JP5784969B2 - Deodorizing device, deodorizing method, air cleaning device and air cleaning method - Google Patents

Description

  The present invention relates to a deodorizing device, a deodorizing method, an air cleaning device, and an air cleaning method, and more particularly to a device that performs deodorization using active species.

  2. Description of the Related Art Conventionally, an air cleaning device for removing dust particles such as various dusts and tobacco smoke in the air (for example, a smoke separation device for collecting and removing tobacco smoke) is known. This air purifier is installed in a smoking room or the like to clean the air in the smoking room.

  Moreover, the conventional air purifying apparatus has various types of collection parts for collecting various dusts and tobacco smoke. In this air cleaning device, tar content of tobacco smoke or the like adheres and accumulates on the collecting part and may cause generation of a strange odor. In particular, a bad odor becomes strong at the start of operation.

  Furthermore, for example, in a company or the like, when the working hours have ended, the air cleaning operation of these devices is stopped, and the next day (for the first time after being left in a long-time stop state) for the first time, The off-flavor leaking out of the air cleaning device main body becomes particularly strong, and the smoking room is filled with odor.

  Therefore, air purifiers using activated carbon filters, catalytic filters, etc. are used to remove odors in smoking rooms, but these air purifiers also generate odors from dirt collected by the filters. Occurrence occurs, and when the operation is started after a long stop, the odor accumulated in the air purifier is discharged and the odor chamber is filled with odor.

  Therefore, there is known an air cleaning device that circulates an air flow in the air cleaning device while the dust collecting operation is stopped and suppresses odor generated from dirt collected by the collecting unit using a cycle light deodorization technique. (For example, refer to Patent Document 1).

JP 2001-104457 A

  However, in the conventional air purifier using the cycle photodeodorization technology, in order to improve the deodorization effect, the amount of air passing through the photocatalyst (the flow rate of air) is increased, the size of the photocatalyst is increased, and the ultraviolet lamp Although it is necessary to increase the number, there is a problem that the apparatus becomes larger.

  In addition, the intensity of ultraviolet rays emitted from ultraviolet lamps and the like is gradually lowered due to deterioration of the ultraviolet lamps, so that the odor oxidation resolution is lowered. And in order to prevent this fall and to maintain the deodorizing performance of an air purifying apparatus, there exists a problem that it is necessary to replace | exchange an ultraviolet lamp suitably.

  The present invention has been made in view of the above problems, and can improve the deodorizing effect without increasing the size of the device, and can maintain the deodorizing effect for a longer period of time than before. An object is to provide a device, a deodorizing method, and an air cleaning method.

The invention according to claim 1, that a deodorizing apparatus that is configured to perform deodorization of the object by using the active species generated in the active species generating unit, passes through the active species in the generator The air containing the active species is mixed with the air that has passed through the bypass channel formed outside the active species generating device, and the mixed air is flowed to the object so as to perform deodorization. The active species generating apparatus is an apparatus for generating a circle plasma by generating a discharge between the discharge electrode and the counter electrode by causing a desired current to flow between the discharge electrode and the counter electrode. A high-voltage transformer, a high-voltage control circuit for generating a predetermined high-voltage DC voltage as an output from the high-voltage transformer to the discharge electrode, and an output current level of the high-voltage DC voltage output from the high-voltage transformer to a predetermined constant current. A power source for an active species generating device, and a constant voltage control circuit for controlling an output voltage level of a high-voltage DC voltage output from the high-voltage transformer to a predetermined constant voltage, the active species generating device The power source for use is a deodorizing device characterized in that the amount of active species generated is substantially constant even when the discharge characteristics between the electrodes change due to contamination .

The invention according to claim 2, in claim 1 Symbol placement deodorizing apparatus, the deodorizing apparatus, by circulating air between said object the active species generating apparatus, deodorizing the object It is the deodorizing apparatus comprised as follows.

Invention of Claim 3 is provided with the collection part which collects the dust particle | grains in the air as the said target object, The said collection by the deodorizing apparatus of any one of Claims 1-2. It is the air purifying apparatus comprised so that a part may be deodorized.

Invention of Claim 4 is a deodorizing method using the deodorizing apparatus of any one of Claims 1-3, Comprising: The active species production | generation stage which produces | generates an active species using an active species production | generation apparatus An object deodorization stage for deodorizing an object using the active species generated in the active species generation stage, air containing the active species generated in the active species generation stage, and the active species generation apparatus. A mixing stage that mixes the air that has passed through the bypass flow path formed on the outside, and the object deodorizing stage flows the air mixed in the mixing stage to the object by flowing the object. It is a deodorizing method which is a stage which deodorizes.

  ADVANTAGE OF THE INVENTION According to this invention, a deodorizing effect can be improved, without enlarging an apparatus, and there exists an effect that a deodorizing effect can be maintained longer than before.

It is sectional drawing which shows schematic structure of the air purifying apparatus which concerns on embodiment of this invention. It is the figure which showed typically the flow of the air in an active species production | generation apparatus and a bypass flow path. It is a disassembled perspective view which shows schematic structure of an active species production | generation apparatus. It is a figure which shows the power supply characteristic of an active species production | generation apparatus. It is a figure which shows the relationship between the electric current value which flows between the electrodes of an active species production | generation apparatus, and the production amount of ozone. It is a figure which shows the procedure of a deodorizing test. It is a figure which shows the result of a deodorizing test. It is a figure which shows schematic structure of an active species production | generation apparatus and the active species production | generation apparatus installation bracket in which this active species production | generation apparatus was installed, (a) is a front view, (b) is a side view, (c) (D) is a bottom view, (e) is a figure which shows the VIII-VIII cross section in (a). It is a figure which shows schematic structure of the active species production | generation apparatus accommodating part in which the active species production | generation apparatus and the active species production | generation apparatus installation bracket were installed, (a) is a front view, (b) is a side view, c) is a plan view, and (d) is a bottom view. It is an enlarged view of the XX cross section in Fig.9 (a). It is the figure which showed the deodorizing mechanism typically.

  As shown in FIG. 1, an air purifying device (air purifier; for example, a smoke separating device that collects and removes tobacco smoke) 1 according to an embodiment of the present invention includes a collecting unit (dust collecting unit) 3 and a deodorizing unit ( Deodorizing device) 5. The collection unit 3 collects dust particles (including smoke such as tobacco) in the air, and is configured to deodorize the collection unit 3 and the like by the deodorization unit 5.

  That is, the deodorizing device 5 is configured to include an active species generating device 7, and using the active species generated by the active species generating device 7, deodorization (collecting unit 3) of an object (such as the collecting unit 3). And the like, such as tar adhering to the dust, and the odor generated by the dirt adhering to the collecting unit 3 are decomposed and removed).

  As will be described in detail later, the active species are the first electrode (discharge electrode; needle electrode; see FIG. 3) 9 of the active species generator 7 and the second electrode (counter electrode; plate-like) of the active species generator 7. The electrode is generated by generating a circle plasma between the electrode 11 and the electrode 11 (see FIG. 3).

  Further, the deodorizing device 5 mixes the air containing the active species by passing through the active species generating device 7 and the air that has passed through the bypass flow path 13 (see FIGS. 1 and 2). Deodorization is performed by flowing air through the collection unit 3.

  The bypass flow path 13 is an air flow path formed outside the active species generating device 7, and the air that has passed through the bypass flow path 13 does not contain active species. In addition, the concentration of the active species in the mixed air is less than that in the air immediately after passing through the active species generating apparatus 7.

  In the active species generating device 7, the discharge characteristics (characteristics of the power source 15 of the active species generating device 7) between the electrodes (between the discharge electrode 9 and the counter electrode 11) for generating active species are, for example, the electrodes 9 and 11. Even if it changes due to the adhesion of dirt, the amount of generated active species is almost constant. In the active species generation device 7 (active species generation device power supply 15), the voltage applied to the discharge electrode 9 and the counter electrode 11 is lower than the spark voltage. There is no spark between them.

  The deodorization device 5 is configured to deodorize the collection unit 3 and the like by circulating air between the collection unit 3 and the active species generation device 7.

  That is, when the active species generation device 7 is operated to deodorize the collection unit 3, the air is collected in the collection unit 3, the downstream space 19 of the collection unit 3, the active species generation device 7 and the bypass channel 13, It circulates in the upstream space 17 of the collection part 3 in this order, and is comprised so that it may deodorize.

  More specifically, the mixed air (air containing active species) flows from the upstream side (upstream side space 17) to the downstream side (downstream side space 19) of the collection unit 3 to flow through the collection unit 3. By passing, dirt itself such as tar adhering to the collection part 3 is decomposed. Moreover, when the mixed air passes through the collection unit 3, the off-flavor (odour-odor component) generated by the contamination of the collection unit 3 is decomposed. In addition, air containing an unpleasant odor remaining without being decomposed (air containing active species) comes out of the collection unit 3 (downstream space 19). (Odor-smelling component) is also decomposed by active species.

  Furthermore, the air (the air in which the off-flavor components are decomposed and, for example, a slight amount of active species remains) that has come out of the collection unit 3 (downstream space 19) is removed from the deodorizer 5 (in the active species generator 7). And the bypass channel 13), the active species are included, and again flow through the collection unit 3 to remove off-flavors (unusual odor components) as described above.

  Here, the air cleaning device 1 will be described in more detail.

  As shown in FIG. 1, the air purification device 1 is a table-type air purification device, and includes a rectangular flat plate-shaped top plate 21 and a rectangular bowl-shaped housing 23. The housing 23 is integrally provided on the top plate 21 below the top plate 21. In the housing 23, the collection unit 3 and the fan 25 are arranged.

  The top plate 21 is provided with an air suction port 27, the collection unit 3 is provided in the upper portion of the housing 23 provided in the top plate 21, and the fan is provided in the lower portion of the housing 23. 25 is provided. An air outlet 29 is provided at the lower side of the casing 23. The space between the top plate 21 and the collection unit 3 is an upstream space (upper space) 17, and the space between the collection unit 3 and the fan 25 is a downstream space (lower space) 19. It has become.

  In FIG. 1, the collection unit 3 cleans the air by flowing air from the upper air suction port 27 to the lower air ejection port 29. The space between the air suction port 27 of the top plate 21 and the collection unit 3 is a closed space that does not communicate with the outside of the apparatus. A fan 25 is disposed in the space below the collection unit 3 of the housing 23, and the space below the collection unit 3 of the housing 23 is on the side surface of the housing 23 on the short side side. It is a closed space that does not communicate with the outside of the apparatus except that it communicates with the provided air outlet 29. Accordingly, the fan 25 sucks air from the air suction port 27, passes through the collection unit 3, and then blows out purified air from the air blowing port 29.

  Here, the collection unit 3 electrostatically collects particles such as dust in the air sucked from the air suction port 27, collects the particles by filtration, or collects them by the action of both, and cleans them. Any method may be used as long as the converted air is discharged from the air ejection port 29, but in the present embodiment, the electrostatic dust collection type collection unit 3 is used.

  In other words, the collection unit 3 includes a pre-filter, an ionizer (charging unit) having a function of charging dust, and a collector (dust collection unit) that collects dust in the air suction port 27 in order. Built in. Therefore, when dust-containing air or the like is sent from the air suction port 27, clean air from which dust has been removed is discharged from the air ejection port 29 on the opposite side.

The ionizer and collector are formed by a combination of a discharge electrode member, a counter electrode member, a non-dust collection electrode member, and a dust collection electrode member. The counter electrode member and the dust collection electrode member have a volume resistivity of 10 ⁷ Ωcm or less. Preferably, the non-dust collecting electrode member is formed of a conductive resin material, and the non-dust collecting electrode member is formed of a semiconductive resin material having a volume resistivity of 10 ¹⁰ to 10 ¹³ Ωcm.

  In this case, the ionizer is configured by a combination of a discharge electrode member and a counter electrode member, and the collector is configured by a combination of a dust collection electrode member and a non-dust collection electrode member. In the ionizer and collector configured as described above, even if conductive dust is mixed in particles charged by the ionizer, the movement of the charge of the non-dust collecting electrode member is limited by the resistance of the semiconductive resin material. Therefore, it is possible to prevent the occurrence of sparks between the non-dust collection electrode member and the dust collection electrode member of the collection unit 3.

  The collecting unit 3 can be easily detached from the housing 23.

  Note that a so-called corrugated dust collecting unit may be employed as the dust collecting unit of the collecting unit 3. The corrugated dust collecting section is configured to include a plurality of electrode plates, a plurality of spacers, and a DC high-voltage power supply, as disclosed in, for example, Japanese Patent Publication No. 61-6708.

  The electrode plate includes an insulating film formed in an elongated rectangular flat plate shape and a conductive layer. The conductive layer is exposed at the central portion (the central portion in the width direction of the insulating film) of one surface (one surface in the thickness direction) of the insulating film, and is provided on the insulating film. In addition, the conductive layer is not formed in the both ends (the both ends of the width direction) of the single side | surface of an insulating film, and the insulating part is formed by this.

  Each of the electrode plates is stacked with each spacer interposed therebetween. The spacer is formed in a form that allows passage of air, such as a corrugated shape, and is provided at the insulating portion. And air flows between the laminated electrode plates.

  Further, each electrode plate is connected to a DC high voltage power source and charged so that adjacent electrode plates have different polarities, and dust is collected on the plate surface of the electrode plate.

  The active species generation device (inactivation device) 7 is a device that generates (generates) active species based on the same principle as that shown in the specification and drawings of Japanese Patent Application No. 2009-250967.

  As shown in FIGS. 2 and 3, the active species generating device 7 includes an electrode fixing frame 31 made of an insulator such as plastic, a discharge electrode 9 fixed to the electrode fixing frame 31, and the discharge electrode 9. And a flat plate-like counter electrode (plate electrode) 11 disposed opposite to each other.

  The electrode fixing frame 31 is formed in an elongated rectangular bowl shape, and the bottom plate portion 37 of the electrode fixing frame 31 is provided with a rectangular through hole 39 that constitutes an air introduction portion of the active species generating device 7. Yes.

  The counter electrode 11 is made of a conductive metal having an elongated rectangular flat plate shape, and a plurality of circular openings (through holes penetrating in the thickness direction) 41 are formed at the center. The openings 41 are provided side by side with a predetermined interval in the longitudinal direction of the counter electrode 11 and constitute an air discharge part of the active species generator 7.

  Further, the flat counter electrode 11 is disposed so that the surface (both planes in the thickness direction) is substantially orthogonal to the air flow generated by the deodorizing fan 43 (see FIG. 1 and the like). (See FIG. 2 etc.).

  The counter electrode 11 is fixed to the electrode fixing frame 31 so as to block the opening of the electrode fixing frame 31 (the opening on the side opposite to the bottom plate portion 37). The number of openings 41 in the counter electrode 11 is not limited to four, and may be any number greater than or equal to one.

  The discharge electrode 9 is made of a conductive metal having a long flat plate shape, and is provided with protrusions 45 having a needle shape at a plurality of locations on one side (side extending in the longitudinal direction). Both ends in the longitudinal direction of the discharge electrode 9 are fixed to the electrode fixing frame 31. In a state where the discharge electrode 9 and the counter electrode 11 are fixed to the electrode fixing frame 31, the discharge electrode 9 and the counter electrode 11 are in a non-conductive state, and the discharge electrode 9 is positioned inside the electrode fixing frame 31. Yes. Further, the tip of each protrusion 45 of the discharge electrode 9 is the center of each opening 41 formed in the counter electrode 11.

  Further, in a state where the discharge electrode 9 and the counter electrode 11 are fixed to the electrode fixing frame 31, the tip end portion of each protrusion 45 is set to be in the same plane as the counter electrode 11 (FIG. 2). reference). More specifically, the tip of the protrusion 45 of each discharge electrode 9 exists on the same plane as the one surface (surface on the electrode fixing frame 31 side) in the thickness direction of the counter electrode 11.

  In the active species generating device 7 shown in FIG. 3, the protrusion 45 of the discharge electrode 9 is disposed in each opening 41 provided in the counter electrode 11. The structure by which the protrusion 45 is arrange | positioned may be sufficient. For example, a configuration in which every other protrusion 45 is arranged in each opening 41 aligned in the longitudinal direction of the counter electrode 11 may be employed.

  The active species generating apparatus 7 is operated by an active species generating apparatus power supply 15 (see FIG. 1). The active species generator power supply 15 uses the discharge electrode 9 as a negative voltage (second voltage) and the counter electrode 11 as a ground voltage (first voltage) (that is, the second voltage is relative to the first voltage). In other words, a constant current flows between the counter electrode 11 and the discharge electrode 9.

  Then, by generating a discharge between the discharge electrode 9 and the counter electrode 11, the inside of the opening 41 provided in the counter electrode 11 is brought into a high excitation density state (described later), and active species are introduced into the opening 41. It is supposed to be generated.

  In the active species generating device 7, a desired current is passed between the discharge electrode 9 and the counter electrode 11, thereby generating a discharge in the space in the opening 41 between the discharge electrode 9 and the counter electrode 11. Then, circle plasma (circular light emission discharge) is generated around the opening 41. Next, circle plasma will be described.

  When the counter electrode 11 is set to the ground voltage and a negative high voltage is applied to the protrusion 45 of the discharge electrode 9 at the center of the opening 41, plasma is generated in the vicinity of the protrusion 45 and plasma is also generated around the opening 41. Occur. Plasma generated around the opening 41 is referred to as circle plasma. When the circle plasma is generated, the discharge region inside the opening 41 is in a high excitation density state. Among these, the vicinity of the protrusion 45 and the periphery of the opening 41 are mainly ionized regions, and the intermediate region is mainly the excitation / dissociation region. It becomes. Visible light is generated in the excitation / dissociation region near the center, and infrared light is generated in the excitation / dissociation region near the periphery.

  The ionization region means that when electrons colliding with a gas molecule are larger than the ionization energy (electron charge Q × ionization voltage V) of the gas molecule, the orbital electrons are taken away from the gas atom, and positive ions and secondary electrons are taken. Is an active region.

  The excitation region means that orbital electrons are not taken away from atoms when electrons that collide with gas molecules have energy lower than the ionization energy of the gas molecules and higher than the lowest excitation voltage. However, this is a region where the energy is transferred to a high energy orbit and activity occurs. Excited molecules are classified into a final state via a metastable state and a state where the excited molecule falls directly to the ground state with direct emission.

  The dissociation region is an active region in which a phenomenon of splitting into two atoms occurs when electrons accelerated by an electric field collide with molecules. Various active species are generated in these active regions.

  Then, a voltage is applied to the discharge electrode 9 and the counter electrode 11 from the power source 15 for the active species generating device to generate a circle plasma, and the deodorizing fan 43 is driven in this state from the air introduction part of the electrode fixing frame 31. When air is introduced, the air passes through a plurality of openings 41 provided in the counter electrode 11, and active species are added to the air by this passage.

  As active species, ozone and hydroxyl radical can be listed. When the odor component is, for example, formaldehyde, formic acid is generated by a chemical reaction between formaldehyde and ozone or hydroxyl radical. Further, carbon dioxide and water are generated by chemical reaction of formic acid with ozone or hydroxyl radical, and formaldehyde is decomposed and removed.

  The air cleaning device 1 will be further described. In the air cleaning device 1, the collection unit 3 is provided inside the housing 23 and above the housing 23. The deodorizing unit 5 is also provided inside the housing 23 and above the housing 23. However, in plan view, the collection unit 3 is provided in a wide area at the center of the housing 23 (top plate 21) below the air suction port 27, and the deodorizing unit 5 is disposed around the housing 23. It is provided in a small area of a part of the part.

  The collection unit 3 and the deodorization unit 5 divide the space inside the housing 23 into an upper space and a lower space. If the deodorizing unit 5 is closed and air does not flow between the upper space and the lower space through the deodorizing unit 5, the upper space (upstream space 17) to the lower space. To the (downstream space 19), the air flows only through the collection part 3.

  The active species generating device 7 of the deodorizing unit 5 is integrally installed on the active species generating device installation bracket 49 (see FIG. 8). Further, the active species generating device installation bracket 49 on which the active species generating device 7 is installed is integrally installed inside the active species generating device housing (deodorizing unit housing) 51 (see FIGS. 9 and 10). ).

  The deodorizing unit housing 51 is provided integrally with the housing 23 inside the housing 23. A deodorizing air suction port 53 is formed on the lower side surface of the deodorizing unit housing 51, and a deodorizing air ejection port 55 is formed on the upper side surface of the deodorizing unit housing 51. The deodorizing air suction port 53 opens to the collection unit 3 side (the center side of the housing 23) below the collection unit 3. The deodorizing air ejection port 55 opens above the collection unit 3 to the collection unit 3 side (the center side of the housing 23).

  The interior of the deodorizing unit housing 51 is separated into an upper space and a lower space by a partition plate 57. A deodorizing opening 59 is formed in the partition plate 57, and a deodorizing fan 43 is provided in the deodorizing opening 59. The active species generating device 7 and the active species generating device installation bracket 49 are provided in the above space. In addition, the bypass channel 13 is formed in the upper space and outside the active species generating device installation bracket 49 (see FIGS. 1 and 10).

  When the deodorizing fan 43 is driven, the air in the downstream space 19 of the collection unit 3 is sucked from the deodorizing air suction port 53, and the sucked air is discharged into the lower space (inside the deodorizing unit casing 51. Through the space), through only the deodorizing opening 59 and the deodorizing fan 43, and further through the active species generating device 7 and the bypass channel 13 formed in parallel to the active species generating device 7, From the elongated rectangular deodorizing air outlet 55, the air is blown out to the upstream space 17 of the collection unit 3.

  Regardless of the driving state of the fan 25 (whether the fan 25 is driven or not driven), when the deodorizing fan 43 is driven, the downstream space 19 of the collection unit 3, the deodorizing unit 5 (active species generation) In the device housing 51), the upstream space 17 of the collection unit 3, the collection unit 3, the downstream space 19 of the collection unit 3... Yes.

  Further, the air (air containing active species) that has come out from the active species generating device 7 and the air that has flowed through the bypass flow path 13 are within the active species generating device storage body 51 and the active species generating device 7. They are mixed with each other in the downstream space. In addition, the air that has flowed out from the active species generation device 7 and the air that has flowed through the bypass flow path 13 may be mixed in the upstream space 17 of the collection unit 3 outside the active species generation device storage body 51. .

  The area of the air flow path in the deodorization unit 5 (the area of the plane orthogonal to the air flow direction) will be described. The area of the four through holes 41 of the active species generation device 7 is the area of the bypass flow path 13. Is smaller than Further, the area of the deodorizing air suction port 53 and the area of the deodorizing opening 59 are equal to each other, for example, and the area of the air flow path of the deodorizing fan 43 is slightly smaller than the area of the deodorizing opening 59. It is getting smaller.

  The sum of the area of the bypass channel 13 and the area of the four through holes 41 is substantially equal to or larger than the area of the deodorizing air suction port 53.

  The area of the deodorizing air ejection port 55 is smaller than the area of the deodorizing air suction port 53. Thereby, in the air flow in the deodorizing part 5, the deodorizing air outlet 55 becomes resistance. And in the deodorizing part housing | casing 51, the air containing the active species which came out from the active species production | generation apparatus 7 and the air which flowed through the bypass flow path 13 fully mixed, and the density | concentration of active species is substantially uniform. Is blown out from the deodorizing air outlet 55.

  In addition, since the deodorizing air ejection port 55 becomes a resistance, the air blown out from the deodorizing air ejection port 55 is located at the site of the collection unit 3 far from the deodorizing air ejection port 55 (on the right side in FIG. 1). Can reach the collection part 3), and the collection part 3 can be deodorized almost uniformly.

  Further, since the deodorizing air ejection port 55 is long in the direction orthogonal to the paper surface of FIG. 1, the collection unit 3 can be deodorized almost evenly in the direction orthogonal to the paper surface of FIG.

  Here, the power source (power source of the inactivation device) 15 of the active species generation device 7 will be described in detail.

  The active species generating apparatus power supply 15 includes, for example, a high voltage control circuit, a constant voltage control circuit, a constant current control circuit, and a high voltage transformer (none of which are shown) as disclosed in Japanese Patent Laid-Open No. 2009-195853. Yes.

  The high voltage control circuit generates a predetermined high voltage DC voltage as an output from the high voltage transformer to the discharge electrode 9. The constant voltage control circuit controls the output voltage level of the high-voltage DC voltage output from the high-voltage transformer to a predetermined constant voltage.

  The active species generator power supply 15 controls the output current level of the high-voltage DC voltage output from the high-voltage transformer to a predetermined constant current.

  That is, the active species generating apparatus power supply 15 has a voltage-current characteristic that causes the high-voltage power from the power supply transformer to be represented by, for example, diagrams PG1 and PG2 in FIG. The diagram PG1 is a segment connecting the points P1 and P2, and the diagram PG2 is a segment connecting the points P2 and P3.

  FIG. 4 will be further described.

  4 is a voltage applied by the active species generating apparatus power supply 15 between the discharge electrode 9 and the counter electrode 11 of the active species generating apparatus 7, and the vertical axis in FIG. 4 is the active species generating apparatus. 7 shows a current flowing between the discharge electrode 9 and the counter electrode 11.

  The diagram G11 shows the relationship between the voltage and current in the initial product of the active species generator 7 (electrodes 9 and 11) that is not contaminated. That is, in the initial electrodes 9 and 11, when the voltage between the electrodes 9 and 11 is about 3.9 kV, a current of about 80 μA flows between the electrodes 9 and 11 (points on the diagram PG2). See PA1). At this time, 0.016 mg / min of ozone is generated by the active species generator 7 (electrodes 9 and 11).

  Similarly, the diagram G12 shows the relationship between the voltage and current in the electrodes 9 and 11 that are slightly soiled. That is, when the voltage between the electrodes 9 and 11 is about 4.3 kV, a current of about 71 μA flows between the electrodes 9 and 11 (see point PA2 on the diagram PG1). At this time, 0.014 mg / min of ozone is generated by the active species generator 7.

  Similarly, the diagram G13 shows the relationship between the voltage and current in the soiled electrodes 9, 11. That is, when the voltage between the electrodes 9 and 11 is about 4.4 kV, a current of about 54 μA flows between the electrodes 9 and 11 (see point PA3 on the diagram PG1). At this time, 0.016 mg / min of ozone is generated by the active species generator 7.

  Similarly, the diagram G14 shows the relationship between the voltage and the current in the electrodes 9 and 11 with much dirt. That is, when the voltage between the electrodes 9 and 11 is about 4.4 kV, a current of about 54 μA flows between the electrodes 9 and 11 (see point PA4 on the diagram PG1). At this time, 0.014 mg / min of ozone is generated by the active species generator 7.

  FIG. 5 is a diagram showing the relationship between the value of the current flowing between the electrodes 9 and 11 and the amount of ozone generated by the active species generator 7.

  The horizontal axis of FIG. 5 indicates the current flowing between the electrodes 9 and 11, and the vertical axis indicates the amount of ozone generated by the active species generating device 7. The diagram G21 shows the relationship between the current value between the unclean electrodes 9 and 11 and the amount of ozone generated. The diagram G22 shows the relationship between the current value between the electrodes 9 and 11 that are slightly soiled and the amount of ozone generated. The diagram G23 shows the relationship between the current value between the contaminated electrodes 9 and 11 and the amount of ozone generated. Further, the diagram G24 shows the relationship between the current value between the electrodes 9 and 11 that are heavily contaminated and the amount of ozone generated.

  As understood from FIGS. 4 and 5, in the active species generating device 7, the electrodes 9 and 11 are controlled by controlling the voltage and current values between the electrodes 9 and 11 as shown in the diagrams PG 1 and PG 2. Regardless of the degree of contamination, ozone of a substantially constant amount of 0.014 mg / min to 0.016 mg / min is generated.

  Next, with reference to FIG. 11, the concept of the deodorization of the collection part 3 is demonstrated. As described above, when deodorizing the collection unit 3 and the like, since air circulates between the collection unit 3 and the deodorization unit 5, the collection unit 3 depicted on the left side of FIG. The collection unit 3 depicted on the right side of FIG. 11 is the same.

  If dirt is attached to the collection part 3 shown on the left side of FIG. 11, odor comes out from the attached dirt. This odor is decomposed by the discharge part (discharge between the electrodes 9 and 11) of the active species generator 7 (deodorizing effect I). Further, the odor that has been released by the discharge part of the active species generating device 7 is decomposed by the active species generated by the active species generating device 7 (deodorizing effect II). Further, the active species generated by the active species generating device 7 decomposes the dirt adhering to the electrodes 9 and 11 and reduces the amount of odor generated (deodorizing effect III).

  Next, the operation of the air cleaning device 1 will be described.

  First, as an initial state, the collection unit 3, the fan 25, the active species generation device 7, and the deodorizing fan 43 are stopped.

  In the initial state, when a sensor (not shown) senses a person (may be a case where a start switch (not shown) is pressed), under the control of the control device 60 (see FIG. 1), The fan 25 is operated, and for example, air containing cigarette smoke is sucked into the upstream space 17 in the housing 23 (air cleaning device 1) from the air suction port 27.

  The air sucked into the upstream space 17 passes through the collection unit 3 to remove smoke and dust. The air from which the smoke and dust have been removed reaches the downstream space 19 and is further discharged from the air outlet 29 to the housing 23 (air cleaning device 1) through the fan 25.

  When the sensor no longer detects a person, the collecting unit 3 and the fan 25 are stopped. And immediately after this stop, the active species production | generation apparatus 7 and the deodorizing fan 43 operate | move for a predetermined time. Due to the operation of the active species generating device 7 and the deodorizing fan 43, an air flow as indicated by an arrow in FIG. 1 is generated, and the air flows between the deodorizing unit 5 and the collecting unit 3 in the air cleaning device 1. It circulates and the odor removal shown in FIG. 11 etc. is performed.

  In the above description, the active species generation device 7 and the deodorizing fan 43 are operated after the collection unit 3 and the fan 25 are stopped. However, the collection unit 3 and the fan 25 are operated. The activated species generator 7 and the deodorizing fan 43 may be operated as they are.

  Further, when the collection unit 3 and the fan 25 are stopped, the active species generation device 7 and the deodorizing fan 43 are always operated, for example, and when the collection unit 3 and the fan 25 are operating, The seed generator 7 and the deodorizing fan 43 may be stopped.

  According to the air cleaning device 1 (deodorizing device 5), the active species generated by the active species generating device 7 is configured to deodorize the collection unit 3 and the like, so that the deodorizing device 5 is enlarged. Thus, the deodorizing effect can be improved, and the deodorizing effect can be maintained longer than before.

  That is, in the conventional air cleaning device using the cycle light deodorization technique, as described above, it is necessary to increase the size of the photocatalyst and increase the number of ultraviolet lamps in order to increase the deodorization effect, but it is easy to reduce the size. Active species are generated using the active species generating device 7, and deodorization is performed using the generated active species (active species having a larger deodorizing effect than the photocatalyst), so that the deodorizing performance is improved without increasing the size of the device. Can be made.

  Moreover, since the active species production | generation apparatus 7 whose performance degradation by a use period is less than an ultraviolet lamp is used, a deodorizing effect can be maintained longer than before.

  Further, according to the air cleaning device 1, the air containing the active species by passing through the active species generating device 7 and the air passing through the bypass flow path 13 are mixed, and the mixed air is collected. Since the deodorization is performed by flowing in the section 3, pressure loss in the flow of air for deodorization (air containing active species) can be suppressed, and a decrease in the flow rate of the air flowing through the collection section 3 can be prevented. And the deodorizing effect can be further improved.

  That is, since the bypass flow path 13 is provided, the number of the electrodes 9 and 11 in the active species generating apparatus 7 can be increased or the counter electrode 11 can be increased without expanding the air flow path in the active species generating apparatus 7. Even if the number of through holes 41 opened is not increased), the flow rate of air (air containing active species) flowing through the collection unit 3 can be increased, and the deodorizing effect can be further improved. .

  In addition, since the active species produced | generated by the active species production | generation apparatus 7 are mixed with the air which flowed through the bypass flow path 13, the ratio of the active species of the air which flows through the collection part 3 is made thin (active species). The concentration of the active species is thinner than the air coming out of the generator 7). However, since the deodorizing ability of the active species is strong, the concentration of the active species becomes a moderate concentration (concentration that can sufficiently deodorize the collection unit 3 etc.) by being diluted.

  Further, if air flows even a little in the active species generating device 7 (through hole 41), this small amount of air (air containing active species at a high concentration) and the air that has flowed through the bypass passage 13 The air is mixed and the concentration of the active species becomes moderate, and a sufficient amount of the active species is supplied to the collection unit 3 so that the collection unit 3 and the like can be deodorized.

  Further, according to the air cleaning device 1, the active species generating device 7 (active species generating device power supply 15) has a characteristic that the amount of generated active species is substantially constant even when the discharge characteristics between the electrodes 9 and 11 change. Therefore, the deodorizing effect can be maintained longer than before. Moreover, even if the air which passes through the collection part 3 leaks out of the air purifying apparatus 1, it prevents that ozone increases to the level which has a bad influence on a human body in the room | chamber interior in which the air purifying apparatus 1 is installed. be able to.

  Moreover, according to the air purifying apparatus 1, since it is comprised so that the collection part 3 etc. may be deodorized by circulating air between the collection part 3 and the active species production | generation apparatus 7, the deodorization part 5 The active species and off-flavors are almost never leaked to the outside of the air cleaning device 1 when operating, and a further deodorizing effect can be obtained.

  Here, the test of the air cleaning device 1 will be described with reference to FIGS. 6 and 7.

  FIG. 6 shows a test method of the air cleaning device 1, reference numeral 61 denotes a chamber, reference numeral 63 denotes a burnt cigarette, and reference numeral 65 denotes a sampling machine. Reference numeral 67 indicates a jig, and reference numeral 69 indicates a blower.

  First, as shown in FIG. 6A, the dust collecting electrode (collecting unit 3) is set using a jig 67 in the chamber 61, the blower 69 is operated, and smoke equivalent to 2000 cigarettes is emitted. Collect on the dust collecting electrode.

  Subsequently, as shown in FIG. 6B, the dust collecting electrode that collects the cigarette smoke is set in the air cleaning device 1, and the deodorizing unit (not shown in FIG. 6B) is operated to remove the deodorization. The operation is performed for 10 hours, for example.

  Then, as shown in FIG.6 (c), the air purifying apparatus 1 is installed in the chamber 61, and dust collection operation | movement is performed for 1 minute.

  Subsequently, as shown in FIG. 6D, after the dust collection operation is stopped, a part of the air in the chamber 61 is sampled by the sampling machine 65, and the odor is measured.

  The odor concentration is measured by a three-point odor bag method. That is, the operation shown in FIGS. 6A to 6D is repeated three times to collect 6000 cigarette smoke.

  FIG. 7 shows the test results of the air cleaning device 1, the horizontal axis shows the number corresponding to the tobacco load, and the vertical axis shows the odor concentration.

  A diagram G31 in FIG. 7 shows a test result in the air cleaning device 1 according to the embodiment of the present invention, and a diagram G32 in FIG. 7 shows a test result in the air cleaning device in which the deodorizing unit is not provided. ing. As can be understood from FIG. 7, in the air cleaning device 1 according to the embodiment of the present invention, the odor is about 1/10 compared to the air cleaning device in which the deodorizing unit is not provided.

  By the way, you may grasp | ascertain the description content of the said embodiment as invention of a method. That is, an active species generating stage for generating active species using an active species generating apparatus, and an object deodorizing method for deodorizing an object using the active species generated in the active species generating stage. You may grasp | ascertain as invention.

  In this case, the air containing the active species generated in the active species generating stage and the air that has passed through the bypass channel formed outside the active species generating device (the active species by passing through the bypass channel) A mixture stage (air containing no active species / air stage containing no active species), and the object deodorization stage flows the air mixed in the mixture stage to the object. It is desirable that the target object is deodorized.

  Further, it is desirable that the active species generating device has a characteristic that the amount of active species generated is substantially constant even when the discharge characteristics between the electrodes for generating the active species change.

  Furthermore, it is desirable that the deodorization method is a method for deodorizing the object by circulating air between the object and the active species generator.

  In addition, the object is a collection unit that collects dust particles in the air, and has a collection step of collecting dust particles in the air by the collection unit, and the collection unit is configured to perform the deodorization method. It may be grasped as an air cleaning method for deodorizing.

1 Air purifier 3 Collection part (object)
5 Deodorization device (deodorization part)
7 Active species generator 9 Electrode (discharge electrode)
11 electrode (counter electrode)
13 Bypass channel

Claims (4)

A deodorizing apparatus that is configured to perform deodorization of the object by using the active species generated in the active species generating unit,
The air containing the active species by passing through the inside of the active species generating device and the air passing through the bypass flow path formed outside the active species generating device are mixed, and the mixed air is mixed with the air It is configured to deodorize by flowing to the object,
The active species generator is a device for generating a circle plasma by generating a discharge between the discharge electrode and the counter electrode by flowing a desired current between the discharge electrode and the counter electrode, A high-voltage control circuit for generating a predetermined high-voltage DC voltage as an output from the high-voltage transformer to the discharge electrode, and a constant-current control circuit for controlling the output current level of the high-voltage DC voltage output from the high-voltage transformer to a predetermined constant current; A power source for an active species generator having a constant voltage control circuit that controls the output voltage level of the high-voltage DC voltage output from the high-voltage transformer to a predetermined constant voltage,
The deodorizing apparatus according to claim 1, wherein the power source for the active species generating device has a characteristic that the amount of active species generated is substantially constant even if the discharge characteristics between the electrodes are changed due to contamination . In deodorizing apparatus according to claim 1 Symbol placement,
The deodorizing apparatus is configured to deodorize the target object by circulating air between the target object and the active species generating apparatus. As the object, comprising a collection unit for collecting dust particles in the air,
It is comprised so that the said collection part may be deodorized with the deodorizing apparatus of any one of Claims 1-2 . The air purifier characterized by the above-mentioned. A deodorizing method using the deodorizing apparatus according to any one of claims 1 to 3,
An active species generating stage for generating active species using an active species generating device;
An object deodorization step of deodorizing the object using the active species generated in the active species generation step;
A mixing step of mixing the air containing the active species generated in the active species generating step with the air that has passed through the bypass flow path formed outside the active species generating device;
Have
The object deodorization step is a step of deodorizing the object by flowing the air mixed in the mixing step to the object.

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