JP2013072584A - Air purifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air purifier having increased air purification properties due to ion being blown out.SOLUTION: A first air blower 13 blasts air, thus drawing air in from the outside to a first air flow channel 3, and an air purification part 11 purifies the air and blows out the purified air. A second air blower 14 blasts air, thus drawing air in from the outside to a second air flow channel 4, and the air is blown out together with ion generated by an ion generator 12. A control part controls the amount of air blasted by the second air blower 14, according to the amount of air blasted by the first air blower 13.

Description

  The present invention relates to an air cleaner that cleans and sucks out sucked air and blows out air together with ions.

  Indoor air contains various substances that are uncomfortable or toxic to the human body, such as dust, pollen, tobacco smoke, and exhaled air. Particularly in recent years, since houses are airtight, harmful substances tend to accumulate in the room. Therefore, it is difficult to perform natural ventilation to open the window of the room in areas with severe air pollution, homes or workplaces with hay fever patients, etc., so an air purifier that has a function of purifying air with a filter that purifies indoor air Has become widespread.

  In order to purify the air and adjust the air to a more comfortable humidity, air purifiers with a humidifying function have been commercialized. In such air purifiers, the air purifier is purified by passing through the filter section. The conditioned air is further humidified by passing through a humidification filter.

Further, positive ions H ⁺ (H ₂ O) _n (n is a natural number) and negative ions O ₂ ⁻ (H ₂ O) _m An air cleaner that includes an ion generator that generates (m is a natural number), blows out ions together with the sucked air, and inactivates mold, bacteria, and the like floating in the air has been commercialized.

  Patent Document 1 describes an air cleaner provided with two ventilation paths for blowing out air sucked from separate suction ports from separate upward outlets. In this conventional air purifier, a humidifying filter is arranged in one ventilation path, the air is humidified and blown out, and an ion generator is arranged in another ventilation path. Blow out. Blowers are arranged in the two ventilation paths, respectively, so that the air volumes of the two fans can be controlled independently. Thereby, the air cleaner of patent document 1 can perform control which humidifies air independently, and control which cleans air.

  Patent Document 2 includes ions generated by an ion generator after sucking air from one suction port into a ventilation path when one blower blows air, and passing the sucked air through a purification filter. An air cleaner is described which is adapted to blow out from separate outlets. The air outlet of the air cleaner includes an upward-facing canopy outlet and a forward-facing bottom outlet that is slightly inclined upward. The air cleaner described in Patent Document 2 can effectively perform sterilization and the like by blowing out air containing ions upward and forward.

JP 2010-276296 A JP 2009-142356 A

  However, in the conventional air cleaner described in Patent Document 1, since the blowing for humidifying the air and the blowing for purifying the air are both upward, the two airflows affect each other. . That is, since the two air outlets are arranged in the same upward direction, two airflows are generated on one side and the other side of the boundary between the two air outlets, and a large amount of ions are contained in the airflow on one side. In the airflow on the other side, it may occur that ions are not included so much. For example, when an air purifier is used indoors, depending on how it is placed, the right half of the room has a high ion concentration, the left half has a low ion concentration, and air purification that inactivates mold and fungi is inefficient. It becomes uniform.

  Moreover, in the conventional air cleaner of patent document 2, after letting the air suck | inhaled when one air blower ventilates flow through a purification | cleaning filter, ion is included in air. The purification filter is a heavy load for the blower of the blower. If the air flow rate is increased to increase the ion concentration, the rotational speed of the blower increases and the generated sound becomes loud.

  This invention is made | formed in view of such a situation, The place made into the objective is to provide the air cleaner which can mainly improve the air-cleaning performance by the ion to blow out.

  The air cleaner according to the present invention blows air from the first blower and sucks air from the outside into the first ventilation path, purifies the air by the air purifying unit, and blows out air, while blowing air from the second blower and second from the outside. In an air purifier that sucks air into a ventilation path and blows air in a direction different from the direction blown out of the first ventilation path together with ions generated by the ion generator, the operation of the first blower and the second blower is controlled. A control unit is provided, wherein the control unit controls the amount of air blown by the second blower according to the amount of air blown by the first blower.

  In the present invention, air is blown out together with ions from the second ventilation path in a direction different from the direction in which the air is purified by the air purification section and the air is blown out from the first ventilation path, and the first blower blows air according to the amount of air blown. Since the amount of air blown by the second blower is controlled, the amount of air blown together with ions from the second air passage is controlled according to the amount of air blown from the first air passage, and the ions blown out. The air cleaning performance can be improved.

  In the air purifier according to the present invention, the control unit controls the amount of air blown by the second blower according to the amount of air blown by the first blower. It is characterized by being.

  In the present invention, when the amount of air blown by the first fan is increased, the amount of air blown by the second fan is also increased, and when the amount of air blown by the first fan is decreased, the second fan blows air. Since control is performed to reduce the air volume, the influence of the air blown out from the first ventilation path on the air blown out together with the ions from the second ventilation path can be reduced, and the air cleaning performance by the blown-out ions can be enhanced.

  The air cleaner according to the present invention further includes a dirt detection unit that detects a degree of dirt of the air sucked into the first ventilation path, and the control unit determines the first according to a detection result by the dirt detection unit. The amount of air blown from the blower and the second blower is controlled.

  In the present invention, the degree of dirt of the air sucked into the first ventilation path is detected, and the amount of dirt of the first blower and the second blower is controlled according to the detection result. If the air flow is increased to remove air dirt in a short time, and the degree of dirt is low, it is possible to operate quietly with the air flow reduced.

  The air cleaner according to the present invention further includes humidity detection means for detecting the humidity of the air sucked into the first ventilation path, and humidification means for humidifying the air sucked into the first ventilation path, and the control unit includes The amount of air blown from the first blower and the second blower is controlled according to the detection result by the humidity detecting means.

  In the present invention, the humidity of the air sucked into the first ventilation path is detected, and the blast volume of the first and second blowers is controlled according to the detection result. Then, when the air is humidified in a shorter time and the humidity is high, it is possible to operate silently by reducing the amount of air blown.

  The air cleaner according to the present invention is characterized in that air is blown from the first ventilation path and the second ventilation path obliquely upward and in directions opposite to each other in plan view.

  In the present invention, air is blown from the first ventilation path and the second ventilation path obliquely upward and in directions opposite to each other in plan view, so that the air blown out with the ions from the second ventilation path, The influence of the air blown out from the first ventilation path can be reduced, and the air cleaning performance can be enhanced by blowing out ions into the indoor air.

  According to the present invention, air is blown out together with ions from the second ventilation path in a direction different from the direction in which air is purified by the air purification unit and blown out of the air from the first ventilation path, and according to the amount of air blown by the first blower, Since the amount of air blown by the second blower is controlled, the amount of air blown out from the second air passage along with the ions is controlled according to the amount of air blown out from the first air passage. Air cleaning performance can be improved.

It is a perspective view of the front side of the air cleaner which concerns on embodiment of this invention. It is a perspective view of the back side of the air cleaner of FIG. It is a sectional side view of the air cleaner of FIG. It is a block diagram which shows schematic structure of the control system of the air cleaner of FIG. It is a schematic diagram which shows typically the state by which the air cleaner was put indoors. It is a graph which shows the ion concentration of the center point P when changing the ventilation volume of a 1st air blower. It is a graph which shows the ion concentration of the center point P when changing the ventilation volume of a 1st air blower and a 2nd air blower. It is a graph which shows an example of the setting table | surface of the ventilation volume of a 1st air blower and a 2nd air blower. It is a graph which shows the correspondence of a dirt detection result and the air volume setting of air volume mode "automatic". It is a flowchart which shows the process sequence of the operation control of an air cleaner. 10 is a chart showing a correspondence relationship between a humidity detection result and an air volume setting of an air volume mode “automatic”. It is a graph which shows the example of the setting value of the ventilation volume in manual mode.

  Embodiments of an air cleaner according to the present invention will be described below with reference to the drawings.

  1 is a front perspective view of an air cleaner 1 according to an embodiment of the present invention, FIG. 2 is a rear perspective view of the air cleaner 1 of FIG. 1, and FIG. 3 is a side of the air cleaner of FIG. It is sectional drawing. In FIG. 3, the left side of the paper surface is the front side (front side) of the air cleaner 1, the right side of the paper surface is the back side (rear side) of the air cleaner 1, and the vertical direction of the paper surface is the left-right direction of the air cleaner 1.

  The air cleaner 1 of this embodiment has an air cleaning function by deodorization and dust collection, an air cleaning function by positive ions and negative ions (hereinafter referred to as positive and negative ions), and an air humidification function. As shown in FIGS. 1 to 3, the air purifier 1 includes a vertical rectangular parallelepiped casing 6, and as shown in FIG. 3, the air purifier 1 is installed in a room having walls W and a floor F. 6 is placed on the floor F in such a posture that the back side of the wall 6 faces the wall W. The air cleaner according to the present embodiment includes a first ventilation path 3, a second ventilation path 4, and a control chamber 60 that are partitioned from each other inside the casing 6, and an operation panel is provided on the top cover 62 of the casing 6. 2 is provided.

  First, the first ventilation path 3 will be described. In the first ventilation path 3, an air purification unit 11, a humidification filter unit 5, a first blower 13, a dirt detection unit 15, a temperature / humidity sensor 16, and the like are arranged. The first air passage 3 is divided by a partition wall 31 into a rear (back side) filter housing portion 3a and a front (front side) blowout air passage 3b. The suction port 33 opens in the rear cover 63 of the housing 6, and the filter housing portion 3 a communicates with the outside through the suction port 33. Further, the blowout air passage 3 b communicates with the outside through the air outlet 34 provided in the top cover 62 of the housing 6, and the filter housing portion 3 a and the blowout air passage 3 b are provided below the partition wall 31. It communicates with each other through the provided opening 31a. The rear panel 32 is detachably attached to a rear rectangular air purification chamber 35 included in the filter housing portion 3a, and a plurality of vent holes 300, 300,... Are formed. Therefore, in detail, the air flowing through the suction port 33 is air flowing through the vent holes 300, 300,. The air purification unit 11 is accommodated in the air purification chamber 35.

  The air purifying unit 11 includes a rectangular deodorizing filter 111 and a dust collecting filter 112. The deodorizing filter 111 has, for example, a configuration in which activated carbon is dispersed and held in a non-woven fabric, and has an action of adsorbing and removing odorous components during ventilation. The dust collection filter 112 is, for example, a known HEPA (High Efficiency Particulate Air) filter, and functions to collect and remove fine dust contained in the ventilation. Therefore, the air that has passed through the air purification unit 11 is purified by adsorbing and removing odor components and collecting and removing dust. The air purified by the air purification unit 11 is humidified by the humidifying filter unit 5.

  The humidification filter unit 5 includes a humidification filter 50, a water tray 51, a drive gear 52, and an electric motor 53, and is disposed on the downstream side of the air purification unit 11 and on the upstream side of the opening 31a. The humidifying filter 50 is a sheet made of a material having a high water content and allowing ventilation, such as a non-woven fabric. The humidifying filter 50 is folded in a bellows shape so as to increase a contact area with the air to be ventilated, and forms a hollow disk-shaped holding frame 54. It is stored in. The water tray 51 stores water at a substantially constant water level using a known constant water level valve or the like, and supports the humidifying filter 50 and the holding frame 54 by two roller members (not shown) provided therein.

  A driven gear 55 is attached along the outer periphery of the holding frame 54, and the driven gear 55 meshes with the drive gear 52 disposed on the humidifying filter 50. When the driving gear 52 is rotated by the electric motor 53 disposed on the upper side of the humidifying filter 50, the driving force is transmitted to the driven gear 55, and the humidifying filter 50 and the holding frame 54 are rotated. As the humidifying filter 50 rotates, the portion immersed in the water receiving tray 51 sequentially moves in the circumferential direction to suck up water, and the entire humidifying filter 50 is in a state of containing moisture. As a result, the air that has passed through the humidifying filter 50 is humidified. On the other hand, when the humidifying filter 50 is not rotating, the air that has passed through the humidifying filter 50 hardly absorbs moisture.

  The first blower 13 includes a fan motor 131 and a fan 132, and the fan motor 131 rotationally drives the fan 132. The fan 132 is a multi-blade impeller having a plurality of blades whose rotation center side is displaced in the rotation direction with respect to the outer edge, in other words, a sirocco fan having a cylindrical shape. The fan motor 131 is fixed to the outside of the wall of the blowing air passage 3b. The fan 132 is fixed to the output shaft of the fan motor 131 and is disposed opposite to the opening 31 a below the partition wall 31. When the fan 132 rotates, outside air is introduced into the filter housing portion 3a through the suction port 33 and flows forward in the filter housing portion 3a as shown by the white arrow in FIG. The air is sucked into the fan 132 through the opening 31 a below the partition wall 31. The air sucked into the fan 132 changes its direction upward and is led out into the blowout air passage 3b, and is sent to the outside through the air outlet 34 at the end of the blowout air passage 3b.

  Further, in the blowout air passage 3b, the air passage wall surfaces 36a and 36b for guiding the air from the fan 132 to the air outlet 34 are arranged so as to be inclined from the front lower side to the rear upper side, and the wind direction provided in the air outlet 34 The restricting plates 37, 37,... Are also inclined so as to incline from the front lower side to the rear upper side. Thereby, the 1st ventilation path 3 blows off air from the blower outlet 34 toward back diagonally upward direction. Note that the air blown toward the rear obliquely upward rises along the wall W, flows in a direction away from the wall W along the ceiling, descends near the wall on the opposite side of the room, and moves along the floor F. Circulates in the room by flowing in the direction of the wall W.

  The dirt detection unit 15 includes an odor sensor 15a and a dust sensor 15b. As shown in FIG. 2, the odor sensor 15 a and the dust sensor 15 b are arranged in the casing 6 (outside the air purification chamber 35) on the upper side wall of the air purification chamber 35. The upper portion of the side wall of the air purification chamber 35 to which the odor sensor 15a and the dust sensor 15b are attached communicates with the filter housing portion 3a. A through hole 35 a is provided in the vicinity of the mounting position of the rear panel 32 in the upper portion of the side wall of the air purification chamber 35. A part of the air sucked from the suction port 33 is sucked from the through hole 35a without passing through the air purifying part 11, passes through the dirt detecting part 15, and flows to the filter accommodating part 3a.

  The odor sensor 15a is a known gas sensor or the like, and detects the level of odor in the external air sucked from the through hole 35a by detecting the concentration of gas that causes odor. For example, the gas sensor detects the gas concentration by utilizing the fact that the resistance value of the gas sensitive body heated to several hundred degrees changes depending on the concentration of the surrounding gas. When the detected gas concentration is low, the odor level is low, and when the detected gas concentration is high, the odor level is high.

  The dust sensor 15b is, for example, an optical particle sensor. An optical particle sensor detects the amount of dust by radiating infrared rays from a light emitting diode into a through hole provided in the sensor, and detecting reflected light from particles floating in the through hole with a phototransistor, Even fine particles such as cigarette smoke can be detected. In the optical particle sensor, the amount of dust is detected depending on the voltage output from the phototransistor.

  The temperature / humidity sensor 16 is arranged in the housing 6 at the upper side of the side wall of the air purification chamber 35, similarly to the dirt detection unit 15, detects the temperature and humidity of the external air sucked from the through-hole 35 a, and detects the relative humidity. Measure.

  Next, the second ventilation path 4 will be described. An air filter 40, a second blower 14, an ion generator 12, an ion sensor 17, and the like are disposed in the second ventilation path 4. The second ventilation path 4 is divided by the second blower 14 into a lower suction chamber 4a and an upper blowout chamber 4b. The front part 61 of the housing 6 has a front panel 611 and a front cover 612, and the suction port 41 is provided in the front cover 612. The front panel 611 covers the upper side of the suction port 41 and both left and right sides from the front side. The suction chamber 4 a communicates with the outside through the suction port 41. The air outlet 42 opens at a boundary portion between the front panel 611 and the top cover 62 of the housing 6, and the air outlet chamber 4 b communicates with the outside via the air outlet 42, and the air outlet 4 a The chambers 4b communicate with each other via the second blower 14.

  The air filter 40 is, for example, a rough lattice net, and is detachably disposed in the suction port 41. The air filter 40 collects and removes coarse dust contained in the air flowing into the suction chamber 4a.

  The second blower 14 includes a fan motor 141 (see FIG. 4) and a fan 142, and the fan motor 141 rotationally drives the fan 142 around a horizontal axis. The fan 142 is a cross-flow fan having a cylindrical multi-blade impeller having a plurality of blades whose outer edge side is displaced in the rotation direction with respect to the rotation center. The fan 142 is arranged so that the direction of the rotation center is the left-right direction of the air cleaner 1. The fan motor 141 is fixed inside the housing 6 by a support portion (not shown). The fan 142 is fixed to the output shaft of the fan motor 141 and rotates by driving the fan motor 141. As the fan 142 rotates, the indoor air (specifically, the air below the front of the housing 6) passes through the suction port 41 as shown by the solid arrow in FIG. The air sucked into the air 4 flows into the blowout chamber 4b from the suction chamber 4a and blows out into the room through the blowout port 42. On the wall surface of the blowout chamber 4b, an ion generator 12 is disposed on the upstream side, and an ion sensor 17 is disposed on the downstream side.

  The ion generator 12 is fixed to the wall of the blowout chamber 4b, and has a needle-like discharge electrode and an induction electrode arranged opposite to the discharge electrode. The discharge electrode to which a high voltage is applied causes a corona discharge to be positive or negative. Generate ions. The discharge electrode of the ion generator 12 is exposed to the blowout chamber 4b, and the generated positive and negative ions float in the air flowing through the blowout chamber 4b and are sent out together with the air from the blowout port 42. Positive and negative ions released into the room together with the air blown out through the air outlet 42 kill or inactivate fungi, viruses, allergens, etc., and cause substances that cause malodors (for example, organic compounds such as acetaldehyde). Decompose.

  The ion sensor 17 detects positive and negative ions flowing through the blowing chamber 4b, and repeatedly outputs the detection result to the control unit 10 (see FIG. 4) at appropriate time intervals. This detection result shows the number of positive and negative ions flowing through the blowing chamber 4b, and thus the number of positive and negative ions generated by the ion generator 12. When the amount of positive and negative ions generated by the ion generator 12 is below a predetermined amount, it can be seen that the ion generator 12 is fouled or deteriorated.

  In the suction chamber 4a, the air flows from the front lower side to the rear upper side, and in the blowing chamber 4b, the air flows in the front upper side. In addition, the air direction restriction plate 43 is disposed at the air outlet 42 in order to restrict the direction in which the air flows, and the second ventilation path 4 is provided in front of the air so that the blown air can easily reach the central portion of the room. Air blows diagonally upward.

  The direction of the air blown out from the second ventilation path 4 is different from the direction of the air blown out from the first ventilation path 3. That is, air is blown out from the first ventilation path 3 in the diagonally upward rear direction, and air is blown out from the second ventilation path 4 diagonally upward in the front, and the first ventilation path 3 and the second ventilation path. The air is blown out obliquely upward from 4 and in a direction opposite to each other in plan view.

  FIG. 4 is a block diagram showing a schematic configuration of the control system of the air purifier 1. The control system of the air cleaner 1 receives the operation signal from the operation panel 2 and the operation panel 2 operated by the user, and controls the operation of the first blower 13 and the second blower 14 to the control unit 10 and the control unit 10. It is configured by a sensor such as the above-described dirt detection unit 15 that inputs various physical quantities.

  The control unit 10 includes a ROM that stores information such as a program, a CPU that performs input / output control and calculation according to a control program stored in advance in the ROM, a RAM that stores temporarily generated information, a nonvolatile write / It has an input / output interface for performing input / output with a readable storage unit 10a and an external circuit. The dirt detection unit 15, the temperature / humidity sensor 16, and the ion sensor 17 are connected via the input / output interface, and the control unit 10 takes in the detection values of these sensors.

  Further, the control unit 10 is connected with a stop button 21, an air cleaning on button 22, a humidified air cleaning on button 23, and an air volume switching button 24 disposed on the top cover 62 of the housing 6. Yes. An operation on the operation panel 2 is received by the control unit 10. Specifically, the operation of the air cleaner 1 is accepted by the control unit 10 by operating the stop button 21. In addition, the selection of the air cleaning operation mode for purifying the air without humidification by the operation of the air cleaning on button 22, and the selection of the humidified air cleaning operation mode for purifying the air while humidifying by the operation of the humidifying air cleaning on button 23 are performed. , Respectively, are received by the control unit 10.

  Further, every time the air volume switching button 24 is operated, “silent”, “medium”, “strong” which are air volume modes for manually setting the air volume, and “auto” which is an air volume mode for automatically setting the air volume. The switching of the four air volume modes is accepted by the control unit 10 in this order, for example. The operation panel 2 includes display lamps 20, 20,..., Lamps for displaying the air cleaning operation mode according to the operations of the air cleaning button 22, the humidified air cleaning button 23, and the air volume switching button 24, respectively. A lamp for displaying the air cleaning operation mode and a lamp for displaying the air volume modes “silent”, “medium”, “strong”, and “automatic” are provided.

  In addition, the control unit 10 includes a fan motor 131 and a second blower 14 of the first blower 13 via the first motor drive circuit 103, the second motor drive circuit 104, the motor drive circuit 105, and the high voltage circuit 106, respectively. The fan motor 141, the electric motor 53 of the humidifying filter 50, and the ion generator 12 are connected. Based on the operation signal received from the operation panel 2 and the detected value of each sensor, the control unit 10 outputs a command signal to each of the drive circuit and the high voltage circuit, the fan motor 131 of the first blower 13, the first 2 The fan motor 141 of the blower 14, the electric motor 53 of the humidifying filter 50, and the ion generator 12 are controlled.

  Next, the amount of air blown from the first ventilation path 3 and the second ventilation path 4 controlled by the control unit 10 will be described. FIG. 5 is a schematic view schematically showing a state where the air purifier 1 is placed indoors. As an example, it is assumed that the room is about 21 tatami mats wide, 6.92 m long, 4.72 m wide, and 2.4 m high. The vertical, horizontal, and height directions of the room are divided into four equal parts, and the center point P of the room is set as the position of the vertical direction B position, the horizontal direction b position, and the height direction 1.2 m. The air purifier 1 is placed on the floor F at the position b in the lateral direction near the wall W. As described above, the direction D1 for blowing air from the first ventilation path 3 is a rearward (wall W direction) diagonally upward direction, and the direction D2 for blowing air from the second ventilation path 4 is a diagonally upper front direction.

The ion concentration at the center point P varies depending on the amount of air blown from the first ventilation path 3 and the second ventilation path 4. FIG. 6 is a chart showing the ion concentration at the center point P when the air flow rate of the first blower 13 is changed. In FIG. 6, on the second ventilation path 4 side, the amount of air blown out from the second ventilation path 4 is fixed horizontally with the air flow rate fixed at 1.6 m ³ / min in a state where ions are generated by the ion generator 12. It is assumed that the direction is tilted 14 deg upward. If the air flow rate of the first ventilation path 3 is 1.5 m ³ / min, the ion concentration at the center point P is high, but the air flow rate of the first ventilation path 3 is 3.5 m ³ / min or 7.0 m. ^If it is increased to ³ / min, the ion concentration at the center point P is lowered. In this way, the ion concentration at the center point P becomes low when the air flow rate of the first ventilation path 3 is increased and the circulation formed near the wall surface, ceiling, and floor surface by the air blown out from the first ventilation path 3. It is considered that the wind becomes stronger and the air blown out from the second ventilation path 4 is attracted by this circulating wind, and the ions reaching the center point P are reduced.

FIG. 7 is a chart showing the ion concentration at the center point P when the blast volume of the first blower 13 and the second blower 14 is changed. In FIG. 7, the second ventilation path 4 side has a direction in which the blowing angle of the air blown out from the second ventilation path 4 is inclined by 14 deg from the horizontal while the ions are generated by the ion generator 12. When the air flow rate of the first ventilation path 3 is 1.5 m ³ / min and the air flow rate of the second ventilation path 4 is 1.6 m ³ / min, the ion concentration at the center point P is high. When the blowing rate of the first air passage 3 by increasing the 2.4m ³ /min,3.5m ³ / min, respectively 1.7 m ³ the blowing rate of the second air passage 4 /min,1.8m ³ / If it is increased with min, the ion concentration at the center point P remains high. As described above, the air blown from the first air passage 3 is formed by setting the air flow of the second air passage 4 to be large / small according to the amount of air flow of the first air passage 3. Without being influenced by the circulating wind, the air blown out from the second ventilation path 4 is directed to the central point P, and the ion concentration at the central point P can be maintained at a high level. Here, when the air flow rate of the first ventilation path 3 is large, the air flow rate of the first ventilation path 3 is set so that the air flow rate of the first ventilation path 3 is large. When the amount is small, it means that the air flow rate of the second ventilation path 4 is set to be small.

FIG. 8 is a chart showing an example of a setting table for the air flow rate of the first blower 13 and the second blower 14. Specifically, in the air volume mode “silent” in which the air volume is manually set, the air flow rate of the first ventilation path 3 is 1.5 m ³ / min, the air flow rate of the second ventilation path 4 is 1.6 m ³ / min, In the air volume mode “medium”, the air flow rate of the first ventilation path 3 is 2.4 m ³ / min, the air flow volume of the second ventilation path 4 is 1.7 m ³ / min, and in the air volume mode “strong”, the first air flow path 3 is set. Is set to 3.5 m ³ / min, and the second blowing path 4 is set to 1.8 m ³ / min. The control unit 10 outputs command signals corresponding to the air volume modes “silent”, “medium”, and “strong” to the first motor driving circuit 103 and the second motor driving circuit 104. The first motor drive circuit 103 and the second motor drive circuit 104 drive the fan motor 131 and the fan motor 141 at a rotational speed that can obtain the airflow rate in each airflow mode in accordance with the command signal.

  Further, in the air volume mode “automatic”, the air volume setting 1, the air volume setting 2 and the air volume setting 3 are the air volume in the air volume modes “silent”, “medium” and “strong”, respectively. Accordingly, any one of the air volume setting 1 to the air volume setting 3 is set. In this case, the control unit 10 outputs a command signal corresponding to the air volume setting 1 to the air volume setting 3 to the first motor driving circuit 103 and the second motor driving circuit 104 according to the detection result by the dirt detection unit 15. The first motor drive circuit 103 and the second motor drive circuit 104 drive the fan motor 131 and the fan motor 141 at a rotational speed that can obtain an air flow rate at each air volume setting according to the command signal. As in the setting table shown in FIG. 8, the control unit 10 controls the air flow rate of the second ventilation path 4 to be greater / smaller according to the amount of air flow of the first ventilation path 3.

FIG. 9 is a chart showing a correspondence relationship between the dirt detection result and the air volume setting of the air volume mode “automatic”. FIG. 9 shows an example in which the gas concentration detected by the odor sensor 15a is detected at three stages of odor levels, and similarly, the dust sensor 15b detects the amount of dust at three stages of dust levels. The odor level and the dust level indicate a state in which more odor and dust are contained in the air as the numerical value is larger. Further, in the example shown in FIG. 9, the degree of air pollution due to odor and dust is determined as an added value of the numerical values of the odor level and dust level, and the air volume setting of the air volume mode “automatic” is selected according to the degree of dirt. For example, when the odor level is 1 and the dust level is 3, the degree of contamination is 4, and the air volume setting 2 of the air volume mode “automatic” is selected. The air volume setting 2 corresponds to the air volume in the air volume mode “medium” as shown in FIG. 8, and specifically, the air volume of the first ventilation path 3 is 2.4 m ³ / min, This corresponds to setting the air flow rate of the ventilation path 4 to 1.7 m ³ / min.

  FIG. 10 is a flowchart showing a processing procedure for operation control of the air purifier 1. The following processing is executed by the CPU of the microcomputer in accordance with a control program stored in advance in the built-in ROM of the microcomputer of the control unit 10. Below, the case where the control part 10 carries out operation control of the air cleaner 1 based on the correspondence relationship shown in FIG. 9 memorize | stored in the setting table | surface of the ventilation volume shown in FIG. 8 and the memory | storage part 10a as an example is demonstrated. Further, the storage unit 10a stores an identification number of the air volume mode at the time of the previous operation (manufacturing air volume mode initial value: for example, “medium”).

  Further, when the air cleaning input button 22 and the humidified air cleaning input button 23 are operated by the user, the identification number of the operated button is updated and stored in the RAM as operation button information. Therefore, the control part 10 shall be able to acquire the identification number of the air cleaning on button 22 or the humidified air cleaning on button 23 operated most recently from RAM. However, as will be described later, in step S20, the operation button information written in the RAM is reset to a value indicating a state in which neither the air cleaning on button 22 nor the humidified air cleaning on button 23 is operated.

  First, the operation control process is started by connecting the power line of the air purifier 1 to, for example, a household AC100V commercial power supply.

  The control unit 10 determines whether or not the air cleaner 1 is operating in the air cleaning mode or the humidified air cleaning mode (step S10). When it determines with not driving | running | working (step S10: NO), the operation button information preserve | saved at RAM is read, and it is determined whether it is the state by which the air purifier on button 22 was operated (step S11). When it is determined that the air clean-up button 22 is not operated (step S11: NO), the operation button information stored in the RAM is read again, and it is determined whether or not the humidified air clean-up button 23 is operated. Determination is made (step S12). If it is determined that the humidified air clean-up button 23 is not operated (step S12: NO), the process returns to step S10.

  In order to operate the air purifier 1 in the air purifying mode, when the user operates the air purifying on button 22, operation button information is stored in the RAM. The control unit 10 acquires the operation button information from the RAM, determines that the air clean-up button 22 has been operated (step S11: YES), and the air volume mode during the previous operation stored in the storage unit 10a. Is read out (step S13).

  After step S13, the control unit 10 performs control for operating the air cleaner 1 in the air cleaning operation mode (step S14). In the control process in step S14, when the identification number of the read air volume mode is one of the identification numbers of the air volume modes “silent”, “medium”, and “strong”, the controller 10 sets the identification number of each mode. Corresponding command signals are output to the first motor drive circuit 103 and the second motor drive circuit 104. The first motor drive circuit 103 and the second motor drive circuit 104 drive the fan motor 131 and the fan motor 141 at a rotational speed that can obtain the air flow rate in each mode according to the command signal. Further, the control unit 10 instructs the high voltage circuit 106 so that the ion generator 12 generates ions, and instructs the motor drive circuit 105 to stop the electric motor 53.

  In addition, when the identification number of the read air volume mode is the identification number of the air volume mode “automatic”, the control unit 10 acquires the detection result by the dirt detection unit 15 and calculates the degree of dirt from the odor level and the dust level. Then, one of the air volume setting 1 to the air volume setting 3 is selected based on the correspondence shown in FIG. The control unit 10 outputs a command signal corresponding to the selected air volume setting to the first motor driving circuit 103 and the second motor driving circuit 104. The first motor drive circuit 103 and the second motor drive circuit 104 drive the fan motor 131 and the fan motor 141 at a rotational speed that can obtain the air flow rate in each mode according to the command signal. Further, the control unit 10 instructs the high voltage circuit 106 so that the ion generator 12 generates ions, and instructs the motor drive circuit 105 to stop the electric motor 53.

  After the process of step S14, the process returns to the start by return, and returns to step S10. Here, no buttons other than the air clean button 22 are operated, and the air clean switch button 22 is maintained. The flow of processing when there is a case will be described. In this case, the control unit 10 determines that the vehicle is in operation (step S10: YES), determines that the air volume switching button 24 is not operated (step S17: NO), and does not operate the stop button 21. The determination is made (step S19: NO), and the process returns to step S11. In step S11, the control unit 10 determines that the air clean-up button 22 has been operated (step S11: YES), and performs operation control in the air clean operation mode through steps S13 and S14.

  Next, when the user operates the humidified air cleaning input button 23 in order to operate the air cleaner 1 in the humidified air cleaning mode, the operation button information is stored in the RAM. The control unit 10 obtains the operation button information from the RAM, determines that the humidified air clean-in button 23 has been operated (step S12: YES), and the identification number of the air volume mode stored in the storage unit 10a. Is read (step S15).

  After step S15, the control unit 10 performs control to operate the air cleaner 1 in the humidified air cleaning operation mode (step S16). In the control process in step S16, when the identification number of the read air volume mode is one of the identification numbers of the air volume modes “silent”, “medium”, and “strong”, the controller 10 sets the identification number of each mode. Corresponding command signals are output to the first motor drive circuit 103 and the second motor drive circuit 104. The first motor drive circuit 103 and the second motor drive circuit 104 drive the fan motor 131 and the fan motor 141 at a rotational speed that can obtain the air flow rate in each mode according to the command signal. Further, the control unit 10 instructs the high voltage circuit 106 so that the ion generator 12 generates ions.

  In addition, when the identification number of the read air volume mode is the identification number of the air volume mode “automatic”, the control unit 10 acquires the detection result by the dirt detection unit 15 and calculates the degree of dirt from the odor level and the dust level. Then, one of the air volume setting 1 to the air volume setting 3 is selected based on the correspondence shown in FIG. The control unit 10 outputs a command signal corresponding to the selected air volume setting to the first motor driving circuit 103 and the second motor driving circuit 104. The first motor drive circuit 103 and the second motor drive circuit 104 drive the fan motor 131 and the fan motor 141 at a rotational speed that can obtain the air flow rate in each mode according to the command signal. Further, the control unit 10 instructs the high voltage circuit 106 so that the ion generator 12 generates ions.

  Further, the control unit 10 acquires the detection result of the relative humidity from the temperature / humidity sensor 16 in any airflow mode, and drives the electric motor 53 when the relative humidity is less than 60%, for example. The motor drive circuit 105 is instructed to stop the electric motor 53 if it is 60% or more. By driving the electric motor 53, the humidifying filter 50 rotates to absorb moisture, and the air that has passed through the humidifying filter 50 is humidified. On the other hand, when the electric motor 53 is stopped, the rotation of the humidifying filter 50 is stopped, and the air that has passed through the humidifying filter 50 is hardly humidified.

  After the process of step S16, the process returns to the start by return, and returns to step S10. Here, no buttons other than the humidified air clean-in button 23 are operated, and the humidified air clean-in button 23 is maintained. A flow of processing in the case of being performed will be described. In this case, the control unit 10 determines that the vehicle is in operation (step S10: YES), determines that the air volume switching button 24 is not operated (step S17: NO), and does not operate the stop button 21. A determination is made (step S19: NO), it is determined that the air clean-up button 22 has not been operated (step S11: NO), and the process returns to step S12. In step S12, the controller 10 determines that the humidified air cleaning button 23 has been operated (step S12: YES), and performs operation control in the humidified air cleaning operation mode in steps S15 and S16.

  Next, a case where the air volume switching button 24 is operated during operation will be described. The controller 10 determines in step S10 that the vehicle is operating (step S10: YES), and determines whether or not the air volume switching button 24 has been operated (step S17). When it is determined that the air volume switching button 24 has been operated (step S17: YES), the control unit 10 updates the identification number of the air volume mode stored in the storage unit 10a to the identification number of the next air volume mode, and changes the air volume mode. Rewrite (step S18).

  Next, the case where the operation is stopped from the air cleaning operation or the humidified air cleaning operation state will be described. After performing any operation control, the control unit 10 returns to the start by return, determines that the operation is being performed in Step S10 (Step S10: YES), and determines whether or not the air volume switching button 24 has been operated. (Step S17). Regardless of the determination in step S17, the control unit 10 determines whether or not the stop button 21 has been operated in step S19. When it determines with the stop button 21 having been operated (step S19: YES), the control part 10 is the state in which the air clean input button 22 and the humidification air clean input button 23 are not operated for the operation button information preserve | saved at RAM. Reset to a value representing.

  As described above, the air purifying unit 11 purifies the air and blows out the air from the first ventilation path 3, while the air from the second ventilation path 4 and the ions in a direction different from the direction of blowing out the air from the first ventilation path 3. Since the second blower 14 controls the amount of air blown by the first blower 13 according to the amount of blown air, the first blower 13 controls the amount of air blown from the first ventilation path 3. The amount of air blown out from the two air passages 4 with the ions is controlled, and the air cleaning performance by the blown-out ions can be enhanced.

  Further, for example, based on the setting table of the air flow rate as shown in FIG. 8, the air flow amount that the second air blower 14 blows is controlled to be large / small according to the air flow amount that the first air blower 13 blows. Thus, the influence of the air blown out from the first ventilation path 3 on the air blown out together with the ions from the second ventilation path 4 can be reduced, and the air cleaning performance by the blown-out ions can be enhanced.

  Further, the degree of dirt of the air sucked into the first ventilation path 3 is detected by the dirt detection unit 15, and according to the detection result, for example, according to the correspondence shown in FIG. In order to control the air flow rate, when the level of dirt is high, the air volume can be increased to remove air dirt in a short time, and when the level of dirt is low, the air flow rate can be reduced to operate quietly. .

  Since air is blown obliquely upward from the first ventilation path 3 and the second ventilation path 4 in directions opposite to each other in plan view, the first ventilation path with respect to the air blown out together with the ions from the second ventilation path 4 The influence of the air blown out from 3 can be reduced, and the air cleaning performance can be enhanced by blowing out ions into the indoor air.

(Modification 1)
In the above-described embodiment, the control unit 10 detects the air volume in the air volume mode “automatic” during the humidified air cleaning operation in the same manner as the air volume setting in the air volume mode “automatic” during the air cleaning operation. Although it is set based on the result, the air volume setting in the air volume mode “automatic” may be performed based on the relative humidity calculated based on the detection result of the temperature / humidity sensor 16. FIG. 11 is a chart showing the humidity detection result and the air volume setting in the air volume mode “automatic”. Thus, when the humidity of air is sucked into the first ventilation path 3 is detected by the temperature / humidity sensor 16 and the air volume of the first blower 13 and the second blower 14 is controlled according to the detection result, the humidity is low. Can increase the air flow rate to humidify the air in a shorter time, and when the humidity is high, the air flow rate can be reduced to operate quietly.

(Modification 2)
FIG. 12 is a chart showing an example of setting values of the air flow rate in the manual mode. Specifically, in the air volume mode “silent”, the air volume of the first ventilation path 3 is 1.5 m ³ / min, the air volume of the second ventilation path 4 is 0.8 m ³ / min, and the air volume mode “medium” ", The air flow rate of the first ventilation path 3 is 3.5 m ³ / min, the air flow rate of the second ventilation path 4 is 1.8 m ³ / min, and in the air volume mode" strong ", the air flow rate of the first ventilation path 3 is 7.0 m < ³ > / min and the ventilation volume of the 2nd ventilation path 4 shall be 1.8 m < ³ > / min. In this setting, in the relationship between the air volume mode “silent” and the air volume mode “medium”, the air flow rate of the second blower 14 is controlled to be large / small according to the amount of air flow of the first blower 13. However, in the relationship between the air volume mode “medium” and the air volume mode “strong”, the air volume of the second fan 14 is set to the same value although the air volume of the first fan 13 is increased. In the air volume mode “silent”, the air volume of the second blower 14 is set to a low value in order to ensure a quieter state. Further, in the air volume mode “medium”, in order to improve the air cleaning performance, the air volume of the first fan 13 is set to be large, and the air volume of the second fan 14 is also set so that the ion concentration can sufficiently reach the center point P. Many are set. In the air volume mode “strong”, in order to further improve the air cleaning performance, the air volume of the first air blower 13 is set to be larger, while the air flow rate in the air volume mode “medium” remains on the second air fan 14 side. . In this way, the air flow rate of the second air passage 4 may be controlled to be large / small depending on the amount of air flow of the first air passage 3 partially.

  The present invention is not limited to the present embodiment, but covers the technical scope of the invention described in the claims and the equivalent scope thereof.

DESCRIPTION OF SYMBOLS 3 1st ventilation path 4 2nd ventilation path 10 Control part 11 Air purification part 12 Ion generator 13 1st air blower 14 2nd air blower 15 Dirt detection part (dirt detection means)
16 Temperature and humidity sensor (humidity detection means)
50 Humidification filter (humidification means)

Claims (5)

Air is blown by the first blower and air is sucked into the first ventilation path from the outside, purified by the air purification unit and blown out, and air is blown by the second blower and sucked into the second ventilation path from the outside to generate ions. In the air purifier that blows out air in a direction different from the direction blown out from the first ventilation path together with the ions generated by the vessel,
A control unit for controlling operations of the first blower and the second blower,
The said control part controls the ventilation volume which a said 2nd blower ventilates according to the ventilation volume which the said 1st blower blows, The air cleaner characterized by the above-mentioned. The control unit is configured to control the amount of air blown by the second fan according to the amount of air blown by the first blower. Air cleaner as described in. A dirt detecting means for detecting the degree of dirt of the air sucked into the first ventilation path;
The said control part controls the ventilation volume of a said 1st air blower and a said 2nd air blower according to the detection result by the said dirt detection means. The Claim 1 or Claim 2 characterized by the above-mentioned. Air cleaner. Humidity detecting means for detecting the humidity of the air sucked into the first ventilation path;
Humidifying means for humidifying the air sucked into the first ventilation path,
The said control part controls the ventilation volume of a said 1st air blower and a said 2nd air blower according to the detection result by the said humidity detection means. The Claim 1 or Claim 2 characterized by the above-mentioned. Air cleaner. 5. The air according to claim 1, wherein air is blown out obliquely upward and in a direction opposite to each other in plan view from the first ventilation path and the second ventilation path. Air cleaner.

Images