 and an exhaust fan 510 is installed at the upper part of the main body 100.
Air sterilizer using light plasma. The method of claim 5, wherein the VUV lamp 220 is characterized in that it emits vacuum ultraviolet rays in the form of optical plasma in the vacuum ultraviolet wavelength range corresponding to 100 nm to 200 nm.
Air sterilizer using light plasma.