JP2009125123A - Air cleaner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent high humidity air from flowing out of an air passage in an air cleaner for removing a malodorous substance in air by utilizing the discharge through a discharge part and the supply of water by a water supply means. <P>SOLUTION: The discharge part (30a) for generatng discharge and the water supply means (31) for supplying moisture to air are provided in the air passage (11). A moisture absorbing member (60) having a moisture absorbing agent is further provided on the downstream side of the water supply means (31). Water vapor contained in air is absorbed/adsorbed by the moisture absorbing member (60). As a result, air of relatively low moisture flows out of the air passage (11). <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an air purification device that removes odorous substances in the air.

  2. Description of the Related Art Conventionally, air purification apparatuses that remove odorous substances in the air have been widely applied to, for example, applications for purifying indoor spaces and applications for deodorizing exhaust gas discharged from kitchens and factories.

  Patent Document 1 discloses a home air purification device. In this air purification apparatus, functional parts such as a prefilter, a streamer discharge unit, and a catalyst filter are arranged in an air passage in the casing.

  The streamer discharge part includes a plurality of pairs of electrodes. When a voltage is applied from the power source to each electrode pair, streamer discharge is generated between the electrodes, and low temperature plasma is generated. Along with the generation of this low temperature plasma, highly reactive substances (active species) such as radicals, fast electrons and ozone are generated in the air. By reacting the active species with the odorous substance in the air, the odorous substance is oxidatively decomposed and removed.

  The catalyst filter is disposed downstream of the streamer discharge part. In the catalyst filter, a deodorizing agent is supported on the surface of the substrate. Specifically, a catalyst that oxidizes and decomposes odorous substances and an adsorbent that adsorbs odorous substances are used as the deodorizing agent. When air passes through the catalyst filter, the odorous substance remaining in the air is oxidized by the catalyst and further adsorbed by the adsorbent. Moreover, the odor substance adsorbed by the adsorbent is oxidatively decomposed by the active species generated in the streamer discharge section. Thereby, in the catalyst filter, the adsorbent is regenerated and the adsorption capacity is restored. The air from which the odorous substances are removed as described above is discharged to the outside of the casing and supplied into the room. As a result, the indoor space can be cleaned.

Patent Document 2 discloses an air purification device that deodorizes exhaust gas in a kitchen space. This air purifier is provided with water supply means for supplying moisture into the air flowing through the air passage in addition to the streamer discharge section similar to that of Patent Document 1. When water is supplied from the water supply means to the air, odorous substances contained in the air are absorbed / dissolved and captured. In this air purification device, air is purified by utilizing decomposition of odorous substances using streamer discharge and capture of odorous substances by supplying water.
JP 2006-224102 A JP 2006-231161 A

  By the way, in the thing which supplies water to an air passage like patent document 2, and deodorizes, the humidity of the air which flows through an air passage becomes comparatively high. Accordingly, when the air purified by the air purification device is supplied to, for example, a room or the like, the humidity in the room may increase and the comfort may be impaired. In addition, when high-humidity and high-temperature air is discharged outside, moisture may be condensed near the discharge port.

  The present invention has been made in view of the above point, and an object of the present invention is to remove the odorous substance by using discharge and supply of moisture into the air, and to treat the humidity of the air after the treatment. Is to prevent it from becoming too high.

  The first aspect of the present invention is a discharge section (30a) that is disposed in an air passage (11) through which air flows and generates a discharge between a pair of electrodes (31, 32), and air that flows through the air passage (11). It presupposes an air purification device provided with water supply means (31) for supplying water therein. In the air purification device, the air passage (11) is provided with a moisture absorbing member (60) that is disposed on the downstream side of the water supply means (30a) and has a moisture absorbent that captures water vapor in the air. It is characterized by that.

  In the air purification device of the first invention, predetermined air flows into the air passage (11) and flows around the discharge part (30a). In the discharge part (30a), a predetermined discharge is generated between the pair of electrodes (31, 32). Accompanying the discharge in the discharge part (30a), active species such as radicals, fast electrons, and excited molecules are generated in the air. Odor substances in the air react with these active species and are oxidatively decomposed. Further, water is supplied to the air passage (11) from the water supply means (31). Odor substances in the air are absorbed / dissolved in water and trapped.

  In the present invention, the hygroscopic member (60) is provided on the downstream side of the air passage (11) with respect to the water supply means (31). In the hygroscopic member (60), water vapor contained in the air is absorbed / adsorbed by the hygroscopic agent to dehumidify the air. The air deodorized and dehumidified as described above flows out of the air passage (11) and is supplied to the room or the like.

  According to a second aspect of the present invention, in the air purification device of the first aspect, the discharge part (30a) is configured to cause streamer discharge between the pair of electrodes (31, 32). It is what.

In the second invention, streamer discharge is generated in the discharge part (30a). In this streamer discharge, active species can be generated at a high density with a relatively small electric power. Therefore, in the discharge part (30a), the decomposition efficiency of odorous substances is improved. In addition, when streamer discharge occurs in the presence of water (that is, H ₂ O), generation of OH radicals having strong oxidizing power is promoted. Thereby, the removal capability of the odorous substance by streamer discharge improves.

  According to a third aspect of the present invention, there is provided the air purification device according to the first or second aspect, wherein the air passage (11) is disposed downstream of the water supply means (31) and upstream of the moisture absorbing member (60). Further, a water capturing member (22) for physically capturing moisture in the air is provided.

  In the third invention, the water capturing member (22) is provided between the water supply means (31) and the moisture absorbing member (60). The water capturing member (22) physically captures moisture (water droplets, etc.) contained in the air by attaching it to the surface. As a result, the water capturing member (22) removes relatively large water droplets in the air. The air that has passed through the water capturing member (22) is sent to the moisture absorbing member (60). The moisture absorbing member (60) absorbs / adsorbs water vapor remaining in the air.

  According to a fourth aspect of the present invention, in the air purifying apparatus according to any one of the first to third aspects, the supply of water from the water supply means (31) to the air and the stop of the supply of water to the air Is provided with a water supply amount control means (15) for controlling the amount of water supplied from the water supply means (31) so that the above is repeated every predetermined time.

  In the fourth invention, the water supply amount control means (15) controls the water supply by the water supply means (31). Specifically, the water supply means (31) is controlled to repeat the supply of water and the stop of the supply of water every predetermined time. That is, the water supply means (31) intermittently supplies water to the air passage (11). Thereby, at the time of water supply by the water supply means (31), the odorous substance can be captured and removed by the water. On the other hand, when the water supply means (31) is stopped, the humidity of the air flowing through the air passage (11) is lowered, so that the moisture absorbent of the moisture absorbent member (60) can be dried with air.

  According to a fifth aspect of the present invention, in the air purifying apparatus according to any one of the first to third aspects, an odor detecting means (70) for detecting an index indicating an amount of an odorous substance in the air flowing into the air passage (11). ) And an index indicating the amount of the odorous substance detected by the odor detecting means (70) is large, the water is supplied so as to increase the amount of water supplied to the air from the water supply means (31). Water supply amount control means (15) for controlling the supply water amount of the supply means (31) is provided. Here, the “index indicating the amount of odorous substances” in the fifth invention means the concentration of odorous substances in the air, the amount of odorous substances to be treated per unit time (that is, odor load), the air Odor concentration of the odor substance (concentration of odor considering human olfaction required by so-called sensory test) and the like.

  In the fifth invention, the odor detection means (70) detects an index (hereinafter referred to as odor amount) indicating the amount of odorous substance in the air flowing into the air passage (11). The water supply amount control means (15) increases the amount of water supplied from the water supply means (31) when the detected odor amount is large. Further, the water supply amount control means (15) reduces (or sets to 0) the amount of water supplied from the water supply means (31) when the detected odor amount is small. Thereby, since the water according to the amount of odors is supplied, an odorous substance can be efficiently removed without supplying excessive water.

  Specifically, when the odor amount of the air processed by the air purification device is large, that is, when the load of odor is large, the supply of odorous substances in the air is increased by increasing the amount of water supplied by the water supply means (31). A large amount of water can be captured, and odorous substances can be efficiently removed by promoting the amount of generated OH radicals and the effect of diffusing active species by water. Therefore, such a high-load odor can be reliably removed.

  On the other hand, when the odor amount of the air processed by the air purification device is small, that is, when the odor load is small, the amount of water supplied into the air by reducing the water supply means (31) to zero or zero. Can be limited. As a result, the amount of water vapor in the air flowing through the hygroscopic member (60) can be reduced, and the hygroscopic agent of the hygroscopic member (60) can be dried with air. Therefore, even when the amount of odor increases thereafter and the amount of water supplied increases, water in the air can be efficiently captured by the hygroscopic agent.

  According to a sixth aspect of the present invention, in the air purification device according to any one of the second to fifth aspects, the discharge section (30a) includes an ejector (31) for spraying water into the air as the water supply means; A discharge electrode (32) provided so as to face the ejector (31), and applying a potential difference between the ejector (31) and the discharge electrode (32) from a power source (33), A streamer discharge is generated from the discharge electrode (32) toward the water ejected from the ejector (31).

  The discharge part (30a) of the sixth invention is provided with an ejector (31) and a discharge electrode (32). The ejector (31) constitutes water supply means, and water is sprayed from the ejector (31) into the air. When a potential difference is applied between the ejector (31) and the discharge electrode (32) from the power source (33), streamer discharge is generated from the discharge electrode (32) toward the water ejected from the ejector (31). To occur.

  Specifically, for example, when a voltage is applied so that the discharge electrode (32) is a positive electrode and the ejector (31) is a negative electrode, the water ejected from the ejector (31) is negatively charged. Electron avalanche is generated from the negatively charged jet water toward the positively charged discharge electrode (32), and the jet water loses a negative charge. On the other hand, a positive arc micro-arc (so-called leader) develops from the discharge electrode (32) and reaches the jet water.

  Here, the positively charged squirting water moves in a direction away from the squirter (31), and a minute space is formed between the plurality of water droplets sprayed in a granular form. It does not progress to the ejector (31), thereby suppressing the occurrence of spark discharge (spark). Therefore, in the present invention, stable streamer discharge occurs between the water ejected from the ejector (31) and the discharge electrode (32). In the discharge part (30a), the above-described electron avalanche and the formation of the minute arc are alternately repeated, whereby the streamer discharge is stably formed as a plasma column accompanied by light emission.

  According to a seventh aspect of the present invention, in the air purification device of the sixth aspect, the ejector (31) is configured to eject water in a hollow conical shape, and the tip of the discharge electrode (32) The discharge part (30a) is located inside the hollow conical region where water ejected from the discharge vessel (31) exists, and the discharge portion (30a) extends from the distal end portion of the discharge electrode (32). It is configured to cause streamer discharge toward the water after jetting.

  In the seventh invention, water is ejected from the ejector (31) in a hollow conical shape, and the tip of the discharge electrode (32) is disposed inside the hollow conical region. Thereby, a fixed space | interval is ensured between the front-end | tip part of a discharge electrode (32), and hollow conical jet water. As a result, the distance between the discharge electrode (32) and the jet water can be kept constant, and the streamer discharge is further stabilized. On the other hand, for example, when spray water is sprayed in a solid conical shape from the spray device, the distance between the spray water and the tip of the discharge electrode (32) is likely to change and become non-uniform. The discharge will not be stable.

  Also, when water is ejected from the ejector (31) in a hollow conical shape and the tip of the discharge electrode (32) is positioned inside, the streamer discharge radiates from the tip of the discharge electrode (32) toward the ejected water. Will spread. As a result, the active species generated with the streamer discharge are uniformly diffused over a wide range, so that the decomposition efficiency of the odorous substance by the active species is improved.

  According to an eighth aspect of the present invention, in the discharge device according to the seventh aspect, the discharge electrode (32) is constituted by a needle-like electrode whose tip is directed toward the ejection port side of the ejector (31). It is characterized by.

  The discharge electrode (32) of the eighth invention is formed in a needle shape such that the tip thereof faces the jet port side of the ejector (31). In the discharge section (30a), the streamer discharge spreads radially from the tip of the needle-like discharge electrode (32) to the hollow conical jet water ejected from the ejector (31), and active species are generated in a wide range. The

  In the present invention, the moisture absorbing member (60) that absorbs water vapor in the air is disposed downstream of the water supply means (31) for supplying water to the air passage (11). Thereby, according to this invention, the water vapor | steam in air can be adsorbed / absorbed by the moisture absorbent of a moisture absorption member (60), and air can be dehumidified. Therefore, the humidity of the air that has flowed out of the air passage (11) can be reduced. As a result, for example, it can be avoided that high humidity air is supplied into the room and indoor comfort is impaired, or that high humidity air is discharged to the outside and condensed water is generated.

  In the second invention, the active species can be generated at a high density with a relatively small electric power by performing the streamer discharge in the discharge section (30a). Therefore, the deodorizing efficiency and energy saving performance of the air purification device can be improved. In addition, by causing streamer discharge in the presence of water, a large amount of OH radicals can be generated, and odorous substances can be effectively removed using the OH radicals.

  Furthermore, according to the third aspect of the present invention, the water capturing member (22) is disposed upstream of the moisture absorbing member (60), so that relatively large water droplets contained in the air are removed upstream of the moisture absorbing member (60). Can be captured. Therefore, it is possible to avoid a drop in moisture absorption due to water droplets adhering to the moisture absorbing member (60), and the moisture can be stably dehumidified by the moisture absorbing member (60).

  According to the fourth aspect of the invention, since water is intermittently supplied into the air from the water supply means (31), when the supply of water is stopped, the moisture absorbing member (60) is utilized using air. The hygroscopic agent can be dried. Therefore, the dehumidifying ability of air by the hygroscopic member (60) can be maintained over a long period of time.

  Furthermore, in the fifth invention, when the load of odor is large, the amount of water supplied from the water supply means (31) is increased, so that the odorous substance can be actively absorbed into water and removed. Moreover, generation | occurrence | production of OH radical is promoted, the spreading | diffusion effect of an active species is improved, and a high load odor can be decomposed | disassembled reliably. On the other hand, by reducing the amount of water supplied from the water supply means (31) when the odor load is small, the hygroscopic agent of the hygroscopic member (60) can be quickly dried. Therefore, the dehumidifying ability of air by the hygroscopic member (60) can be maintained over a long period of time.

  In the sixth aspect of the invention, streamer discharge is performed from the discharge electrode (32) to the water ejected from the ejector (31). Thereby, according to this invention, the stable streamer discharge can be maintained, suppressing generation | occurrence | production of a spark, and an active species can be produced | generated stably.

  In particular, according to the seventh and eighth inventions, since the tip of the discharge electrode (32) is positioned inside the hollow conical region where the jetted water exists, the discharge electrode (32) and the jet are discharged. A constant interval can be maintained with the subsequent water, and the streamer discharge is further stabilized. In addition, a radial streamer discharge can be generated from the tip of the discharge electrode (32) toward the water, and active species can be generated uniformly and in a wide range around the discharge electrode (32). Therefore, the deodorizing performance of the air purification device (10) can be effectively improved.

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

Embodiment 1 of the Invention
The air purification device (10) of Embodiment 1 of the present invention purifies the exhaust gas generated from the kitchen space. The air purification device (10) is provided in an exhaust duct that discharges air in the kitchen space to the outside.

  As shown in FIG. 1, the air purification device (10) has an air passage (11) through which air flows inside a predetermined casing. One end of the air passage (11) is connected to the exhaust hood facing the kitchen space, and the other end opens to the outdoor space. A blower fan (not shown) is provided in the air passage (11). By operating the blower fan, in the air passage (11), air in the kitchen space flows from one end side and air flows out from the other end side to the outdoor space.

  In order from the upstream side to the downstream side of the air passage (11), the grease filter (21), the discharge part (30a) of the discharge unit (30), the dust collection unit (40), the demister (22), and A moisture absorbing member (60) is disposed. The grease filter (21) physically collects relatively large dust (oil mist and dust) contained in the air.

  The discharge unit (30) generates active species (radicals, fast electrons, excited molecules, ozone, etc.) for decomposing odorous substances in the air by causing streamer discharge. The discharge unit (30) includes an ejector (31), a discharge electrode (32), and a power source (33).

  The ejector (31) is formed in an elongated cylindrical shape extending in the air flow direction, and is supported in a horizontal posture on the air passage (11). The jet outlet of the ejector (31) faces the downstream side of the air passage (11). The ejector (31) has a hole diameter, a spray amount, and the like set so that droplets having a particle size of about 10 to 200 μm are sprayed from the jet outlet. Moreover, as for the ejector (31), the shape of the ejection port, the spray amount, and the like are set so that water is sprayed in a hollow conical shape from the ejection port. That is, the ejector (31) is configured to form a hollow conical region where water exists and a conical region where water does not exist. Further, the ejector (31) is made of a stainless material having excellent corrosion resistance.

  Moreover, the ejector (31) is connected to a predetermined water source via a water passage. As the water source, water tanks or storage tanks for storing water are used. Water is supplied from the water source to the ejector (31) through the water passage. For the supply of water from the water source to the ejector (31), for example, a pump or a device utilizing a water head difference is used. In this embodiment, water is supplied to a predetermined storage tank or the recovered water is sent to the ejector (31) using the pump (14). As described above, the water supply means for supplying water to the air passage (11) is configured by the ejector (31), the pump (14), and the like.

  The discharge electrode (32) is disposed so as to face the ejector (31). The discharge electrode (32) constitutes a needle-like electrode, and the tip thereof faces the ejector (31) side (upstream side of the air flow). Moreover, the discharge part (30a) is comprised so that the said discharge electrode (32) may be located inside the hollow cone-shaped area | region where the water ejected from the ejector (31) exists. Specifically, the needle-like discharge electrode (32) is coaxial with the axis of the ejector (31) and the axis of the hollow conical region.

  The ejector (31) and the discharge electrode (32) are electrically connected to the power source (33). In this embodiment, the ejector (31) is a negative pole and the discharge electrode (32) is a positive pole, but these relationships may be reversed. In addition, either the ejector (31) or the discharge electrode (32) may be a ground electrode. In short, any configuration can be used as long as a potential difference can be applied between the ejector (31) and the discharge electrode (32). good. The power source (33) is preferably a high-voltage DC power source, but may be an AC power source or a pulse power source. In addition, the power source (33) is preferably controlled by so-called constant current control so that the discharge current value in the discharge section (30a) is constant.

  The ejector (31) and the discharge electrode (32) constitute a pair of electrodes, and constitute a discharge part (30a) that generates a streamer discharge. When a potential difference is applied between the ejector (31) and the discharge electrode (32), streamer discharge occurs from the discharge electrode (32) toward the water ejected from the ejector (31). That is, in the discharge unit (30), the ejector (31) and the discharge electrode (32) are mutually connected so that streamer discharge occurs between the water ejected from the ejector (31) and the discharge electrode (32). And the potential difference and discharge current value applied from the power source (33) are set. In the present embodiment, two pairs of the ejector (31) and the discharge electrode (32) to be paired are provided in the air passage (11), but one set or three or more sets may be provided. .

  The dust collection unit (40) is for electrically collecting relatively small dust contained in the air by charging it. The dust collection unit (40) includes a charging unit (41) for charging the dust and a dust collection unit (45) for attracting and collecting the charged dust electrically.

  The charging unit (41) is provided with a plurality of ionization lines (42) extending perpendicular to the air flow and a plurality of first electrode plates (43) extending in parallel with each ionization line (42). . The ionization wire (42) and the first electrode plate (43) are electrically connected to the power source, the ionization wire (42) is a positive electrode, and the first electrode plate (43) is a negative electrode.

  In the dust collection section (45), the dust collection plates (46) and the second electrode plates (47) are alternately arranged in a parallel posture. The dust collecting plate (46) and the second electrode plate (47) are electrically connected to a power source, and the dust collecting plate (46) has a negative pole (that is, a polarity opposite to the ionization line (42)), The second electrode plate (47) is a positive electrode.

  The demister (22) constitutes a water droplet collecting means for physically capturing relatively large water droplets contained in the air. The water captured by the demister (22) is dropped into the storage container (23) and collected. The water collected in the storage container (23) is used as, for example, jet water from the jet device (31).

  A moisture absorbing member (60) is provided on the downstream side of the demister (22). As shown in FIG. 2, the hygroscopic member (60) is configured such that the hygroscopic agent (62) is carried on the surface of the base material (61). The base material (61) has a plurality of holes through which air can flow, thereby reducing the pressure loss in the air passage (11). As the structure of the substrate (51), a mesh structure, a honeycomb structure, a filter structure, a lattice structure, or the like can be adopted. Further, the substrate (51) is preferably a material having a predetermined absorption / adsorption ability with respect to moisture, and more preferably a porous inorganic material. In particular, it is preferable that the base material (51) is made of fibers containing ceramics (for example, ceramic paper) because it is lightweight and has good workability.

  The hygroscopic agent (62) is composed of a granular carrier, and for example, a silica-based inorganic material, an alumina-based inorganic material, particularly a ceramic material such as zeolite, silica gel, cordierite, etc. is used, and a predetermined absorption / adsorption with respect to moisture is used. Has the ability.

  In addition, you may make it carry | support the deodorizing agent (adsorbent and catalyst) which has the adsorption | suction effect | action of an odor substance, or an oxidation effect | action on a base material (61). Examples of the deodorizer include materials containing at least one metal element selected from palladium, iridium, rhodium, osnium, ruthenium, nickel, cobalt, iron, manganese, cadmium, zinc, titanium, aluminum, gold, silver, copper, and platinum. , Transition metal oxides, rare earth oxides, or typical element oxides. Examples of the transition metal oxide include an oxide of a metal selected from at least one of iron, titanium, manganese, nickel, cobalt, copper, zirconium, chromium, and molybdenum. Moreover, as said rare earth oxide, the oxide of the metal chosen from at least 1 sort (s) among cerium, yttrium, neodymium, praseodymium, and samarium is mentioned. Further, examples of the typical element oxide include oxides of metals selected from at least one of tin, indium, aluminum, silicon, carbon, magnesium, and calcium. In particular, as the deodorizing agent (52), titanium dioxide, zinc oxide, tungsten oxide or cadmium sulfide is suitable.

  The air purification device (10) includes water supply amount control means (15) for controlling the supply (spraying) of water from the ejector (31) to the air passage (11). Specifically, the water supply amount control means (15) of the first embodiment is configured so that the spraying operation and the stopping operation of the ejector (31) are repeated every predetermined time during the operation of the air purification device (10). Control the start and stop of the pump (14).

-Driving action-
Next, the operation of the air purification device (10) will be described. When the air purification device (10) is operated in a state where the air blowing fan is operated and air flows through the air passage (11), the pump (14) is activated and water is sprayed from the ejector (31). Further, a voltage is applied from the power source (33) to the ejector (31) and the discharge electrode (32). In addition, in the charging unit (41) and the dust collection unit (45), a voltage is applied to each corresponding electrode.

  The air that has flowed into the air passage (11) passes through the grease filter (21). In the grease filter (21), relatively large dust (for example, particles having a particle size of 10 microns or more) contained in the air is physically collected.

  The air that has passed through the grease filter (21) flows into the discharge part (30a) of the discharge unit (30). In the discharge unit (30), streamer discharge is generated from the discharge electrode (32) toward the water after ejection. Specifically, as shown in FIG. 3, granular water droplets (31a) having a negative charge are ejected from the ejection port of the ejector (31). Electron avalanche is generated from the discharged negatively charged water droplet (31a) toward the discharge electrode (32). As a result, the water droplet (31a) loses a negative charge and becomes electrically neutral.

  On the other hand, from the discharge electrode (32), a micro arc (light column) called a positive charge leader develops toward the water droplet (31a). Here, if the negatively charged water droplet (31a) is stagnant or moves toward the ejector (31) side, the leader further advances to the ejector (31) side, and a spark is generated. It tends to occur. On the other hand, in this embodiment, the water droplet (31a) ejected from the ejector (31) moves in the direction away from the ejector (31) (that is, the direction approaching the discharge electrode (32)). Is suppressed, and the occurrence of sparks is prevented. In addition, the plurality of water droplets (31a) ejected are separated from each other at a slight interval, and a space is formed between each water droplet (31a). Since this space functions as an insulator between the water droplets (31a), the progress of the leader is suppressed and the occurrence of sparks is prevented. In the discharge part (30a) of the discharge unit (30), electron avalanche → leader formation → leader disappearance → electron avalanche → ... is repeated, and streamer discharge is stably formed as a flared plasma column with light emission. The

  Further, as shown in the figure, water droplets (31a) are sprayed in a hollow conical shape from the ejector (31), and the discharge electrode (32) is disposed inside such a hollow conical region. . Therefore, since a certain distance is maintained between the tip of the discharge electrode (32) and the water droplet (31a), the occurrence of spark is prevented and the streamer discharge is stabilized. Moreover, since the discharge electrode (32) is located at the axial center of the hollow conical region, the distance from the tip of the discharge electrode (32) to the water droplet (31a) is uniform over the circumferential direction. Accordingly, streamer discharge occurs radially or flared from the tip of the discharge electrode (32) with respect to the surrounding water droplet (31a).

  By the streamer discharge as described above, active species (fast electrons, ions, ozone, radicals and other excited molecules (excited oxygen molecule, excited nitrogen molecule, excited water molecule, etc.)) are generated in the discharge part (30a). In particular, since a large amount of water is supplied to the discharge field, generation of OH radicals is promoted in the presence of water. Further, the generated active species are scattered so as to adhere to the sprayed water, so that the diffusion effect of the active species is increased.

  The odorous substance contained in the air is removed by oxidative decomposition by reacting with the active species. Further, among the odorous substances, hydrophilic substances are absorbed and captured by the water ejected from the ejector (31). Further, hydrophobic substances among odorous substances are easily oxidized and become hydrophilic by active species. Therefore, the odorous substance that has become hydrophilic is also absorbed and captured by the water ejected from the ejector (31).

  As described above, in the discharge unit (30a) of the discharge unit (30), the oxidative decomposition action of the odorous substance by the streamer discharge and the absorption / dissolution action of the odorous substance using the water sprayed from the ejector (31) (that is, The scrubber action) effectively removes odorous substances. Such removal of the odorous substance is similarly performed on the downstream side of the discharge part (30a) of the discharge unit (30) in the air passage (11).

  The air that has passed through the discharge part (30a) of the discharge unit (30) flows in the vicinity of the dust collection unit (40). In the dust collection unit (40), first, fine dust contained in the air is positively charged in the charging unit (41). Thereafter, in the dust collecting section (45), dust having a positive charge is attracted to the dust collecting plate (46) serving as a negative electrode. As a result, dust is captured one after another on the surface of the dust collecting plate (46).

  The air that has passed through the dust collection unit (40) flows in the vicinity of the demister (22). In the demister (22), water droplets contained in the air are physically captured. The water droplets captured by the demister (22) are collected in the storage container (23) and supplied again, for example, to the ejector (31).

  The air that has passed through the demister (22) flows in the vicinity of the hygroscopic member (60). In the hygroscopic member (60), water vapor in the air is absorbed / adsorbed by the base material (61) and the hygroscopic agent (62). As a result, the air is dehumidified by the hygroscopic member (60).

  As described above, the air from which the odorous substance is removed and the moisture is removed is discharged to the outside through the air passage (11). Here, since the air discharged to the outside has a relatively low humidity, even if the air is cooled outside, it is difficult for condensed water to be generated.

  During operation of such an air purification device (10), the water supply amount control means (15) controls the amount of water supplied to the ejector (31). Specifically, the water supply amount control means (15) starts and stops the pump (14) so as to alternately repeat the spraying operation and the stopping operation of the ejector (31) every predetermined time. Note that the duration of the spray operation and the duration of the stop operation are set to be changeable by a controller or the like. During the spraying operation of the ejector (31), a large amount of active species is generated as described above, and odorous substances are actively decomposed / removed.

  On the other hand, when the ejector (31) is stopped, dry air flows through the hygroscopic member (60), so that the base material (61) and the hygroscopic agent (62) of the hygroscopic member (60) are quickly dried. Therefore, the moisture absorption capability of water vapor by the moisture absorbing member (60) can be recovered. Further, the streamer discharge is not performed during the stop operation of the ejector (31). In this case, a low-load odor substance may be removed by, for example, a deodorant carried on the moisture absorbing member (60).

-Effect of Embodiment 1-
In the first embodiment, the moisture absorbing member (60) that absorbs water vapor in the air is disposed on the downstream side of the ejector (31) that supplies water to the air passage (11). Thereby, moisture in the air can be adsorbed / absorbed by the hygroscopic agent of the hygroscopic member (60) to dehumidify the air. Therefore, the humidity of the air that has flowed out of the air passage (11) can be reduced. As a result, it is possible to avoid the occurrence of dew condensation water due to high humidity air being discharged outside the room.

  In addition, by performing streamer discharge in the discharge part (30a), active species can be generated with high density at relatively low power. Therefore, the deodorizing efficiency and energy saving performance of the air purification device can be improved. In addition, by causing streamer discharge in the presence of water, a large amount of OH radicals can be generated, and odorous substances can be effectively removed using the OH radicals. Moreover, an odorous substance can be removed by a scrubber action by supplying water from the ejector (31) to the air flowing through the discharge part (30a). Further, the diffusion effect of active species can be improved by the jetted water, and the decomposition efficiency of odorous substances is improved.

  Moreover, generation | occurrence | production of a spark can be suppressed by making streamer discharge generate | occur | produce with respect to the water ejected from the ejector (31), and streamer discharge can be stabilized. Further, water is sprayed in a hollow conical shape from the ejector (31), and the discharge electrode (32) is positioned inside the hollow conical region, whereby the tip of the discharge electrode (32) and the water after the ejection are ejected. A certain distance can be maintained between. Therefore, the so-called interelectrode distance is maintained at a predetermined distance, and streamer discharge can be further stabilized. In addition, since streamer discharge can be generated in a flared or radial form from the tip of the discharge electrode (32), the active species can be generated while being evenly dispersed around the discharge electrode (32). Therefore, the decomposition efficiency of odorous substances is further improved.

  In addition, since the discharge electrode (32) can be washed away by the jetted water, it is possible to avoid the contamination of oil mist, dust and the like on the surface of the discharge electrode (32). Furthermore, since the sprayed water and the active species come into contact with each other, a sterilizing effect of the sprayed water is also obtained. For example, scum generated due to the growth of bacteria in the water is clogged by the sprayer (31). Can also be avoided.

  Furthermore, by disposing the demister (22) on the upstream side of the moisture absorbing member (60), relatively large water droplets contained in the air can be captured on the upstream side of the moisture absorbing member (60). Therefore, it is possible to avoid a drop in moisture absorption due to water droplets adhering to the moisture absorbing member (60), and the moisture can be stably dehumidified by the moisture absorbing member (60).

  Moreover, since water was intermittently supplied into the air from the ejector (31), the moisture absorbent of the moisture absorbent member (60) can be dried using air when the supply of water is stopped. Therefore, it is possible to maintain the water-absorbing ability of the moisture absorbing member (60) for a long time, and to reliably avoid the discharge of high-humidity air outside the room.

-Modification of Embodiment 1-
The air purification device (10) according to the modification of the first embodiment is different from the first embodiment in the method of controlling the supply of moisture by the ejector (31). As shown in FIG. 4, the air purification device (10) of this modification has an odor sensor (70) for detecting the amount of odorous substance flowing into the air passage (11).

  Specifically, the odor sensor (70) is an index indicating the amount of the odorous substance, that is, the substance concentration of the predetermined odorous substance, the odor density of the odorous substance (the odor sense or intensity representing the smell of human beings), The odor detection means is configured to measure the amount of odorous substances (that is, odor load) to be processed per unit time by the air purification device (10).

  The water supply amount control means (15) of this modified example is configured to enter the air from the ejector (31) into the air based on an index indicating the amount of odorous substance detected by the odor sensor (70) (hereinafter referred to as odor amount). Control the amount of water supplied. Specifically, in this modification, the spray amount of the ejector (31) is increased when the detected odor amount is large, and the spray amount of the ejector (31) is decreased when the detected odor amount is small. To control the pump (14).

  More specifically, when the odor amount detected by the odor sensor (70) is large during operation of the air purification device (10), the pump (14) is set so that the spray amount of the ejector (31) is increased. Be controlled. This makes it possible to capture a large amount of odorous substances with water ejected from the ejector (31) even under heavy odor load, promote the generation of OH radicals associated with streamer discharge, and the effect of diffusion of active species by water Thus, odorous substances can be removed efficiently. Therefore, such a high-load odor can be reliably removed.

  On the other hand, when the air purification device (10) is operating, if the odor amount detected by the odor sensor (70) is small, the pump (14) is controlled so that the spray amount of the ejector (31) becomes small. . Thereby, under the condition where the load of odor is small, the amount of water supplied from the ejector (31) to the air is limited. As a result, moisture in the air sent to the hygroscopic member (60) can be minimized, and the hygroscopic member (60) can be quickly dried. Therefore, the dehumidifying ability of the moisture absorbing member (60) can be maintained over a long period of time, and it is possible to reliably avoid the discharge of high-humidity air outside the room.

  When the amount of odor detected by the odor sensor (70) is small, the pump (14) may be stopped to completely stop the spraying operation of the ejector (31). In this case, the low-load odor can be removed, for example, by a deodorant carried on the moisture absorbing member (60). Further, the spray amount of the ejector (31) may not be controlled linearly according to the amount of odor, and may be controlled stepwise based on a predetermined determination value.

<< Embodiment 2 of the Invention >>
The air purification apparatus (10) of Embodiment 2 of this invention is what is called an air cleaner for households, Comprising: Clean indoor space. The air purification device (10) is installed indoors, and after taking in indoor air and processing it, supplies the processed air into the room.

  As shown in FIG. 5, the air purification device (10) includes a rectangular casing (80). The casing (80) has an air inlet (81) on the front surface and an air outlet (82) on the upper surface. An air passage (11) through which air flows is formed in the casing (80) from the air inlet (81) to the air outlet (82).

  In the air passage (11), a prefilter (84), a discharge unit (30), a moisture absorbing member (60), and a blower fan (86) are arranged in order from the upstream side to the downstream side. The pre-filter (84) constitutes a dust collecting filter that physically collects relatively large dust in the air.

  The discharge unit (30) has an ejector (31), a discharge electrode (32), and a power source (33), as in the first embodiment. The ejector (31) of the second embodiment is supported so that its ejection port faces downward. On the other hand, the discharge electrode (32) is disposed on the lower side of the corresponding ejector (31), and the tip thereof faces upward. The axes of the ejector (31) and the discharge electrode (32) coincide with each other so as to be vertical. Other configurations of the ejector (31), the discharge electrode (32), and the power source (33) are the same as those in the first embodiment.

  Moreover, in Embodiment 2, the collection container (90) is installed in the lower part in a casing (80). The collection container (90) is positioned vertically below the ejector (31) and is configured to be able to collect water ejected from the ejector (31).

  The collection container (90) is connected to the water tank (93) via the water return channel (91). The water tank (93) is disposed in the upper part of the casing (80). The water return channel (91) is provided with a return pump (92) for sending the water collected in the collection container (90) to the water tank (93). Further, the water tank (93) is connected to the ejector (31) through a predetermined water passage. A pump (14) is provided in the water passage, and the water in the water tank (93) can be transferred to the ejector (31).

  The hygroscopic member (60) is configured in the same manner as in the first embodiment. That is, the hygroscopic member (60) has the hygroscopic agent (62) supported on the surface of the base material (61) to absorb moisture. In addition, you may carry | support the above-mentioned deodorizing agent on the surface of the base material (61) of a moisture absorption member (60).

-Driving action-
Next, the operation of the air purification device (10) of Embodiment 2 will be described. When the air purification device (10) is in operation, the blower fan (86) and the pump (14) are in operation, and voltage is applied from the power source (33) to the ejector (31) and the discharge electrode (32).

  The room air taken into the air passage (11) from the air suction port (81) by the blower fan (86) passes through the prefilter (84). In the prefilter (84), dust contained in the air is captured. Thereafter, the air passes through the discharge part (30a) of the discharge unit (30).

  In the discharge part (30a) of the discharge unit (30), streamer discharge is generated from the discharge electrode (32) with respect to the water ejected in a hollow conical shape from the ejector (31), as in the first embodiment. Yes. This streamer discharge generates active species such as OH radicals, and the odorous substance reacts with the active species and is oxidatively decomposed. The odorous substance is absorbed and removed by the water ejected from the ejector (31).

  The air that has flowed out of the discharge part (30a) of the discharge unit (30) passes through the moisture absorbing member (60). In the hygroscopic member (60), moisture contained in the air is captured by the base material (61) and the hygroscopic agent (62). The air dehumidified by the moisture absorbing member (60) is supplied into the room from the air outlet (82) in a relatively low humidity state.

-Effect of Embodiment 2-
Also in the second embodiment, the moisture absorbing member (60) that absorbs water vapor in the air is disposed on the downstream side of the ejector (31) that supplies water to the air passage (11). Thereby, moisture in the air can be adsorbed / absorbed by the hygroscopic agent of the hygroscopic member (60) to dehumidify the air. Therefore, the humidity of the air that has flowed out of the air passage (11) can be reduced. As a result, it can be avoided that high-humidity air is supplied indoors and indoor comfort is impaired. In the second embodiment, it is needless to say that the amount of water supplied to the ejector (31) may be made variable by controlling the pump (14), as in the first embodiment or the modification described above.

  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 an air purification device that removes odorous substances in the air.

FIG. 1 is an overall configuration diagram of an air purification device according to the first embodiment. FIG. 2 is a schematic configuration diagram of the hygroscopic member of the first embodiment. FIG. 3 is a schematic configuration diagram enlarging the vicinity of the discharge part. FIG. 4 is an overall configuration diagram of an air purification device according to a modification of the first embodiment. FIG. 5 is an overall configuration diagram of an air purification device according to the second embodiment.

Explanation of symbols

10 Air purifier
11 Air passage
15 Water supply control means
30a Discharge part
31 Ejector (water supply means)
32 Discharge electrode
33 Power supply
60 Hygroscopic material
61 Substrate
62 Hygroscopic agent
70 Odor sensor (odor detection means)

Claims (8)

Water is supplied to the air flowing through the air passage (11) and the discharge portion (30a) that is disposed in the air passage (11) through which air flows and generates discharge between the pair of electrodes (31, 32) An air purification device comprising water supply means (31),
The air passage (11) is provided with a moisture absorbing member (60) disposed downstream of the water supply means (31) and having a moisture absorbent for capturing water vapor in the air. Air purification device. In claim 1,
The air purifier characterized in that the discharge part (30a) is configured to cause streamer discharge between the pair of electrodes (31, 32). In claim 1 or 2,
The air passage (11) is provided with a water capturing member (22) that physically captures moisture in the air downstream of the water supply means (31) and upstream of the moisture absorbing member (60). An air purifying device characterized by that. In any one of Claims 1 thru | or 3,
Water for controlling the amount of water supplied by the water supply means (31) so that the supply of water from the water supply means (31) to the air and the stop of the supply of water to the air are repeated every predetermined time. An air purification apparatus comprising supply amount control means (). In any one of Claims 1 thru | or 3,
Odor detection means (70) for detecting an index indicating the amount of odorous substance in the air flowing into the air passage (11);
When the index indicating the amount of odorous substance detected by the odor detecting means (70) is large, the water supply means (31) increases the amount of water supplied to the air from the water supply means (31). 31) A water supply amount control means (15) for controlling the supply water amount of (31). In any one of Claims 2 thru | or 5,
The discharge part (30a) includes an ejector (31) for spraying water into the air as the water supply means, and a discharge electrode (32) provided so as to face the ejector (31). By applying a potential difference between the ejector (31) and the discharge electrode (32) from (33), streamer discharge from the discharge electrode (32) toward the water after the ejector (31) is ejected. An air purification device characterized by being configured to occur. In claim 6,
The ejector (31) is configured to eject water into a hollow cone,
The tip of the discharge electrode (32) is located inside a hollow conical region where water ejected from the ejector (31) is present,
The air purifier is characterized in that the discharge part (30a) is configured to cause a streamer discharge from the tip of the discharge electrode (32) toward the water after the ejection of the ejector (31). apparatus. In claim 7,
The air purification apparatus according to claim 1, wherein the discharge electrode (32) is configured by a needle-like electrode whose tip is directed to the jet port side of the jetting device (31).

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