CN112762562A - Method and device for electrostatic adsorption self-cleaning dust removal of air purifier - Google Patents
Method and device for electrostatic adsorption self-cleaning dust removal of air purifier Download PDFInfo
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- CN112762562A CN112762562A CN202011633187.0A CN202011633187A CN112762562A CN 112762562 A CN112762562 A CN 112762562A CN 202011633187 A CN202011633187 A CN 202011633187A CN 112762562 A CN112762562 A CN 112762562A
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B08—CLEANING
- B08B—CLEANING IN GENERAL; PREVENTION OF FOULING IN GENERAL
- B08B5/00—Cleaning by methods involving the use of air flow or gas flow
- B08B5/02—Cleaning by the force of jets, e.g. blowing-out cavities
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/88—Electrical aspects, e.g. circuits
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24F—AIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
- F24F11/00—Control or safety arrangements
- F24F11/89—Arrangement or mounting of control or safety devices
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Abstract
The invention provides a method and a device for electrostatic adsorption self-cleaning dust removal of an air purifier, wherein the air purifier comprises an electrostatic adsorption electrode, and the method comprises the following steps: stopping the purification working state of the air purifier; and applying a high-voltage electric field with alternately switched polarity to the electrostatic adsorption electrode to peel off the pollutants adsorbed on the electrostatic adsorption electrode. The method and the device for electrostatic adsorption self-cleaning dust removal of the air purifier provided by the invention can ensure that the electrostatic adsorption pollutants in the air purifier can be removed more conveniently and quickly, and the use convenience of the air purifier is improved.
Description
Technical Field
The invention relates to the technical field of air purification, in particular to a method and a device for electrostatic adsorption self-cleaning dust removal of an air purifier.
Background
In the existing air purifier adopting the types of plasma, ionization, electrostatic adsorption and the like, after being used for a period of time, pollutants in the air are inevitably adsorbed on internal devices due to the electrostatic action, so that the air purifier is polluted.
The method is characterized in that pollutants adsorbed by static electricity in the air purifier are removed, in the prior art, a motor is adopted to drive a hammer to hammer an electrode cavity besides a cleaning solution for periodically disassembling a dust collection electrode for washing, but the method is high in noise and limited in effect, and still needs a professional person to use a professional medicament for periodic removal, so that the cleaning and maintenance procedures of the existing plasma, ionization and other air purifiers are complex and tedious, and the use convenience needs to be improved.
It is to be noted that the information disclosed in the background section above is only for enhancement of understanding of the background of the invention and therefore it may contain information that does not constitute prior art that is already known to a person skilled in the art.
Disclosure of Invention
In order to solve the problems in the prior art, the invention provides an electrostatic adsorption self-cleaning dust removal method and device for an air purifier, which can enable the electrostatic adsorption pollutants in the air purifier to be removed more conveniently and quickly and overcome the problems in the prior art.
The invention provides an electrostatic adsorption self-cleaning dust removal method for an air purifier, wherein the air purifier comprises an electrostatic adsorption electrode, and the method is characterized by comprising the following steps: stopping the purification working state of the air purifier; and applying a high-voltage electric field with alternately switched polarity to the electrostatic adsorption electrode to peel off the pollutants adsorbed on the electrostatic adsorption electrode.
According to a preferred embodiment of the present invention, the air cleaner further comprises a cleaning electrode, and in the step of applying the high voltage electric field with the polarity alternately switched to the electrostatic adsorption electrode, the high voltage electric field with the polarity alternately switched to the cleaning electrode is also applied to the cleaning electrode.
According to a preferred embodiment of the invention, the air purifier further comprises a fan and a dust suction fan, and the method for electrostatic adsorption self-cleaning dust removal further comprises starting the dust suction fan, blowing off the pollutants adsorbed on the purifying electrode and the electrostatic adsorption electrode, and/or controlling the fan to make the air flow in the direction opposite to the purifying operation state.
According to a preferred embodiment of the invention, high voltage electric fields with alternating polarity can be applied at varying frequencies.
According to a preferred embodiment of the present invention, the method further comprises applying vibration to the electrostatic adsorption electrode and the purge electrode.
The invention also provides a device for electrostatic adsorption self-cleaning dust removal of the air purifier, which comprises an electrostatic adsorption electrode, a controller and a high-voltage electrostatic power supply, wherein the controller controls the high-voltage electrostatic power supply to apply a high-voltage electric field to the electrostatic adsorption electrode in the purification working state of the air purifier, and controls the high-voltage electrostatic power supply to apply a high-voltage electric field with alternately-switched polarity to the electrostatic adsorption electrode when the air purifier stops the purification working state and starts the self-cleaning dust removal continuously.
According to a preferred embodiment of the present invention, the air purifier electrostatic adsorption self-cleaning dust removing device further comprises a purifying electrode, and the controller controls the high voltage electrostatic power supply to apply the high voltage electric field with the polarity being alternately switched to the purifying electrode when applying the high voltage electric field with the polarity being alternately switched to the electrostatic adsorption electrode.
According to a preferred embodiment of the invention, the air purifier electrostatic adsorption self-cleaning dust removal device further comprises a fan and a dust suction fan, and the controller controls the dust suction fan to be started and/or controls the fan to enable air to flow in a direction opposite to that in the purification working state.
According to a preferred embodiment of the present invention, the controller controls the high voltage electrostatic power supply to apply the high voltage electric field with the polarity alternately switched at a varying frequency.
According to a preferred embodiment of the invention, the device for electrostatic adsorption self-cleaning dust removal of the air purifier further comprises a vibrator, the vibrator is directly or indirectly connected with the electrostatic adsorption electrode and/or the purification electrode, and the controller controls the on and vibration of the vibrator.
The method and the device for electrostatic adsorption self-cleaning dust removal of the air purifier provided by the invention can ensure that the electrostatic adsorption pollutants in the air purifier can be removed more conveniently and quickly, and the use convenience of the air purifier is improved.
Drawings
The above and other features of the present invention will be described in detail below with reference to certain exemplary embodiments thereof, which are illustrated in the accompanying drawings, and which are given by way of illustration only, and thus are not limiting of the invention, wherein:
fig. 1 is a schematic front view showing an internal structure of a plasma air cleaner according to an embodiment of the present invention.
Fig. 2 is a side view schematically showing the internal structure of the plasma air cleaner of fig. 1.
Fig. 3 shows a functional block diagram of a plasma air cleaner according to an embodiment of the present invention.
Fig. 4 shows an electrical control block diagram of a plasma air cleaner according to an embodiment of the present invention.
Fig. 5 shows a schematic view of a plasma reaction chamber in a plasma air purifier according to an embodiment of the present invention.
FIG. 6 shows a cross-sectional view of the plasma reaction chamber of FIG. 5 along the central axis after being covered with an insulating layer.
Fig. 7 is a schematic view showing another structure of a plasma reaction chamber in a plasma air cleaner according to an embodiment of the present invention.
Fig. 8 shows a cross-sectional view of the plasma reaction chamber of fig. 7 along a central axis.
Fig. 9A and 9B respectively show a schematic plan view and a schematic cross-sectional view along a line a-a of the charge distribution of the surface of a general electrode material.
Fig. 10A and 10B respectively show a schematic plan view and a schematic cross-sectional view along line B-B of the charge distribution of the surface of the electrode material employing surface charge control according to an embodiment of the present invention.
Fig. 11 is a sectional view showing a plasma purifying tube composed of a plasma reaction chamber and an electrostatic adsorption chamber in a purification chamber of a plasma air purifier according to an embodiment of the present invention.
Fig. 12 is a schematic view illustrating a plasma purge tube array composed of a plurality of plasma purge tubes as shown in fig. 11 in a plasma air cleaner according to an embodiment of the present invention.
Fig. 13 is an exploded perspective view illustrating a clean room and a dust room in the plasma air cleaner according to an embodiment of the present invention.
Fig. 14 shows an exploded side view of the cleanroom and dirt collection chamber shown in fig. 13.
Fig. 15 shows a rear exploded view of the cleanroom and dirt collection chamber shown in fig. 13.
Fig. 16 shows an assembled perspective view of the cleanroom and dirt collection room shown in fig. 13.
Fig. 17 shows a top view of the cleanroom and dirt collection room shown in fig. 16.
Fig. 18 illustrates a perspective view of a dust box supporting frame in a plasma air cleaner according to an embodiment of the present invention.
Figure 19 shows a cross-sectional view of the dust bin support frame shown in figure 18 taken along line C-C.
Fig. 20 illustrates a perspective view of a dust box in a plasma air cleaner according to an embodiment of the present invention.
Figure 21 shows a side view of the dust bin shown in figure 20.
Fig. 22 illustrates an air flow path in a dust collecting chamber when the plasma air cleaner self-cleans dust according to an embodiment of the present invention.
Fig. 23 shows a schematic cross-sectional view of a plate-plate type electrostatic adsorption chamber according to an embodiment of the present invention.
Fig. 24 is a schematic view illustrating an array of purge pipes comprising a plasma reaction chamber and the electrostatic adsorption chamber shown in fig. 23 according to an embodiment of the present invention.
Detailed Description
The present invention is described in detail below with reference to specific examples so that those skilled in the art can easily practice the present invention in light of the disclosure of the present specification. The embodiments described below are only a part of the embodiments of the present invention, and not all of them. All other embodiments obtained by a person skilled in the art based on the embodiments in the present specification without inventive step are within the scope of the present invention.
As shown in fig. 1 and 2, the plasma air cleaner according to an embodiment of the present invention includes a housing 100, an air outlet 1, a fan chamber 2, a buffer chamber 3, a catalyst chamber 4, an ozone reaction chamber 5, a cleaning chamber 6, an air inlet 7, a dust collection chamber 8, and an appliance chamber 9. A guide plate 10 can be arranged in the air outlet 1 and used for guiding purified clean air.
The dashed arrows in fig. 2 schematically indicate the direction and path of the air flow during the cleaning process. Specifically, polluted air to be purified enters a purification chamber 6 above a dust collection chamber 8 through an air inlet 7, then passes through an ozone reaction chamber 5, a catalyst chamber 4, a buffer chamber 3 and a fan chamber 2 in sequence under the action of a fan optionally arranged in the air inlet 7 and/or a fan arranged in the fan chamber 2, and finally flows out of the air purifier through an air outlet 1 under the guidance of a guide plate 10.
The electric appliance chamber 9 is internally provided with electric elements such as an electronic switch, a plasma high-voltage generator, a positive direct-current high-voltage generator, a negative direct-current high-voltage generator, a controller (a micro control unit, MCU), a communication module and a cooling fan, and the electric elements control the operation and the closing of each part of the plasma air purifier.
The dust collecting chamber 8 includes a dust collecting case, a dust collecting case support frame, and the like, and the specific structure of the dust collecting chamber 8 will be further described below.
The upper portion of the dust collecting chamber 8 is an air inlet 7, and a plurality of sensors, such as formaldehyde, TVOC, PM2.5, PM0.3, temperature and humidity sensors, can be installed inside the air inlet 7 and used for monitoring air at the air inlet 7 and collecting various index parameters of the air. A blower (not shown) is optionally provided at an upper portion of the air inlet 7 near the clean room 6 to increase the amount of air supplied from the air inlet 7 and promote the flow of air inside the air cleaner. The air inlet opening 7 may also be integrated with the support frame of the dust chamber 8, the specific structure of which will be further described below.
The upper part of the air inlet 7 is provided with a purifying chamber 6. The purifying chamber 6 comprises a plasma purifying tube array which is composed of a plurality of plasma purifying tubes arranged in parallel. Each plasma purifying tube is formed by connecting a plasma reaction cavity and an electrostatic adsorption cavity in series, and the specific structure of the plasma purifying tube can be described in detail in the following description in conjunction with fig. 11. The specific structure of the plasma reaction chamber and the electrostatic adsorption chamber can be described in detail with reference to fig. 5 to 10. The plasma reaction chamber and the electrostatic adsorption chamber in the plasma purification tube array can be connected with a vibrator, so that a plasma purification unit and an electrostatic adsorption dust removal unit (shown as dotted line boxes 301 and 302 in fig. 3) are respectively formed, and the vibrator (shown as fig. 13-16) can be arranged on the plasma purification tube module formed by the plasma purification tube array and used for vibrating the plasma purification tube when the plasma purification tube is cleaned, so that pollutants adhered to the plasma purification tube are enabled to be peeled off. The specific structures of the plasma reaction chamber and the electrostatic adsorption chamber, the specific structure of the plasma purification tube, and the specific structure of the plasma purification tube array will be described in further detail below with reference to fig. 5 to 12.
The inside of the ozone reaction chamber 5 is a space with a certain volume, and the ozone generated by the plasma reaction cavity and the electrostatic adsorption cavity kills and purifies the virus, bacteria and harmful substances in the air in the space, and part of the ozone is reduced into oxygen.
The catalyst chamber 4 is filled with a porous ozone reduction catalyst, for example, a catalyst mainly composed of manganese dioxide.
The buffer chamber 3 is used to buffer the flow of clean air purified through the purification chamber 6, the ozone reaction chamber 5, and the catalyst chamber 4 to equalize the air pressure.
The fan chamber 2 is provided with a fan for increasing the air output of the air outlet 1 and promoting the air flow inside the air cleaner.
A plurality of different sensors can be installed inside the air outlet 1, for example, formaldehyde, TVOC, PM2.5, PM0.3, temperature and humidity sensor for monitoring the air at the air outlet 1 and acquiring various index parameters of the air. In addition, a discharge needle (not shown in the figure) for releasing negative ions can be further installed inside the air outlet 1.
The sensors and the discharge needles arranged in the ozone reaction chamber 5, the catalyst chamber 4, the buffer chamber 3, the fan chamber 2 and the air outlet 1 are all known in the art, and the structure and the working principle thereof are not described herein again.
In addition, the plasma air purifier of the invention can be externally provided with a display screen, a switch element, a touch screen or the like so as to realize the control of the air purifier from the outside.
The working principle and flow of the plasma air cleaner of the present invention will be described with reference to fig. 3 and 4.
When the plasma air purifier according to an embodiment of the present invention is started, the controller 303, the display screen 312, the various sensors 313, and the communication module 311 are started; the first electronic switch 3161, the second electronic switch 3162 and the multi-stage electronic switch 310 are turned on, the third electronic switch 3163, the fourth electronic switch 3164 and the fifth electronic switch 3165 are turned off, and the first negative high-voltage power supply 3151, the plasma high-voltage source 317, the fan 309 and the discharge needle 308 start to operate. At this time, harmful polluted air containing hundreds of pollutants such as viruses, bacteria, formaldehyde, ammonia, odor, benzene, xylene, smoke, nicotine and the like, and toxic gases such as carbon monoxide and the like enters the air purifier through the air inlet 7, and the quantity of the harmful substances in the air is detected by a plurality of sensors 313 installed in the air inlet 7, such as formaldehyde, TVOC, PM2.5, PM0.3, temperature, humidity and the like.
The harmful polluted air sequentially passes through the plasma reaction chamber 306 and the electrostatic adsorption chamber 307 in the purification chamber 6. In the plasma reaction chamber 306, when virus and bacteria in the air contact with the high-potential plasma, the virus and bacteria can be inactivated and killed due to the destruction of the polarity and the structure of the protein; when hundreds of pollutants such as formaldehyde, ammonia, odor, benzene, xylene, smoke dust, nicotine and the like in the air are contacted with a large number of high-potential active particles in plasma, the pollutants are decomposed and removed, and the method mainly comprises two ways: firstly, under the instantaneous high-energy action of high-energy electrons, chemical bonds of certain harmful gas molecules are opened, so that the harmful gas molecules are directly decomposed into simple substance atoms or harmless molecules; secondly, under the action of a large amount of high-energy electrons, ions, excited particles, oxygen free radicals, hydroxyl free radicals (free genes have unpaired electrons and have strong activity) and the like, the materials are oxidized and decomposed into harmless products. At the same time, a large amount of high-concentration ozone is generated by the high voltage in the plasma reaction chamber 306. Ozone with high concentration is a strong oxidant, has the oxidation capacity higher than chlorine (1.36V) and chlorine dioxide (1.5V), can destroy and decompose the cell wall of bacteria, can directly react with bacteria and viruses to destroy cells and ribonucleic acid (RNA), and decompose macromolecular polymers such as deoxyribonucleic acid (DNA), RNA, protein, lipid and polysaccharide, so that the metabolism and the propagation process of the bacteria are destroyed. Its bactericidal power is 600-3000 times greater than that of chlorine, its bactericidal and disinfecting action is almost instantaneous, and its strong oxidizing property can be used for redox of toxic and harmful gases of ammonia and carbon monoxide, etc.
In the electrostatic adsorption cavity 307, the electrodes are charged with high voltage and form corona through discharge, so that particles (including virus and bacteria) in the air can be effectively adsorbed, and the air is purified. At the same time, a large amount of high-concentration ozone is also generated in the electrostatic adsorption chamber 307 by the high voltage. Ozone with high concentration is a strong oxidant, has the oxidation capacity higher than chlorine (1.36V) and chlorine dioxide (1.5V), can destroy and decompose the cell wall of bacteria, can directly react with bacteria and viruses to destroy cells and ribonucleic acid (RNA), and decompose macromolecular polymers such as deoxyribonucleic acid (DNA), RNA, protein, lipid and polysaccharide, so that the metabolism and the propagation process of the bacteria are destroyed. Its bactericidal power is 600-3000 times greater than that of chlorine, its bactericidal and disinfecting action is almost instantaneous, and its strong oxidizing property can be used for redox of toxic and harmful gases of ammonia and carbon monoxide, etc.
The air purified by the plasma reaction chamber 306 and the electrostatic adsorption chamber 307 then enters the ozone reaction chamber 5 from the purification chamber 6. Meanwhile, high-concentration ozone generated when the plasma reaction cavity 306 and the electrostatic adsorption cavity 307 work also enters the ozone reaction chamber 5, in the space, the ozone further kills and purifies virus, bacteria and harmful substances in the air, and meanwhile, part of the ozone is reduced into oxygen, so that the concentration of the residual oxygen is reduced.
The air from the ozone reaction chamber 5 enters the catalyst chamber 4, and the air containing ozone contacts with the porous ozone reduction catalyst filled in the catalyst chamber 4, so that the ozone is reduced into oxygen.
Air from the catalyst chamber 4 enters the buffer chamber 3 to equalize the air pressure.
The air is sent to the outlet 1 by the fan 309 in the fan chamber 2 after coming out of the buffer chamber 3. A plurality of sensors 313 installed in the air outlet 1, such as formaldehyde, TVOC, PM2.5, PM0.3, temperature, humidity and the like, detect the air quality, and release negative ions through a discharge needle 308 in the air outlet 1, and the negative ions are blown out of the air purifier along with the wind and diffused into the air.
The controller 303 located in the electric appliance chamber 9 displays relevant data on the display screen 312 according to data acquired by the sensors 313 installed in the air inlet 7 and the air outlet 1, and adjusts the multi-stage electronic switch 310 according to the relevant data and a preset program so as to adjust the air volume and the working voltage of the plasma reaction chamber 306 and the electrostatic absorption chamber 307 to control the air volume and the working voltage.
The structure of the plasma reaction chamber in the plasma air cleaner according to an embodiment of the present invention is shown in fig. 5 and 6. As shown in fig. 5 and 6, the plasma reaction chamber 306 includes two cleaning electrodes, specifically, in this embodiment, a linear electrode 501 and a coaxial cylindrical electrode 502, wherein a plurality of grooves 503 are formed on the wall of the cylindrical electrode 502, and the grooves 503 divide the wall of the cylindrical electrode 502 into discontinuous, non-closed cylindrical walls. That is, the cylindrical electrode 502 can be regarded as being obtained by: the plurality of grooves 503 are formed on the originally continuous and uniform wall of the cylindrical electrode 502, so that the originally continuous and uniform state of the inner surface of the wall of the cylindrical electrode 502 is broken, and when the inner surface of the cylindrical electrode 502 is charged, the surface charge distribution is not continuous and uniform any more, so that the distribution of the inner surface charge of the cylindrical electrode 502 is controlled, and a specific surface charge distribution pattern is formed. Further, the grooves 503 may be provided in parallel with each other on one side as shown in fig. 5, or may be provided in any shape, for example, the shape of the grooves 503 'provided in parallel with each other in a double-sided staggered manner as shown in fig. 7 and 8, as long as the surface charge distribution of the cylindrical electrodes 502, 502' when the inner surfaces thereof are charged is discontinuous and/or uneven. The wire-like electrodes 501, 501 ' and the cylindrical electrodes 502, 502 ' may be made of metal, wherein the wire-like electrodes 501, 501 ' may be made of fine metal wires, and may have a diameter of 0.1 to 1mm, preferably 0.1 to 0.2mm, made of stainless steel wire.
The control of the charge distribution on the inner surface of the cylindrical electrodes 502 and 502' will be described below with reference to fig. 9A and 9B and fig. 10A and 10B. Fig. 9A and 10A show schematic top views of charge distributions when a common electrode material surface 901 (a uniform continuous electrode material surface, which can be regarded as the developed inner surface of the cylindrical electrodes 502, 502 ' without grooves 503, 503 ') and an electrode material surface 901 ' (a discontinuous and/or non-uniform electrode material surface, which can be regarded as the developed inner surface of the cylindrical electrodes 502, 502 ' with grooves 503, 503 ') using surface charge control according to the present invention are charged, respectively; fig. 9B and 10B show schematic cross-sectional views of the charge distribution of the above-described general material surface and the material surface using surface charge control along lines a-a and B-B in fig. 9A and 10A, respectively, where 902 and 902' show charge distribution layers, respectively. As is clear from the figure, the charge distribution 902 on the surface 901 of a normal material is uniform and continuous, whereas the charge distribution 902 ' on the surface 901 ' of a material according to the invention, which is controlled by surface charges, is discontinuous and/or non-uniform, and this discontinuous and/or non-uniform charge distribution 902 ' can be set and controlled by the pattern of the conductive material on the surface of the electrode. Through the above arrangement of the conductive material on the surface of the counter electrode, specifically in this embodiment, through the arrangement of the inner surfaces of the cylindrical electrodes 502, 502 ', the motion trajectory, action time, uniformity, etc. of the charged particles in the electric field space of the plasma reaction chambers 306, 306' can be changed, so as to greatly improve the purification rate of the plasma on the virus, bacteria and chemical harmful substances in the air.
In order to realize the above-mentioned charge control on the surface of the electrode material, in addition to the hollow formation of the grooves 503, 503 'or other patterns on the cylindrical electrodes 502, 502' as described above, the inner surface of the electrode conductive material may be patterned by coating an insulating layer thereon, or covered with a patterned insulating material thereon, as long as the discontinuous and/or uneven charge distribution can be formed on the surface of the electrode conductive material.
The invention controls the flow direction of the gas to be purified passing through the inner surface of the cylindrical electrodes 502 and 502 ' of the plasma reaction chambers 306 and 306 ' by controlling the charges on the inner surfaces, so that the air to be purified passes through the plasma reaction chambers 306 and 306 ' and generally runs according to the surface shape of the controlled charges, thereby achieving the effect of increasing the gas flow path. As is known to all, the longer the action path of the plasma on the air to be purified is, the better the purification effect is, the invention prolongs the action path and time of the plasma on the air by increasing the airflow path, thereby enhancing the purification effect. In addition, the invention can increase the disturbance among the gases when the gases pass through by forming the charge-no-charge alternating energy field on the inner surface of the cylindrical electrodes 502, 502 ' of the plasma reaction chambers 306, 306 ', so that the pollutants in the gases are further mixed and stirred, and the pollutants in the gases pass through the plasma reaction chambers 306, 306 ' more uniformly, thereby increasing the probability that the pollutants in the gases contact with the plasma, and further achieving better purification effect.
As shown in fig. 6 and 8, the cylindrical electrodes 502 and 502 'of the plasma reaction chambers 306 and 306' may be covered with an insulating material 504 and 504 ', such as teflon, for insulating the outside of the plasma reaction chambers 306 and 306'.
The structure of the electrostatic adsorption chamber may be the same as the basic structure of the plasma reaction chamber 306, 306'. Of course, the patterns of the conductive material on the inner surfaces of the cylindrical electrodes may be different according to the requirement, for example, the electrostatic adsorption cavity 307 shown in fig. 11, which includes two adsorption electrodes, specifically, in this embodiment, a metal wire electrode 1101 and a metal coaxial cylindrical electrode 1102, wherein several grooves 1103 are formed on the wall of the cylindrical electrode 1102. It should be noted that, although the physical structure of the two electrostatic adsorption electrodes 1101 and 1102 in the electrostatic adsorption cavity 307 is similar to or even identical to the structure of the cleaning electrodes 501, 501 'and 502, 502' in the plasma reaction cavities 306, 306 ', the electric fields applied by the electrostatic adsorption electrodes 1101 and 1102 in the electrostatic adsorption cavity 307 and the cleaning electrodes 501, 501' and 502, 502 'in the plasma reaction cavities 306, 306' in the cleaning operation state are completely different, and therefore, the roles and effects of the two electrodes are completely different. Specifically, in the cleaning operation, a high voltage power source, such as a high voltage ac power source, for generating plasma is applied to the plasma reaction chambers 306 and 306', and a high voltage power source, such as a high voltage dc power source, for generating electrostatic attraction is applied to the electrostatic attraction chamber.
Fig. 11 shows a cross-sectional view of a plasma cleaning tube 111 in a cleaning chamber of a plasma air cleaner according to an embodiment of the present invention. As shown, the plasma reaction chamber 306 and the electrostatic adsorption chamber 307 may be connected in series through an insulating material 504, such as a teflon tube, to form the plasma purification tube 111.
As shown in fig. 12, a plurality of plasma purge pipes 111, for example, plasma purge pipes 1111, 1112 … … 111n shown in fig. 12, may be arranged in parallel to form a plasma purge pipe array 121.
The surface charge control technology of the invention changes the motion track, action time, uniformity and the like of charged particles in the electric field space, and greatly improves the purification rate of the plasma on virus, bacteria and chemical harmful substances in the air. In addition, the surface charge control technology and the electrostatic adsorption technology are combined, so that the motion track, action time, uniformity and the like of the charged particles in the electric field space in the electrostatic adsorption cavity 307 can be changed, and the adsorption and purification rate of the static electricity on particulate matters such as PM2.5, PM0.3 and the like is greatly improved.
Fig. 13 to 19 are schematic structural views illustrating the cleaning chamber 6 and the dust collecting chamber 8 in the plasma air cleaner according to an embodiment of the present invention. Fig. 13 to 15 are exploded views of the clean room 6 and the dust room 8 in the plasma air cleaner, and fig. 16 and 17 are perspective views and plan views of the clean room 6 and the dust room 8 after assembly. Fig. 18 and 19 show a perspective view and a sectional view of the dust box support frame. In this embodiment, the cleaning chamber 6 is integrated with the dust chamber 8 by means of an integral dust box support frame 82. Wherein the upper space of the dust box support frame 82 is for accommodating the cleaning chamber 6, and the lower space is for accommodating the dust chamber 8. The plasma purification tube array 121 is fixed in the fixing bracket 123 to form the plasma purification tube module 61. The plasma purification pipe module 61 is provided with a vibrator 122 for applying vibration to the plasma purification pipe module 61 when cleaning it, and assisting in removing contaminants, such as dust particles, etc., adsorbed in the plasma purification pipe 111. The plasma purifying pipe module 61 is installed in the upper space of the dust box supporting frame 82, and is fixed by a plurality of positioning blocks 62 installed on the side wall of the bottom of the upper space of the dust box supporting frame 82, forming the purifying chamber 6. The positioning blocks 62 may be made of foam or other suitable material, and serve to position, fix and buffer the plasma purifying tube module 61. An opening 63 for receiving the vibrator 122 is formed on an upper side wall of the dust box supporting frame 82 to prevent the dust box supporting frame 82 from interfering with the vibrator 122.
The dust box support frame 82 is provided with an opening 71 in a lower side wall thereof for allowing air introduced into the air cleaner from the air inlet 7 to pass therethrough and thus to enter the cleaning chamber 6. The dust box support frame 82 is also provided with an opening 84 in the lower side wall for mounting a suction fan 83, the suction fan 83 being, for example, an axial fan. A drawable dust collecting box 81 is provided at a lower portion of the dust box supporting frame 82 for collecting contaminants, such as dust particles, removed from the cleaning chamber 6 and the like.
As shown in fig. 20 and 21, the dust box 81 has a side wall 811 and a handle 812 for facilitating the drawing of the dust box 81. A filtering material 813 for filtering contaminants, such as dust particles, in the air during the self-cleaning process of the plasma air cleaner is installed inside the sidewall 811 of the dust collecting case 81. The side wall 811 of the dust collecting box 81 is further provided with an opening 814 for air to pass through during the self-cleaning and dust removing process of the plasma air cleaner. The self-cleaning dust removing process of the plasma air cleaner will be described in detail below.
After the plasma air purifier works for a period of time, certain pollutants are inevitably adsorbed in the plasma reaction cavity 306 and the electrostatic adsorption cavity 307, and the working efficiency and the effect of the whole machine are influenced if the pollutants are not removed.
According to another embodiment of the present invention, by applying the dc high voltage electricity with positive and negative polarity changed periodically or irregularly to the linear electrodes 501, 1101 and the cylindrical electrodes 502, 1102 of the plasma reaction chamber 306 and the electrostatic adsorption chamber 307, the pollutants such as particles, dust and the like adsorbed on the linear electrodes 501, 1101 and the cylindrical electrodes 502, 1102 are forced to be stripped off under the action of the electric field force and enter the dust collection box 81, so that the effect of self-cleaning and dust removal of the air purifier can be achieved. In the self-cleaning dust removal process, the vibrator 122 can be used to apply vibration to the plasma purification tube module 61 at the same time, so that each plasma purification tube 111 in the plasma purification tube array 121, including the linear electrodes 501 and 1101 and the cylindrical electrodes 502 and 1102 thereof, generates vibration, and the self-cleaning dust removal efficiency of the linear electrodes 501 and 1101 and the cylindrical electrodes 502 and 1102 stripping off the adsorbed particulate matters, dust and other pollutants and entering the dust collection box 81 is improved.
The following describes a specific operation flow of the self-cleaning dust removal procedure for peeling off the pollutants such as particulate matters and dust adsorbed by the plasma purification tube by using the dc high voltage applying the positive and negative polarity conversion with reference to fig. 3 and 4.
When the plasma air purifier starts a self-cleaning dust removal program, the controller 303, the display screen 312, the various sensors 313 and the communication module 311 are started; the first electronic switch 3161, the second electronic switch 3162 and the multi-gear electronic switch 310 are turned off, and the first negative high-voltage power supply 3151, the plasma high-voltage source 317, the fan 309 and the discharge needle 308 stop working; the third electronic switch 3163, the fourth electronic switch 3164 and the fifth electronic switch 3165 are activated, the vibrator 122 (the vibrator 1221 and/or the vibrator 1222), the second negative high voltage power supply 3152 and the positive high voltage power supply 314 start to operate, and particularly, the fourth electronic switch 3164 and the fifth electronic switch 3165 are alternately turned on and off at a certain frequency, for example, 1Hz, under the control of the controller 303, so that high voltage electric field repulsive force with alternately switched polarities is formed on the linear electrodes 501 and 1101 and the cylindrical electrodes 502 and 1102 of the plasma reaction chamber 306 and the electrostatic absorption chamber 307, thereby peeling off the pollutants absorbed on the electrodes. Meanwhile, the vibrator 122 drives the plasma reaction cavity 306 and the electrostatic absorption cavity 307 to vibrate, so as to further improve the efficiency of stripping and dropping pollutants, the stripped and dropped pollutants drop into the drawn dust collection box 81, and the electric field force and the vibration force are combined to complete the self-cleaning dust removal work.
According to an embodiment of the present invention, the above-mentioned self-cleaning operation mode of the plasma air cleaner can be set such that the polarity alternation is performed at a constant frequency, or preferably at a variable frequency, and the polarity alternation is preferably performed sequentially from high to low. For example, the positive and negative polarities of the electrodes are reversed at a frequency of 2Hz for a duration of 10 seconds; the positive and negative polarities of the electrodes are reversed at the frequency of 3Hz, and the duration time is 10 seconds; and so on until the positive and negative polarities of the electrodes are reversed at a frequency of 10Hz for 10 seconds. The advantage of doing so is, the vibration of short time can "the bullet falls" with the less granule of volume, and long-time vibration can "the bullet falls" with the great granule of volume, guarantees like this that all adsorbed pollutants on the electrode can both "the bullet falls", the pollutant after "the bullet falls makes things convenient for the cleaing away of follow-up technological means.
In addition, in the self-cleaning dust removal process, the low-speed airflow flowing from the air outlet 1 to the air inlet 7 in the opposite direction (i.e. the opposite direction to the airflow shown by the dotted arrow in fig. 2) to the normal working state (air purification) can be generated through the low-speed reverse rotation (60-180 rpm) of the fan optionally arranged inside the air inlet 7 and/or the fan 309 arranged inside the fan chamber 2, so that adsorbates which may be "suspended" in the plasma purification tube module 61 can be "blown off".
In addition, in the self-cleaning dust removal process, the dust collection fan (axial flow fan) 83 can be started to work, so that the adsorption pollutants discharged from the plasma purification pipe module 61 are all trapped in the dust collection box 81 by the filter material 813 in the dust collection box 81, the filter material 813 only stops the splashing of the pollution particles, and any filter material can be used, such as a filter screen of a dust collector. The air flow path in the dust collecting chamber 8 in this state is shown in fig. 22, in which the broken line hollow arrows show the air flow path. It should be noted that, in the purified air operation state of the plasma air cleaner, the dust suction fan 83 is not operated, and the air flow flows in the direction indicated by the broken line arrow in fig. 2.
The starting and stopping of the self-cleaning dust removal technology of the plasma air purifier are controlled by the controller 303, and the self-cleaning dust removal technology of the plasma air purifier can work regularly according to a set period and can be started and stopped intelligently according to purified air data collected by a sensor.
It should be noted that the structure of the electrostatic adsorption cavity 307 in the above embodiments of the present invention may also adopt other types of electrode structures known in the art, such as a wire-plate type electrode, a plate-plate type electrode, and the like. Fig. 23 shows a schematic cross-sectional view of a plate-plate type electrostatic adsorption chamber 307 ' according to an embodiment of the present invention, wherein 1101 ' represents one set of electrodes composed of a plurality of plate-shaped electrodes, 1102 ' represents another set of electrodes composed of a plurality of plate-shaped electrodes, the two sets of electrodes are arranged at intervals, and when being energized, the two sets of electrodes carry charges of different polarities, and contaminants, such as dust particles, having charges of different polarities are electrostatically adsorbed respectively by electrostatic adsorption. Fig. 24 schematically illustrates an array of purge pipes comprising a plurality of plasma reaction chambers 306 (labeled 3061, 3062, 3063, 3064) as shown in fig. 5 and 6 and electrostatic adsorption chambers 307' as shown in fig. 23, according to an embodiment of the present invention. It should be understood that the number of the plasma reaction chambers 306 and the plate-plate type electrostatic adsorption chambers 307' shown in the drawings is only illustrative, and the specific actual number thereof may be increased or decreased as needed.
Furthermore, it will be appreciated by those skilled in the art that the electrostatic adsorption chamber according to the present invention may be configured not only to be connected to the plasma reaction chamber 306, but also to be connected to other types of air purification devices, such as an ionized air purification device, and may also achieve adsorption and self-cleaning of contaminants, such as dust particles.
The surface charge control technology greatly improves the purification efficiency of the plasma on harmful air, reduces the size of the plasma reaction cavity, greatly improves the adsorption efficiency of static on air particles, and reduces the size of the static adsorption cavity. Experiments show that by adopting the surface charge control technology in the embodiment of the invention, the purification rate of formaldehyde can be improved by 10-15%, the purification rate of PM2.5 particles can be improved by 5-8%, and the purification rate of PM0.3 particles can be improved by 10-13% under the same conditions.
The self-cleaning dust removal technology solves the problem of removing pollutants adsorbed by the electrode in the process of purifying air pollutants by electrostatic adsorption and the like, and solves the practical problem that the plasma and the electrostatic adsorption pollutants need to be removed regularly by professional people by using professional medicaments at present.
All documents mentioned in this specification are herein incorporated by reference as if each were incorporated by reference in its entirety.
Furthermore, it should be understood that various changes or modifications can be made by those skilled in the art after reading the above description of the present invention, and such equivalents also fall within the scope of the present invention.
Claims (10)
1. The electrostatic adsorption self-cleaning dedusting method for the air purifier, wherein the air purifier comprises an electrostatic adsorption electrode, and is characterized by comprising the following steps of:
stopping the purification working state of the air purifier; and
and applying a high-voltage electric field with alternately switched polarity to the electrostatic adsorption electrode to peel off the pollutants adsorbed on the electrostatic adsorption electrode.
2. The method for electrostatic adsorption self-cleaning dust removal of the air purifier as claimed in claim 1, wherein the air purifier further comprises a purifying electrode, and in the step of applying the high-voltage electric field with the polarity being alternately switched to the electrostatic adsorption electrode, the high-voltage electric field with the polarity being alternately switched to the purifying electrode is also applied to the purifying electrode.
3. The method for electrostatic adsorption self-cleaning dust removal for the air purifier as claimed in claim 2, wherein the air purifier further comprises a blower and a dust suction fan, and the method for electrostatic adsorption self-cleaning dust removal for the air purifier further comprises the following steps:
and starting the dust absorption fan, blowing off the pollutants adsorbed on the purification electrode and the electrostatic adsorption electrode, and/or controlling the fan to enable air to flow in the direction opposite to the purification working state.
4. The method for electrostatic adsorption self-cleaning dust removal of the air purifier as claimed in any one of claims 1-3, wherein the high-voltage electric field with alternating polarity is applied at a varying frequency.
5. The electrostatic adsorption self-cleaning dedusting method for the air purifier as recited in claim 4, further comprising the following steps:
applying vibration to the electrostatic adsorption electrode and the purification electrode.
6. The utility model provides an air purifier electrostatic adsorption self-cleaning dust removal's device, includes electrostatic adsorption electrode, controller and high-voltage electrostatic power supply under air purifier's purification operating condition, the controller control high-voltage electrostatic power supply to electrostatic adsorption electrode applys high-voltage electric field, its characterized in that when air purifier stops to purify operating condition and starts self-cleaning dust removal and lasts, the controller control high-voltage electrostatic power supply to electrostatic adsorption electrode applys the high-voltage electric field of polarity alternate conversion.
7. The electrostatic adsorption self-cleaning dust removing device of the air purifier as claimed in claim 6, further comprising a cleaning electrode, wherein the controller controls the high voltage electrostatic power supply to apply the high voltage electric field with the polarity alternately switched to the cleaning electrode when applying the high voltage electric field with the polarity alternately switched to the electrostatic adsorption electrode.
8. The electrostatic adsorption self-cleaning dust removing device for the air purifier as claimed in claim 7, further comprising a blower and a dust suction fan, wherein the controller controls the dust suction fan to be turned on and/or controls the blower to make air flow in a direction opposite to that in the purification operation state.
9. The electrostatic adsorption self-cleaning dust removal device for the air purifier as claimed in any one of claims 6 to 8, wherein the controller controls the high-voltage electrostatic power supply to apply the high-voltage electric field with alternating polarity at a variable frequency.
10. The electrostatic adsorption self-cleaning dust removing device of the air purifier as claimed in claim 9, further comprising a vibrator, wherein the vibrator is directly or indirectly connected with the electrostatic adsorption electrode and/or the purification electrode, and the controller controls the on and vibration of the vibrator.
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