JP2014231925A - Air cleaner with dehumidifying function - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air cleaner capable of holding down power consumption.SOLUTION: A dehumidifier-humidifier air cleaner 100 comprises: a main body casing 10; a Sirocco fan 50; a sensor 45; a fan controller 93; and an economical mode controller 98. The sensor 45 detects a cleanliness of indoor air. The fan controller 93 and the economical mode controller 98 control the Sirocco fan 50 to be driven. The economical mode controller 98 has a continuous operation mode and an intermittent operation mode as control modes. The economical mode controller 98 transitions to the intermittent operation mode with a detection result of the sensor 45 satisfying predetermined conditions as a momentum. In the intermittent operation mode, the economical mode controller 98 controls the fan controller 93 to drive the Sirocco fan 50 for a predetermined monitoring period at intervals of predetermined periods. In the monitoring period, the fan controller 93 drives the Sirocco fan 50 with a smaller air volume than that during the continuous operation mode.

Description

  The present invention relates to an air cleaner that harmonizes air in a target space.

  2. Description of the Related Art Conventionally, an air cleaner that takes in air in a target space with a fan and removes dust is known. Some of these air purifiers perform intermittent fan operation depending on the situation in order to reduce power consumption. For example, an air cleaner disclosed in Patent Document 1 (Japanese Patent Application Laid-Open No. 2012-57887) is equipped with a sensor that detects the amount of dust contained in the taken-in air, and the detection result of the sensor is predetermined. The fan is intermittently operated when the conditions are met.

  By the way, in the air cleaner shown to patent document 1, during the period when the fan is performing intermittent operation, the power consumption is suppressed by driving a fan with the minimum rotation speed assumed at the time of continuous operation. . However, according to this, even when the fan is intermittently operated, the power consumption during the period during which the fan is driven may be equivalent to the power consumption during the continuous operation.

  Then, the subject of this invention is providing the air cleaner which can suppress power consumption.

  The air cleaner which concerns on the 1st viewpoint of this invention is an air cleaner which harmonizes the air of object space, Comprising: A casing, a fan, a cleanliness sensor, and a fan control part are provided. The fan is accommodated in the casing. The fan takes the air in the target space into the casing and discharges it outside the casing. The cleanliness sensor detects the cleanliness of the air in the target space taken into the casing. The fan control unit has a plurality of control modes. The fan control unit controls driving of the fan. The control mode includes a continuous operation mode and an intermittent operation mode. In the continuous operation mode, the fan is operated continuously. In the intermittent operation mode, the fan is operated intermittently. The fan control unit transitions to the intermittent operation mode when the detection result of the cleanliness sensor satisfies a predetermined condition in the continuous operation mode. In the intermittent operation mode, the fan control unit causes the fan to perform a light wind operation for a predetermined time every predetermined period in order to cause the cleanliness sensor to periodically detect the degree of cleanliness. The fan control unit drives the fan with a smaller air volume during the light wind operation than when in the continuous operation mode.

  In the air cleaner according to the first aspect of the present invention, the fan control unit causes the fan to perform a light wind operation for a predetermined time every predetermined period in the intermittent operation mode, and the air flow is smaller than that in the continuous operation mode during the light wind operation. Drive the fan. Thereby, the power consumption at the time of a light wind operation is reduced rather than the power consumption at the time of a continuous operation mode. Therefore, power consumption is suppressed.

  The air cleaner which concerns on the 2nd viewpoint of this invention is an air cleaner which concerns on a 1st viewpoint, Comprising: A fan is driven by the rotation speed lower than the rotation speed selected at the time of continuous operation mode at the time of a light breeze driving | operation. .

  In the air cleaner according to the second aspect of the present invention, the fan is driven at a lower rotational speed than the rotational speed selected in the continuous operation mode during the light wind operation. Thereby, the power consumption at the time of a light wind operation is reduced rather than the power consumption at the time of a continuous operation mode.

  The air cleaner which concerns on the 3rd viewpoint of this invention is an air cleaner which concerns on a 1st viewpoint, Comprising: A fan contains a 1st fan and a 2nd fan. The fan control unit continuously operates the first fan in the continuous operation mode. In the intermittent operation mode, the fan control unit stops the first fan and operates the second fan for a predetermined time every predetermined period.

  In the air cleaner according to the third aspect of the present invention, the fan control unit stops the first fan and operates the second fan for a predetermined time every predetermined period in the intermittent operation mode. Thereby, the power consumption at the time of a light wind operation is reduced rather than the power consumption at the time of a continuous operation mode.

  The air cleaner which concerns on the 4th viewpoint of this invention is an air cleaner which concerns on either of the 1st viewpoint to the 3rd viewpoint, Comprising: A fan control part is larger than the time of a breeze driving | operation at the time of continuous operation mode. The fan is driven with an airflow selected from the set airflow.

  In the air cleaner according to the fourth aspect of the present invention, in the continuous operation mode, the fan control unit drives the fan with an air volume selected from a plurality of set air volumes that are larger than those in the light wind operation. Thereby, the power consumption at the time of a light wind operation is reduced rather than the power consumption at the time of a continuous operation mode.

  An air cleaner according to a fifth aspect of the present invention is the air cleaner according to any one of the first to fourth aspects, wherein the discharge unit, the discharge unit power supply unit, the discharge unit control unit, Is further provided. The discharge unit generates ions by being supplied with electric power. The discharge unit power supply unit supplies power to the discharge unit. The discharge unit controller controls the discharge unit power supply unit. The discharge unit control unit stops the power supply to the discharge unit by the discharge unit power supply unit in the intermittent operation mode.

  In the air cleaner according to the fifth aspect of the present invention, the discharge unit control unit stops power supply to the discharge unit by the discharge unit power supply unit in the intermittent operation mode. Thereby, in an air cleaner provided with a discharge unit, power consumption in the intermittent operation mode is further reduced.

  An air cleaner according to a sixth aspect of the present invention is the air cleaner according to any one of the first to fifth aspects, wherein the dehumidifying unit, the power supply unit for the dehumidifying unit, the dehumidifying unit control unit, Is further provided. The dehumidifying unit dehumidifies the air in the target space taken into the casing by being driven by being supplied with electric power. The dehumidifying unit power supply unit supplies power to the dehumidifying unit. The dehumidifying unit controller controls the dehumidifying unit power supply unit. The dehumidifying unit control unit stops power supply to the dehumidifying unit by the dehumidifying unit power supply unit in the intermittent operation mode.

  In the air cleaner according to the sixth aspect of the present invention, the dehumidifying unit controller controls the dehumidifying unit power supply unit. The dehumidifying unit control unit stops power supply to the dehumidifying unit by the dehumidifying unit power supply unit in the intermittent operation mode. Thereby, in an air cleaner provided with a dehumidifying unit, power consumption in the intermittent operation mode is further reduced.

  An air cleaner according to a seventh aspect of the present invention is the air cleaner according to any one of the first to sixth aspects, wherein the humidifying unit, the humidifying unit power supply unit, the humidifying unit control unit, Is further provided. A humidification unit humidifies the air of the object space taken in in a casing by being supplied with electric power and driving. The humidifying unit power supply unit supplies power to the humidifying unit. The humidifying unit control unit controls the humidifying unit power supply unit. The humidifying unit control unit stops power supply to the humidifying unit by the humidifying unit power supply unit in the intermittent operation mode.

  In the air cleaner according to the seventh aspect of the present invention, the humidifying unit control unit controls the humidifying unit power supply unit. The humidifying unit control unit stops power supply to the humidifying unit by the humidifying unit power supply unit in the intermittent operation mode. Thereby, in an air cleaner provided with a humidification unit, the power consumption in the intermittent operation mode is further reduced.

  In the air cleaner according to the first to fourth aspects of the present invention, the power consumption during the light wind operation is reduced compared to the power consumption during the continuous operation mode. Therefore, power consumption is suppressed.

  In the air cleaner which concerns on the 5th viewpoint of this invention, in the air cleaner provided with a discharge unit, the power consumption at the time of an intermittent operation mode is further reduced.

  In the air cleaner which concerns on the 6th viewpoint of this invention, in an air cleaner provided with a dehumidification unit, the power consumption at the time of intermittent operation mode is further reduced.

  In the air cleaner which concerns on the 7th viewpoint of this invention, in an air cleaner provided with a humidification unit, the power consumption at the time of intermittent operation mode is further reduced.

The front perspective view of the dehumidification humidification air cleaner concerning one embodiment of the present invention. The conceptual diagram showing the flow of the air at the time of the driving | operation of the dehumidification / humidification air cleaner which concerns on one Embodiment of this invention. The exploded view of the dehumidification humidification air cleaner concerning one embodiment of the present invention. The schematic block diagram of a refrigerating cycle unit. The front view of the dehumidification / humidification air cleaner in the state which removed the front panel, the discharge unit, the filter unit, and the front frame. FIG. 6 is a front view of the evaporator, the condenser, the humidification rotor, the sirocco fan, and the emitted ion generation unit in FIG. 5. VII-VII sectional view taken on the line of FIG. The schematic diagram which shows the schematic structure of a controller, and the apparatus connected to the controller. The schematic diagram which shows schematic structure of an eco mode control part. The flowchart which shows the flow of a process of an eco mode control part. The timing chart which shows the change of the state of each part when an eco mode introduction command is input. The schematic diagram which shows the internal structure of the dehumidification humidification air cleaner which concerns on 2nd Embodiment. The timing chart which shows the change of the state of each part in case the eco mode introduction command is input in the dehumidification humidification air cleaner which concerns on 2nd Embodiment.

<First Embodiment>
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention, and can be modified as appropriate without departing from the scope of the invention. In the following description, terms indicating directions such as up, down, left, right, front (front), and back (back) are used. These directions are shown in FIG. 1 unless otherwise specified. Means direction.

(1) Dehumidified / humidified air purifier 100
(1-1) Overview FIG. 1 is a front perspective view of a dehumidified / humidified air cleaner (hereinafter referred to as a dehumidified / humidified air cleaner) 100 according to a first embodiment of the present invention. The dehumidifying / humidifying air cleaner 100 is a device that performs harmony by purifying air in a target space, dehumidifying, humidifying, and the like. The dehumidifying / humidifying air cleaner 100 is a floor-standing type and is installed on an indoor floor or the like.

  The dehumidifying / humidifying air cleaner 100 is formed with a lower suction port 101 for taking indoor air into the interior, a left side suction port 102a, and a right side suction port 102b, and a blower port 103 for blowing out purified air is formed. ing. The lower suction port 101 is formed to extend in the left-right direction in the vicinity of the lower end of the front portion. The left side suction port 102a is formed to extend in the vertical direction in the left side surface portion. The right side suction port 102b is formed in the same manner as the left side suction port 102a in the right side surface portion. In the following description, for convenience of explanation, the left side suction port 102a and the right side suction port 102b are collectively referred to as the side suction port 102. The blower outlet 103 is formed in the ceiling part.

  The dehumidifying / humidifying air cleaner 100 has a plurality of operation modes such as an air cleaning mode, a dehumidifying mode, and a humidifying mode, and these modes are selected and operated individually or in combination. Specifically, when the air cleaning mode is selected, the dehumidifying / humidifying air cleaner 100 performs an air cleaning operation that takes in air in the indoor space, removes dust, and discharges it to the indoor space. Further, when the dehumidifying mode is selected, the dehumidifying / humidifying air cleaner 100 performs a dehumidifying operation for taking in air in the indoor space, dehumidifying it, and discharging it to the indoor space. Further, when the humidification mode is selected, the dehumidifying / humidifying air cleaner 100 performs a humidifying operation of taking in air in the indoor space, humidifying it, and discharging it to the indoor space.

  In addition, the dehumidifying / humidifying air cleaner 100 has an eco mode. When the eco mode is selected, the dehumidifying / humidifying air cleaner 100 enters a standby state when the predetermined condition is satisfied.

  The dehumidifying / humidifying air cleaner 100 has a five-stage air volume mode including a maximum air volume mode, a strong air volume mode, a medium air volume mode, a weak air volume mode, and a static air volume mode. The air volume generated in each air volume mode is different, the air volume generated in the maximum air volume mode is the largest, and the air volume generated in the static air volume mode is the smallest. The specific air volume in the present embodiment is 7.5 m 3 / min in the maximum air volume mode, 5.3 m 3 / min in the strong air volume mode, 4.0 m 3 / min in the medium air volume mode, and 2. It is set to 5 m 3 / min and 1.0 m 3 / min in the static air amount mode. However, the said air volume is not necessarily limited to the said numerical value, and can be changed suitably.

  Each mode such as the above-described operation mode, eco mode, and air volume mode is switched by the user via an input key 90a provided on an operation panel 90 described later.

(1-2) Air Flow FIG. 2 is a conceptual diagram showing the air flow when the dehumidifying / humidifying air cleaner 100 is in operation. The outline of the air flow of the dehumidifying / humidifying air cleaner 100 is as follows.

  As shown in FIG. 2, when the operation of the dehumidifying / humidifying air cleaner 100 is started and the sirocco fan 50 is driven, an air flow AF is generated. The air flow AF is a flow of air that flows into the dehumidifying / humidifying air cleaner 100 and flows out of the dehumidifying / humidifying air cleaner 100. When the air flow AF is generated, indoor air is taken into the dehumidifying / humidifying air cleaner 100 via the lower suction port 101 and the side suction port 102. The indoor air taken into the dehumidifying / humidifying air cleaner 100 is freed of dust and odor components by the filter unit 30, dehumidified by the refrigeration cycle unit 60 or humidified by the humidifying unit 70, and then passed through the outlet 103. It is blown out of the dehumidifying / humidifying air cleaner 100 and returned to the room. Further, a part of the air flow AF passes through the streamer discharge unit 80 as a tributary BF without being blown out of the dehumidifying / humidifying air cleaner 100. The tributary BF that has passed through the streamer discharge unit 80 flows into the vertical wind passage member 410 and merges with the air flow AF that passes through the filter unit 30 through the discharge port 41a.

(2) Details of Dehumidifying / Humidifying Air Cleaner 100 Hereinafter, details of the dehumidifying / humidifying air cleaner 100 will be described with reference to FIGS. 1 to 3. FIG. 3 is an exploded view of the dehumidifying / humidifying air cleaner 100.

(2-1) Main body casing 10
An outer shell of the dehumidifying / humidifying air cleaner 100 is constituted by a substantially rectangular parallelepiped main body casing 10 (corresponding to “casing” described in claims). The main body casing 10 is mainly composed of a casing member including a bottom surface portion 11, a back surface portion 12, a left side wall portion 13, a left side suction port forming portion 14 a, a right side suction port forming portion 14 b, a ceiling portion 15, and a front panel 16. ing.

  The bottom surface portion 11 has a substantially rectangular shape that is long in the left-right direction in plan view, and constitutes a bottom surface portion of the dehumidifying / humidifying air cleaner 100.

  The back surface part 12 comprises the back surface part of the dehumidification humidification air cleaner 100, and the back side part of a right side surface. The back surface portion 12 has a substantially L-shaped lower end portion in plan view, and is fixed to the bottom surface portion 11 at the lower end portion.

  The left side wall portion 13 constitutes the left side surface portion of the dehumidifying / humidifying air cleaner 100. The left side wall part 13 is formed with a grip part 13a. The gripping part 13a is a depression that can be gripped by inserting a finger. When a finger is inserted into the grip portion 13a and pulled leftward, the left wall portion 13 is removed. Further, the left side wall portion 13 has a water tank 73 of the humidifying unit 70 fixed to the inner surface thereof. When the water in the water tank 73 is replaced, the water tank 73 can be attached and detached by attaching and detaching the left side wall portion 13.

  The left side suction port forming portion 14 a constitutes a front side portion of the left side surface of the dehumidifying / humidifying air cleaner 100. The right side suction port forming portion 14 b constitutes a front side portion of the right side surface of the dehumidifying / humidifying air cleaner 100. In the following description, for convenience of explanation, the left side suction port forming portion 14a and the right side suction port forming portion 14b are collectively referred to as a side suction port forming portion 14. The side suction port forming portion 14 is a vertically long plate-like member, and is fixed to the bottom surface portion 11 at the lower end thereof. The side suction port forming part 14 is formed with a vertically long opening, and the opening functions as the side suction port 102.

  The ceiling portion 15 constitutes a ceiling portion of the dehumidifying / humidifying air cleaner 100 and is fixed to the back surface portion 12 and the side suction port forming portion 14. The ceiling portion 15 is disposed so as to be inclined so as to have a downward slope in the front direction. On the ceiling portion 15, an operation panel 90 is provided for a user to input a command.

  The ceiling portion 15 is disposed so as to form an opening between the upper end portion of the back surface portion 12. That is, an opening is formed between the ceiling portion 15 and the back surface portion 12 in plan view, and the opening functions as the air outlet 103 of the dehumidifying / humidifying air cleaner 100. The blower outlet 103 is covered with the blower outlet blade 151 when the dehumidifying / humidifying air cleaner 100 is in the operation stop state. The outlet blade 151 opens and closes when the outlet blade motor M151 is driven. When the dehumidifying / humidifying air cleaner 100 is in an operating state, the air outlet 103 is exposed when the air outlet blade 151 is opened. Note that the air outlet 103 is provided with a lattice 103a in order to prevent the object from falling.

  The front panel 16 constitutes a front portion of the dehumidifying / humidifying air cleaner 100. The front panel 16 is fixed to the side suction port forming portion 14 and the ceiling portion 15 and can be removed by pulling in the front direction. A gap is formed between the lower end of the front panel 16 and the bottom surface portion 11, and the gap functions as the lower suction port 101. Instead of forming such a gap between the front panel 16 and the bottom surface portion 11, an opening may be formed in the front panel 16 and the opening may be used as the lower suction port 101.

  Inside the main body casing 10 configured as described above, the discharge unit 20, the filter unit 30, the frame 40, the sirocco fan 50, the refrigeration cycle unit 60, the humidification unit 70, the streamer discharge unit 80, the released ion generation unit 81, and the like. Is stored. Hereinafter, these will be described. In the following description, for convenience of description, the discharge unit 20, the streamer discharge unit 80, and the emitted ion generation unit 81 are collectively referred to as a “discharge unit”.

(2-2) Discharge unit 20
The discharge unit 20 mainly includes a left side discharge unit 20a and a right side discharge unit 20b having a vertically long cylindrical shape. The left side discharge unit 20a is provided in the vicinity of the left side suction port 102a. Therefore, the air taken in from the left side suction port 102a passes through the left side discharge unit 20a. The right side discharge unit 20b is provided in the vicinity of the right side suction port 102b. Therefore, the air taken in from the right side suction port 102b passes through the right side discharge unit 20b.

  The discharge unit 20 includes a tungsten ionization wire as a positive electrode and a stainless metal plate-like electrode as a negative electrode (not shown). The discharge unit 20 is connected to a first power supply unit 201 (corresponding to “a power supply unit for discharge unit” described in the claims) disposed inside an electrical component box 43a, which will be described later, and is supplied with power. The The first power supply unit 201 receives or supplies power from the discharge control unit 96 (described later) or supplies or interrupts power to the discharge unit 20.

  When electric power is supplied from the first power supply unit 201 to the discharge unit 20 and a high voltage is applied, a potential difference is generated between the positive electrode and the negative electrode, and corona discharge occurs to generate ions. That is, the discharge unit 20 generates ions by being supplied with power from the first power supply unit 201. The dust in the air that passes through the discharge unit 20 is charged by the generated ions.

(2-3) Filter unit 30
The filter unit 30 is disposed in the main body casing 10 so that the air flow AF taken into the main body casing 10 from the lower suction port 101 and the side suction port 102 passes. As shown in FIG. 2, the filter unit 30 mainly includes a pre-filter 31, an electrostatic dust collection filter 32, and a deodorization filter 33.

  First, large dust is removed by the pre-filter 31 from the air flow AF flowing into the main casing.

  Next, the electrostatic dust collection filter 32 having higher dust collection performance than the pre-filter 31 removes fine dust, bacteria, and the like charged through the discharge unit 20. When the dehumidifying / humidifying air cleaner 100 is in an operating state, the electrostatic dust collection filter 32 is charged with a polarity opposite to that of dust passing through the discharge unit 20. For example, when dust passing through the discharge unit 20 is charged with a positive charge, the electrostatic dust collection filter 32 is charged with a negative charge. As a result, fine dust or bacteria contained in the airflow AF that has passed through the discharge unit 20 and the prefilter 31 are adsorbed by the electrostatic dust collection filter 32.

  Further, the air that has passed through the electrostatic dust collection filter 32 is decomposed or adsorbed with formaldehyde, odor components, and the like by a deodorizing filter 33 made of activated carbon or the like.

(2-4) Frame 40
The frame 40 is a frame member made of synthetic resin, for example. The frame 40 mainly includes a front frame 41, a center frame 42, and a rear frame 43.

  The front frame 41 has the filter unit 30 fixed to the front portion thereof. In addition, a vertical wind passage member 410 is disposed in the front frame 41 along the vertical direction, which is the vertical direction, at both left and right ends. In the vertical wind passage member 410, a plurality of discharge ports 41a are formed so as to be arranged in the vertical direction. Further, the sensor 45 and the streamer discharge unit 80 are fixed at the upper part of the front frame 41.

  The center frame 42 is provided on the back side of the front frame 41. The center frame 42 has the refrigeration cycle unit 60 fixed to the front side. That is, the refrigeration cycle unit 60 is disposed between the front frame 41 and the center frame 42. The central frame 42 is provided with a humidifying unit 70 on the back side. Further, the central frame 42 accommodates a dehumidification tank 42a for storing water condensed at the time of dehumidifying operation at the bottom portion.

  The rear frame 43 is provided on the back side of the central frame 42. A humidification unit 70 is disposed between the center frame 42 and the rear frame 43. In the upper part of the rear frame 43, an electrical component box 43a that houses various electrical components is fixed. The rear frame 43 is provided with a sirocco fan 50 on the back side. Further, the rear frame 43 is provided with a bell mouth-shaped fan bell mouth 431 at the center portion. The airflow AF flows into the sirocco fan 50 through the fanbell mouth 431.

(2-5) Sensor 45
The sensor 45 (corresponding to “cleanliness sensor” described in the claims) includes semiconductor parts, electronic parts, and the like, and the amount of dust contained in the indoor air flowing into the main body casing 10 as an air flow AF, the smell Detect degree and humidity. That is, the sensor 45 detects the degree of cleanliness of the indoor air taken into the main body casing 10. The sensor 45 A / D-converts the detection result every predetermined period and sends it to the controller 91.

(2-6) Sirocco fan 50
The sirocco fan 50 (corresponding to “fan” described in the claims) is housed in the main casing 10 and generates an air flow AF that flows into the main casing 10 and flows out of the main casing 10. The sirocco fan 50 mainly includes a fan rotor 51 and a scroll casing 52 that houses the fan rotor 51.

  The fan rotor 51 is connected to a rotation shaft of a fan motor M51 disposed on the back side of the fan rotor 51, and rotates when the fan motor M51 is driven. When the fan motor M51 is driven, the fan rotor 51 sucks air from the direction in which the rotating shaft extends and blows it out in the radial direction.

  The fan motor M51 is connected to the fan motor driving unit 511 and driven by being supplied with electric power. The fan motor drive unit 511 is disposed inside the electrical component box 43a, and drives or stops the fan motor M51 by supplying or cutting off power. The fan motor drive unit 511 receives a specified rotation speed drive control signal (described later) from the fan control unit 93 described later, and supplies power so that the fan motor M51 is driven at the rotation speed specified in the signal. Further, the supply of power is stopped upon receiving a fan stop signal (described later) from the fan controller 93.

  The scroll casing 52 is a synthetic resin casing member having a scroll curved portion in which a fan is accommodated. The scroll casing 52 is fixed to the rear portion of the rear frame 43.

  On the front side of the scroll casing 52, an opening having the same area as the fan rotor 51 as viewed from the front is formed, and the opening serves as an inlet 50a (see FIGS. 6 and 7) of the sirocco fan 50. Function. Further, an opening is formed in the upper portion of the scroll casing 52, and the opening functions as a discharge port 50b (see FIG. 7) of the sirocco fan 50. The outlet 50b is connected to the outlet 103, and when the outlet 103 is exposed, the outlet 50b is also exposed.

  Inside the scroll casing 52, a scroll channel and a discharge channel through which air flows are formed. Specifically, the scroll channel is formed outside the outer peripheral surface of the fan rotor 51 in the scroll bending portion, and is formed so that the channel area increases as the distance from the tongue portion increases. The discharge channel communicates with the scroll channel and extends to the discharge port 50b. The air guided to the discharge channel is discharged from the discharge port 50b.

(2-7) Refrigeration cycle unit 60
Hereinafter, the refrigeration cycle unit 60 (corresponding to the “dehumidification unit” recited in the claims) will be described with reference to FIGS. 1 to 7. FIG. 4 is a schematic configuration diagram of the refrigeration cycle unit 60. FIG. 5 is a front view of the dehumidified / humidified air cleaner 100 with the front panel 16, the discharge unit 20, the filter unit 30, and the front frame 41 removed. FIG. 6 is a front view of the evaporator 61, the condenser 63, the humidification rotor 71, the sirocco fan 50, and the emitted ion generation unit 81 in FIG. 7 is a cross-sectional view taken along line VII-VII in FIG.

  The refrigeration cycle unit 60 is driven during the dehumidifying operation of the dehumidifying / humidifying air cleaner 100 to dehumidify the air flow AF. The refrigeration cycle unit 60 mainly includes an evaporator 61, a compressor 62, a condenser 63, a capillary tube 64, and a refrigerant pipe 65, and forms a refrigerant circuit. In addition, as a refrigerant | coolant, various refrigerant | coolants, such as R134a and CO2, are selected, for example.

  The evaporator 61 is, for example, a cross fin type heat exchanger, and is disposed on the back side of the front frame 41. That is, the evaporator 61 is located on the downstream side of the filter unit 30. The evaporator 61 exchanges heat with the air flow AF to evaporate the liquid refrigerant flowing through the evaporator 61, and cools and dehumidifies the air flow AF below the dew point temperature. The drain water condensed when the air flow AF passes through the evaporator 61 is guided to the dehumidification tank 42a and stored.

  The compressor 62 is, for example, a rotary type or scroll type hermetic compressor. The compressor 62 compresses the inflowing gas refrigerant. The compressor 62 includes an accumulator 62a and suppresses inflow of liquid refrigerant. When the compressor 62 is driven, the refrigerant circulates in the refrigerant circuit of the refrigeration cycle unit 60. The compressor 62 is brought into an operation state when the built-in compressor motor M62 is driven. The compressor motor M62 is driven by being connected to a compressor motor drive unit 621 (corresponding to a “dehumidification unit power supply unit” recited in the claims) and supplied with electric power. The compressor motor drive unit 621 is disposed inside the electrical component box 43a. The compressor motor drive unit 621 receives a signal for driving the compressor motor M62 or a signal for stopping the drive of the compressor motor M62 from the compressor control unit 94 (described later), or supplies power to the compressor motor M62. Shut off is performed to drive or stop the compressor motor M62.

  The condenser 63 is, for example, a cross fin type heat exchanger, and is disposed close to the back side of the evaporator 61. The condenser 63 heat-exchanges the air flow AF by condensing the gas refrigerant flowing through the condenser 63 by exchanging heat with the air flow AF.

  The capillary tube 64 is an expansion unit that expands the liquid refrigerant flowing into the evaporator 61. That is, the capillary tube 64 is expanded and decompressed by allowing the high-pressure liquid refrigerant flowing out of the condenser 63 to pass therethrough.

  The refrigerant pipe 65 is a copper pipe through which the refrigerant flows. The refrigerant pipe 65 connects the evaporator 61, the compressor 62, the condenser 63, and the capillary tube 64.

  In the refrigeration cycle unit 60 configured as described above, electric power is supplied to the compressor motor drive unit 621 and the compressor 62 is driven, whereby the refrigerant circulates in the refrigerant circuit, and the evaporator 61 serves as the air flow AF. The indoor air flowing into the main casing 10 is dehumidified.

(2-8) Humidification unit 70
As shown in FIG. 3, the humidification unit 70 mainly includes a humidification rotor 71, a storage unit 72, and a water tank 73.

  The humidification rotor 71 has, for example, a structure in which a vaporization filter is attached to a ring frame. During the humidification operation, humidification is performed by water vaporizing from the vaporization filter. The humidification rotor 71 is connected to a humidification unit motor (not shown), and rotates when the humidification unit motor is driven. The humidification unit motor is driven by being connected to a humidification unit motor drive unit 711 (corresponding to a “humidification unit power supply unit” described in claims) and supplied with electric power. The humidification unit motor drive unit 711 is disposed inside the electrical component box 43a. The humidifying unit motor drive unit 711 receives or supplies a signal for driving the humidifying unit motor or a signal for stopping the driving of the humidifying unit motor from the humidifying control unit 95 (described later), and supplies or interrupts power to the humidifying unit motor. Then, the humidifying unit motor is driven or stopped.

  The reservoir 72 stores the water supplied from the water tank 73. The water tank 73 is a tank for storing water to be supplied to the storage part 72, and is fixed to the inner surface part of the left side wall part 13. The humidifying rotor 71 is provided with a handle rod portion (not shown) on the ring-shaped frame, and when the humidifying rotor 71 rotates, the handle rod portion draws water from the storage portion 73 and supplies water to the vaporization filter. Has been.

  As shown in FIGS. 5 to 7, the humidification rotor 71 is located on the back side of the evaporator 61 and the condenser 63 (on the downstream side of the air flow AF). When the humidifying rotor 71 is passed through the air flow AF during the humidifying operation, the humidified rotor 71 humidifies the vaporized water by including it in the air flow AF. That is, the humidification unit 70 humidifies the air taken into the main body casing 10 when electric power is supplied to the humidification unit motor M71 and the humidification rotor 71 is driven.

(2-9) Streamer discharge unit 80
The streamer discharge unit 80 (corresponding to the “discharge unit” described in the claims) has a needle-like electrode made of tungsten as a positive electrode and a plate-like electrode (counter electrode) facing the electrode ( (Not shown). The streamer discharge unit 80 is connected to a second power supply unit 801 (corresponding to a “discharge unit power supply unit” recited in the claims) provided inside the electrical component box 43a and is supplied with power. The second power supply unit 801 supplies or interrupts power to the streamer discharge unit 80 in response to a signal for supplying power or a signal for stopping power supply from a discharge control unit 96 (described later).

  The streamer discharge unit 80 generates streamer discharge, which is a kind of plasma discharge, when electric power is supplied from the second power supply unit 801 and a high voltage is applied to the needle-like electrode. When this streamer discharge is generated, active species which are ions having high oxidative decomposition power are generated. That is, the streamer discharge unit 80 generates ions by being supplied with power from the second power supply unit 801. The active species generated by the streamer discharge unit 80 rides on the tributary BF passing through the streamer discharge unit 80 and flows into the vertical wind passage member 410. Then, the tributary BF and the active species that have flowed into the vertical wind passage member 410 are discharged from the discharge port 41a, merge with the air flow AF, and pass through the filter unit 30. At this time, the active species decomposes and purifies dust and bacteria adsorbed on the electrostatic dust collection filter 32.

(2-10) Emission ion generation unit 81
The emitted ion generation unit 81 (corresponding to the “discharge unit” described in the claims) is fixed to the scroll casing 52 of the sirocco fan 50 (see FIG. 6). The emitted ion generation unit 81 communicates with the discharge flow path in the scroll casing 52 through a communication port (not shown). The emitted ion generation unit 81 is connected to a third power supply unit 811 (corresponding to the “discharge unit power supply unit” described in the claims) provided inside the electrical component box 43a and is supplied with power. .

  The third power supply unit 811 supplies or blocks power to the emitted ion generation unit 81 in response to a signal for performing power supply or a signal for stopping power supply from a discharge control unit 96 (described later). In the following description, for convenience of description, the first power supply unit 201, the second power supply unit 801, and the third power supply unit 811 are collectively referred to as a “discharge power supply unit”.

  A high voltage electrode and a ground electrode are housed inside the emitted ion generation unit 81, and a linear discharge needle electrode is electrically connected to the high voltage electrode (not shown). The emitted ion generation unit 81 is supplied with electric power from the third power supply unit 811, and generates a strong electric field between the discharge needle electrode and the ground electrode when a negative high voltage is applied from the high voltage electrode to the discharge needle electrode. Let Then, the vicinity of the tip of the discharge needle electrode breaks down to a corona discharge state, and negative ions are generated. That is, the emitted ion generation unit 81 generates ions by being supplied with power from the third power supply unit 811. The produced negative ions flow out into the scroll casing 52 through the communication port.

(2-11) Operation panel 90
The operation panel 90 mainly includes input keys 90a, a display unit 90b, and the like (see FIG. 1). The dehumidifying / humidifying air cleaner 100 receives a command when the user presses the input key 90a.

  The input key 90a includes an operation start key, an operation stop key, an operation mode selection key, an air volume mode selection key, and the like. The operation start key is a button for inputting a command for starting the operation of the dehumidifying / humidifying air cleaner 100 (hereinafter referred to as an operation start command). The operation stop key is a button for inputting a command for stopping the operation of the dehumidifying / humidifying air cleaner 100 (hereinafter referred to as an operation stop command). The operation mode selection key includes a command for operating in the dehumidifying mode (hereinafter referred to as dehumidifying operation command), a command for canceling the dehumidifying mode (hereinafter referred to as dehumidifying release command), and a command for operating in the humidifying mode (hereinafter referred to as humidifying operation command). And a command for releasing the humidification mode (hereinafter referred to as a humidification release command). The air volume mode selection key is a button for the user to select an air volume mode, and is a button for inputting a command for changing the air volume mode (hereinafter referred to as an air volume mode change command).

  The input key 90a includes an eco mode introduction key 90a1. The eco mode introduction key 90a1 is a button for inputting a command for selecting the introduction of the eco mode (hereinafter referred to as an eco mode introduction command). When the introduction of the eco mode is selected, the eco mode is canceled when the eco mode introduction key 90a1 is pressed. A command input through such an input key 90 a is sent to the controller 91.

  The display unit 90b includes a liquid crystal panel, an LED, and the like, and displays the amount of dust, odor, humidity, and the like included in the airflow AF.

(2-12) Controller 91
The controller 91 is disposed inside the electrical component box 43a. The controller 91 is a microcomputer including a RAM, a ROM, a CPU, and the like, and controls the operation of each unit connected via the interface 911.

(3) Details of Controller 91 Details of the controller 91 will be described below with reference to FIG. FIG. 8 is a schematic diagram illustrating a schematic configuration of the controller 91 and devices connected to the controller 91.

  The controller 91, via the interface 911, includes the sensor 45, the input key 90a, the display unit 90b, the outlet blade motor M151, the fan motor driving unit 511, the compressor motor driving unit 621, the humidification unit motor driving unit 711, the first power source. The unit 201, the second power supply unit 801, and the third power supply unit 811 are connected by a wiring 912. The controller 91 executes control of these devices based on a user command input via the input key 90a.

  The controller 91 mainly corresponds to a storage unit 92, a fan control unit 93 (corresponding to “fan control unit” described in claims), and a compressor control unit 94 (corresponding to “dehumidification unit control unit” described in claims). ), A humidification control unit 95 (corresponding to “humidification unit control unit” described in claims), a discharge control unit 96 (corresponding to “discharge unit control unit” described in claims), a display control unit 97, A mode control unit 98 (corresponding to “fan control unit”, “discharge unit control unit”, “dehumidification unit control unit”, and “humidification unit control unit” described in the claims) is configured.

(3-1) Storage unit 92
The storage unit 92 holds a control program corresponding to each operation mode. The storage unit 92 holds detection results sent from the sensor 45 every predetermined period. The storage unit 92 holds a user command input via the input key 90a.

(3-2) Fan control unit 93, compressor control unit 94, humidification control unit 95, discharge control unit 96, display control unit 97, and eco mode control unit 98
The fan control unit 93, the compressor control unit 94, the humidification control unit 95, the discharge control unit 96, the display control unit 97, and the eco mode control unit 98 read a user command stored in the storage unit 92 and respond to the user command. The control program obtained is acquired from the storage unit 92. And control is performed according to the acquired control program.

(3-2-1) Fan Control Unit 93
The fan controller 93 controls the operation of the outlet blade motor M151 and the sirocco fan 50.

  For example, when an operation start command is input by the user and when a sirocco fan operation control signal (described later) is received from the eco mode control unit 98, the fan control unit 93 sends a pulse signal to the outlet blade motor M151. The feed outlet is driven to open the outlet blade 151 to expose the outlet 103 (however, when the outlet blade 151 is already open, no pulse signal is sent to the outlet blade motor M151). Next, the fan control unit 93 sends a signal for driving the fan motor M51 at the designated rotational speed (hereinafter referred to as a designated rotational speed drive control signal) to the fan motor driving unit 511 to drive the sirocco fan 50.

  When the air volume mode change command is input by the user, the fan controller 93 sends a designated rotation speed drive control signal to the fan motor driver 511 to switch the air volume of the sirocco fan 50.

  When receiving a monitoring execution signal (described later) from the eco mode control unit 98, the fan control unit 93 sends a designated rotational speed drive control signal to the fan motor drive unit 511 to drive the sirocco fan 50.

  The fan control unit 93 has six fan control modes including a maximum control mode, a strong control mode, a medium control mode, a weak control mode, a static control mode, and a monitoring control mode. The fan control unit 93 switches the fan control mode when an air volume mode change command is input via the input key 90a and when a monitoring execution signal is received from the eco mode control unit 98. Specifically, the fan control unit 93 performs the medium control when the maximum air volume mode is selected, the maximum control mode is selected, the strong air volume mode is selected, the strong control mode is selected, and the medium air volume mode is selected. When the mode is selected, the control mode is switched to the weak control mode when the mode is selected, and the mode is switched to the static control mode when the mode is selected. In addition, when the fan control unit 93 receives a monitoring execution signal from the eco mode control unit 98, the fan control unit 93 switches the control mode to the monitoring control mode.

  The fan control unit 93 holds in advance a rotation speed table (not shown) indicating the rotation speed of the fan motor M51 determined for each fan control mode, and designates the rotation speed by referring to the rotation speed table. ing. In the rotation speed table, the rotation speed of the fan motor M51 is 7.5 m 3 / min when the air flow AF generated by the sirocco fan 50 is in the maximum control mode, 5.3 m 3 / min when in the strong control mode, and the medium control mode It is set to 4.0 m3 / min in the hour, 2.5 m3 / min in the weak control mode, 1.0 m3 / min in the static control mode, and 0.5 m3 / min in the monitoring control mode. That is, the air volume in the monitoring control mode is smaller than in the other fan control modes, and the rotation speed of the fan motor M51 is switched to the maximum output in the maximum control mode and switched to the minimum output in the monitoring control mode. Therefore, the power consumption of the fan motor M51 is minimized in the monitoring control mode.

  When the operation stop command is input by the user and when a sirocco fan stop signal (described later) is received from the eco mode control unit 98, the fan control unit 93 sends a signal to stop driving the fan motor M51 to the fan motor. This is sent to the drive unit 511. Thereafter, a pulse signal is sent to the blower blade motor M151 to drive it, and the blower blade 151 is closed (however, when a sirocco fan stop signal is received from the eco mode control unit 98, a pulse is sent to the blower blade motor M151. Do not send a signal).

(3-2-2) Compressor control unit 94
The compressor control unit 94 controls the operation of the compressor 62 by controlling the compressor motor driving unit 621.

  For example, when a dehumidifying operation command is input by the user and when a compressor operation signal (described later) is received from the eco mode control unit 98, the compressor control unit 94 generates a signal for driving the compressor motor M62. The refrigerant is sent to the compressor motor drive unit 621 to bring the compressor 62 into an operating state and circulate the refrigerant in the refrigerant circuit of the refrigeration cycle unit 60.

  Further, when the operation stop command or the dehumidification release command is input by the user, and when a compressor stop signal (described later) is received from the eco mode control unit 98, the compressor control unit 94 sets the compressor motor M62. A signal for stopping the driving is sent to the compressor motor driving unit 621 to stop the power supply to the compressor motor M62 and to bring the compressor 62 into a stopped state.

(3-2-3) Humidification control unit 95
The humidification control unit 95 controls the operation of the humidification unit motor M71 by controlling the humidification unit motor drive unit 711.

  For example, when a humidification operation command is input by the user and when a humidification rotor operation signal (described later) is received from the eco mode control unit 98, the humidification control unit 95 sends a signal for driving the humidification unit motor. It sends to the motor drive part 711, and the humidification rotor 71 is rotated.

  Further, when the operation stop command or the humidification release command is input by the user, and when a humidification rotor stop signal (described later) is received from the eco mode control unit 98, the humidification control unit 95 drives the humidification unit motor. A signal to be stopped is sent to the humidifying unit motor driving unit 711 to stop the power supply to the humidifying unit motor and stop the rotation of the humidifying rotor 71.

(3-2-4) Discharge control unit 96
The discharge controller 96 controls the operation of the discharge power supply unit. For example, when an operation start command is input by the user and when a discharge execution signal (described later) is received from the eco mode control unit 98, the discharge control unit 96 supplies a signal for performing power supply to the power supply for discharge. To supply power to the discharge unit.

  In addition, when the operation stop command is input by the user and when a discharge stop signal (described later) is received from the eco mode control unit 98, the discharge control unit 96 supplies a signal for stopping the power supply to supply power for discharge. The power supply to the discharge unit is stopped.

(3-2-5) Display control unit 97
The display control unit 97 controls the operation of the display unit 90b. For example, when an operation start command is input by the user, the display control unit 97 displays on the display unit 90b the selected operation mode, the air volume mode, the presence / absence of eco mode selection, the detection result of the sensor 45, and the like. Display. When the operation stop command is input by the user, the display control unit 97 stops the display on the display unit 90b.

(3-2-6) Eco-mode control unit 98
The eco mode control unit 98 controls operations of the sirocco fan 50, the refrigeration cycle unit 60, the humidification unit 70, and the discharge unit when an eco mode introduction command is input via the eco mode introduction key 90a1. Specifically, the eco mode control unit 98 has a continuous operation mode and an intermittent operation mode as control modes.

  The eco mode control unit 98 continuously operates the sirocco fan 50, the refrigeration cycle unit 60, the humidification unit 70, and the discharge unit in the continuous operation mode. The eco mode control unit 98 transitions to the intermittent operation mode (cancels the continuous operation mode) when the detection result of the sensor 45 satisfies a predetermined condition in the continuous operation mode. In the intermittent operation mode, the eco mode control unit 98 puts the refrigeration cycle unit 60, the humidification unit 70, and the discharge unit in a standby state, and causes the sensor 45 to periodically detect the cleanliness of indoor air. Is intermittently operated. In addition, the eco mode control unit 98 releases the intermittent operation mode (transition to the continuous operation mode) when the detection result of the sensor 45 does not satisfy the predetermined condition in the intermittent operation mode. When the intermittent operation mode is canceled, the eco mode control unit 98 performs control in the continuous operation mode.

  As shown in FIG. 9, the eco mode control unit 98 mainly includes an acquisition unit 981, a determination unit 982, and a signal generation unit 983. The eco mode control unit 98 has a timer function that can measure time, and the acquisition unit 981, the determination unit 982, and the signal generation unit 983 are configured to detect time.

(3-2-6-1) Acquisition unit 981
The acquisition unit 981 acquires the control program from the storage unit 92 when the user inputs an eco mode introduction command via the eco mode introduction key 90a1. The acquisition unit 981 acquires the latest detection result from the sensor 45 from the storage unit 92 every predetermined period (for example, 0.5 seconds). The acquisition unit 981 sends the acquired detection result to the determination unit 982.

(3-2-6-2) Determination unit 982
The determination unit 982 receives the detection result of the sensor 45 sent from the acquisition unit 981, and determines whether or not a predetermined determination item is within a predetermined allowable range. Specifically, the determination unit 982 determines whether or not the amount of dust included in the airflow AF is within a predetermined allowable range, and whether the odor level included in the airflow AF is within the predetermined allowable range. Determine whether or not. In addition, when the dehumidifying operation command or the humidifying operation command is input, the determination unit 982 also determines whether or not the humidity included in the airflow AF is within a predetermined allowable range. Note that the specific numerical range of the allowable range used in the determination is set in advance in the control program acquired by the acquisition unit 981 from the storage unit 92, and can be changed as appropriate.

  When the determination unit 982 determines that any or all of the predetermined determination items are outside the allowable range, the determination unit 982 performs transition to the intermittent operation mode when the determination continues for a predetermined number of times (for example, five times). No determination (or determination to cancel the intermittent operation mode when the operation has already been switched to the intermittent operation mode) is performed. On the other hand, when the determination unit 982 determines that any of the predetermined determination items is within the allowable range, and the determination continues for a predetermined number of times (for example, five times), the determination unit 982 determines to transition to the intermittent operation mode (or When the transition to the intermittent operation mode has already been made, a determination is made to continue the intermittent operation mode).

  The determination unit 982 sends the determination result to the signal generation unit 983.

(3-2-6-3) Signal generator 983
Upon receiving the determination result of the determination unit 982, the signal generation unit 983 generates a control signal and outputs the control signal to the fan control unit 93, the compressor control unit 94, the humidification control unit 95, and the discharge control unit 96.

  Specifically, the signal generation unit 983 receives a determination result of transition to the intermittent operation mode from the determination unit 982 and a signal for stopping the sirocco fan 50 when a predetermined monitoring period (described later) elapses (hereinafter, referred to as a “sirocco fan 50”). A sirocco fan stop signal) is generated and output to the fan controller 93.

  In addition, when the signal generation unit 983 receives a determination result of transition to the intermittent operation mode or a determination result of continuing the intermittent operation mode from the determination unit 982, the signal generation unit 983 stops the compressor 62 (hereinafter referred to as a compressor stop signal). Alternatively, a signal for stopping the humidification rotor 71 (hereinafter referred to as a humidification rotor stop signal) is generated and output to the compressor control unit 94 or the humidification control unit 95 (however, the compressor 62 or the humidification rotor 71 has already stopped). If it is, do not output).

  In addition, when the signal generation unit 983 receives the determination result of transition to the intermittent operation mode or the determination result of continuing the intermittent operation mode from the determination unit 982, the signal generation unit 983 stops the discharge of the discharge unit (hereinafter referred to as a discharge stop signal). Is output to the discharge control unit 96 (however, it is not output when the discharge unit has already stopped discharging).

  Thus, the dehumidifying / humidifying air cleaner 100 shifts to a standby state in which the sirocco fan 50, the compressor 62, the humidifying rotor 71, the discharge unit 20, the streamer discharge unit 80, and the released ion generation unit 81 stop operating (or the standby state is changed). continue.

  In addition, when a predetermined standby period has elapsed since the signal generation unit 983 outputs a sirocco fan stop signal to the fan control unit 93, the signal generation unit 983 detects this and generates a monitoring execution signal and outputs the monitoring execution signal to the fan control unit 93. . Here, the monitoring execution signal is a signal for driving the fan motor M51 with the lowest output in order to generate an air flow AF for causing the sensor 45 to monitor the state of indoor air. In this embodiment, the standby period is set to 5 minutes. Thereby, the dehumidification humidification air cleaner 100 enters into the monitoring period which monitors the condition of indoor air.

  Then, the signal generator 983 detects this when a predetermined monitoring period has elapsed, generates a sirocco fan stop signal and outputs it to the fan controller 93 in order to stop monitoring. In the present embodiment, the monitoring period is set to 1 minute.

  That is, in the transition to the intermittent operation mode, the signal generation unit 983 outputs a monitoring execution signal to the fan control unit 93 when the predetermined standby period elapses, and the sirocco fan when the predetermined monitoring period elapses. The control for outputting the stop signal to the fan controller 93 is repeatedly executed. In other words, the signal generation unit 983 causes the sirocco fan 50 to perform intermittent operation in the intermittent operation mode.

  On the other hand, when the signal generation unit 983 receives from the determination unit 982 a determination result that does not change to the intermittent operation mode or a determination result that cancels the intermittent operation mode (that is, in the continuous operation mode), the selected air volume A signal for operating the sirocco fan 50 in the control mode corresponding to the mode (hereinafter referred to as a sirocco fan operation control signal) is output to the fan control unit 93 (however, the sirocco is controlled in the control mode corresponding to the already selected air volume mode). No output is made when the fan 50 is operating). At the same time, the signal generation unit 983 generates a signal (hereinafter referred to as a discharge execution signal) for discharging the discharge unit and outputs the signal to the discharge control unit 96 (however, the discharge unit has already been discharged). (Do not output if).

  In this case, when a dehumidifying operation command is input, the signal generator 983 outputs a signal for operating the compressor 62 (hereinafter referred to as a compressor operation signal) to the compressor controller 94 (however, (If the compressor 62 is already in operation, it is not output).

  In this case, when the humidification operation command is input, the signal generation unit 983 outputs a signal for operating the humidification rotor 71 (hereinafter referred to as a humidification rotor operation signal) to the humidification control unit 95 (however, already (No output when the humidifying rotor 71 is operating).

(4) Process Flow of Eco Mode Control Unit 98 Hereinafter, an example of a process flow of the eco mode control unit 98 will be described with reference to FIG. FIG. 10 is a flowchart showing a process flow of the eco mode control unit 98. The following is an example of processing, and the eco mode control unit 98 may execute processing of a flow different from this.

  In the present embodiment, the eco-mode control unit 98 performs a flow process as shown in FIG. 10 when an eco-mode introduction command is input when the dehumidifying / humidifying air cleaner 100 is in an operating state.

  In step S <b> 101, the acquisition unit 981 acquires a control program from the storage unit 92. Then, in accordance with the control program, the acquisition unit 981 acquires the latest detection result by the sensor 45 from the storage unit 92 and sends it to the determination unit 982 every predetermined period (for example, 0.5 seconds). Then, the process proceeds to step S102.

  In step S102, the determination unit 982 receives the detection result of the sensor 45 sent from the acquisition unit 981, and determines predetermined determination items (that is, the amount of dust contained in the airflow AF, the odor level, and the dehumidifying operation command). Alternatively, it is determined whether any humidity is within a predetermined allowable range when a humidifying operation command is input. If the determination is NO (that is, if the determination that any or all of the determination items are outside the allowable range is continued five times), the process proceeds to step S103. On the other hand, when the determination is YES (that is, when the determination that all of the determination items are within the allowable range is continued five times), the process proceeds to step S104.

  In step S <b> 103, determination unit 982 determines that the transition to the intermittent operation mode is not performed, and sends the determination result to signal generation unit 983. In response to this, the signal generator 983 generates a sirocco fan operation control signal and outputs it to the fan controller 93 (provided that the sirocco fan 50 is in an operating state in the already selected air volume mode). do not do). When the dehumidifying operation command is input, the signal generation unit 983 generates a compressor operation signal and outputs it to the compressor control unit 94 (however, if the compressor 62 is already in an operating state, it is output). do not do). When the humidifying operation command is input, the signal generating unit 983 generates a humidifying rotor operation signal and outputs it to the humidifying control unit 95 (however, it is not output when the humidifying rotor 71 is already operating). ). Furthermore, the signal generation unit 983 generates a discharge execution signal and outputs it to the discharge control unit 96 (however, it is not output when the discharge unit has already been discharged). Then, the process returns to step S101.

  In step S <b> 104, determination unit 982 determines to transition to the intermittent operation mode, and sends the determination result to signal generation unit 983. Thereby, the control mode of the eco-mode control unit 98 transitions to the intermittent operation mode (cancels the continuous operation mode). Then, the process proceeds to step S105.

  In step S105, the eco mode control unit 98 shifts the dehumidifying / humidifying air cleaner 100 to a standby state. That is, the signal generation unit 983 receives the determination result of transition to the intermittent operation mode from the determination unit 982 (or detects that a predetermined monitoring period has elapsed), generates a sirocco fan stop signal, and the fan control unit To 93. In addition, the signal generation unit 983 receives a determination result of transition to the intermittent operation mode (or continues the intermittent operation mode) of the determination unit 982, generates a compressor stop signal or a humidified rotor stop signal, and performs compressor control. Output to the unit 94 or the humidification control unit 95 (however, it is not output when the compressor 62 or the humidification rotor 71 is already stopped). At the same time, the signal generation unit 983 generates a discharge stop signal and outputs it to the discharge control unit 96 (however, it is not output when the discharge unit has already stopped discharging). Then, the process proceeds to step S106.

  In step S106, the signal generation unit 983 measures time and detects whether or not a predetermined standby period (for example, 5 minutes) has elapsed since the sirocco fan stop signal was output to the fan control unit 93. When this determination is NO (that is, when the standby period of 5 minutes has not elapsed after the sirocco fan stop signal is output to the fan control unit 93), the signal generation unit 983 measures time in step S106. continue. On the other hand, if the determination is YES (that is, if the standby period of 5 minutes has elapsed since the sirocco fan stop signal was output to the fan controller 93), the process proceeds to step S107.

  In step S <b> 107, the signal generation unit 983 generates a monitoring execution signal and outputs the monitoring execution signal to the fan control unit 93. In response to this, the fan control unit 93 sends a designated rotational speed drive control signal to the fan motor drive unit 511 to drive the sirocco fan 50 with the lowest output. Then, the acquisition unit 981 acquires the latest detection result by the sensor 45 from the storage unit 92 and sends it to the determination unit 982 every predetermined period (for example, 0.5 seconds). Then, the process proceeds to step S108.

  In step S108, the determination unit 982 receives the detection result of the sensor 45 sent from the acquisition unit 981, and determines predetermined determination items (that is, the amount of dust contained in the airflow AF, the odor level, and the dehumidifying operation command). Alternatively, it is determined whether any of the humidity is within a predetermined allowable range when a humidifying operation command is input. If the determination is NO (that is, if the determination that any or all of the determination items are outside the allowable range is continued five times), the process proceeds to step S109. On the other hand, when the determination is YES (that is, when the determination that all of the determination items are within the allowable range continues five times), the process proceeds to step S111.

  In step S109, determination unit 982 determines to cancel the intermittent operation mode, and sends the determination result to signal generation unit 983. Thereby, the intermittent operation mode is canceled and the control mode of the eco mode control unit 98 is switched to the continuous operation mode. Then, the process proceeds to step S110.

  In step S <b> 110, the signal generation unit 983 outputs a sirocco fan operation control signal to the fan control unit 93 in response to the determination result of canceling the intermittent operation mode of the determination unit 982. At the same time, the signal generator 983 generates a discharge execution signal and outputs it to the discharge controller 96. When the dehumidifying operation command is input, the signal generation unit 983 outputs a compressor operation signal to the compressor control unit 94. When the humidification operation command is input, the signal generation unit 983 outputs a humidification rotor operation signal to the humidification control unit 95. Then, the process returns to step S101.

  In step S <b> 111, determination unit 982 determines to continue the intermittent operation mode, and sends the determination result to signal generation unit 983. In response to this, the signal generation unit 983 measures time, and detects whether or not a predetermined monitoring period (for example, 1 minute) has elapsed since the monitoring execution signal was output to the fan control unit 93. When this determination is NO (that is, when one minute which is the monitoring period has not elapsed since the monitoring execution signal was output to the fan control unit 93), the signal generation unit 983 returns to Step S108. On the other hand, when the determination is YES (that is, when one minute which is the monitoring period has elapsed since the monitoring execution signal was output to the fan control unit 93), the process returns to step S105.

(5) About the operation state of each part Hereinafter, the operation state of each part when the eco-mode introduction command is input will be described. FIG. 11 is a timing chart showing changes in the state of each part when an eco mode introduction command is input.

  When the operation start command and the dehumidification (or humidification) operation command are input when the dehumidifying / humidifying air cleaner 100 is in the stopped state, the sirocco fan 50 is controlled in the fan control mode by the fan control unit 93 and continuously operated. The At the same time, the compressor 62 (or the humidifying rotor 71) and the discharge unit are in an operating state.

  Next, when an eco-mode introduction command is input and it is determined that any or all of the predetermined determination items are outside the allowable range in the determination by the determination unit 982, the transition to the intermittent operation mode is not performed. Therefore, the sirocco fan 50, the compressor 62 (or the humidification rotor 71), and the discharge unit are controlled in the continuous operation mode by the eco mode control unit 98, and the operation state is continued.

  Thereafter, in the determination by the determination unit 982, if the determination that any of the predetermined determination items is within the allowable range is continued five times, the control mode of the eco mode control unit 98 transitions to the intermittent operation mode (continuous operation mode is changed). The sirocco fan 50, the compressor 62 (or the humidification rotor 71), and the discharge unit are in a standby state in which the operation is stopped.

  When 5 minutes, which is a standby period, elapses, a monitoring period starts and the sirocco fan 50 enters an operating state. The rotation speed of the fan motor M51 during the monitoring period is controlled in the monitoring control mode and switched to the minimum output. Thereafter, in the determination by the determination unit 982, when it is determined that all of the predetermined determination items are within the allowable range, and when 1 minute which is the monitoring period has elapsed, the sirocco fan 50 again becomes a standby period. It will be in a standby state.

  Then, in the determination by the determination unit 982, if the determination that any or all of the predetermined determination items are out of the allowable range continues five times, the intermittent operation mode is canceled (transition to the continuous operation mode), and the sirocco fan 50, the compressor 62 (or the humidification rotor 71) and the discharge unit are controlled in the continuous operation mode and are in an operating state.

(6) Power saving function of the dehumidifying / humidifying emptying machine 100 The dehumidifying / humidifying emptying machine 100 has an eco mode, and also includes an eco mode control unit that controls the eco mode. The eco mode control unit 98 has an intermittent operation mode that is a control mode in which the compressor 62, the humidification rotor 71, and the discharge unit are set in a standby state and the sirocco fan 50 is intermittently operated. In the intermittent operation mode, a monitoring period for driving the sirocco fan 50 is set, and in the monitoring period, the sirocco fan 50 is driven at a rotational speed lower than the rotational speed selected in the continuous operation mode. Therefore, the power consumption of the fan motor M51 in the monitoring period (that is, in the intermittent operation mode) is configured to be reduced from the power consumption in the continuous operation mode. Therefore, in the dehumidifying / humidifying air cleaner 100, the amount of power consumption is suppressed.

(7) Features (7-1)
In the dehumidifying / humidifying air cleaner 100 according to the embodiment, the eco mode control unit 98 has a continuous operation mode in which the sirocco fan 50 performs a continuous operation and an intermittent operation mode in which the sirocco fan 50 performs an intermittent operation. . In the intermittent operation mode, the eco mode control unit 98 causes the fan control unit 93 to drive the sirocco fan 50 for a predetermined monitoring period every time a predetermined standby period elapses. The fan control unit 93 drives the sirocco fan 50 in the monitoring control mode during the monitoring period (that is, in the intermittent operation mode), and the sirocco fan 50 has a smaller air volume than the fan control mode selected in the continuous operation mode in the monitoring control mode. Drive. Thereby, the power consumption in the monitoring period (that is, in the intermittent operation mode) is reduced compared to the power consumption in the continuous mode. Therefore, power consumption is suppressed.

(7-2)
In the dehumidifying / humidifying air cleaner 100 according to the above-described embodiment, the fan motor M51 of the sirocco fan 50 is driven at a lower rotational speed in the monitoring period (that is, in the intermittent operation mode) than in the continuous operation mode. Thereby, the power consumption in the monitoring period (that is, in the intermittent operation mode) is reduced from the power consumption in the continuous operation mode.

(7-3)
In the dehumidifying / humidifying air cleaner 100 according to the above-described embodiment, the fan control unit 93 drives the sirocco fan 50 with a larger air volume than in the monitoring period (that is, in the intermittent operation mode) in the continuous operation mode. Thereby, the power consumption in the monitoring period (that is, in the intermittent operation mode) is reduced from the power consumption in the continuous operation mode.

(7-4)
In the dehumidifying / humidifying air cleaner 100 according to the embodiment described above, in the intermittent operation mode, the eco mode control unit 98 outputs a discharge stop signal to the discharge control unit 96, and the discharge control unit 96 receiving the discharge stop signal is supplied to the discharge power supply unit. The power supply to the discharge unit is stopped. Thereby, the power consumption in the intermittent operation mode is further reduced.

(7-5)
In the dehumidifying / humidifying air cleaner 100 according to the above embodiment, in the intermittent operation mode, the eco mode control unit 98 outputs a compressor stop signal to the compressor control unit 94, and the compressor control unit 94 receiving the compressor stop signal is the compressor motor. The drive unit 621 stops power supply to the compressor motor M62. Thereby, the power consumption in the intermittent operation mode is further reduced.

(7-6)
In the dehumidifying / humidifying air cleaner 100 according to the above-described embodiment, in the intermittent operation mode, the eco mode control unit 98 outputs a humidifying rotor stop signal to the humidifying control unit 95, and the humidifying control unit 95 receiving this signal drives the humidifying unit motor. The unit 711 stops the power supply to the humidification unit motor. Thereby, the power consumption in the intermittent operation mode is further reduced.

(8) Modification (8-1) Modification 1A
In the said embodiment, although the dehumidification humidification air cleaner 100 was a floor-standing type, it is not limited to this, For example, a wall hanging type and a hanging type may be sufficient.

(8-2) Modification 1B
In the above embodiment, the main body casing 10 is composed of the back surface portion 12, the left side wall portion 13, the left side suction port forming portion 14a, the right side suction port forming portion 14b, the ceiling portion 15, the front panel 16, and the like. However, the present invention is not limited thereto, and these may be integrally formed.

(8-3) Modification 1C
In the said embodiment, although the filter unit 30 was mainly comprised from the pre filter 31, the electrostatic dust collection filter 32, and the deodorizing filter 33, it is not necessarily limited to such a structure. For example, the deodorizing filter 33 may be omitted. Further, instead of the electrostatic dust collection filter 32, a non-electric dust collection type HEPA filter or the like may be used. When a filter that is not an electrostatic dust collection method is employed instead of the electrostatic dust collection filter 32, the discharge unit 20 and the first power supply unit 201 may be omitted.

(8-4) Modification 1D
In the above embodiment, the sensor 45 A / D-converts the detection result and sends it to the controller 91, but the present invention is not limited to this. For example, the sensor 45 may send an analog value as a detection result to the controller 91.

(8-5) Modification 1E
In the embodiment, the dehumidifying / humidifying air cleaner 100 includes the discharge unit 20, the refrigeration cycle unit 60, the humidification unit 70, the streamer discharge unit 80, and the released ion generation unit 81. However, these devices and related devices may be omitted as appropriate.

(8-6) Modification 1F
In the above embodiment, the humidifying unit 70 humidifies the airflow AF by the humidifying rotor 71 including a vaporization filter. However, the humidification unit 70 is not limited to one that performs humidification in such a manner, and may be any unit that performs humidification. For example, the humidification unit 70 may perform humidification by a steam humidification method using a heater.

(8-7) Modification 1G
In the above embodiment, the controller 91 is disposed in the electrical component box 43a, but is not limited thereto. For example, the controller 91 may be independently provided below the operation panel 90. Further, the controller 91 is not necessarily provided in the main body casing 10, and may be provided outside the main body casing 10.

  In addition, any or all of the storage unit 92, the fan control unit 93, the compressor control unit 94, the humidification control unit 95, the discharge control unit 96, the display control unit 97, and the eco mode control unit 98 included in the controller 91 are connected to the LAN. Or a remote location connected by a network such as WAN.

(8-8) Modification 1H
In the above embodiment, the controller 91 includes the storage unit 92, the fan control unit 93, the compressor control unit 94, the humidification control unit 95, the discharge control unit 96, the display control unit 97, and the eco mode control unit 98. However, the present invention is not limited to this. For example, the eco mode control unit 98 may be omitted, and the function of the eco mode control unit 98 may be assigned to the fan control unit 93, the compressor control unit 94, the humidification control unit 95, and the discharge control unit 96.

(8-9) Modification 1I
In the above-described embodiment, the fan control unit 93 holds in advance a rotation speed table indicating the rotation speed of the fan motor M51 determined for each fan control mode. However, the present invention is not limited to this, and the fan control unit 93 may acquire the rotation speed table from the storage unit 92.

(8-10) Modification 1J
In the above embodiment, the fan control unit 93, the compressor control unit 94, the humidification control unit 95, the discharge control unit 96, the display control unit 97, and the eco mode control unit 98 have acquired the control program from the storage unit 92. However, the present invention is not limited to this. For example, each of the fan control unit 93, the compressor control unit 94, the humidification control unit 95, the discharge control unit 96, the display control unit 97, and the eco mode control unit 98 has a predetermined storage area. The control program may be stored in the storage area.

(8-11) Modification 1K
In the above embodiment, the eco mode control unit 98 generates a control signal by the signal generation unit 983 and outputs the control signal to the fan control unit 93, the compressor control unit 94, the humidification control unit 95, and the discharge control unit 96. Although the operations of the fan 50, the compressor 62, the humidification rotor 71, and the discharge unit are controlled, the present invention is not limited to this.

  For example, the eco mode control unit 98 may control the operation of the sirocco fan 50 by outputting a control signal to the fan motor drive unit 511 instead of the fan control unit 93. Further, the eco mode control unit 98 may control the operation of the compressor 62 by outputting a control signal to the compressor motor drive unit 621 instead of the compressor control unit 94. Further, the eco mode control unit 98 may control the operation of the humidification rotor 71 by outputting a control signal to the humidification unit motor drive unit 711 instead of the humidification control unit 95. Further, the eco mode control unit 98 may control the operation of the discharge unit by outputting a control signal to the discharge power supply unit instead of the discharge control unit 96.

(8-12) Modification 1L
In the above embodiment, the acquisition unit 981 acquires the latest detection result from the sensor 45 from the storage unit 92 every 0.5 seconds, which is a predetermined period, but is not limited thereto. For example, the acquisition unit 981 may acquire the latest detection result by the sensor 45 from the storage unit 92 every 2 seconds, and the predetermined period can be appropriately changed.

(8-13) Modification 1M
In the above embodiment, the determination unit 982 is configured to perform a predetermined determination when the predetermined determination item is determined to be within the allowable range or out of the allowable range and the determination is continued five times. . However, the number of determinations can be changed as appropriate. For example, when the determination unit 982 determines that the predetermined determination item is within the allowable range or out of the allowable range, the determination unit 982 may be configured to perform the predetermined determination when the determination continues 10 times. A predetermined determination may be made if the determination is made once.

(8-14) Modification 1N
In the above embodiment, the specific numerical range of the allowable range used for the determination by the determination unit 982 is set in advance in the control program, but is not limited to this. For example, the determination unit 982 may hold a specific numerical range within the allowable range in advance.

(8-15) Modification 1O
In the above embodiment, the signal generation unit 983 detects this when a standby period of 5 minutes has elapsed since the sirocco fan stop signal is output to the fan control unit 93, generates a monitoring execution signal, and performs fan control. Output to the unit 93. However, the waiting period is not limited to 5 minutes and can be changed as appropriate. For example, the standby period may be 10 minutes.

  Further, the signal generation unit 983 detects this when a monitoring period of 1 minute has elapsed, generates a sirocco fan stop signal and outputs it to the fan control unit 93 in order to stop monitoring. However, the monitoring period is not limited to 1 minute and can be changed as appropriate. For example, the monitoring period may be 3 minutes.

(8-16) Modification 1P
In the above embodiment, when the signal generation unit 983 receives a determination result from the determination unit 982 that does not perform transition to the intermittent operation mode or a determination result that cancels the intermittent operation mode, when the dehumidifying operation command is input. The compressor operation signal is output to the compressor control unit 94, and the humidification rotor operation signal is output to the humidification control unit 95 when the humidification operation command is input. However, the signal generation unit 983 is not limited to this, and the humidity is within an allowable range even when the signal generation unit 983 receives a determination result from the determination unit 982 that does not perform transition to the intermittent operation mode or a determination result that cancels the intermittent operation mode. In such a case, the compressor operation signal and the humidification rotor operation signal may not be output.

Second Embodiment
The present invention is also applicable to a dehumidified / humidified air cleaner (hereinafter referred to as a dehumidified / humidified air cleaner) 110 as shown in FIG. Hereinafter, the dehumidifying / humidifying air cleaner 110 according to the second embodiment of the present invention will be described. The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention, and can be modified as appropriate without departing from the scope of the invention. 1 to 6, 9, and 10 are common to the dehumidifying / humidifying air cleaner 100. 8, the fan motor driving unit 511 is the fan motor driving unit 511a, the controller 91 is the controller 91a, the fan control unit 93 is the fan control unit 93a, and the eco mode control unit 98 is the eco mode control unit 98a. It is the same as the dehumidifying / humidifying air cleaner 100 except that it changes.

(1) Dehumidifying / humidifying air cleaner 110
FIG. 12 is a schematic diagram showing the internal configuration of the dehumidifying / humidifying air cleaner 110. The dehumidifying / humidifying air cleaner 110 corresponds to a mini fan 55 (corresponding to “second fan” described in claims) separately from the sirocco fan 50 (corresponding to “first fan” recited in claims) in the main body casing 10. ) Is provided. The mini fan 55 is provided in the vicinity of the blower outlet 103, for example.

  The mini fan 55 is driven only during the monitoring period. That is, the mini fan 55 is a dedicated fan for monitoring. The mini fan 55 has a lower capacity than the sirocco fan 50, and is a small cross flow fan, for example. The air volume of the mini fan 55 is smaller than that of the sirocco fan 50. Specifically, the air volume generated by the mini fan 55 is 0.5 m <3> / min. The mini fan 55 is driven with less power consumption than the sirocco fan 50.

  The mini fan 55 is connected to the fan motor M55. The fan motor M55 is driven by being supplied with electric power from the fan motor driving unit 511a. The fan motor drive unit 511a receives a signal from the fan control unit 93a and supplies power so that the fan motor M51 and the fan motor M55 are driven at the number of rotations specified in the signal. Note that the rotation speed of the fan motor M55 is constant.

  The controller 91a is connected to the fan motor drive unit 511a instead of the fan motor drive unit 511, is provided with a fan control unit 93a instead of the fan control unit 93, and is replaced with the eco mode control unit 98. The controller 91 is the same as the controller 91 except that an eco mode control unit 98a is provided.

  The eco mode control unit 98a continuously operates the sirocco fan 50, the refrigeration cycle unit 60, the humidification unit 70, and the discharge unit in the continuous operation mode. The eco mode control unit 98a transitions to the intermittent operation mode (cancels the continuous operation mode) when the detection result of the sensor 45 satisfies a predetermined condition in the continuous operation mode. In the intermittent operation mode, the eco mode control unit 98a places the sirocco fan 50, the refrigeration cycle unit 60, the humidification unit 70, and the discharge unit in a standby state, and causes the sensor 45 to periodically detect the cleanliness of indoor air. The mini fan 55 is operated intermittently. Further, the eco mode control unit 98a cancels the intermittent operation mode (transition to the continuous operation mode) when the detection result of the sensor 45 does not satisfy the predetermined condition in the intermittent operation mode. When the intermittent operation mode is canceled, the eco mode control unit 98a performs control in the continuous operation mode.

  The processing of the eco mode control unit 98a is the same as that of the eco mode control unit 98 except for the processing of the signal generation unit 983. When the signal generation unit 983 receives the determination result of transition to the intermittent operation mode or the determination result of continuing the intermittent operation mode from the determination unit 982, the signal generation unit 983 outputs a sirocco fan stop signal, a compressor stop signal, a humidification rotor stop signal, and a discharge stop signal. Generated and output to the fan control unit 93a, the compressor control unit 94, the humidification control unit 95, and the discharge control unit 96 (however, all of the sirocco fan 50, the compressor 62, the humidification rotor 71, and the discharge control unit 96 are already provided). Is not output if is stopped). As a result, the dehumidifying / humidifying air cleaner 110 shifts to a standby state where the sirocco fan 50, the compressor 62, the humidifying rotor 71, and the discharge unit stop operating (or continues the standby state).

  In addition, when a predetermined standby period has elapsed since the signal generation unit 983 outputs a sirocco fan stop signal to the fan control unit 93a, the signal generation unit 983 detects this and generates a monitoring execution signal and outputs it to the fan control unit 93a. . Here, the monitoring execution signal is a signal for driving the fan motor M55 so as to generate an air flow AF for causing the sensor 45 to monitor the state of indoor air. In the present embodiment, the waiting period is set to 5 minutes. Thereby, the dehumidification / humidification air cleaner 110 enters a monitoring period in which the state of indoor air is monitored.

  The signal generation unit 983 detects this when a predetermined monitoring period has elapsed, generates a signal for stopping the mini fan 55 (hereinafter referred to as a mini fan stop signal) to stop monitoring, and stops the monitoring. It outputs to the control part 93a. In the present embodiment, the monitoring period is set to 1 minute.

  That is, in the transition to the intermittent operation mode, the signal generation unit 983 outputs a monitoring execution signal to the fan control unit 93a when the predetermined standby period has elapsed, and the mini fan when the predetermined monitoring period has elapsed. The control for outputting the stop signal to the fan controller 93a is repeatedly executed. In other words, the signal generation unit 983 causes the mini fan 55 to perform intermittent operation in the intermittent operation mode.

  Further, the signal generation unit 983 also outputs a mini fan stop signal to the fan control unit 93a when the determination result of canceling the intermittent operation mode is received from the determination unit 982 (however, the mini fan 55 is already stopped). (Do not output if).

  Further, when the signal generation unit 983 receives from the determination unit 982 a determination result for canceling the intermittent operation mode or a determination result for not making a transition to the intermittent operation mode, the signal generation unit 983 outputs a sirocco fan operation control signal to the fan control unit 93a. (However, no output is made when the sirocco fan 50 is operating in the control mode corresponding to the already selected air volume mode). At the same time, the signal generation unit 983 generates a discharge execution signal and outputs it to the discharge control unit 96 (however, it is not output when the discharge unit has already been discharged).

  In this case, when the dehumidifying operation command is input, the signal generation unit 983 outputs a compressor operation signal to the compressor control unit 94 (however, if the compressor 62 is already in an operating state, the output is performed). do not do). In this case, when the humidification operation command is input, the signal generation unit 983 outputs the humidification rotor operation signal to the humidification control unit 95 (however, it is not output when the humidification rotor 71 is already operating). ).

  When the fan control unit 93a receives a monitoring execution signal from the eco mode control unit 98a, the fan control unit 93a sends a signal for driving the fan motor M55 to the fan motor driving unit 511a to drive the mini fan 55. When the fan control unit 93a receives the mini fan stop signal from the eco mode control unit 98a, the fan control unit 93a sends a signal for stopping the driving of the fan motor M55 to the fan motor driving unit 511a.

  Accordingly, the mini fan 55 is driven during the monitoring period. In the continuous operation mode, the mini fan 55 stops operating and the sirocco fan 50 is driven.

  The dehumidifying / humidifying air cleaner 110 has the same configuration as the dehumidifying / humidifying air cleaner 100 except for the points described above.

(2) Operational state of each part of dehumidification / humidification air cleaner 110 Hereinafter, the operation state of each part when the eco-mode introduction command is input in the dehumidification / humidification air cleaner 110 will be described. FIG. 13 is a timing chart showing changes in the state of each part when an eco-mode introduction command is input in the dehumidifying / humidifying air cleaner 110.

  When the operation start command and the dehumidification (or humidification) operation command are input when the dehumidification / humidification air cleaner 110 is in the stopped state, the sirocco fan 50 is controlled in the fan control mode by the fan control unit 93a and continuously operated. The At the same time, the compressor 62 (or the humidifying rotor 71) and the discharge unit are in an operating state. At this time, the mini fan 55 is in a stopped state.

  Next, when the eco mode introduction command is input and the determination by the determination unit 982 continues to determine that any or all of the predetermined determination items are outside the allowable range, the transition to the intermittent operation mode is performed. Therefore, the sirocco fan 50, the compressor 62 (or the humidifying rotor 71), and the discharge unit are controlled in the continuous operation mode by the eco mode control unit 98a and continue to operate. At this time, the mini fan 55 is in a stopped state.

  Thereafter, in the determination by the determination unit 982, if the determination that any of the predetermined determination items is within the allowable range continues five times, the control mode of the eco mode control unit 98a transitions to the intermittent operation mode (that is, continuous operation). The mode is released), and the sirocco fan 50, the mini fan 55, the compressor 62 (or the humidification rotor 71), and the discharge unit are in a standby state in which the operation is stopped.

  Then, when 5 minutes, which is a standby period, elapses, the monitoring period starts and the mini fan 55 enters an operating state. Thereafter, in the determination by the determination unit 982, it is determined that all of the predetermined determination items are within the allowable range, and when the monitoring period of 1 minute elapses, the standby period again becomes the mini fan 55 and the mini fan 55 is on standby. It becomes a state.

  Then, in the determination by the determination unit 982, when the determination that any or all of the predetermined determination items are out of the allowable range is continued five times, the intermittent operation mode is canceled (that is, transition to the continuous operation mode), and The mini fan 55 is stopped. And the sirocco fan 50, the compressor 62 (or humidification rotor 71), and a discharge part are controlled by a continuous operation mode, and will be in an operation state.

(3) Features of the dehumidifying / humidifying air cleaner 110 In the dehumidifying / humidifying air cleaner 110, the sirocco fan 50 and the mini fan 55 that are accommodated in the main body casing 10, take in indoor air into the main body casing 10, and discharge the air outside the main body casing 10. Is provided. The eco mode control unit 98a continuously operates the sirocco fan 50 in the continuous operation mode, stops the sirocco fan 50 in the intermittent operation mode, and operates the mini fan 55 for a predetermined monitoring period every predetermined period. The fan control unit 93a drives the mini fan 55 in the monitoring control mode during the monitoring period (that is, in the intermittent operation mode), and the mini fan 55 has a smaller air volume than the fan control mode selected in the continuous operation mode in the monitoring control mode. Drive. Thereby, the power consumption in the monitoring period (that is, in the intermittent operation mode) is reduced compared to the power consumption in the continuous mode. Therefore, power consumption is suppressed.

(4) Modification (4-1) Modification 2A
In the above embodiment, the mini fan 55 is disposed in the vicinity of the air outlet 103 in the main body casing 10. However, the present invention is not limited to this, and the mini fan 55 may be disposed anywhere in the main body casing 10. Further, the mini fan 55 may be disposed outside the main body casing 10.

(4-2) Modification 2B
In the above embodiment, the mini fan 55 is a cross flow fan, but is not limited thereto, and may be another type of fan such as a propeller fan.

(4-3) Modification 2C
In the above embodiment, the fan motor M55 is driven by supplying power to the fan motor driving unit 511a. However, the fan motor M55 is not necessarily supplied with power to the fan motor drive unit 511, and may be driven by being supplied with power from a drive unit different from the fan motor drive unit 511a.

  Further, although the rotation speed of the fan motor M55 is constant, the rotation speed of the fan motor M55 may be variable.

  The present invention can be used for an air purifier that harmonizes air in a target space.

10 Main body casing (casing)
20 discharge unit 30 filter unit 32 electrostatic dust collection filter 40 frame 45 sensor (cleanness sensor)
50 Sirocco fan (fan, first fan)
51 Fan rotor 52 Scroll casing 55 Mini fan (second fan)
60 Refrigeration cycle unit (dehumidification unit)
61 Evaporator 62 Compressor 63 Condenser 64 Capillary tube 65 Refrigerant piping 70 Humidification unit 71 Humidification rotor (humidification filter)
80 Streamer discharge unit (discharge unit)
81 Emitted ion generation unit (discharge unit)
90 Operation panel 90a Input key 90a1 Eco mode introduction key 90b Display unit 91, 91a Controller 92 Storage unit 93, 93a Fan control unit 94 Compressor control unit (dehumidification unit control unit)
95 Humidification control unit (humidification unit control unit)
96 Discharge Control Unit (Discharge Unit Control Unit)
97 Display control unit 98, 98a Eco mode control unit (fan control unit, dehumidification unit control unit, humidification unit control unit, discharge unit control unit)
100, 110 Dehumidifying / humidifying air purifier (air purifier)
101 Lower suction port 102 Side suction port 103 Outlet 201 First power supply unit (electric power supply unit for discharge unit)
511 Fan motor drive unit 621 Compressor motor drive unit (dehumidification unit power supply unit)
711 Humidification unit motor drive section (humidification unit power supply section)
801 Second power supply unit (electric power supply unit for discharge unit)
811 Third power supply unit (electric power supply unit for discharge unit)
981 Acquisition unit 982 Judgment unit 983 Signal generation unit AF Air flow BF Tributary M50, M55 Fan motor M62 Compressor motor M151 Outlet blade motor

JP 2012-57887 A

Claims (7)

An air purifier that harmonizes the air in the target space,
A casing (10);
A fan (50, 55) that is accommodated in the casing, takes air in the target space into the casing, and discharges the air out of the casing;
A cleanliness sensor (45) for detecting the cleanliness of the air in the target space taken into the casing;
A fan control unit (93, 93a, 98, 98a) which has a plurality of control modes and controls driving of the fan;
With
The control mode is
Continuous operation mode for continuously operating the fan;
Intermittent operation mode for intermittent operation of the fan;
Including
The fan controller is
Transition to the intermittent operation mode when the detection result of the cleanliness sensor satisfies a predetermined condition in the continuous operation mode,
In the intermittent operation mode, in order to cause the cleanliness sensor to detect the cleanliness periodically, the fan is operated for a predetermined time every predetermined period,
During the light wind operation, the fan is driven with a smaller air volume than in the continuous operation mode.
Air purifier (100, 110). The fan is driven at a lower rotational speed than the rotational speed selected in the continuous operation mode during the light wind operation.
The air cleaner (100) according to claim 1. The fan includes a first fan (50) and a second fan (55),
The fan controller is
During the continuous operation mode, the first fan is continuously operated,
In the intermittent operation mode, the first fan is stopped and the second fan is operated for a predetermined time every predetermined period.
The air cleaner (110) according to claim 1. The fan control unit drives the fan with an air volume selected from a plurality of set air volumes larger than those during the light wind operation during the continuous operation mode.
The air cleaner according to any one of claims 1 to 3. A discharge unit (20, 80, 81) for generating ions by being supplied with electric power;
A discharge unit power supply unit (201, 801, 811) for supplying power to the discharge unit;
A discharge unit controller (96, 98, 98a) for controlling the power supply unit for the discharge unit;
Further comprising
The discharge unit control unit stops power supply to the discharge unit by the discharge unit power supply unit during the intermittent operation mode.
The air cleaner according to any one of claims 1 to 4. A dehumidifying unit (60) for dehumidifying the air in the target space taken into the casing by being driven by electric power; and
A dehumidifying unit power supply unit (621) for supplying power to the dehumidifying unit;
A dehumidifying unit controller (94, 98, 98a) for controlling the dehumidifying unit power supply unit;
Further comprising
The dehumidifying unit control unit stops power supply to the dehumidifying unit by the dehumidifying unit power supply unit during the intermittent operation mode.
The air cleaner according to any one of claims 1 to 5. A humidification unit (70) for humidifying the air in the target space taken into the casing by being driven by electric power; and
A humidifying unit power supply unit (711) for supplying power to the humidifying unit;
A humidifying unit control unit (95, 98, 98a) for controlling the humidifying unit power supply unit;
Further comprising
The humidifying unit control unit stops power supply to the humidifying unit by the humidifying unit power supply unit during the intermittent operation mode.
The air cleaner according to any one of claims 1 to 6.

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