JP7244766B2 - Humidification unit - Google Patents

Description

The present disclosure relates to humidification units.

Patent Literature 1 discloses a humidity control device for humidifying a room. This humidity control apparatus includes a housing that accommodates a heater, a humidity control member, a first blower, and a second blower. The housing is formed with a first flow path for discharging the air introduced from the outdoors by the first blower to the outside, and a second flow path for supplying the air introduced from the outdoors by the second blower into the room. ing.

In the first flow path, a humidity control member and a first blower are arranged in order from the upstream side to the downstream side. In the second flow path, a heater, a humidity control member, and a second blower are arranged in this order from the upstream side to the downstream side. The air flowing through the first flow path absorbs moisture on the humidity control member and is discharged to the outside. The air flowing through the second flow path is warmed by the heater, humidified by the humidity control member, and supplied into the room.

Japanese Patent Application Laid-Open No. 2006-170492

The humidity control apparatus may perform a ventilation operation for ventilating the room in addition to the humidification operation for humidifying the room as described above. In the ventilation operation, the heater and the humidity control member are not operated, so the air flowing through the second flow path is supplied indoors by the second blower without being heated and humidified.

When the air volume setting of the second blower is the same during the humidification operation and during the ventilation operation, if the second blower is operated at the same rotation speed, the heater is operated during the humidification operation. The air temperature around the fan is higher than during ventilation operation. When the air temperature rises in this way, the air density becomes low, so the air volume of the second blower is reduced.

An object of the present disclosure is to provide a humidification unit that can increase the air volume of a fan that blows air into a target space during humidification operation.

(1) The present disclosure is a humidification unit that performs a humidification operation for humidifying a target space and a ventilation operation for ventilating the target space,
an adsorption member having a moisture absorption area that adsorbs moisture and a moisture release area that releases moisture;
a first fan that takes in air from the outdoors during the humidification operation and the ventilation operation, and generates a first air flow so as to blow the taken-in air into the target space via the moisture desorption region of the adsorption member;
a heater disposed on the upstream side of the first airflow relative to the first fan and heating the air taken in from the outdoors by the first fan during the humidification operation;
a control device that controls the rotation speed of the first fan,
When the air volume setting of the first fan is the same during the humidification operation and during the ventilation operation, the rotation speed of the first fan controlled by the control device during the humidification operation is the same as that of the control device during the ventilation operation. is greater than the rotational speed of the first fan controlled by

According to the humidifying unit configured in this way, the air temperature around the first fan during the humidifying operation is higher than when the number of revolutions of the first fan is the same during the humidifying operation and during the ventilation operation. As it becomes lower, the air density around the first fan becomes higher. As a result, it is possible to increase the air volume of the first fan that blows air into the target space during the humidification operation.

(2) The humidification unit takes in air from outdoors during the humidification operation and the ventilation operation, and generates a second air flow so as to discharge the taken-in air to the outdoors through the moisture absorption region of the adsorption member. a second fan;
a common air passage through which the first air flow and the second air flow pass;
It is preferable that the first fan and the second fan distribute the first air flow and the second air flow that have passed through the air passage in different directions.

In such a configuration, during the humidification operation, the air in the first air flow is heated by the heater arranged on the upstream side of the first air flow from the first fan. An air temperature difference occurs with the surroundings, and the air temperature difference causes a static pressure difference. If such a static pressure difference occurs, the air volume balance between the air volume of the first fan and the air volume of the second fan will be lost, and the air volume of the first fan will decrease. However, since the rotation speed of the first fan is higher during humidification operation than during ventilation operation, compared to the case where the rotation speed of the first fan is the same during humidification operation and ventilation operation, the rotation speed of the first fan is lower. Air volume increases. As a result, even if the static pressure difference occurs, it is possible to prevent the air volume balance between the air volume of the first fan and the air volume of the second fan from being lost.

(3) The humidification unit takes in air from outdoors during the humidification operation and the ventilation operation, and generates a second air flow so as to discharge the taken-in air to the outdoors through the moisture absorption region of the adsorption member. a second fan;
It is preferable to further include a housing that accommodates the first fan and the second fan.
In such a configuration, since the first fan and the second fan are housed in a limited space within the housing, one of these fans must be a small fan. At that time, if the first fan is a small fan, the air volume of the first fan will further decrease. However, even in such a case, the air volume of the first fan can be increased by controlling the control device so that the number of revolutions of the first fan is higher during the humidification operation than during the ventilation operation.

(4) Preferably, the humidifying unit further comprises a duct for taking in the air of the first airflow from outdoors.
In such a configuration, the duct increases the resistance of the first air flow, which further reduces the air volume of the first fan. However, even in such a case, the air volume of the first fan can be increased by controlling the control device so that the number of revolutions of the first fan is higher during the humidification operation than during the ventilation operation.

It is a mimetic diagram of a humidification unit concerning an embodiment. It is an external appearance perspective view of the housing|casing of a humidification unit. 4 is a schematic plan view with the top plate of the housing removed; FIG. It is a schematic bottom view with the panel of the housing removed. 4 is a schematic front view of the housing with the front plate removed; FIG. It is a top view of a moisture absorption rotor. It is an exploded perspective view showing a moisture absorption rotor. It is a perspective view of a heater. 4 is a flowchart showing an example of control of the first fan by the control device;

Hereinafter, embodiments will be described with reference to the accompanying drawings.
<Overall configuration of humidifying unit>
FIG. 1 is a schematic diagram of a humidification unit according to an embodiment.
The humidification unit 3 humidifies and ventilates the target space S1. The target space S1 is, for example, a space in a room partitioned by a ceiling wall 4, a side wall 5, and a floor wall (not shown).

The humidification unit 3 introduces outdoor air, humidifies it, and releases the humidified air into the target space S1. The humidification unit 3 includes a moisture absorption rotor 41 , a heater 42 , a first fan 43 , a second fan 44 , a temperature/humidity sensor 45 , a control device 46 , a housing 47 , an introduction duct 48 and an exhaust duct 49 .

A housing 47 accommodates the devices 41 to 46 described above. The housing 47 has a housing main body 50 , a panel 51 , an introduction connecting pipe 52 and an exhaust connecting pipe 53 . Most of the housing body 50 is arranged in the ceiling space S2. A lower end portion of the housing body 50 is arranged so as to penetrate the ceiling wall 4 . The ceiling space S2 is a space formed above the ceiling wall 4 . The lower end of the housing body 50 is open and closed by a panel 51 .

The panel 51 is detachably attached to the lower end of the housing body 50 . The entire lower surface of the panel 51 is exposed to the target space S1. The panel 51 is formed with openings 54 and 72 that communicate the inside of the housing body 50 and the target space S1. The opening includes an air outlet 54 for blowing air from the housing body 50 to the target space S1. A humidity sensor 60 that detects the humidity of the air blown out from the air outlet 54 is provided near the air outlet 54 . The opening includes an inflow port 72 that allows the air in the target space S1 to flow into the housing body 50 . A temperature/humidity sensor 45 is provided near the inlet 72 to detect the temperature and humidity of the air flowing into the target space S1 from the inlet 72 .

One end of the introduction connection pipe 52 and one end of the discharge connection pipe 53 are connected to the housing body 50 . An opening on the other end side of the introduction connecting pipe 52 is an intake port 55 for taking in outdoor air. An opening on the other end side of the discharge connecting pipe 53 is a discharge port 56 for discharging air to the outdoors. The intake port 55 and the discharge port 56 may be configured by openings formed in the wall surface of the housing body 50 without using the introduction connection pipe 52 and the discharge connection pipe 53 .

The housing 47 has a first air passage P1 and a second air passage P2. The first air passage P1 and the second air passage P2 are "humidifying air passages" used for humidifying the target space S1. The first air passage P<b>1 is an air passage through which outdoor air is introduced from the intake port 55 into the housing body 50 and flows to the blowout port 54 . The second air passage P<b>2 is an air passage through which outdoor air is introduced from the intake port 55 into the housing body 50 and flows to the exhaust port 56 .

The housing 47 further has a third air passage P3 and a fourth air passage P4.
The third air passage P3 is a "state detection air passage" used to detect the temperature and humidity, which are the states of the air in the target space S1. The air in the target space S1 that has flowed into the housing 47 from the inlet 72 flows through the third air passage P3. The third air passage P3 merges with the second air passage P2. The air flowing through the third air passage P3 is discharged from the discharge port 56 together with the air flowing through the second air passage P2.

The fourth air passage P4 is a “cooling air passage” used for cooling heat-generating components included in the control device 46 . Outdoor air introduced into the housing 47 from the intake port 55 flows through the fourth air passage P4. The fourth air passage P4 merges with the second air passage P2 after cooling the heat generating component. The air flowing through the fourth air passage P4 is discharged from the discharge port 56 together with the air flowing through the second air passage P2.

One end of the introduction duct 48 is connected to the introduction connection pipe 52 of the housing 47 . The other end of the introduction duct 48 penetrates the side wall 5 and communicates with the outdoors. The introduction duct 48 of this embodiment includes a first introduction duct for taking in outdoor air from the intake port 55 into the first air passage P1, and a second introduction duct for taking in outdoor air from the intake port 55 into the second air passage P2. 2 It also serves as an introduction duct.

One end of the discharge duct 49 is connected to the discharge connecting pipe 53 of the housing 47 . The other end of the discharge duct 49 penetrates the side wall 5 and communicates with the outside. The air flowing through the second air passage P2 is discharged to the outside through the discharge port 56 and the discharge duct 49 .

A moisture absorption rotor (adsorption device) 41 is arranged in the middle of the first air passage P1 and the second air passage P2. The moisture absorption rotor 41 is configured to absorb moisture from the air flowing through the second air passage P2 and release the moisture to the air flowing through the first air passage P1 to humidify the air. The heater 42 is provided in the middle of the first air passage P1, and heats the pre-humidified air flowing through the first air passage P1.

The first fan 43 is arranged near the outlet 54 in the first air passage P1. The first fan 43 generates airflow in the first air passage P1. Specifically, the first fan 43 introduces the outdoor air into the first air passage P1 through the introduction duct 48, and blows it out from the outlet 54 through the moisture absorption rotor 41 into the target space S1. are placed in

The second fan 44 is arranged near the outlet 56 in the second air passage P2. The second fan 44 generates an air flow within the second air passage P2. Specifically, the second fan 44 is positioned so that it can introduce the outdoor air into the second air passage P2 via the introduction duct 48 and discharge it to the outdoors from the outlet 56 via the moisture absorbing rotor 41. are placed. The second fan 44 also creates airflow in the third air passage P3 and the fourth air passage P4.

The temperature/humidity sensor 45 is provided inside the housing body 50 and detects the temperature and humidity of the air in the target space S1. The humidity sensor 60 is provided inside the housing body 50 and detects the humidity of the air blown into the target space S1. Detected values of the temperature/humidity sensor 45 and the humidity sensor 60 are input to the control device 46 . Rotation detection sensors (not shown) such as encoders are provided for the first fan 43 and the second fan 44 , and detection values of the rotation detection sensors are also input to the control device 46 .
The control device 46 controls the operation of the moisture absorbing rotor 41 , the heater 42 , the first fan 43 and the second fan 44 based on the detection values of the various sensors 45 and 60 .

The humidification unit 3 performs "humidification operation" and "ventilation operation". In the humidification operation, the control device 46 operates the moisture absorption rotor 41 , the heater 42 , the first fan 43 and the second fan 44 . As a result, outdoor air passes through the introduction duct 48 and is introduced into the first air passage P<b>1 and the second air passage P<b>2 of the housing body 50 . Moisture in the air introduced into the second air passage P2 is taken away by the moisture absorbing rotor 41 . The dehydrated air passes through the exhaust duct 49 and is exhausted to the outside. The air introduced into the first air passage P<b>1 is humidified by the moisture absorption rotor 41 . The humidified air is blown out from the outlet 54 to the target space S1. The control device 46 performs the humidification operation so that the humidity of the target space S1 detected by the temperature/humidity sensor 45 becomes the target humidity (set humidity).

In the ventilation operation, the control device 46 operates the first fan 43 and the second fan 44 and does not operate the moisture absorption rotor 41 and the heater 42 . As a result, outdoor air passes through the introduction duct 48 and is introduced into the first air passage P<b>1 and the second air passage P<b>2 of the housing body 50 . The air introduced into the first air passage P<b>1 is blown out from the outlet 54 into the target space S<b>1 without being humidified by the moisture absorbing rotor 41 .

In the humidification operation and the ventilation operation, the volume of air blown out from the outlet 54 to the target space S1 is larger than the volume of air discharged from the target space S1 to the outside through the inlet 72 and the third air passage P3. is set to be Therefore, the inside of the target space S1 becomes positive pressure due to the air discharged from the outlet 54 . As a result, the air in the target space S1 leaks out of the target space S1 from places other than the humidifying unit 3, and the target space S1 can be ventilated. Therefore, the humidification unit 3 of this embodiment is a humidification unit of a type (external air pushing type) that pushes outdoor air into the target space S1.

<Specific configuration of housing>
FIG. 2 is an external perspective view of the housing 47 of the humidifying unit 3. As shown in FIG. In the following description, expressions such as “top”, “bottom”, “left”, “right”, “front”, and “back” may be used to describe directions and positions. These representations follow the directions of mutually orthogonal arrows X, Y, and Z shown in FIG. 2 unless otherwise specified. Specifically, in the following description, the direction of arrow X (first direction) in FIG. called direction. However, these expressions representing directions and positions are used for convenience of explanation and do not limit the present disclosure.

A housing body 50 of the housing 47 is formed in a rectangular parallelepiped box shape. The housing body 50 has a front panel 50a, a rear panel 50b, a left panel 50c, a right panel 50d, and a top panel 50e. The lower end of the housing body 50 is open and closed by a panel 51 .

An inlet connecting pipe 52 and an outlet connecting pipe 53 are provided on the rear plate 50 b of the housing body 50 . The housing body 50 is formed so that its length in the direction (horizontal direction Y) in which air flows in and out through the introduction connecting pipe 52 and the discharge connecting pipe 53 is longer in the direction (horizontal direction X) perpendicular thereto. ing. A blowout port 54 and an inlet port 72 are formed in the panel 51 . In the left-right direction X, the outlet 54 is arranged on one side of the panel 51 and the inlet 72 is arranged on the other side of the panel 51 . Therefore, the outlet 54 and the inlet 72 are spaced apart in the left-right direction X. As shown in FIG.

FIG. 3 is a schematic plan view of the housing 47 with the top plate 50e removed. FIG. 4 is a schematic cross-sectional view of the housing 47 with the panel 51 removed. FIG. 5 is a schematic front view of the housing 47 with the front plate 50a removed. As shown in FIGS. 3 to 5, devices such as the moisture absorbing rotor 41, the first fan 43, the second fan 44, etc. are arranged in the horizontal direction X in the housing 47. As shown in FIGS.

The housing body 50 is provided with a first partition plate 61 that vertically divides the internal space. As shown in FIGS. 3 and 5 , a second partition plate 62 , a third partition plate 63 and a fourth partition plate 64 are provided on the first partition plate 61 . As shown in FIGS. 4 and 5, below the first partition plate 61, a fifth partition plate 65, a sixth partition plate 66, and a seventh partition plate 67 are provided.

As shown in FIG. 3, the first partition plate 61 has a region surrounded by the second and third second partition plates 62 and 63 and the third and fourth third partition plates 63 and 64 in plan view in FIG. (the area excluding the area where the second fan 44 is arranged and the area where a part of the control device 46 is arranged).

As shown in FIG. 3, the second partition plate 62 includes two vertical plate portions 62a and 62c extending in the front-rear direction Y and an inclined plate portion 62b connecting the vertical plate portions 62a and 62c in plan view. ,have. The vertical plate portion 62 a extends rearward from the front plate 50 a of the housing body 50 . The vertical plate portion 62c extends forward from the rear plate 50b of the housing body 50. As shown in FIG. The positions of the vertical plate portion 62a and the vertical plate portion 62c in the left-right direction X are shifted. The inclined plate portion 62b connects the rear end of the vertical plate portion 62a and the front end of the vertical plate portion 62c.

The third partition plate 63 is spaced apart in the left-right direction X from the second partition plate 62 . The third partition plate 63 has two vertical plate portions 63a and 63c extending in the front-rear direction Y and an inclined plate portion 63b connecting the vertical plate portions 63a and 63c in plan view. The vertical plate portion 63 a extends rearward from the front plate 50 a of the housing body 50 . The vertical plate portion 63c extends forward from the rear plate 50b of the housing body 50. As shown in FIG. The positions of the vertical plate portion 63a and the vertical plate portion 63c in the left-right direction X are shifted. The inclined plate portion 63b connects the rear end of the vertical plate portion 63a and the front end of the vertical plate portion 63c.

The fourth partition plate 64 extends in the left-right direction X across the middle portion in the front-rear direction Y of the vertical plate portion 63 c of the third partition plate 63 and the right side plate 50 d of the housing body 50 .

With the above configuration, a first space R1 extending in the front-rear direction Y of the housing body 50 by the second partition plate 62 and the third partition plate 63 is provided on the upper side of the housing body 50 and substantially in the center in the left-right direction X. is formed. A second space R<b>2 is formed by a third partition plate 63 and a fourth partition plate 64 on the front right side of the upper portion of the housing body 50 . A third space R<b>3 is formed by the vertical plate portion 63 c of the third partition plate 63 and the fourth partition plate 64 on the right rear side of the upper portion of the housing body 50 .

As shown in FIG. 4 , the fifth partition plate 65 arranged below the first partition plate 61 extends forward from the rear plate 50 b of the housing body 50 . The fifth partition plate 65 is arranged below the vertical plate portion 62c (see FIG. 3) of the second partition plate 62. As shown in FIG. The sixth partition plate 66 extends in the left-right direction X across the front end of the fifth partition plate 65 and the right side plate 50 d of the housing body 50 . The seventh partition plate 67 extends in the front-rear direction Y across the middle portion of the sixth partition plate 66 in the left-right direction X and the front plate 50 a of the housing body 50 .

With the above configuration, a fourth space R4 is formed by the fifth partition plate 65 and the sixth partition plate 66 on the lower right rear side of the housing body 50 . A fifth space R<b>5 is formed by the sixth partition plate 66 and the seventh partition plate 67 on the right front side on the lower side of the housing body 50 .

The first partition plate 61 does not exist between the third space R3 shown in FIG. 3 and the fourth space R4 shown in FIG. Therefore, the third space R3 and the fourth space R4 communicate vertically. Electrical components including the control device 46 are arranged in the third space R3 and the fourth space R4. A first fan 43 is arranged in the fifth space R5.

In the housing body 50, the area on the left side of the second partition plate 62 as shown in FIG. 3 and the area on the left side of the fifth partition plate 65 and the seventh partition plate 67 as shown in FIG. A continuously connected sixth space R6 is formed. A second fan 44 is arranged in the sixth space R6. A portion of the sixth space R6 forms a portion of the second air passage P2 (see FIG. 1) through which the second fan 44 causes air to flow.
Note that the configuration for dividing the internal space of the housing body 50 is not limited to this embodiment, and can be changed as appropriate.

As shown in FIGS. 3 and 4, the introduction connection pipe 52 is provided on the rear plate 50b of the housing body 50 at positions corresponding to the first space R1 and the fourth space R4. An intake port 55 of the introduction connecting pipe 52 communicates with the first space R1 and the fourth space R4. The first space R1 forms part of the first air passage P1 (see FIG. 1) and part of the second air passage P2 through which the air taken in from the intake port 55 flows. The fourth space R4 forms a fourth air passage P4 (see FIG. 1) through which the air taken in from the intake port 55 flows. The second space R2 communicates with the first space R1 via a heater case 41f of the moisture absorbing rotor 41, which will be described later, and forms a first air passage P1 together with the first space R1.

An air filter 73 is provided on the inner surface of the rear plate 50 b of the housing body 50 to remove dust and the like from the air taken into the housing body 50 through the intake port 55 . The air filter 73 is attached to a mounting frame 74 provided on the rear plate 50b.

The discharge connecting pipe 53 is provided on the rear plate 50b of the housing body 50 at a position corresponding to the sixth space R6. The discharge port 56 of the discharge connection pipe 53 communicates with the sixth space R6. The sixth space R6 communicates with the first space R1 via an adsorption member 41a of the moisture absorbing rotor 41, which will be described later, and forms a second air passage P2 together with the first space R1.

As shown in FIGS. 4 and 5, the outlet 54 formed in the panel 51 is formed at a position corresponding to the fifth space R5. As shown in FIGS. 3 and 4, the inlet 72 formed in the panel 51 is formed at a position corresponding to the sixth space R6. A portion of the sixth space R6 forms a third air passage P3 (see FIG. 1).

A temperature and humidity sensor 45 is arranged in the sixth space R6. The temperature/humidity sensor 45 detects the temperature and humidity of the air flowing through the sixth space R6 from the inlet 72 .

<Configuration of control device>
As shown in FIGS. 3 and 4, the control device 46 is arranged in the third space R3 and the fourth space R4. The control device 46 includes a first control board 81 and a second control board 82 . The first control board 81 controls the operation of the first fan 43 . The second control board 82 controls operations of the second fan 44 and the heater 42 . A microcomputer having a CPU, memory, etc., and an inverter (power supply circuit) having a rectifying circuit, an inverter circuit, etc. are mounted on the first and second control boards 81 and 82 .

Heat-generating components such as switching elements included in the inverter are mounted on the second control board 82 . As shown in FIG. 4, the second control board 82 is attached with a heat sink (cooler) 84 for cooling heat-generating components. The heat sink 84 is a block made of an aluminum alloy or the like, and has a large number of fins formed on its surface. The heat sink 84 is positioned near the front side of the inlet connection tube 52 . In the fourth space R4 in which the control device 46 is arranged, a partition wall 85 is arranged along the front-rear direction Y to separate a region (cooling space) R4a in which the heat sink 84 is arranged and other regions. The cooling space R4a forms a fourth air passage P4 (see FIG. 1).

As shown in FIG. 4, the attachment frame 74 to which the air filter 73 is attached has a shielding plate 74a below the first partition plate 61 for shielding air circulation. The shielding plate 74a is formed with an inlet 74b through which the air taken in from the inlet 55 flows into the cooling space R4a.

An opening 66 a is formed in the sixth partition plate 66 . The opening 66a communicates the cooling space R4a and the sixth space R6. Since the sixth space R6 forms the second air passage P2, the opening 66a constitutes a junction for joining the fourth air passage P4 to the second air passage P2. Therefore, the air taken in from the intake port 55 flows through the cooling space R4a from the inflow port 74b and is discharged from the opening 66a into the sixth space R6. Air flowing through the cooling space R4a is supplied to the heat sink 84 arranged in the cooling space R4a, and the heat-generating components mounted on the second control board 82 are cooled.

<Configuration of the first fan>
As shown in FIG. 5, the first fan 43 is provided below the first partition plate 61 in the fifth space R5. The first fan 43 has a fan body 43a having a plurality of blades, a fan case 43b that houses the fan body 43a, and a fan motor 43c that rotates the fan body 43a. The first fan 43 is a smaller fan than the second fan 44 . The first fan 43 of this embodiment is, for example, a centrifugal fan.

The first partition plate 61 is formed with a suction port 61a through which air is sucked into the fan case 43b by the rotation of the fan main body 43a. A discharge port 43d is formed at the lower end of the fan case 43b for discharging air out of the fan case 43b by rotation of the fan body 43a. The outlet 43 d is connected to the outlet 54 of the panel 51 and communicates with the outlet 54 . The first fan 43 takes in air from the outdoors into the introduction duct 48 and generates an air flow (first air flow) for flowing the air taken into the introduction duct 48 into the first air passage P1.

As shown in FIG. 4 , the fan case 43 b of the first fan 43 is provided with a humidity sensor 60 and a temperature fuse (temperature detector) 76 . The humidity sensor 60 detects the humidity of the air blown out from the outlet 43d. The thermal fuse 76 has an electric wire that disconnects when the ambient air temperature exceeds a predetermined temperature, and is incorporated in a circuit that transmits a signal to the control device 46 . The detected value of the humidity sensor 60 and the disconnection state of the thermal fuse 76 are input to the control device 46 .

<Configuration of the second fan>
As shown in FIGS. 3 to 5, a second fan 44 is provided in the sixth space R6. The second fan 44 has a fan body 44a having a plurality of blades, a fan case 44b that houses the fan body 43a, and a fan motor 43c that rotates the fan body 43a. A suction port 44d is formed in the lower surface of the fan case 44b for sucking air into the fan case 44b by the rotation of the fan body 44a.

A discharge port 44e is formed at the rear end of the fan case 44b for discharging air out of the fan case 44b by rotation of the fan body 44a. The discharge port 44 e is connected to the discharge connection pipe 53 . The second fan 44 takes in air from the outdoors into the introduction duct 48 and generates an air flow (second air flow) that flows the air taken into the introduction duct 48 into the second air passage P2. The second fan 44 of this embodiment is a sirocco fan. The second fan 44 generates an airflow with a larger volume than the first fan 43 .

<Structure of Moisture Absorption Rotor>
As shown in FIGS. 3 to 5, the moisture absorption rotor (moisture absorption device) 41 is provided on the first partition plate 61 . As shown in FIG. 3, the moisture absorbing rotor 41 is arranged below the inclined plate portion 63b and the vertical plate portion 63a of the third partition plate 63 in plan view. The moisture absorbing rotor 41 is arranged across the first space R1 and the second space R2. As shown in FIG. 4, the moisture absorbing rotor 41 is arranged in the sixth space R6 in bottom view.

6 is a plan view of the moisture absorbing rotor 41. FIG. 7 is an exploded perspective view of the moisture absorbing rotor 41. FIG. The moisture absorption rotor 41 has an adsorption member 41a, a ring gear 41b, a pinion gear 41c, a support frame 41d, and a heater case 41f. 7 shows a state in which the attracting member 41a and the ring gear 41b are separated upward from the support frame 41d, and the illustration of the pinion gear 41c is omitted.

The adsorption member 41a is a desiccant material formed in an annular shape. The adsorption member 41a adsorbs moisture from the air passing through itself when its temperature is low. When the temperature of the adsorption member 41a is high, the adsorption member 41a releases moisture adsorbed to itself into the air passing through the adsorption member 41a to humidify the air.

The ring gear 41b consists of an external gear. The ring gear 41b is attached to the outer periphery of the adsorption member 41a. The adsorption member 41a and the ring gear 41b are integrated. The adsorption member 41a and the ring gear 41b are arranged on the support frame 41d. The adsorption member 41a and the ring gear 41b are rotatably supported by the support frame 41d at the center O of the adsorption member 41a.

The support frame 41 d is formed integrally with the first partition plate 61 of the housing body 50 or fixed to the first partition plate 61 . Approximately fan-shaped through holes 41d1 and 41d2 are formed in the support frame 41d. The through hole 41d1 is formed at a position corresponding to a first area A1 (see FIG. 3), which will be described later. The through holes 41d2 are formed at positions corresponding to second and third regions A2 and A3, which will be described later. Three through-holes may be formed corresponding to each of the first area A1 to the third area A3.

The pinion gear 41c is rotatably supported on the support frame 41d on the outer peripheral side of the ring gear 41b. The pinion gear 41c meshes with the ring gear 41b. The pinion gear 41c is rotated by a motor (not shown). When the pinion gear 41c rotates, the attracting member 41a rotates around the center O together with the ring gear 41b. In this embodiment, the adsorption member 41a rotates to one side in its circumferential direction (the direction indicated by the outlined arrow B in FIG. 3).

As shown in FIGS. 4, 5, and 7, the support frame 41d of the moisture absorbing rotor 41 is provided with a heater case 41f. The heater case 41f is formed in a substantially arcuate shape in plan view, and is arranged at a position corresponding to the through hole 41d2 of the support frame 41d. The heater case 41f is formed in a box shape with an open upper end. As shown in FIG. 5, the heater case 41f is arranged below the adsorption member 41a in the sixth space R6. The heater case 41f is arranged in the range of a second area A2 and a third area A3 (angle range of 240°) described later in plan view in FIG. The heater case 41f functions as a passage member that forms a passage for air passing through the adsorption member 41a. The heater case 41f forms part of the first air passage P1 between the first space R1 and the second space R2.

A heater 42 is accommodated in the heater case 41f. As shown in FIG. 3, the heater 42 is arranged below the inclined plate portion 63b on the upstream side of the first air flow in the first air passage P1 relative to the first fan 43. As shown in FIG. The heater 42 is arranged at a position corresponding to between the second area A2 and the third area A3. As shown in FIG. 7, inside the heater case 41f, the upstream side of the first air flow in the first air passage P1 from the heater 42 constitutes a heater front space 41f1. The heater front space 41f1 is arranged in the third area A3 (see FIGS. 3 and 4). The air before being warmed by the heater 42 is introduced into the heater front space 41f1.

Inside the heater case 41f, the downstream side of the first air flow in the first air passage P1 constitutes a post-heater space 41f2. The post-heater space 41f2 is arranged in the second area A2 (see FIGS. 3 and 4). The air after being warmed by the heater 42 is introduced into the post-heater space 41f2.

FIG. 8 is a perspective view of the heater 42. FIG. The heater 42 is made of metal, for example, and has a rectangular cross section. The heater 42 has a grid-like frame 42a to increase the contact area with the air passing through it. One open end of the heater 42 is an air inlet 42b and the other open end of the heater 42 is an air outlet 42c.

The heater 42 is arranged with the inlet 42b facing the heater front space 41f1 and the outlet 42c facing the heater post-space 41f2. The air in the heater front space 41f1 is introduced from the inlet 42b into the heated heater 42, and is warmed by coming into contact with the frame 42a and the like when passing through the inside of the heater 42. As shown in FIG. The warmed air moves from the outlet 42c of the heater 42 to the post-heater space 41f2, and heats the adsorption member 41a located above the post-heater space 41f2 (see FIG. 3). Therefore, the heater 42 indirectly warms the adsorption member 41a.

The heater 42 may directly heat the adsorption member 41a instead of warming the air. In that case, for example, the heater 42 may be arranged above the adsorption member 41a, and the radiation heat of the heater 42 may warm the adsorption member 41a.

As shown in FIG. 3, the moisture absorbing rotor 41 has a first area (moisture absorbing area) A1, a second area (moisture releasing area) A2, and a third area A3 in plan view. The first area A1, the second area A2, and the third area A3 are each set within an angular range of 120° around the center O of the adsorption member 41a. The first area A1 is adjacent to the second area A2 and the third area A3. The second area A2 is adjacent to the first area A1 and the third area A3. The third area A3 is adjacent to the first area A1 and the second area A2.

The first to third areas A1 to A3 are areas fixed at fixed positions. Therefore, when the attracting member 41a rotates in the direction of the arrow B, the first area A1 to the third area A3 move relatively on the attracting member 41a.

The first area A1 is set within an angular range of 120° from the vertical plate portion 63a of the third partition plate 63 in the direction opposite to the arrow B. As shown in FIG. Thereby, the first area A1 is interposed between the first space R1 and the sixth space R6.

When outdoor cold air is introduced into the first space R1 from the intake port 55, part of the air passes through the first region A1 of the adsorption member 41a and flows into the sixth space R6. The first area A1 of the adsorption member 41a is cooled by the air and the temperature is lowered. Therefore, the first region A1 of the adsorption member 41a adsorbs moisture in the air passing through the adsorption member 41a. When the adsorption member 41a rotates after the first region A1 of the adsorption member 41a adsorbs moisture in the air, the first region A1 becomes the second region A2.

The second area A2 is formed in an angular range of 120° from the vertical plate portion 63a of the third partition plate 63 to the inclined plate portion 63b in the arrow B direction. The second area A2 is interposed between the second space R2 and the post-heater space 41f2 of the heater case 41f. The air heated by the heater 42 in the heater case 41f moves from the post-heater space 41f2 to the second space R2 through the second region A2 of the adsorption member 41a. At this time, the second area A2 of the adsorption member 41a is warmed by the air and the temperature rises, so moisture is released to the air passing through the second area A2 to humidify the air.

The third area A3 is formed within an angular range of 120° from the inclined plate portion 63b of the third partition plate 63 in the arrow B direction. The third area A3 is interposed between the first space R1 and the heater front space 41f1 of the heater case 41f. When the cold outdoor air is introduced into the first space R1 from the intake port 55, part of the air passes through the third region A3 of the adsorption member 41a and moves to the heater front space 41f1. At that time, the third region A3 of the adsorption member 41a is preliminarily cooled by cold air. Cold air is preliminarily warmed by the third region A3 of the adsorption member 41a. The adsorption member 41a does not necessarily have to have the third area A3.

As described above, the moisture absorption rotor 41 rotates the single adsorption member 41a to adsorb moisture in the air flowing through the first air passage P1 in the first area A1 and to adsorb moisture in the second area A2. 2, the air flowing through the air passage P2 can be humidified, and the humidification unit 3 can be configured compactly.

<Summary of air passages>
As shown in FIGS. 3 and 4, when the second fan 43 is driven during humidification operation, outdoor air is introduced into the first space R1 of the housing body 50 from the intake port 55 of the introduction connecting pipe 52. As shown in FIGS. The air introduced into the first space R1 passes through the first region A1 of the adsorption member 41a, moves to the sixth space R6, and is discharged from the discharge port 56 of the discharge connecting pipe 53 to the outside.

Therefore, in the present embodiment, the pipe inner space of the introduction connecting pipe 52, the first space R1, the sixth space R6, and the pipe inner space of the discharge connecting pipe 53 are the second air passage through which air flows from the intake port 55 to the discharge port 56. It constitutes P2. The first area A1 of the adsorption member 41a and the second fan 44 are arranged in the middle of the second air passage P2. The adsorption member 41a adsorbs moisture in the air flowing through the second air passage P2 in the first region A1.

When the second fan 44 is operated, the air in the target space S1 flows into the sixth space R6 from the inlet 72 formed in the panel 51 . The air introduced into the sixth space R6 flows in the vicinity of the temperature/humidity sensor 45 and is discharged to the outside through the discharge port 56 of the discharge connecting pipe 53. As shown in FIG. Therefore, in this embodiment, a portion of the sixth space R6 constitutes the third air passage P3. The third air passage P3 merges with the second air passage P2.

When the second fan 44 is operated, the air that has flowed in from the intake port 55 flows into the cooling space R4a in the fourth space R4 through the inlet 74b formed in the mounting frame 74 of the air filter 73. As shown in FIG. After cooling the heat-generating components of the control device 46, the air that has flowed into the cooling space R4a passes through the opening 66a formed in the sixth partition plate 66, flows into the sixth space R6, and is discharged to the outside from the discharge port 56. be done. Therefore, in this embodiment, the cooling space R4a of the fourth space R4 constitutes the fourth air passage P4. The fourth air passage P4 merges with the second air passage P2 downstream of the adsorption member 41a in the second air passage P2.

When the first fan 43 is operated during the humidification operation, outdoor air is introduced into the first space R1 from the intake port 55 of the introduction connection pipe 52, passes through the third region A3 of the adsorption member 41a, and enters the heater case 41f. It moves to the heater front space 41f1. The air that has moved to the heater front space 41f1 is warmed by the heater 42 in the heater case 41f, moves to the heater back space 41f2, passes through the second area A2 of the adsorption member 41a, and moves to the second space R2. The air that has moved to the second space R2 is blown out from the air outlet 54 of the panel 51 by the first fan 43 to the target space S1.

Therefore, in the present embodiment, the inner space of the introduction connecting pipe 52, the first space R1, the pre-heater space 41f1, the post-heater space 41f2, and the second space R2 are the first spaces through which air flows from the inlet 55 to the outlet . It constitutes an air passage P1. A third area A3 and a second area A2 of the adsorption member 41a, the heater 42, and the first fan 43 are arranged in the middle of the first air passage P1.

In the first air passage P1, the air before being warmed by the heater 42 passes through the third region A3 of the adsorption member 41a, thereby preliminarily cooling the adsorption member 41a. The adsorption member 41a releases moisture to the air as the air warmed by the heater 42 passes through the second region A2 of the adsorption member 41a. As a result, the air passing through the second area A2 of the adsorption member 41a is humidified.

During the humidification operation, both the first air flow in the first air passage P1 and the second air flow in the second air passage P2 pass through the first space R1, which is a common air passage. However, the first space R1 is not provided with a partition plate for separating the first airflow and the second airflow passing through the first space R1. Since the second fan 44 operates with a larger air volume than the first fan 43, there is a difference in air suction force between the second fan 44 and the first fan 43, and the difference in suction force causes the first air to flow. This is because it is divided into the air stream and the second air stream. The first fan 43 and the second fan 44 distribute the first airflow and the second airflow that have passed through the common air passage (the first space R1) in different directions. Since both the first airflow and the second airflow pass through the first space R1, which is a common air passage, the structure inside the housing body 50 can be simplified.

When the first fan 43 and the second fan 44 are operated during the ventilation operation, outdoor air flows through the first air passage P1 and the second air passage P2 as in the humidification operation. However, since the moisture absorption rotor 41 and the heater 42 do not operate, the air flowing through the first air passage P1 is not humidified by the adsorption member 41a of the moisture absorption rotor 41, and is blown out from the blowout port 54 of the panel 51 into the target space S1. be. The reason why not only the first fan 43 but also the second fan 44 is operated during the ventilation operation is that the first fan 43 generates a smaller amount of air flow than the second fan 44, so it is not enough to operate the first fan 43 alone. , it may be difficult to draw in outdoor air through the introduction duct 48 .

<Air Volume Control of First Fan and Second Fan>
The first fan 43 and the second fan 44 are controlled by the control device 46 so as to generate airflows of predetermined airflows, respectively, in order to operate the second fan 44 with a larger airflow than the first fan 43 as described above. The number of revolutions of each fan motor 43c, 44c is controlled by . For example, the control device 46 controls the rotation speeds of the fan motors 43c and 44 so that the air volume of the first fan 43 and the air volume of the second fan 44 have a ratio of 1:5 (air volume balance).

Since the heater 42 does not operate during the ventilation operation, the air of the first air flow in the first air passage P1 is not heated by the heater 42 . Since the air of the first airflow is not heated, almost no static pressure difference due to the air temperature difference occurs between the first fan 43 and the second fan 44 . Therefore, during the ventilation operation, the air volume balance between the air volume of the first fan 43 and the air volume of the second fan 44 is not lost, and the air volume of the first fan 43 does not decrease.

On the other hand, during the humidification operation, the air in the first air stream is heated by the heater 42 arranged upstream of the first air stream relative to the first fan 43, so the air around the first fan 43 and around the second fan There is an air temperature difference between and, and the air temperature difference causes a static pressure difference. When such a static pressure difference occurs, the air volume balance between the air volume of the first fan 43 and the air volume of the second fan 44 is lost, and the air volume of the first fan 43 decreases. When the air volume of the first fan 43 decreases in this way, the first fan 43 is a small fan, and the resistance of the first air flow increases when the air taken in from the outdoors passes through the introduction duct 48. As a factor, the air volume of the first fan 43 is further reduced.

From the above, when the air volume setting of the first fan 43 is the same during the humidification operation and the ventilation operation, the rotation speed of the first fan 43 (fan motor 43c) is set to be the same during the humidification operation and the ventilation operation. Also, the air volume of the first fan 43 is lower during the humidification operation than during the ventilation operation. As a countermeasure, it is conceivable to increase the number of rotations of the first fan 43 during the humidification operation and the ventilation operation. However, in that case, the air volume of the first fan 43 increases during the ventilation operation, and the operation noise becomes louder during the ventilation operation.

Therefore, when the air volume setting of the first fan 43 during the humidifying operation and the ventilation operation is the same, the control device 46 sets the air volume of the first fan 43 during the humidifying operation to the air volume of the first fan 43 during the ventilation operation. The rotation speed of the first fan 43 is controlled so as to be the same as . At that time, the control device 46 controls the rotation speed of the first fan 43 so that the rotation speed of the first fan 43 during the humidification operation is higher than the rotation speed of the first fan 43 controlled during the ventilation operation. . The air volume setting includes not only the case where the air volume is set by operating a remote controller (not shown), but also the case where the air volume is set in advance in the microcomputer of the control device 46 or the like.

In this embodiment, the number of revolutions of the first fan 43 during the ventilation operation is set to a relatively low number of revolutions so that the operation noise of the first fan 43 can be kept low. The control device 46 controls the number of rotations of the first fan 43 to be higher during the humidification operation than during the ventilation operation. At that time, the first fan 43 rotates during the humidification operation so that the air volume of the first fan 43 during the humidification operation is the same as the air volume of the first fan 43 during the ventilation operation even if the static pressure difference decreases. number is set. The number of rotations of the first fan 43 during the humidification operation is set in consideration of the fact that the first fan 43 is a small fan and the fact that the resistance of the first airflow passing through the introduction duct 48 increases. ing.

FIG. 9 is a flowchart showing an example of control of the first fan 43 by the control device 46. As shown in FIG. This control example shows the processing executed by the control device 46 when the air volume settings during the humidifying operation and during the ventilation operation are the same. The control device 46 determines whether or not the operation mode of the humidification unit 3 is the humidification operation (step ST11). This determination can be made based on an operation signal input from the remote controller. When the operation mode is the humidification operation ("Yes" in step ST11), the control device 46 controls the rotation speed of the fan motor 43c to relatively increase to operate the first fan 43 (step ST12).

When the operation mode is not the humidification operation (“No” in step ST11), the controller 46 determines whether the operation mode of the humidification unit 3 is the ventilation operation (step ST13). This determination can also be determined by an operation signal input from the remote controller. When the operation mode is the ventilation operation ("Yes" in step ST13), the control device 46 controls the rotation speed of the fan motor 43c to be relatively small to operate the first fan 43 (step ST14). If the operation mode is not the ventilation operation ("No" in step ST13), the control device 46 terminates the process.

<Action and effect of the embodiment>
(1) According to the humidification unit 3 of the present embodiment, when the air volume setting of the first fan 43 is the same during the humidification operation and during the ventilation operation, the control device 46 sets the air volume during the humidification operation to that during the ventilation operation. The rotation speed of the first fan 43 is controlled so that the rotation speed of the first fan 43 increases. As a result, the air temperature around the first fan 43 during the humidification operation is lower than when the number of revolutions of the first fan 43 is the same during the humidification operation and during the ventilation operation. The air density around 43 increases. As a result, it is possible to increase the air volume of the first fan 43 that blows air into the target space S1 during the humidification operation.

(2) The humidification unit 3 includes a common air passage (first space R1) through which the first air flow in the first air passage P1 and the second air flow in the second air passage P2 pass, and the first fan 43 and The second fan 44 distributes the first air flow and the second air flow that have passed through the common air passage in different directions. In such a configuration, during the humidification operation, the air of the first air flow is heated by the heater 42 arranged on the upstream side of the first air flow from the first fan 43 . There is an air temperature difference between the two fans 43, and the air temperature difference causes a static pressure difference. When such a static pressure difference occurs, the air volume balance between the air volume of the first fan 43 and the air volume of the second fan 44 is lost, and the air volume of the first fan 43 decreases. However, since the rotation speed of the first fan 43 is higher during the humidification operation than during the ventilation operation, compared to the case where the rotation speed of the first fan 43 is the same during the humidification operation and during the ventilation operation, the first fan 43 The air volume of the fan 43 increases. As a result, even if the static pressure difference occurs, it is possible to prevent the air volume balance between the air volume of the first fan 43 and the air volume of the second fan 44 from being lost.

(3) The first fan 43 and the second fan 44 are housed in the housing 47 . In such a configuration, since the first fan 43 and the second fan 44 are housed in a limited space within the housing 47, one of the first and second fans 43 and 44 is made a small fan. There is a need. In this embodiment, since the first fan 43 is a small fan, the air volume of the first fan 43 is further reduced during the humidification operation. However, even in such a case, the controller 46 controls the number of revolutions of the first fan 43 to be higher during the humidification operation than during the ventilation operation, so the air volume of the first fan 43 can be increased.

(4) The humidification unit 3 includes an introduction duct 48 that takes in air of the first airflow from the outdoors. In such a configuration, since the introduction duct 48 increases the resistance of the first air flow, the air volume of the first fan 43 is further reduced. However, even in such a case, the controller 46 controls the number of revolutions of the first fan 43 to be higher during the humidification operation than during the ventilation operation, so the air volume of the first fan 43 can be increased.

<Others>
The present disclosure is not limited to the above examples, but is indicated by the scope of the claims, and is intended to include all modifications within the meaning and scope of equivalents of the scope of the claims.

In the above embodiment, the attracting member 41a is rotated by a gear mechanism consisting of the ring gear 41b and the pinion gear 41c, but may be rotated by another rotation transmission mechanism such as a belt.

Although the first air flow and the second air flow pass through the common air passage (the first space R1) in the above embodiment, they may pass through different air passages. In this case, the first air flow and the second air flow may take air into the housing 47 from separate intakes.

In the above embodiment, the first fan 43 and the second fan 44 are housed in one housing 47, but may be housed in separate housings.

In the above embodiment, the rotation speed of the first fan 43 during the ventilation operation is set to a relatively low rotation speed, but the rotation speed of the first fan 43 during the humidification operation is set to a relatively high rotation speed. You may Specifically, the air volume of the first fan 43 during the humidification operation is set to be the same as the air volume of the first fan 43 during the ventilation operation even if the static pressure difference reduces the air volume of the first fan 43 during the humidification operation. can be set. In this case, if the number of revolutions of the first fan 43 during the ventilation operation is the same as that during the humidification operation, the air volume of the first fan 43 will increase and the operation noise during the ventilation operation will become louder. Therefore, the controller 46 preferably controls the number of rotations of the first fan 43 during the ventilation operation so as to be lower than the number of rotations of the first fan 43 during the humidification operation. As a result, it is possible to reduce the air volume during the ventilation operation, thereby reducing the operation noise during the ventilation operation.

3 humidification unit 41a adsorption member 42 heater 43 first fan 44 second fan 46 control device 47 housing 48 introduction duct (duct)
A1 first area (moisture absorption area)
A2 Second area (moisture release area)
R1 First space (air passage)
S1 target space

Claims (3)

A humidification unit that performs a humidification operation for humidifying the target space (S1) and a ventilation operation for ventilating the target space (S1),
an adsorption member (41a) having a moisture absorption area (A1) that adsorbs moisture and a moisture release area (A2) that releases moisture;
During the humidification operation and the ventilation operation, air is taken in from the outdoors, and the first airflow is blown out to the target space (S1) through the moisture desorption area (A2) of the adsorption member (41a). a first fan (43) that generates
a heater (42) arranged on the upstream side of the first airflow relative to the first fan (43) and heating the air taken in from the outdoors by the first fan (43) during the humidification operation;
a control device (46) that controls the rotation speed of the first fan (43);
A second air flow is generated to take in air from the outdoors during the humidification operation and the ventilation operation and discharge the taken-in air to the outside through the moisture absorption region (A1) of the adsorption member (41a). a fan (44);
A housing (47) that houses the first fan (43) and the second fan (44),
When the air volume setting of the first fan (43) during the humidification operation and during the ventilation operation is the same, the rotation speed of the first fan (43) controlled by the control device (46) during the humidification operation is a humidification unit, wherein the number of revolutions of the first fan (43) controlled by the control device (46) is higher than that of the first fan (43) during the ventilation operation. A humidification unit that performs a humidification operation for humidifying the target space (S1) and a ventilation operation for ventilating the target space (S1),
an adsorption member (41a) having a moisture absorption area (A1) that adsorbs moisture and a moisture release area (A2) that releases moisture;
During the humidification operation and the ventilation operation, air is taken in from the outdoors, and the first airflow is blown out to the target space (S1) through the moisture desorption area (A2) of the adsorption member (41a). a first fan (43) that generates
a heater (42) arranged on the upstream side of the first airflow relative to the first fan (43) and heating the air taken in from the outdoors by the first fan (43) during the humidification operation;
a control device (46) that controls the rotation speed of the first fan (43);
A second air flow is generated to take in air from the outdoors during the humidification operation and the ventilation operation and discharge the taken-in air to the outside through the moisture absorption region (A1) of the adsorption member (41a). a fan (44);
a common air passage (R1) through which the first air flow and the second air flow pass;
The first fan (43) and the second fan (44) distribute the first air flow and the second air flow that have passed through the air passage (R1) in different directions ,
When the air volume setting of the first fan (43) during the humidification operation and during the ventilation operation is the same, the rotation speed of the first fan (43) controlled by the control device (46) during the humidification operation is a humidification unit, wherein the number of revolutions of the first fan (43) controlled by the control device (46) is higher than that of the first fan (43) during the ventilation operation. 3. A humidification unit according to claim 1 or claim 2, further comprising a duct (48) for taking in air of said first air flow from outdoors.

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