JP2009056448A - Air treatment device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress also a manufacturing cost without enlarging an apparatus in adopting a constitution that water droplets are charged in a water droplet generating part (32) in an air treatment device provided with a dust charging section (31) and the water droplet generating part (32). <P>SOLUTION: The device comprises the dust charging section (31) charging the dust in air to be treated, the water droplet generating part (32), and a water droplet charging part (33) charging the water droplets, and a unit (30) is constituted by at least two among the components of the dust charging section (31), the water droplet generating part (32), and the water droplet charging part (33). <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an air treatment device, and more particularly to a technology for reducing the size and cost of an air treatment device.

  Conventionally, as an air treatment device for deodorizing air, there is one described in Patent Document 1. The apparatus of Patent Document 1 includes an ionization unit (dust charge unit) that charges dust such as dust and mist in the air, and a scrubber unit that sprays water droplets downstream of the ionization unit in the air flow direction. (Water droplet generator). Then, the charged dust or mist is attached to and captured by water droplets sprayed by the scrubber portion.

In this air treatment apparatus, it is conceivable to charge the water droplets in the scrubber portion so that dust and mist adhere to the water droplets by Coulomb force. In this way, the dust and mist collection efficiency is increased, so that the dust collection performance of the apparatus can be improved.
JP 2003-126728 A

  However, in order to charge the water droplets in the scrubber section, it is necessary to provide a discharge mechanism in the scrubber section separately from the discharge mechanism provided in the ionization section. If two discharge mechanisms are provided in this way, the apparatus becomes large. Further, when the device is enlarged, the manufacturing cost of the device also increases.

  The present invention has been made in view of such a point, and an object of the present invention is to provide a large-sized apparatus when adopting a configuration in which a water droplet is charged by a scrubber unit in an air treatment apparatus including a dust charging unit and a scrubber unit. The manufacturing cost is also suppressed without being converted.

  1st invention presupposes the air processing apparatus which collects dust with to-be-processed air.

  The air treatment apparatus includes a dust charging unit (31) that charges dust, a water droplet generation unit (32) that blows out water droplets, and a water droplet charging unit (33) that charges the water droplets with a polarity opposite to that of the dust. The dust charging unit (31), the water droplet generating unit (32), and the water droplet charging unit (33) constitute at least two units to form one unit (30).

  In the first aspect of the invention, dust is charged in the dust charging unit (31), and water droplets are charged in the water droplet generating unit (32) by the water droplet charging unit (33). In this case, the polarity of the charge of the dust and the polarity of the charge of the water droplet are opposite. As a result, the dust is attracted and attached to the water droplet by the Coulomb force in the space after the dust and the water droplet are charged. Therefore, the dust collection efficiency can be increased and the dust collection performance of the apparatus can be enhanced.

  2nd invention presupposes the air processing apparatus which collects dust and deodorizes with respect to to-be-processed air.

  The air treatment apparatus includes a dust charging unit (31) that charges dust, a water droplet generation unit (32) that blows out water droplets, a water droplet charging unit (33) that charges the water droplets in the opposite polarity to the dust, Active species generating part (34) for converting the active species into active species by electrical action, the dust charging part (31), the water droplet generating part (32), the water droplet charging part (33), and the active species generating part (34) One unit (30) is configured by at least two of the components.

  In the second aspect of the invention, dust is charged in the dust charging unit (31), and water droplets are charged in the water droplet generating unit (32) by the water droplet charging unit (33). In this case, the polarity of the charge of the dust and the polarity of the charge of the water droplet are opposite. As a result, the dust is attracted and attached to the water droplet by the Coulomb force in the space after the dust and the water droplet are charged. Therefore, the dust collection efficiency can be increased and the dust collection performance of the apparatus can be enhanced. In addition, the active species generating unit (34) generates various active species from the water droplets. Therefore, it is possible to decompose odorous substances and pollutants in the air.

  According to a third invention, in the first or second invention, as the one unit (30), a water droplet charging unit (33) is disposed in the direction of water droplet ejection of the water droplet generating unit (32), and the water droplet charging unit (33) Is characterized in that a potential different from that of the water droplet generator (32) is applied.

  In the third aspect of the invention, one of the water droplet generating part (32) and the water droplet charging part (33) constituting one unit (30) acts as a discharge electrode (42), and the other acts as a counter electrode. Water droplets are charged. This charged water droplet adsorbs dust charged to a reverse polarity.

  According to a fourth aspect of the present invention, in the second aspect of the present invention, an active species generator (34) is disposed as the one unit (30) in the direction of water droplet ejection of the water droplet generator (32), and the water droplet generator (32) and the active unit are activated. One of the seed generating parts (34) is configured as a discharge electrode (42), and the other is configured as a counter electrode.

  In the fourth aspect of the invention, one of the water droplet generator (32) and the active species generator (34) constituting one unit (30) acts as a discharge electrode (42), and the other acts as a counter electrode. As a result, water droplets are charged. This charged water droplet adsorbs dust charged to a reverse polarity.

  According to a fifth invention, in the first or second invention, a plurality of electrodes (41, 42) and a plurality of water droplet blowing members (38, 39) are provided as the constituent elements. The electrodes (41, 42) or the water droplet blowing members (38, 39) are integrated with each other.

  In the fifth aspect of the invention, the plurality of electrodes (41, 42) or the water droplet blowing members which are constituent elements of the dust charging unit (31), the water droplet charging unit (33) and the active species generating unit (34) are integrated. Is done.

  In a sixth aspect based on the fifth aspect, the electrodes (41, 42) or the water droplet blowing members (38, 39) constituting the one unit (30) are located at the same position in the flow direction of the air to be treated. It is characterized by being arranged.

  In the sixth aspect of the invention, the plurality of electrodes (41, 42) or the water droplet blowing members which are constituent elements of the dust charging unit (31), the water droplet charging unit (33) and the active species generating unit (34) are covered with each other. Arranged at the same position in the flow direction of processing air

  A seventh invention is characterized in that, in the fifth invention, a plurality of electrodes (41, 42) constituting the one unit (30) are connected to the same power source (37).

  In the seventh invention, a plurality of electrodes (41, 42) which are constituent elements of the dust charging unit (31) and the water droplet charging unit (33) are connected to the same power source (37), and the same power source ( Power is supplied from 37).

  The eighth invention is characterized in that, in the fifth invention, the water supply means (72) is provided in which the plurality of water droplet blowing members (38, 39) constituting the one unit (30) are connected in parallel. It is said.

  In the eighth aspect of the invention, a plurality of water droplet blowing members which are constituent elements of the water droplet charging unit (33) and the active species generating unit (34) are connected in parallel to the water supply unit (72), and one water supply unit (72 ) To supply water to a plurality of water droplet blowing members.

  According to a ninth invention, in the fifth invention, the one unit (30) includes a plurality of electrodes (41, 42) or a plurality of water droplets on a conductive and air-permeable base (35, 36). It is characterized by being constituted by fixing members (38, 39).

  In the ninth aspect of the invention, the plurality of electrodes (41, 42) or the water droplet blowing members (38, 39) constituting the one unit (30) are electrically conductive and air-permeable base materials (35, Fixed to 36).

  According to a tenth aspect of the present invention, in the first or second aspect of the present invention, a casing (10) for housing the one unit (30) is provided, and the unit (30) is configured to be detachable from the casing (10). It is characterized by being.

  In the tenth aspect of the present invention, the plurality of electrodes (41, 42) or the water droplet blowing members which are constituent elements of the dust charging unit (31), the water droplet charging unit (33) and the active species generating unit (34) The unit (30) can be attached to and detached from the casing (10).

  The eleventh aspect of the invention is characterized in that, in the first or second aspect of the invention, the dust charging part (31) is arranged in the direction of water discharge in the water droplet generation part (32).

  In the eleventh aspect of the invention, the water sprayed from the water droplet generating part (32) is sprayed onto the electrodes (41, 42) of the dust charging part (31), so that dirt that tends to adhere to the dust charging part (31) is removed. Can be removed.

  In a twelfth aspect according to the first or second aspect, the water droplet charging section (33) has a nozzle (38) for spraying water droplets and a mesh-like counter electrode (35, 36) facing the nozzle (38). ), And is configured to charge water droplets by applying a potential difference to the nozzle (38) and the counter electrode (35, 36).

  In the twelfth aspect of the invention, one unit (30) can be constructed from the nozzle (38) of the water droplet charging section (33) and the counter electrode (35, 36).

  In a thirteenth aspect based on the second aspect, the water droplet charging section (33) has a first nozzle (38) for spraying water droplets and a mesh-like counter electrode (35, 36) facing the nozzle (38). ), And the active species generator (34) includes a second nozzle (39) for spraying water droplets, and a needle-like discharge electrode (42) facing the nozzle (38), and the first The nozzle (38) and the meshed counter electrode (35, 36) are charged with water by charging them with a potential difference, and the second nozzle (39) and the needle-like discharge electrode (42) A feature is that active species are generated by generating a streamer discharge by applying a potential difference.

  In the thirteenth invention, one unit (30) can be constituted by the first nozzle (38) of the water droplet charging unit (33) and the counter electrode (35, 36), and the active species generating unit (34) Another unit (30) can be constructed from the two nozzles (39) and the counter electrode (35, 36).

  In a fourteenth aspect based on the thirteenth aspect, the first nozzle (38) and the second nozzle (39) are arranged on the same plane and are connected in parallel to the common water supply means (72). It is characterized by that.

  In the fourteenth aspect, the first nozzle (38) and the second nozzle (39) disposed on the same plane are connected in parallel to the common water supply means (72), and the common water supply means (72 ) To supply water to the first nozzle (38) and the second nozzle (39).

  In a fifteenth aspect based on the thirteenth aspect, the nozzle (38) side potential is set to the same potential between the nozzles (38), and the counter electrode (35, 36) side potential is set to the counter electrode (35). , 36) are set to the same potential and different from the nozzle (38) side.

  In the fifteenth aspect of the invention, in the water droplet charging section (33) and the active species generating section (34), the same potential between the nozzles (38) and the same between the counter electrodes (35, 36) and the nozzle (38) side. Discharge occurs between different potentials.

  A sixteenth aspect of the invention is characterized in that, in the first or second aspect of the invention, the water droplet collection section (60) is provided on the most downstream side in the flow direction of the air to be treated.

  In the sixteenth aspect of the present invention, water that has been used for processing or water that has not been used is captured by the water droplet collection section (60).

  According to the present invention, dust is charged in the dust charging unit (31), and water droplets are charged in the water droplet generating unit (32) by the water droplet charging unit (33). In this case, the polarity of the charge of the dust and the polarity of the charge of the water droplet are opposite. As a result, dust is attracted to and adhered to the water droplets by Coulomb force. Therefore, the dust collection efficiency can be increased and the dust collection performance of the apparatus can be enhanced. Here, in this invention, one unit (30) is comprised by at least 2 among the components of a dust charge part (31), a water droplet generation part (32), and a water droplet charge part (33). Therefore, the manufacturing cost can be suppressed without increasing the size of the apparatus.

  According to the second aspect of the invention, dust is charged in the dust charging unit (31), and water droplets are charged in the water droplet generating unit (32) by the water droplet charging unit (33). In this case, the polarity of the charge of the dust and the polarity of the charge of the water droplet are opposite. As a result, dust is attracted to and adhered to the water droplets by Coulomb force. Therefore, the dust collection efficiency can be increased and the dust collection performance of the apparatus can be enhanced. In addition, the active species generating unit (34) generates various active species from the water droplets. Therefore, it is possible to decompose odorous substances and pollutants in the air. Here, in this invention, one unit (30) is comprised by at least 2 among the components of a dust charge part (31), a water droplet generation part (32), and a water droplet charge part (33). Therefore, the manufacturing cost can be suppressed without increasing the size of the apparatus.

  According to the third aspect of the invention, one of the water droplet generating part (32) and the water droplet charging part (33) constituting one unit (30) acts as the discharge electrode (42), and the other acts as the counter electrode. As a result, water droplets are charged. The charged water droplets adsorb dust charged to a reverse polarity. In the present invention, since the water droplet generator (32) and the water droplet charging unit (33) constitute one unit (30), the manufacturing cost can be reduced without increasing the size of the apparatus. Moreover, water droplets having opposite polarity can be generated using the electrodes (41, 42) having the same potential polarity as the dust charging part (31), and thus it is suitable for the unit (30) of the device parts and the same power source (37).

  According to the fourth aspect of the present invention, one of the water droplet generator (32) and the water droplet charging unit (33) / active species generator (34) constituting one unit (30) acts as the discharge electrode (42). The other droplet acts as a counter electrode to charge the water droplets. The charged water droplets adsorb dust charged to a reverse polarity. In this invention, since the water droplet generator (32) and the water droplet charging unit (33) / active species generator (34) constitute one unit (30), the manufacturing cost can be reduced without increasing the size of the apparatus. be able to. Moreover, water droplets having opposite polarity can be generated using the electrodes (41, 42) having the same potential polarity as the dust charging part (31), and thus it is suitable for the unit (30) of the device parts and the same power source (37). In the case of streamer discharge, the activation power is increased and the performance is improved, and the structure is similar to that of the water droplet charging part (33), so it is easy to integrate.

  According to the fifth aspect, the plurality of electrodes (41, 42) or the water droplet blowing members that are components of the dust charging unit (31), the water droplet charging unit (33), and the active species generating unit (34) are provided. Since they are integrated, the manufacturing cost can be reduced without increasing the size of the apparatus.

  According to the sixth invention, the plurality of electrodes (41, 42) or the water droplet blowing members which are constituent elements of the dust charging unit (31), the water droplet charging unit (33) and the active species generating unit (34) are provided. Since the air to be treated is disposed at the same position in the flow direction, the manufacturing cost can be reduced without increasing the size of the apparatus.

  According to the seventh aspect, the plurality of electrodes (41, 42), which are constituent elements of the dust charging unit (31) and the water droplet charging unit (33), are connected to the same power source (37). Since power is supplied from the power source (37), the number of necessary power sources (37) can be reduced.

  According to the eighth aspect of the invention, a plurality of water droplet blowing members that are constituent elements of the water droplet charging section (33) and the active species generating section (34) are connected in parallel to the water supply means (72), and one water supply means Water is supplied to the plurality of water droplet blowing members from (72). In this way, the water droplet charging unit (33) and the active species generating unit (34) share the water supply means (72), thereby making it possible to reduce the size and cost of the apparatus.

  According to the ninth aspect of the present invention, the plurality of electrodes (41, 42) or the water droplet blowing members (38, 39) constituting the one unit (30) are electrically conductive and air-permeable base materials ( 35, 36), the air to be treated can be directly passed through the treatment space. Therefore, high performance can be obtained even if the apparatus is downsized.

  According to the tenth aspect of the present invention, the plurality of electrodes (41, 42) or the water droplet blowing members which are constituent elements of the dust charging unit (31), the water droplet charging unit (33) and the active species generating unit (34) are provided. Since the unit (30) can be attached to and detached from the casing (10), the single unit (30) can be formed as an integral structure, and the number of parts can be reduced.

  According to the eleventh aspect of the invention, since the water ejected from the water droplet generator (32) is sprayed on the electrodes (41, 42) of the dust charging part (31), it tends to adhere to the dust charging part (31). Dirt can be removed. Accordingly, it is possible to eliminate the need for maintenance of the dust charging unit (31) and to increase the maintenance interval.

  According to the twelfth aspect of the invention, since one unit (30) can be constituted by the nozzle (38) and the counter electrode (35, 36) of the water droplet charging part (33), the manufacturing cost can be reduced without increasing the size of the apparatus. Can also be suppressed.

  According to the thirteenth aspect of the present invention, one unit (30) can be constructed from the first nozzle (38) and the counter electrode (35, 36) of the water droplet charging section (33), and the active species generating section (34) Since the second nozzle (39) and the counter electrode (35, 36) can constitute another unit (30), the manufacturing cost can be reduced without increasing the size of the apparatus.

  According to the fourteenth aspect, the first nozzle (38) and the second nozzle (39) arranged on the same plane are connected in parallel to the common water supply means (72), and this common water supply means Water is supplied from (72) to the first nozzle (38) and the second nozzle (39). Even if comprised in this way, a manufacturing cost can also be held down, without enlarging an apparatus.

  According to the fifteenth aspect of the invention, in the water droplet charging part (33) and the active species generating part (34), the same potential between the nozzles (38) and the same between the counter electrodes (35, 36) and the nozzle (38 Discharge occurs between different potentials from the) side. Since the nozzles (38) are set to the same potential and the counter electrodes (35, 36) are set to the same potential different from the nozzle (38) side, the electrical system can be simplified.

  According to the sixteenth aspect of the present invention, water that has been used for processing or water that has not been used is captured in the water droplet collection section (60), so that it is possible to prevent water from flowing out of the apparatus. Therefore, restrictions on where the device is used can be eliminated.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1 of the Invention
A first embodiment of the present invention will be described.

  The first embodiment relates to an air treatment device according to the present invention, and has a function of removing oil mist and dust contained in kitchen exhaust, which is air to be treated, and decomposing odor components. These functions are performed by utilizing the dust collecting action by spraying water droplets and the odor decomposition action of the low temperature plasma generated by the discharge.

<overall structure>
First, the overall configuration of the apparatus will be described. FIG. 1 is a block diagram showing the configuration of the air treatment device (1). The air treatment (1) includes a casing (10) and functional parts arranged in an air passage (11) formed in the casing (10). The casing (10) has an air inlet (12) formed on the inlet side of the air to be processed with respect to the air passage (11), and an air outlet (13) on the outlet side of the air to be processed with respect to the air passage (11). Is formed.

  In the casing (10), from the upstream side to the downstream side of the air passage (11), a grease filter (20), a processing unit (30), a processing space (50), and a water droplet collection part (60) are arranged in this order. Has been placed. The water droplet collection unit (60) is disposed on the most downstream side in the flow direction of the air to be treated in the casing (10), and includes a demister (61) and a water tray (62) provided below the demister. is doing.

  In the casing (10), a water circulation having a water storage tank (71) for storing the water recovered by the water droplet recovery section (60) and a pump (water supply means) (72) for supplying the water to the treatment unit (30) A mechanism (70) is provided. The water circulation mechanism (70) has a recovery side water pipe (73) connected between the water tray (62) and the water tank (71), and a pump between the water tank (71) and the treatment unit (30). And a supply-side water pipe (74) connected via (72).

  FIG. 2 is a layout view showing the appearance of the air treatment device (1) and the positional relationship of the functional components therein. FIG. 2 (A) is a right side view and FIG. 2 (B) is a front view. It is. In the figure, for the sake of convenience, the outer shape of the casing (10) and the shape of the internal functional components are indicated by solid lines.

  The casing (10) has a base (10a) located on the floor located at the lower end, a stand (10b) raised from the rear of the base (10a), and an upper part of the stand (10b) And an air treatment unit (10c) provided in A cooking utensil such as a stove (2) is placed on the upper surface of the base (10a).

  The base (10a) of the casing (10) is a space in which the water storage tank (71) and the pump (72) are stored. The air treatment part (10c) of the casing (10) is also a space. The front side above the stove (2) in the air treatment unit (10c) is a tapered surface. The taper surface is formed with the air suction port (12), and a grease filter (20) is disposed along the air suction port (12) in the air treatment section (10c). The grease filter (20) is for capturing a relatively large oil mist contained in the kitchen exhaust and preventing it from entering the casing (10).

  The space above the grease filter (20) in the air treatment unit (10c) is a substantially rectangular parallelepiped space, and the electrical component (15) and the treatment unit (30) are placed in the treatment space (S1) that occupies the upper part of this space. And a demister (61), and a water tray (62) is disposed in a water receiving space (S2) between the processing space (S1) and the demister (61). Thick black arrows indicate the flow of water, and hatched arrows indicate the flow of air. As can be seen from the arrow on the right side of the demister (61), an air outlet (13) is formed in the upper right surface of the casing, and this air outlet (13) is connected to an exhaust duct (not shown). And communicate with the outdoor space. Although not shown, the exhaust duct is provided with an exhaust fan.

<Specific configuration>
Next, a specific configuration of functional parts including the processing unit (30) will be described with reference to FIGS. FIG. 3 is a configuration diagram of the processing unit (30) of FIGS. 1 and 2 as viewed from above. As shown in FIG. 3, the processing unit (30) includes an oil mist charging unit (dust charging unit) (31) for charging oil mist (dust), a water droplet generating unit (32) for blowing water droplets, and the water droplets. The water droplet charging part (33) that charges the oil mist with the opposite polarity to the oil mist, and the active species generating part (34) that converts the water droplets into active species by electrical action, these components are combined into one unit It is configured. The charged oil mist and water droplets contact in the treatment space (50).

  The processing unit (30) has a metal first mesh plate (35) and a second mesh plate (36) arranged to face each other at a predetermined interval, and the first mesh plate (35) is a second mesh. It arrange | positions with respect to the board (36) in the upstream of the flow direction of kitchen exhaust. A power source (37) for charging oil mist and water droplets is connected to the first mesh plate (35) and the second mesh plate (36). The power source (37) is a DC high-voltage power source (37), and a negative pole is connected to the first mesh plate (35), and a positive pole is connected to the second mesh plate (36).

  As shown in FIG. 4, a plurality of nozzles (water droplet generators (32)) (38, 39) are fixed to the first mesh plate (35) at predetermined intervals in the vertical and horizontal directions. Among these nozzles (38, 39), the ones excluding the nozzles at the four corners (39) are the first nozzles (38) used for the water droplet charging section (33), and the nozzles at the four corners are the active species generating section (34). It is the 2nd nozzle (39) used for. Each nozzle (38, 39) is connected in parallel to the pump (72) via a supply-side water pipe (74). The nozzles (38, 39) have a spray port (not shown) whose dimensions and shape are determined so that the particle size of water to be blown out is 10 μm or more and 100 μm or less.

  As shown in FIG. 3, an electrode plate (40) is placed on the second mesh plate (36) so that the second mesh plate (36) and the electrode plate (40) are electrically connected. Yes. This electrode plate (40) is also composed of a mesh-like conductive thin plate material. As shown in FIG. 5, the electrode plate (40) has a staggered arrangement (staggered arrangement) with respect to the nozzles (38, 39) (first nozzle (38)) for the water droplet generating section (32). Thus, the protruding first discharge electrode (41) for the oil mist charging part (31) is formed. That is, the first discharge electrode (41) is disposed at a position shifted from the water blowing direction of the first nozzle (38).

  Further, the electrode plate (40) has a position facing the second nozzle (39) provided at the four corners of the first mesh plate (35) (a position in the water droplet blowing direction of the second nozzle (39)). A second discharge electrode (42) for the active species generator (34) is formed (FIG. 3). This 2nd discharge electrode (42) is comprised by the some acicular electrode, and the 2nd nozzle (39) is comprised as a counter electrode. An active species is generated by generating a streamer discharge by applying a potential difference between the second nozzle (39) and the second discharge electrode (42).

  In this electrode plate (40), a discharge electrode (41, 42) is provided at a position facing the first nozzle (38) for the water droplet charging section (33) (a position in the water droplet blowing direction of the first nozzle (38)). Is not formed and has a flat shape. In the second electrode plate (40), a portion facing the first nozzle (38) constitutes a water droplet charging unit (33). That is, the water droplet charging unit (33) includes a first nozzle (38) for spraying water droplets, and a mesh (mesh) -like flat counter electrode unit (43) facing the first nozzle (38), In a state where a potential difference is applied to the first nozzle (38) and the counter electrode part (43), water droplets sprayed from the first nozzle (38) pass through the mesh-like counter electrode part (43). The water droplets are charged (negative charge). For this reason, a potential different from that of the second nozzle (39) is applied to the water droplet charging unit (33).

  In this way, the processing unit is provided with a plurality of electrodes (41, 42, 43) and a plurality of nozzles (38, 39) as components thereof, and the electrodes (41, 42, 43) and nozzles. (38, 39) are integrated. The electrodes (41, 42, 43) constituting this one unit are arranged at the same position with respect to the flow direction of the air to be processed, and the nozzles (38, 39) are also flow direction of the air to be processed. Are arranged at the same position. The electrodes (41, 42, 43) and the nozzles (38, 39) are arranged at positions on a plane facing each other apart from each other.

  The plurality of electrodes (41, 42, 43) are connected to the same power source (37) (one power source (37)). And a plurality of electrodes (41, 42, 43) and a plurality of nozzles (38, 39) are fixed to a mesh plate (35, 36) as a base material having conductivity and ventilation, The processing unit (30) is configured as one module. The processing unit (30) is configured to be detachable from the casing (10).

  In the above configuration, corona discharge is generated from the first discharge electrode (41) for the oil mist charging section (31) using the first mesh plate (35) as the counter electrode. Since the first discharge electrode (41) of the oil mist charging unit (31) is connected to the positive side of the power source (37), the oil mist passes through the discharge field of the oil mist charging unit (31). Charges positively. Further, in the water droplet charging unit (33), the water droplet sprayed from the first nozzle (38) passes through the counter electrode unit (43) of the second mesh plate (36), so that the water droplet is negatively charged. Further, in the active species generating section (34), streamer discharge is generated from the second discharge electrode (42) using the first mesh plate (35) and the second nozzle (39) as the counter electrodes. By this streamer discharge, active species such as various radicals are generated from the water droplets.

  Then, in the processing space (50) on the downstream side in the air flow direction with respect to the processing unit (30), the positively charged oil mist and the negatively charged water droplet are attracted and combined by Coulomb force. Some oil mists flow downstream without being combined with water droplets and have a positive charge alone, and downstream alone with a negative charge without being combined with oil mist. There are also flowing water droplets. Moreover, the odor component in to-be-processed air is decomposed | disassembled by the effect | action of the active species generated by the streamer discharge.

  The demister (61) is a conductive mesh member (61) having a large number of air circulation holes that prevent the passage of water droplets while allowing the air to flow. Specifically, the demister (61) is a thin metal fiber. Are formed into a porous shape having a predetermined thickness. The demister (61) is grounded via the casing (10). That is, the demister (61) is given a polarity (ground potential) different from the charge of the water droplet and the charge of the oil mist.

  The water tray (62) collects water droplets with oil mist attached thereto. The water tray (62) is connected to the water storage tank (71) via an oil separation mechanism (not shown) that separates oil from the collected water. The recovery-side water pipe (73), the pump (72), and the supply-side water pipe (74) allow the water separated in the water tank (71) after the oil component is separated by the oil separation mechanism to flow into the water droplet generator (32 The water conveyance mechanism (75) which conveys to () is comprised.

-Driving action-
In this air treatment device, when an exhaust fan provided in the exhaust duct is activated when using a cooking appliance such as a stove (2), the kitchen exhaust is sucked into the casing (10) from the air suction port (12). . The kitchen exhaust sucked into the casing (10) passes through the grease filter (20), and at that time, a relatively large oil mist in the kitchen exhaust is removed. The oil mist having a relatively small particle diameter (about several μm) that has passed through the grease filter (20) is positively charged by passing through the oil mist charging section (31) of the processing unit (30).

  In the water droplet generator (32), the water supplied from the pump (72) to the first and second nozzles (38, 39) via the water supply pipe (44) is discharged from the kitchen exhaust passage (11). Spraying toward the downstream side in the flow direction. A second mesh plate (36) to which a positive potential is applied is disposed in the immediate vicinity of the spray direction with respect to the first nozzle (38), and water drops pass through the second mesh plate (36). When the water droplet passes through the second mesh plate (36), the water droplet is negatively charged.

  In this way, the positively charged oil mist and the negatively charged water droplet are attracted to each other by the Coulomb force in the processing space (50), and flow downstream. There are also oil mist and water droplets that are not bonded, and these flow downstream with positive and negative charges.

  On the other hand, a streamer discharge field (34a) is formed in the active species generating part (34). In this streamer discharge field (34a), various active species are generated by the action of streamer discharge on air or water. This active species includes radicals such as fast electrons, ions, and hydroxy radicals, and other excited molecules (excited oxygen molecules, excited nitrogen molecules, excited water molecules, etc.). The activated species generated here flow into the treatment space (50), and harmful components and odor components contained in the air to be treated are decomposed. In addition, not all of the water droplets are changed to active species in the streamer discharge field (34a), and some flow into the treatment space (50) in the state of water droplets. This water droplet is charged by passing through the streamer discharge field (34a). Therefore, a relatively small oil mist that could not be removed by the grease filter (20) is adsorbed by electric force.

  A demister (61) is provided on the downstream side of the processing space (50). For this reason, the water droplets to which the oil mist is attached are captured by the demister (61) when passing through the demister (61). At this time, the oil mist is also captured by the demister (61) together with the water droplets. Further, since the demister (61) has a ground potential and has a different potential from the positively charged oil mist and the negatively charged water droplet, the electric image power between the oil mist and the water droplet and the demister (61) is different. The oil mist and water droplets that exist independently without being coupled to each other are also captured by the demister (61).

  The water droplets adhering to the demister (61) grow as water aggregates and flow downward along the mesh of the demister (61). At that time, the oil mist adhering to the demister (61) is also washed away. . Water droplets and oil mist dripped from the demister (61) are collected in the water tray (62). As described above, although not shown, the water tray (62) is provided with a mechanism for separating water and oil mist, and only water is sucked into the pump (33) via the water pipe (34). The The water sucked into the pump (45) is reused for spraying from the nozzle (38).

  The kitchen exhaust gas that has passed through the demister (61) is clean air from which oil mist has been removed. Then, the kitchen exhaust gas thus treated in a clean state flows into the exhaust duct from the air outlet (13) of the casing (10) and is blown out through the exhaust fan (70).

-Effect of Embodiment 1-
According to this embodiment, the oil mist is charged in the oil mist charging unit (31), and the water droplet is charged in the water droplet generating unit (32) by the water droplet charging unit (33). In this case, the polarity of the charge of the oil mist and the polarity of the charge of the water droplet are opposite. As a result, the oil mist attracts and adheres to the water droplets by Coulomb force. Therefore, the oil mist collection efficiency can be increased and the performance of the device (1) can be enhanced. In addition, the active species generating unit (34) generates various active species from the water droplets. Therefore, it is possible to decompose odorous substances and pollutants in the air. Here, in this embodiment, one unit is comprised by the component of the oil mist charge part (31), the water droplet generation | occurrence | production part (32), and the water droplet charge part) (33). Therefore, the manufacturing cost can be suppressed without increasing the size of the apparatus.

  Furthermore, in this embodiment, the nozzles (38, 39) of the water droplet generating unit (32) and the electrodes (41, 42, 43) of the water droplet charging unit (33) / active species generating unit (34) constituting one unit. One of these acts as a discharge electrode and the other acts as a counter electrode, whereby water droplets are charged. The charged water droplets adsorb oil mist charged to a reverse polarity. In this embodiment, since the water droplet generator (32) and the water droplet charging unit (33) / active species generator (34) constitute one unit, the manufacturing cost can be suppressed without increasing the size of the apparatus. it can. In addition, water droplets of the opposite polarity can be produced using electrodes having the same potential polarity as the oil mist charging section (31), which is suitable for unitization of apparatus parts and the same power supply. In the case of streamer discharge, the activation force is increased and the performance is improved, and the structure is similar to that of the water droplet charging part (33), so that it is easy to integrate.

  In addition, a plurality of electrodes (41, 42, 43) or nozzles (38, 39) that are components of the oil mist charging unit (31), water droplet charging unit (33), and active species generating unit (34) are integrated. In addition, since it is arranged at the same position with respect to the flow direction of the air to be treated, the manufacturing cost can be reduced without increasing the size of the apparatus.

  Furthermore, since the plurality of electrodes, which are constituent elements of the oil mist charging unit (31) and the water droplet charging unit (33), are connected to the same power source (37), and power is supplied from the same power source (37). The number of power supplies (37) required is small.

  In addition, a plurality of nozzles (38, 39) that are components of the water droplet charging unit (33) and the active species generating unit (34) are connected in parallel to the pump (72), and a plurality of nozzles (72) Water is supplied to the nozzles (38, 39). Thus, by sharing the pump (72) between the water droplet charging unit (33) and the active species generating unit (34), the apparatus can be reduced in size and cost.

  Furthermore, a plurality of electrodes (41, 42, 43) or nozzles (38, 39) constituting one unit are fixed to a conductive and air-permeable substrate (mesh plates (35, 36)). Therefore, the air to be treated can be directly passed through the treatment space (S1). Therefore, high performance can be obtained even if the device (1) is downsized.

  Further, a plurality of electrodes (41, 42, 43) or nozzles (38, 39), which are constituent elements of the oil mist charging unit (31), the water droplet charging unit (33), and the active species generating unit (34), are connected to each other. Since one unit (30) can be attached to and detached from the casing (10), one unit (30) can be made into an integral structure, and the number of parts can be reduced.

  Further, since water ejected from the nozzles (38, 39) of the water droplet generating part (32) is sprayed to the second discharge electrode (42) of the oil mist charging part (31), it is applied to the second discharge electrode (42). Dirt that tends to adhere can be removed. Therefore, maintenance of the oil mist charging unit (31) can be made unnecessary, and the maintenance interval can be lengthened.

  Further, a common pump (72) is connected in parallel to the first nozzle (38) and the second nozzle (39) arranged on the same plane, and the first nozzle (38) is connected to the common pump (72). Water is supplied to the second nozzle (39). If comprised in this way, a manufacturing cost can also be held down, without enlarging an apparatus.

  Further, in the water droplet charging part (33) and the active species generating part (34), the same potential between the nozzles (38, 39) and the same between the discharge electrodes (41, 42) and the nozzle (38, 39) side Discharge occurs when different potentials are applied. Since the nozzles (38, 39) have the same potential and the discharge electrodes (41, 42, 43) have the same potential different from the nozzle (38, 39) side, the electrical system can be simplified.

  Furthermore, since the water used for the treatment and the water not used are captured in the water recovery unit (60), it is possible to prevent the water from flowing out from the device (1). Therefore, restrictions on where the device is used can be eliminated.

<< Embodiment 2 of the Invention >>
A second embodiment of the present invention will be described.

  In the second embodiment, as shown in FIG. 6, the oil mist charging unit (31) and the active species generating unit (34) are configured as one unit, and the water droplet charging unit (33) is a single unit. This is an example configured as a unit. Here, the unit of the oil mist charging unit (31) and the active species generating unit (34) is referred to as a first unit (30a), and the unit of the water droplet charging unit (33) is referred to as a second unit (30b). The first mesh plate (35) includes an upstream first mesh plate (35a) and a downstream first mesh plate (35b).

  The first unit (30a) includes an upstream first mesh plate (35a) and an electrode plate (40). On the first mesh plate (35), the second nozzles (39) of the water droplet generator (32) are arranged at a predetermined interval. On the electrode plate (40), the first discharge electrode (41) of the oil mist charging section (31) is arranged in a positional relationship between the second nozzle (39) and the staggered arrangement (alternate arrangement), and the second nozzle (39 The second discharge electrode (42) of the active species generating part (34) is disposed at a position opposite to.

  The second unit (30b) includes a first nozzle (33) for the water droplet charging unit (33) disposed in a predetermined positional relationship with the downstream first mesh plate (35b) and the downstream first mesh plate (35b). 38) and a second mesh plate (36) arranged to face the first mesh plate (35).

  The electrode plate (40) and the second mesh plate (36) are connected in parallel to the positive electrode of the power source (37). The upstream first mesh plate (35a) and the downstream second mesh plate (36) are connected in parallel to the negative pole of the power source (37). The negative pole of this power supply (37) is on the ground side.

Further, all of the first nozzle (38) and the second nozzle (39) are connected in parallel to the pump (72). In the second embodiment, the first unit (30a) charges the oil mist. A function of giving a stream and a function of causing a streamer discharge, and a function of giving a charge to the water droplet in the second unit (30b). Even in this case, when the air to be treated (kitchen exhaust) flows, water droplets and oil mist adhere to the processing space (50) on the downstream side of these units (30a, 30b) and are generated by streamer discharge. The active species decomposes odor components and harmful components in the air to be treated. Therefore, the air to be treated can be made clean air by the same function as in the first embodiment.

  The configuration is the same as that of the first embodiment except that the processing unit (30) is divided into a first unit (30a) and a second unit (30b). Therefore, it is possible to achieve the same effects as those of the first embodiment, for example, it is possible to simultaneously reduce the size of the device (1) and improve the performance.

<< Embodiment 3 of the Invention >>
Embodiment 3 of the present invention will be described.

  This Embodiment 3 is an example which has arrange | positioned the electrode plate (40) between the 1st mesh board (35) and the 2nd mesh board (36) which were arrange | positioned at predetermined intervals, as shown in FIG.

  A plurality of second nozzles (39) of the water droplet generator (32) used for the active species generator (34) are arranged on the first mesh plate (35) located on the upstream side. The second nozzle (39) is configured to blow water droplets toward the electrode plate (40) on the downstream side in the air flow direction. A second discharge electrode (42) is disposed on the electrode plate (40) at a position facing the second nozzle (39). The electrode plate (40) is provided with a first discharge electrode (41) in an arrangement that is in a staggered arrangement with the second nozzle (39).

  A plurality of first nozzles (38) are fixed to the second mesh plate (36), and water droplets are blown out toward the electrode plate (40) from the downstream side to the upstream side in the air flow direction. It is configured.

  The first mesh plate (35) and the second mesh plate (36) are connected in parallel to the negative pole of the power source (37). The electrode plate (40) is connected to the positive electrode of the power source (37). In this configuration, the negative pole is on the ground side.

  Although not shown, the first nozzle (38) and the second nozzle (39) are connected in parallel to one pump (72).

  In this Embodiment 3, the function which gives an electric charge to oil mist between the 1st mesh board (35) and an electrode board (40) and the function which raise | generates a streamer discharge are performed, and an electrode board (40) and a 2nd mesh board ( 36) Performs a function to charge the water droplets. Even in this case, when the air to be treated (kitchen exhaust) flows, water droplets and oil mist adhere in the treatment space (50) downstream of the treatment unit (30), and the active species generated by the streamer discharge The odor components and harmful components in the air to be treated are decomposed. Therefore, the air to be treated can be made clean air by the same function as in the first and second embodiments.

  In addition, although the configuration of the processing unit (30) is different from that of the first and second embodiments, the same effects as those of the first and second embodiments can be achieved, such as compatibility between downsizing of the device (1) and improvement of performance.

<< Embodiment 4 of the Invention >>
Embodiment 4 of the present invention will be described.

  The second and third embodiments are examples in which the oil mist charging unit (31) and the active species generating unit (34) are integrated. However, as shown in FIG. ) And the active species generating part (34). In this figure, the direction of air flow is the direction from the bottom to the top of the figure.

  In this processing unit (30), the electrode plate (40) is divided into an upstream electrode plate (40a) and a downstream electrode plate (40b), and a first discharge electrode (41) is provided on the upstream electrode plate (40a). In addition, the second discharge electrode (42) is provided on the downstream electrode plate (40b). An upstream electrode plate (40a), a first mesh plate (35), a second mesh plate (36), and a downstream electrode plate (40b) are arranged in this order from the upstream side.

  The upstream electrode plate (40a) is arranged at a predetermined distance from the first mesh plate (35) so that the first discharge electrode (41) faces the direction of the first mesh plate (35).

  The first mesh plate (35) is provided with a first nozzle (38) and a second nozzle (39), and a second mesh plate (36) disposed at a predetermined distance from the first mesh plate (35). It is configured to blow water droplets in the direction of

  The second mesh plate (36) and the downstream electrode plate (40b) are disposed so as to overlap each other, and the second discharge electrode (42) is disposed so as to face the second nozzle (39).

  In this Embodiment 4, the function which gives an electric charge to oil mist between an upstream electrode plate (40a) and a 1st mesh plate (35) is performed, a 1st mesh plate (35), a 2nd mesh plate (36), and The downstream electrode plate (40b) performs a function of giving electric charges to water droplets and a function of causing streamer discharge. Even in this case, when the air to be treated (kitchen exhaust) flows, water droplets and oil mist adhere in the treatment space (50) downstream of the treatment unit (30), and the active species generated by the streamer discharge The odor components and harmful components in the air to be treated are decomposed. Therefore, the air to be treated can be made clean air by the same function as in the first to third embodiments.

  Further, although the configuration of the processing unit (30) is different from those of the first to third embodiments, the same effects as those of the first to third embodiments can be achieved, such as compatibility between the downsizing of the apparatus and the improvement of performance.

<< Other Embodiments >>
About the said embodiment, it is good also as following structures.

  In each of the above embodiments, an active species generating part (34) is provided to decompose odorous components and harmful components in the air to be treated by streamer discharge. However, depending on the use of the device (1), it may be active. The seed generation part (34) may not be provided.

  In addition, Embodiment 1 is an example in which all of the oil mist charging unit (31), the water droplet charging unit (33), and the active species generation unit (34) are configured as one unit, and Embodiments 2 to 4 are at least one of them. In this example, the two units can be unitized. However, what is unitized with the functional components used in the processing unit (30) is not limited to those described in the above embodiments, and may be changed as appropriate.

  Further, the use of the device (1) is not limited to a device for treating kitchen exhaust, and may be for treating dust other than oil mist.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a technique for reducing the size and cost of an air treatment device.

FIG. 1 is a block diagram showing the configuration of the air treatment device. FIG. 2 is a layout view showing the appearance of the air treatment device and the positional relationship of the functional components therein. FIG. 2 (A) is a left side view and FIG. 2 (B) is a front view. FIG. 3 is a configuration diagram of the processing unit as viewed from above. FIG. 4 is a layout diagram of nozzles in the processing unit. It is a perspective view which shows the mutual positional relationship of a 1st discharge electrode and a 1st nozzle. It is the block diagram which looked at the processing unit which concerns on Embodiment 2 from the plane. It is the block diagram which looked at the processing unit which concerns on Embodiment 3 from the plane. It is the block diagram which looked at the processing unit which concerns on Embodiment 4 from the plane.

Explanation of symbols

1 Air treatment device
10 Casing
30 processing units
31 Oil mist charging part (dust charging part)
32 Water drop generator
33 Water droplet charging section
34 Active species generator
35 First mesh plate (counter electrode, base material)
36 Second mesh plate (counter electrode, base material)
37 Power supply
38 1st nozzle (water droplet blowing member)
39 Second nozzle (water droplet blowing member)
41 First discharge electrode
42 Second discharge electrode
60 Water drop recovery unit
72 Pump (water supply means)

Claims (16)

An air treatment device that collects dust from air to be treated,
A dust charging unit (31) for charging the dust, a water droplet generating unit (32) for blowing out water droplets, and a water droplet charging unit (33) for charging the water droplets with a polarity opposite to that of the dust,
An air treatment characterized in that at least two of the components of the dust charging unit (31), the water droplet generating unit (32), and the water droplet charging unit (33) constitute one unit (30). apparatus. An air treatment device for collecting and deodorizing air to be treated,
A dust charging unit (31) for charging dust, a water droplet generating unit (32) for blowing out water droplets, a water droplet charging unit (33) for charging the water droplets with a polarity opposite to that of dust, and water droplets as active species by electrical action An active species generating part (34) for conversion,
One unit (30) is configured by at least two of the components of the dust charging unit (31), the water droplet generating unit (32), the water droplet charging unit (33), and the active species generating unit (34). An air treatment device characterized by comprising: In Claim 1 or 2, a water droplet charging part (33) is arranged in the water droplet blowing direction of the water droplet generating part (32) as the one unit (30),
An air treatment device, wherein the water droplet charging unit (33) is provided with a potential different from that of the water droplet generating unit (32). In claim 2,
The active species generating part (34) is arranged in the water droplet blowing direction of the water droplet generating part (32) as one unit (30),
One of the water droplet generator (32) and the active species generator (34) is configured as a discharge electrode, and the other is configured as a counter electrode. In claim 1 or 2,
A plurality of electrodes (41, 42) and a plurality of water droplet blowing members (38, 39) are provided as the above components,
Said one unit (30) is comprised by integrating electrodes (41, 42) or water droplet blowing members (38, 39), The air processing apparatus characterized by the above-mentioned. In claim 5,
The air treatment, wherein the electrodes (41, 42) or the water droplet blowing members (38, 39) constituting the one unit (30) are arranged at the same position in the flow direction of the air to be treated. apparatus. In claim 5,
A plurality of electrodes (41, 42) constituting the one unit (30) are connected to the same power source (37). In claim 5,
An air treatment apparatus comprising water supply means (72) in which a plurality of water droplet blowing members (38, 39) constituting the one unit (30) are connected in parallel. In claim 5,
The one unit (30) is formed by fixing a plurality of electrodes (41, 42) or a plurality of water droplet blowing members (38, 39) to a conductive and ventilating base material (35, 36). An air treatment device comprising the air treatment device. In claim 1 or 2,
An air treatment apparatus comprising a casing (10) for housing the one unit (30), wherein the unit (30) is configured to be detachable from the casing (10). In claim 1 or 2,
An air treatment apparatus, wherein the dust charging unit (31) is disposed at a position deviated from the water blowing direction in the water droplet generation unit (32). In claim 1 or 2,
The water droplet charging section (33) includes a nozzle (38) for spraying water droplets, and a mesh-like counter electrode (35, 36) facing the nozzle (38),
An air treatment device configured to charge a water droplet by applying a potential difference between the nozzle (38) and the counter electrode (35, 36). In claim 2,
The water droplet charging section (33) includes a first nozzle (38) for spraying water droplets, and a mesh-like counter electrode (35, 36) facing the nozzle (38),
The active species generator (34) includes a second nozzle (39) for spraying water droplets, and a needle-like discharge electrode (42) facing the nozzle (39),
The first nozzle (38) and the mesh-like counter electrode (35, 36) are charged with water by charging them with a potential difference, and the second nozzle (39) and the needle-like discharge electrode ( 42) An air treatment apparatus configured to generate active species by applying a potential difference to 42) to cause streamer discharge. In claim 13,
The air treatment apparatus, wherein the first nozzle (38) and the second nozzle (39) are arranged on the same plane and are connected in parallel to a common water supply means (72). In claim 13,
The potential on the nozzle (38) side is set to the same potential between the nozzles (38), and the potential on the counter electrode (35, 36) side is the same between the counter electrodes (35, 36). The air processing apparatus is set to a potential different from that of the) side. In claim 1 or 2,
An air treatment apparatus comprising a water droplet collection part (60) on the most downstream side in the flow direction of the air to be treated.

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