JP2018087679A - Humidifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a humidifier comprising a humidification rotor having high use efficiency.SOLUTION: A humidification unit 60 includes a humidification rotor 63 consisting of adsorbents. The adsorbents adsorb moisture in the air and release the adsorbed moisture in the air by being heated. The humidification rotor 63 is rotatable about a rotating shaft 63d. Viewed along the rotating shaft 63d, the humidification rotor 63 is partitioned into a plurality of adsorbent regions 69a, 69b. Specifications of the adsorbents in the plurality of adsorbent regions 69a, 69b adjacent to each other differ from each other. Due to this configuration, in accordance with characteristics of air passing through the humidification rotor 63 and a temperature distribution of the humidification rotor 63, the appropriate adsorbents are provided in the respective adsorbent regions 69a, 69b of the humidification rotor 63, so as to enable adsorbing capacity of the humidification rotor 63 to be improved.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a humidifier including a humidification rotor capable of repeatedly performing moisture absorption for adsorbing moisture in the air and moisture release for releasing moisture in the air.

  2. Description of the Related Art Conventionally, a humidifying device including a humidifying rotor capable of repeating adsorption and release of water is known as a humidifying device used for an air cleaner with a humidifying function. For example, a humidifier disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 2001-91002) has a moisture absorption region that adsorbs moisture in the air and a moisture release region that releases the adsorbed moisture into the air. A humidification rotor is provided. In this humidifier, the moisture release area of the humidification rotor is heated by the heater, and the moisture adsorbed in the moisture release area is released into the air. Air containing moisture released from the moisture release area is sent to the humidification target space by the fan.

  The humidification rotor is made of an adsorbent that adsorbs moisture in the air and releases the adsorbed moisture into the air when heated. The adsorbent of the conventional humidification rotor is uniform. That is, the humidification rotor is composed of one type of adsorbent. However, the flow rate of air passing through the humidification rotor and the temperature of the humidification rotor are not uniform. For example, the radially outer region of the disc-shaped humidifying rotor tends to have a higher flow rate of passing air than the radially inner region. Therefore, when the adsorbent of the humidification rotor is uniform, there is a possibility that the utilization efficiency of the humidification rotor may be lowered due to an insufficient adsorption capacity of the adsorbent.

  The objective of this invention is providing a humidification apparatus provided with the humidification rotor which has high utilization efficiency.

  A humidifier according to a first aspect of the present invention includes a humidification rotor made of an adsorbent. The adsorbent adsorbs moisture in the air and releases the adsorbed moisture into the air when heated. The humidification rotor is rotatable about the rotation axis, and is divided into a plurality of adsorbent regions when viewed along the rotation axis. The specifications of the adsorbents in the adsorbent regions adjacent to each other are different.

  In the humidifier according to the first aspect, the humidification rotor is composed of a plurality of types of adsorbents. This makes it possible to improve the adsorption capacity of the humidification rotor by providing an appropriate adsorbent in each adsorbent region of the humidification rotor in accordance with the characteristics of the air passing through the humidification rotor and the temperature distribution of the humidification rotor. it can. Therefore, the humidification apparatus which concerns on a 1st viewpoint is provided with the humidification rotor which has high utilization efficiency.

  A humidifying device according to a second aspect of the present invention is a humidifying device according to the first aspect, wherein the humidifying rotor has a plurality of adsorbents according to the distance from the rotating shaft when viewed along the rotating shaft. It is divided into areas.

  In the humidifying device according to the second aspect, each adsorbent region of the humidifying rotor is provided with an adsorbent selected based on the distance from the rotating shaft of the humidifying rotor. The characteristics of the air passing through the humidification rotor and the temperature distribution of the humidification rotor tend to change according to the distance from the rotation axis of the humidification rotor. Therefore, the humidifier according to the second aspect includes a humidification rotor having high utilization efficiency.

  A humidifier according to a third aspect of the present invention is a humidifier according to the second aspect, and the humidification rotor has a circular shape centered on the rotation axis when viewed along the rotation axis. . A boundary between a plurality of adsorbent regions adjacent to each other has a circular shape centering on the rotation axis when viewed along the rotation axis.

  In the humidifier according to the third aspect, the humidification rotor has a disk shape, and the boundary between two adjacent adsorbent regions is a circle centered on the rotation axis of the humidification rotor. The characteristics of the air passing through the humidification rotor and the temperature distribution of the humidification rotor tend to change along the radial direction of the humidification rotor. Therefore, the humidifier according to the third aspect includes a disk-shaped humidification rotor having high utilization efficiency.

  The humidifying device according to the fourth aspect of the present invention is the humidifying device according to the third aspect, wherein the humidifying rotor has a first adsorbent region and a second adsorbent region. The first adsorbent region is an adsorbent region located on the outermost side in the radial direction of the humidifying rotor. The second adsorbent region is an adsorbent region that is further inward in the radial direction than the first adsorbent region. The moisture adsorption capacity of the adsorbent in the first adsorbent region is larger than the moisture adsorption capacity of the adsorbent in the second adsorbent region.

  In the humidifying device according to the fourth aspect, when the flow rate of the air passing through the humidifying rotor increases toward the radially outer side of the disc-shaped humidifying rotor, the diameter of the humidifying rotor is larger than the radially inner side (center side) of the humidifying rotor. An adsorbent having a larger adsorption capacity is provided on the outer side (outer peripheral side) in the direction. Therefore, the humidifying device according to the fourth aspect includes a humidifying rotor having high utilization efficiency when the flow rate of air passing through the humidifying rotor increases toward the radially outer side of the disk-shaped humidifying rotor.

  The humidifying device according to the fifth aspect of the present invention is the humidifying device according to the third aspect, wherein the humidifying rotor has a first adsorbent region and a second adsorbent region. The first adsorbent region is an adsorbent region including the radial center of the humidification rotor. The second adsorbent region is an adsorbent region that is further on the inner side and on the outer side in the radial direction than the first adsorbent region. The temperature at which moisture adsorbed by the adsorbent in the first adsorbent region can be released is higher than the temperature at which moisture adsorbed by the adsorbent in the second adsorbent region can be released.

  In the humidifying device according to the fifth aspect, when the heat of the humidifying heater is likely to hit the central portion in the radial direction of the disc-shaped humidifying rotor, from the radially outer side (outer peripheral side) and the radial inner side (center side) of the humidifying rotor. Also, an adsorbent capable of releasing moisture at a higher temperature is provided at the central portion in the radial direction of the humidifying rotor. Therefore, the humidifying device according to the fifth aspect includes a humidifying rotor having high utilization efficiency when the heat of the humidifying heater is likely to hit the central portion in the radial direction of the disc-shaped humidifying rotor.

  A humidifying device according to a sixth aspect of the present invention is the humidifying device according to any one of the first to third aspects, and the humidifying rotor passes through the humidifying rotor when viewed along the rotation axis. It is divided into a plurality of adsorbent regions according to the distribution of the air flow rate.

  In the humidifier according to the sixth aspect, each adsorbent region of the humidification rotor is provided with an adsorbent suitable for the flow rate of air passing through the region. Therefore, the humidifier according to the sixth aspect can include a humidification rotor having high utilization efficiency according to the distribution of the flow rate of air passing through the humidification rotor.

  A humidifying device according to a seventh aspect of the present invention is the humidifying device according to any one of the first to third aspects, and the humidifying rotor passes through the humidifying rotor when viewed along the rotation axis. It is divided into a plurality of adsorbent regions according to the distribution of the temperature of the air.

  In the humidifier according to the seventh aspect, each adsorbent region of the humidification rotor is provided with an adsorbent suitable for the temperature of the air passing through the region. Therefore, the humidifier according to the seventh aspect can include a humidifying rotor having high utilization efficiency according to the temperature distribution of the air passing through the humidifying rotor.

  The humidifier according to the first aspect of the present invention includes a humidification rotor having high utilization efficiency.

  A humidifier according to a second aspect of the present invention includes a humidification rotor having high utilization efficiency.

  A humidifier according to a third aspect of the present invention includes a disk-shaped humidification rotor having high utilization efficiency.

  The humidification device according to the fourth aspect of the present invention includes a humidification rotor having high utilization efficiency when the flow rate of air passing through the humidification rotor increases toward the radially outer side of the disk-shaped humidification rotor.

  The humidifying device according to the fifth aspect of the present invention includes a humidifying rotor having high utilization efficiency when the heat of the humidifying heater is likely to hit the radial central portion of the disc-shaped humidifying rotor.

  The humidification device according to the sixth aspect of the present invention can include a humidification rotor having high utilization efficiency according to the distribution of the flow rate of air passing through the humidification rotor.

  The humidifying device according to the seventh aspect of the present invention can include a humidifying rotor having high utilization efficiency according to the temperature distribution of the air passing through the humidifying rotor.

It is a lineblock diagram of air conditioner 10 provided with humidification unit 60 which is one embodiment of the humidification device concerning the present invention. It is a top view of the outdoor unit 30 in the state where the top plate 48 of the casing 40 is removed. FIG. 3 is a front view of the outdoor unit 30 in a state where a protective grill 56 is removed from the outdoor unit 30 of FIG. 2. FIG. 5 is a diagram showing the flow of air passing through a humidification rotor 63. FIG. 7 is a perspective view of an adsorption duct 68, a humidifying duct 73, a humidifying fan 75, and a second humidifying duct 180. 7 is a front view of a rotor frame wall 65. FIG. It is the schematic diagram of the humidification rotor 63 looked along the rotating shaft 63d. It is the schematic diagram of the humidification rotor 63 looked along the rotating shaft 63d in the modification A. It is the schematic diagram of the humidification rotor 63 seen along the rotating shaft 63d in the modification B.

  Embodiments of the present invention will be described with reference to the drawings. The embodiments described below are specific examples of the present invention and do not limit the technical scope of the present invention.

(1) Configuration of Air Conditioner 10 FIG. 1 is a configuration diagram of an air conditioner 10 including a humidifying unit 60 that is an embodiment of a humidifier according to the present invention. The air conditioner 10 is a refrigeration apparatus including a refrigeration cycle that uses a refrigerant circulating in a refrigerant circuit. The air conditioner 10 mainly includes an indoor unit 20 and an outdoor unit 30. The indoor unit 20 and the outdoor unit 30 are connected to each other by the refrigerant communication pipes 14 and 16 and the air supply hose 18. In FIG. 1, the flow of air passing through the indoor unit 20 and the outdoor unit 30 is indicated by white arrows.

  The air conditioner 10 has a plurality of operation modes such as a cooling operation, a heating operation, a dehumidifying operation, a humidifying operation, and an air supply operation. In the humidifying operation and the air supply operation, air is sent from the outdoor unit 30 to the indoor unit 20 through the air supply hose 18 in order to supply air into the room. In particular, in the humidifying operation, high humidity air containing a large amount of moisture is sent from the outdoor unit 30 to the indoor unit 20, so that moisture is taken in from the outside air in the outdoor unit 30. The outdoor unit 30 includes a humidification unit 60 having a function of taking moisture from outside air. In FIG. 1, the flow of air passing through the humidification unit 60 is indicated by dotted arrows.

(2) Configuration of Indoor Unit 20 The indoor unit 20 mainly includes an indoor heat exchanger 21 and an indoor fan 22. As shown in FIG. 1, the indoor fan 22 is disposed on the downstream side of the indoor heat exchanger 21, and is driven by an indoor fan motor 22a. When the indoor fan 22 is driven, the indoor air sucked from the indoor suction port 23 at the upper part of the indoor unit 20 passes through the indoor heat exchanger 21 and is blown out from the indoor outlet 24 at the lower part of the indoor unit 20. The indoor fan 22 is, for example, a cross flow fan.

  In the indoor unit 20, the indoor air supply port 25 is provided in the upstream space of the indoor heat exchanger 21. One end of the air supply hose 18 is connected to the indoor air supply port 25, and the other end of the air supply hose 18 is connected to the humidification unit 60 of the outdoor unit 30. The high-humidity air sent from the humidification unit 60 is supplied to the upstream space of the indoor heat exchanger 21 through the indoor air supply port 25. When the indoor fan 22 is driven in a state where high-humidity air is supplied to the upstream space of the indoor heat exchanger 21, the humidity of the conditioned air blown from the indoor outlet 24 of the indoor unit 20 is increased. be able to.

(3) Configuration of Outdoor Unit 30 The outdoor unit 30 mainly includes a casing 40, a compressor 31, an outdoor heat exchanger 33, an outdoor fan 39, and a humidification unit 60. A four-way switching valve 32, an electric expansion valve 34, an accumulator 36, a liquid side closing valve 37, and a gas side closing valve 38 are attached to the refrigerant circuit inside the outdoor unit 30.

  FIG. 2 is a plan view of the outdoor unit 30 with the top plate 48 of the casing 40 removed. FIG. 3 is a front view of the outdoor unit 30 with the protective grill 56 removed from the outdoor unit 30 of FIG. In FIG. 2, the flow of air passing through the outdoor unit 30 is indicated by dotted arrows.

(3-1) Casing 40
The casing 40 mainly includes a left side plate 45, a front plate 46, a right side plate 47, a top plate 48 (see FIG. 3), a bottom plate 49 (see FIG. 3), and a back surface portion 44. The internal space of the casing 40 is partitioned into a blower chamber 41 and a machine chamber 42 by a partition member 43. The blower chamber 41 is a space in which the outdoor heat exchanger 33, the outdoor fan 39, and a part of the humidification unit 60 are arranged. The machine room 42 is a space in which the compressor 31 and a part of the humidification unit 60 are arranged.

  The partition member 43 is a plate-like member extending substantially in parallel with the right side plate 47 from the top plate 48 side toward the bottom plate 49 side. The partition member 43 extends in an arc shape from the inner side of the front plate 46 toward the end of the outdoor heat exchanger 33 on the right side plate 47 side. As a result, the partition member 43 has a function of shielding the air flow so that the air flow does not flow from the blower chamber 41 toward the machine chamber 42.

  As shown in FIG. 3, an electrical component unit 50 is installed in the blower chamber 41. The electrical component unit 50 is equipped with a control board on which electronic components for driving the compressor 31 and the outdoor fan 39 are integrated.

  As shown in FIG. 3, a circular outdoor air outlet 46 a is formed in the front plate 46. A ring-shaped bell mouth 52 is attached to the outdoor air outlet 46a along the peripheral edge thereof. As shown in FIG. 2, a protective grill 56 is attached to the front plate 46 of the casing 40. The protective grill 56 covers the outdoor outlet 46a. The protective grill 56 is formed with a plurality of openings for blowing air from the internal space of the casing 40 to the external space.

(3-2) Compressor 31
As shown in FIG. 1, the compressor 31 is disposed in the machine room 42. The compressor 31 is fixed to the bottom plate 49. Since the compressor 31 is at a high temperature during operation, the temperature of the machine room 42 is higher than that of the blower room 41.

(3-3) Outdoor heat exchanger 33
As shown in FIG. 2, the outdoor heat exchanger 33 is formed in an L shape so as to face the back surface portion 44 and the left side plate 45 of the casing 40. The vertical dimension of the outdoor heat exchanger 33 is substantially equal to the distance between the top plate 48 and the bottom plate 49.

(3-4) Outdoor fan 39
The outdoor fan 39 is disposed on the downstream side of the outdoor heat exchanger 33. The outdoor fan 39 includes an outdoor fan motor 39a and a propeller 39b. The propeller 39b is driven by the outdoor fan motor 39a. A part of the propeller 39b is arranged in a space surrounded by the bell mouth 52.

  When the propeller 39b is driven by the outdoor fan motor 39a, outside air is sucked from the back surface portion 44 side of the outdoor heat exchanger 33. The sucked outside air passes through the outdoor heat exchanger 33 and is blown out from the outdoor outlet 46a (see FIG. 3). Since the front surface of the outdoor outlet 46a is covered with a protective grill 56 (see FIG. 2), the propeller 39b cannot be touched from the outside of the outdoor unit 30.

(3-5) Humidification unit 60
As shown in FIG. 2, the humidification unit 60 is disposed between the front plate 46 and the back surface portion 44 so as to straddle the blower chamber 41 and the machine chamber 42. Specifically, a part of the humidifying unit 60 is disposed in the blower chamber 41, and the other part is disposed in the machine chamber 42. The humidification unit 60 is disposed above the blower chamber 41 and the machine chamber 42 and has a function as a part of the partition member 43.

  The humidification unit 60 mainly includes a humidification rotor 63, a humidification heater 71, an adsorption duct 68, a humidification duct 73, a humidification fan 75 (see FIG. 1), and a second humidification duct 180.

(3-5-1) Humidification rotor 63
The humidification rotor 63 is a disk-shaped member. The humidification rotor 63 adsorbs and releases moisture contained in the air while rotating around the rotation axis. The rotating shaft of the humidifying rotor 63 passes through the center of the circular main surface of the humidifying rotor 63 and extends along the horizontal direction. That is, the humidification rotor 63 is arranged so that its main surface is along the vertical direction.

  The humidification rotor 63 is disposed so as to face the front plate 46. As shown in FIG. 3, a portion of the humidification rotor 63 faces the outdoor suction port 46 b that is an opening formed in the front plate 46. The outdoor suction port 46b has a fan shape with a central angle of about 240 °. The fan-shaped center of the outdoor suction port 46 b is located on the rotation axis of the humidification rotor 63. The humidification rotor 63 is surrounded by the rotor frame wall 65. The rotor frame wall 65 will be described later.

  FIG. 4 is a diagram illustrating the flow of air passing through the humidification rotor 63. In FIG. 4, the flow of air passing through the humidification rotor 63 is indicated by white arrows, and the rotation direction of the humidification rotor 63 is indicated by dotted arrows. As shown in FIG. 4, the humidification rotor 63 includes a moisture adsorption region 63a and a moisture release region 63b. The moisture adsorption region 63a is a part of the main surface of the humidification rotor 63 and is a region facing the outdoor suction port 46b. The moisture release area 63b is a part of the main surface of the humidification rotor 63 and is not an area facing the outdoor suction port 46b. Similar to the outdoor suction port 46b, the moisture adsorption region 63a has a fan shape with a central angle of about 240 °. The moisture release region 63b is adjacent to the moisture adsorption region 63a and has a sector shape with a central angle of about 120 °. The moisture adsorption region 63a is a region where moisture contained in the air is adsorbed. The moisture release region 63b is a region where the adsorbed moisture is released into the air. The moisture adsorption region 63a is disposed closer to the bell mouth 52 than the moisture release region 63b.

  When the humidification rotor 63 rotates around the rotation axis, the moisture adsorption region 63a becomes the moisture release region 63b, and the moisture release region 63b becomes the moisture adsorption region 63a. Thereby, the humidification rotor 63 can repeat adsorption | suction and discharge | release of the water | moisture content contained in the air by rotating around the rotating shaft.

  The moisture adsorption region 63a and the moisture release region 63b have a honeycomb structure formed by firing of zeolite or the like. Adsorbents such as zeolite adsorb moisture in the air at room temperature and release the adsorbed moisture when exposed to high-temperature air and heated.

  As shown in FIG. 4, a plurality of teeth 63 t are formed on the outer peripheral surface of the humidification rotor 63 along the circumferential direction. Thereby, the humidification rotor 63 functions as a gear having a plurality of teeth 63t. As shown in FIG. 3, the teeth 63t of the humidification rotor 63 mesh with the pinion gear 64a. The pinion gear 64 a is rotated by the power of the rotor driving motor 64. The humidification rotor 63 can rotate around its rotation axis by the rotational movement of the pinion gear 64a.

(3-5-2) Humidifier 71
The humidifying heater 71 is disposed between the moisture release region 63b of the humidification rotor 63 and the front plate 46 so as to face the moisture release region 63b. As shown in FIG. 4, the humidifying heater 71 heats the air sent to the moisture releasing region 63 b in order to release moisture from the moisture releasing region 63 b of the humidifying rotor 63. The air heated by the humidifying heater 71 releases moisture from the humidifying rotor 63 when passing through the moisture release region 63b, and becomes high-humidity air.

  As shown in FIG. 4, the air heated by the humidifying heater 71 is air that has passed through the moisture release region 63 b of the humidifying rotor 63. This air is outside air taken in from a humidifying opening 40a (see FIG. 1) formed in the casing 40.

  As shown in FIG. 4, in the moisture discharge region 63b, the region through which the outside air taken in from the humidifying opening 40a passes is more rotated than the region through which the air heated by the humidifying heater 71 passes. It is located downstream in the direction. The outside air taken in from the humidifying opening 40a passes through the moisture release region 63b before being heated by the humidifying heater 71, whereby the heat of the humidifying rotor 63 is recovered.

(3-5-3) Adsorption duct 68
FIG. 5 is a perspective view of the suction duct 68, the humidification duct 73, the humidification fan 75, and the second humidification duct 180.

  The adsorption duct 68 is a member for guiding outside air, which is air containing moisture, to the moisture adsorption region 63 a of the humidification rotor 63. The suction duct 68 has an air inlet 681 that opens toward the outdoor suction port 46 b of the front plate 46. The shape of the air inlet 681 is a sector shape with a central angle of about 240 °, like the outdoor suction port 46b. The air inlet 681 is connected to the outdoor suction port 46b.

  As shown in FIG. 4, the outside air sucked from the outdoor suction port 46b flows through the adsorption duct 68, reaches the moisture adsorption region 63a of the humidification rotor 63, and passes through the moisture adsorption region 63a. At this time, the moisture contained in the outside air is adsorbed by the moisture adsorption region 63a. The air that has passed through the moisture adsorption region 63a is discharged from the air outlet 683 of the adsorption duct 68 (see FIG. 2). The air outlet 683 is in contact with a space (a space on the upstream side of the bell mouth 52) that becomes negative pressure when the outdoor fan 39 rotates. Therefore, since the atmospheric pressure on the air outlet 683 side becomes lower than the air pressure on the air inlet 681 side due to the rotation of the outdoor fan 39, the outside air is sucked from the air inlet 681. That is, the outdoor fan 39 is a moisture absorption fan for guiding outside air to the passage where the moisture adsorption region 63a of the humidification rotor 63 is disposed.

  As shown in FIG. 3, the outdoor suction port 46b opens to the front plate 46, like the outdoor blowout port 46a. As shown in FIG. 4, the air that has passed through the outdoor heat exchanger 33 by the outdoor fan 39 is pushed out and blown out of the casing 40 from the outdoor outlet 46 a. Therefore, the air blown out from the outdoor air outlet 46a is not sucked into the outdoor air inlet 46b. Thereby, it is avoided that the low-temperature air that has passed through the outdoor heat exchanger 33 and is blown out from the outdoor outlet 46a during the heating operation is sucked into the air inlet 681 via the outdoor inlet 46b. If the low-temperature air blown out from the outdoor outlet 46a continues to be sucked into the air inlet 681 and the temperature of the humidification rotor 63 is extremely reduced, the amount of moisture that can be adsorbed by the humidification rotor 63 decreases. Therefore, the fall of the moisture content which the humidification rotor 63 can adsorb | suck is suppressed by avoiding that the air which blown off from the outdoor blower outlet 46a is suck | inhaled by the outdoor suction inlet 46b.

(3-5-4) Humidification duct 73
The humidification duct 73 guides the air that has been heated by the humidification heater 71 and passed through the moisture release region 63 b to the humidification fan 75. The air flow guided to the humidification duct 73 is generated by the humidification fan 75.

  The air guided to the humidifying duct 73 is heated by the humidifying heater 71 to become high-temperature air, and further releases moisture from the moisture releasing area 63b when passing through the moisture releasing area 63b. As shown in FIG. 4, the air that has passed through the moisture release region 63 b and has become hot and humid flows in the humidifying duct 73 and is guided to the humidifying fan 75.

(3-5-5) Humidification fan 75
The humidifying fan 75 is disposed in the machine room 42. As shown in FIG. 1, the humidifying fan 75 includes a humidifying fan rotor 75a and a humidifying fan motor 75b. The humidifying fan rotor 75a rotates around the rotation axis, and sends out humidified air in a predetermined direction through the moisture release region 63b of the humidifying rotor 63. The humidifying fan motor 75b drives the humidifying fan rotor 75a. The humidifying fan 75 is arranged so that the rotating shaft of the humidifying fan rotor 75a is along the horizontal direction. The rotating shaft of the humidifying fan rotor 75a is connected to the rotating shaft of the humidifying fan motor 75b. The humidifying fan rotor 75a is formed of resin, for example.

  The humidifying fan rotor 75 a is surrounded by a fan casing 81. The outlet of the fan casing 81 is connected to the inlet of the second humidifying duct 180. The humidifying fan motor 75 b is covered with a motor cover 82. As shown in FIGS. 4 and 5, the fan casing 81 has a suction port 81 a through which air sucked by the humidifying fan 75 passes. The suction port 81 a corresponds to the inlet of the fan casing 81 and is connected to the outlet of the humidifying duct 73. The suction port 81a of the humidifying fan 75 is provided so as to be positioned at the center of the humidifying fan rotor 75a when viewed along the rotation axis of the humidifying fan rotor 75a. The air flowing through the humidifying duct 73 and sucked into the suction port 81a is sent to the second humidifying duct 180 by the rotating humidifying fan rotor 75a.

(3-5-6) Second humidification duct 180
The second humidifying duct 180 is a duct that guides the high-temperature and high-humidity air sent by the humidifying fan 75 to the connection port of the air supply hose 18 (see FIG. 1). Almost all of the second humidifying duct 180 is disposed in the machine room 42. However, a part of the second humidifying duct 180 that is connected to the connection port of the air supply hose 18 is located on the opposite side of the machine room 42 with the right side plate 47 interposed therebetween (see FIG. 2). ).

  As shown in FIG. 5, the second humidifying duct 180 has a horizontal duct portion 181 and a vertical duct portion 182. The horizontal duct portion 181 guides high-temperature and high-humidity air in the horizontal direction. The vertical duct part 182 is connected to the horizontal duct part 181 and guides the hot and humid air passing through the horizontal duct part 181 downward. The horizontal duct portion 181 extends from the inside of the machine room 42 toward the right side plate 47. The vertical duct part 182 extends downward from the connection part with the horizontal duct part 181. The end of the vertical duct portion 182 is connected to the connection port of the air supply hose 18.

(4) Detailed Configuration of Humidification Rotor 63 and Rotor Frame Wall 65 The rotor frame wall 65 is a member for rotatably supporting the humidification rotor 63 at a predetermined position. FIG. 6 is a front view of the rotor frame wall 65. In FIG. 6, the disk-shaped outline of the humidification rotor 63 supported by the rotor frame wall 65 is indicated by a dotted line. In FIG. 6, the rotation direction of the humidification rotor 63 is indicated by a dotted arrow. FIG. 6 is a view of the humidifying rotor 63 as viewed along the rotating shaft 63d.

  The rotor frame wall 65 has an annular portion 65 a surrounding the humidifying rotor 63. As shown in FIG. 6, the surrounding surface 65 b that is the inner peripheral surface of the annular portion 65 a is a surface that faces the outer peripheral surface of the humidifying rotor 63 on the radially outer side of the humidifying rotor 63. The radial direction of the humidification rotor 63 is the radial direction of the circular main surface of the humidification rotor 63.

  As shown in FIG. 6, a resin bearing member 65 c is attached to the rotor frame wall 65. The bearing member 65 c has a shaft 66. The shaft 66 is a tapered protrusion for rotatably supporting the humidification rotor 63. When viewed along the rotation shaft 63 d of the humidification rotor 63, the bearing member 65 c is located at the center of the annular portion 65 a of the rotor frame wall 65.

  As shown in FIGS. 4 and 6, the humidification rotor 63 has a shaft through hole 67 through which the shaft 66 passes. The shaft through hole 67 is formed in the central portion of the main surface of the humidification rotor 63. As with the shaft 66, the shaft through hole 67 has a tapered shape. The humidifying rotor 63 is attached to the rotor frame wall 65 by passing the shaft 66 of the bearing member 65c attached to the rotor frame wall 65 through the shaft through hole 67 of the humidifying rotor 63.

  While the humidifying rotor 63 is rotated around the rotation shaft 63 d by the power of the rotor driving motor 64, the inner peripheral surface of the shaft through hole 67 of the humidifying rotor 63 slides with the outer peripheral surface of the shaft 66. That is, the inner peripheral surface of the shaft through hole 67 corresponds to the sliding surface of the sliding bearing.

(5) Operation of Air Conditioner 10 The operation of the air conditioner 10 in each of the cooling operation mode, the heating operation mode, and the humidification operation mode will be described.

(5-1) Cooling Operation During the cooling operation, the four-way switching valve 32 connects the discharge side of the compressor 31 and the gas side of the outdoor heat exchanger 33, and the suction side of the compressor 31 and the indoor heat. The gas side of the exchanger 21 is connected. In FIG. 1, the state of the four-way switching valve 32 during the cooling operation is indicated by a solid line.

  The liquid side closing valve 37 and the gas side closing valve 38 are in an open state. The opening degree of the electric expansion valve 34 is adjusted so that the degree of superheat of the refrigerant at the refrigerant outlet of the indoor heat exchanger 21 becomes constant at a predetermined target value.

  In the refrigerant circuit in such a state, when the operation of the compressor 31, the outdoor fan 39, and the indoor fan 22 is started, the low-pressure gas refrigerant is sucked into the compressor 31 and compressed to become a high-pressure gas refrigerant. The high-pressure gas refrigerant is sent to the outdoor heat exchanger 33 via the four-way switching valve 32 and condensed by heat exchange with the outdoor air supplied by the outdoor fan 39 to become a high-pressure liquid refrigerant. The high-pressure liquid refrigerant is reduced in pressure by the electric expansion valve 34 to become a gas-liquid two-phase refrigerant, and then sent to the indoor unit 20 via the liquid-side closing valve 37 and the liquid refrigerant communication pipe 14.

  The refrigerant in the gas-liquid two-phase state sent to the indoor unit 20 enters the indoor heat exchanger 15, where the liquid refrigerant evaporates by heat exchange with the indoor air in the indoor heat exchanger 15, and becomes a low-pressure gas refrigerant. The low-pressure gas refrigerant is sent to the outdoor unit 30 via the gas refrigerant communication pipe 16 and the gas-side closing valve 38, and flows into the accumulator 36 via the four-way switching valve 32. The low-pressure gas refrigerant that has flowed into the accumulator 36 is again sucked into the compressor 31.

  In this manner, the air conditioner 10 performs a cooling operation in which the outdoor heat exchanger 33 functions as a refrigerant condenser and the indoor heat exchanger 21 functions as a refrigerant evaporator.

(5-2) Heating Operation During the heating operation, the four-way switching valve 32 connects the discharge side of the compressor 31 and the gas side of the indoor heat exchanger 21, and the suction side of the compressor 31 and the outdoor heat. The gas side of the exchanger 33 is connected. In FIG. 1, the state of the four-way switching valve 32 during the heating operation is indicated by a dotted line.

  The liquid side closing valve 37 and the gas side closing valve 38 are in an open state. The opening degree of the electric expansion valve 34 is adjusted so that the pressure of the refrigerant flowing into the outdoor heat exchanger 33 is reduced to a pressure at which the liquid refrigerant can be completely evaporated in the outdoor heat exchanger 33.

  In the refrigerant circuit in such a state, when the operation of the compressor 31, the outdoor fan 39, and the indoor fan 22 is started, the low-pressure gas refrigerant is sucked into the compressor 31 and compressed to become a high-pressure gas refrigerant. The high-pressure gas refrigerant is sent to the indoor unit 20 via the four-way switching valve 32, the gas side closing valve 38 and the gas refrigerant communication pipe 16.

  The high-pressure gas refrigerant sent to the indoor unit 20 is condensed by heat exchange with room air in the indoor heat exchanger 21 to become a high-pressure liquid refrigerant. The high-pressure liquid refrigerant is sent to the outdoor unit 30 via the liquid refrigerant communication pipe 14 and the liquid side shut-off valve 37.

  The high-pressure liquid refrigerant sent to the outdoor unit 30 is decompressed by the electric expansion valve 34 to become a gas-liquid two-phase refrigerant, and then flows into the outdoor heat exchanger 33. The low-pressure gas-liquid two-phase refrigerant that has flowed into the outdoor heat exchanger 33 evaporates as a low-pressure gas refrigerant by heat exchange with the outdoor air supplied by the outdoor fan 39. The low-pressure gas refrigerant flows into the accumulator 36 via the four-way switching valve 32. The low-pressure gas refrigerant that has flowed into the accumulator 36 is again sucked into the compressor 31.

  In this manner, the air conditioner 10 performs a heating operation in which the indoor heat exchanger 21 functions as a refrigerant condenser and the outdoor heat exchanger 33 functions as a refrigerant evaporator.

(5-3) Humidification operation The humidification operation of the air conditioner 10 is performed in combination with the heating operation. As shown in FIGS. 2, 3, and 5, the air inlet 681 (see FIG. 5) of the adsorption duct 68 of the humidifying unit 60 faces the outdoor suction port 46 b (see FIG. 3) of the front plate 46. The air outlet port 683 (see FIG. 2) opens to the upstream side of the bell mouth 52, which becomes negative pressure when the outdoor fan 39 rotates. When the outdoor fan 39 is operated, the air pressure on the air outlet 683 side becomes lower than the air inlet 681 side, and the outside air that has not passed through the outdoor heat exchanger 33 is sucked in from the air inlet 681. Moisture contained in the outside air sucked from the air inlet 681 is adsorbed by the moisture adsorption region 63 a of the humidification rotor 63.

  The humidification rotor 63 is located between the air inlet 681 and the air outlet 683 and in the vicinity of the air outlet 683. During the humidification operation, the humidification rotor 63 is rotated at a predetermined rotation speed around the rotation shaft 63d by the power of the rotor driving motor 64. By the rotation of the humidification rotor 63, the moisture adsorbed in the moisture adsorption region 63a is carried to the moisture release region 63b.

  At the same time, by driving the humidification fan 75, the outside air taken in from the humidification opening 40a is guided to the surroundings of the humidification heater 71 and heated. The air heated by the humidifying heater 71 passes through the moisture release region 63 b of the humidifying rotor 63. At this time, moisture is released from the portion exposed to the heated air in the moisture release region 63b. Thereafter, the high-humidity air containing moisture released from the moisture release region 63 b is guided to the humidification duct 73 and supplied into the second humidification duct 180 by the humidification fan 75. The high-humidity air supplied to the second humidification duct 180 is guided to the indoor unit 20 via the air supply hose 18.

(6) Detailed configuration of the humidification rotor 63 The humidification rotor 63 is a disk-shaped member that adsorbs and releases moisture contained in the air while rotating around the rotation shaft 63d. FIG. 7 is a schematic diagram of the humidification rotor 63 viewed along the rotation shaft 63d. In the following, the case where the humidification rotor 63 is viewed along the rotation axis 63d means the case where the humidification rotor 63 is viewed so that the line of sight is parallel to the rotation axis 63d and the line of sight overlaps the rotation axis 63d. To do. In this case, as shown in FIG. 7, only the circular main surface of the humidification rotor 63 enters the field of view.

  FIG. 7 shows a circular main surface of the humidification rotor 63. The rotating shaft 63 d passes through the center of the circular main surface of the humidifying rotor 63 and passes through the center of the shaft through hole 67 of the humidifying rotor 63. In FIG. 7, the rotation direction of the humidification rotor 63 is indicated by a dotted arrow.

  The humidification rotor 63 is composed of a plurality of types of adsorbents. Specifically, as shown in FIG. 7, the main surface of the humidification rotor 63 is partitioned into a plurality of adsorbent regions 69a and 69b. Each of the adsorbent regions 69a and 69b is composed of one kind of adsorbent. The plurality of adsorbent regions 69a and 69b adjacent to each other on the main surface of the humidification rotor 63 are composed of different types of adsorbents. That is, the specifications of the adsorbents constituting the adsorbent regions 69a and 69b adjacent to each other are different from each other. The specifications of the adsorbent include, for example, the temperature at which moisture adsorbed by the adsorbent starts to be released, the moisture adsorption capacity per unit volume of the adsorbent, and the amount of adsorbent applied in each of the adsorbent regions 69a and 69b. is there. When the adsorbent has a honeycomb structure formed by firing of zeolite or the like, the cell pitch of the honeycomb structure may be used as the specification of the adsorbent. In addition, the specification of the adsorbent is constant in the thickness direction of the disk of the humidifying rotor 63, that is, in the direction along the rotating shaft 63d.

  In the humidification unit 60 of the present embodiment, as shown in FIG. 7, when the humidification rotor 63 is viewed along the rotation shaft 63d, the main surface of the humidification rotor 63 is the first adsorbent region 69a and the second adsorption. It is divided into two adsorbent regions 69a and 69b composed of a material region 69b. The first adsorbent region 69a and the second adsorbent region 69b are adjacent to each other. In FIG. 7, the first adsorbent region 69a and the second adsorbent region 69b are shown as different hatching regions, and the boundary between the first adsorbent region 69a and the second adsorbent region 69b is indicated by a dotted line. .

  The first adsorbent region 69 a is an adsorbent region located on the outermost side in the radial direction of the humidifying rotor 63. The radial direction of the humidification rotor 63 means the radial direction of the circular main surface of the humidification rotor 63 when the humidification rotor 63 is viewed along the rotation shaft 63d. The second adsorbent region 69b is an adsorbent region located on the inner side in the radial direction of the humidification rotor 63 than the first adsorbent region 69a. The second adsorbent region 69 b is an annular region surrounding the shaft through hole 67. The first adsorbent region 69a is an annular region surrounding the second adsorbent region 69b. When the humidification rotor 63 is viewed along the rotation shaft 63d, the boundary between the first adsorbent region 69a and the second adsorbent region 69b has a circular shape centering on the rotation shaft 63d. In the humidification rotor 63, the moisture adsorption capacity of the adsorbent in the first adsorbent region 69a is larger than the moisture adsorption capacity of the adsorbent in the second adsorbent region 69b.

(7) Features In the humidification unit 60 of this embodiment, the humidification rotor 63 is composed of a plurality of types of adsorbents. Thus, by providing an appropriate adsorbent in each adsorbent region 69a, 69b of the humidification rotor 63 in accordance with the characteristics of the air passing through the humidification rotor 63 and the temperature distribution of the humidification rotor 63, the humidification rotor 63 The moisture adsorption capacity can be improved. The characteristic of air passing through the humidification rotor 63 is, for example, the flow rate of air passing through the humidification rotor 63 per unit time.

  As shown in FIG. 7, on the circular main surface of the disc-shaped humidification rotor 63, the boundary between two adsorbent regions 69a and 69b adjacent to each other (the first adsorbent region 69a and the second adsorbent region 69b). Is a circular shape centering on the rotating shaft 63 d of the humidifying rotor 63. Therefore, each of the first adsorbent region 69a and the second adsorbent region 69b has an annular shape centering on the rotation shaft 63d. Since the first adsorbent region 69 a and the second adsorbent region 69 b have an annular shape, the specifications of the adsorbent constituting the humidification rotor 63 change along the radial direction of the humidification rotor 63. This is based on the fact that the characteristics of the air passing through the humidification rotor 63 and the temperature distribution of the humidification rotor 63 tend to change along the radial direction of the humidification rotor 63.

  For example, when the flow rate of air passing through the humidifying rotor 63 increases toward the radially outer side of the disc-shaped humidifying rotor 63, the humidifying rotor 63 radially outward (center side) of the humidifying rotor 63 ( By providing an adsorbent with a larger adsorption capacity on the outer periphery side, the moisture adsorption capacity of the entire humidification rotor 63 can be made larger than when the humidification rotor 63 is composed of only one type of adsorbent. Can do.

  In the humidification rotor 63 shown in FIG. 7, the adsorption capacity of the adsorbent in the first adsorbent region 69a on the radially outer side is larger than the adsorption capacity of the adsorbent in the second adsorbent region 69b on the radially inner side. large. Therefore, when the flow rate of air passing through the first adsorbent region 69a is larger than the flow rate of air passing through the second adsorbent region 69b, the adsorbent in the first adsorbent region 69a is the second adsorbent region 69b. Since a larger amount of air than the adsorbent can be adsorbed, the humidification rotor 63 can efficiently adsorb moisture contained in the air passing through the humidification rotor 63. In addition, when the adsorbent cost is higher as the moisture adsorption capacity is larger, the first adsorbent region 69a and the second adsorbent region 69b are compared with the humidifying rotor 63 made of only the adsorbent in the first adsorbent region 69a. The humidification rotor 63 made of the adsorbent has a lower manufacturing cost.

  Thus, the humidification unit 60 is composed of a plurality of types of adsorbents having different moisture adsorption capacities when the flow rate of air passing through the humidification rotor 63 increases toward the radially outer side of the disc-shaped humidification rotor 63. By providing the humidifying rotor 63 to be used, the utilization efficiency of the humidifying rotor 63 can be improved.

  Further, by improving the utilization efficiency of the humidifying unit 60, the rotational speed of the outdoor fan 39 for guiding the outside air to the moisture adsorption region 63a of the humidifying rotor 63 can be suppressed. Thereby, the noise generated from the outdoor fan 39 is suppressed, and the power consumption of the outdoor fan 39 is reduced.

  Further, by improving the utilization efficiency of the humidifying unit 60, it is possible to suppress the power consumption of the humidifying heater 71 for sending heated air to the moisture release region 63b of the humidifying rotor 63.

  Further, the characteristics of the air passing through the humidification rotor 63 and the temperature distribution of the humidification rotor 63 tend to change along the radial direction of the humidification rotor 63. Therefore, when the humidification rotor 63 has a disk shape having a circular main surface, as shown in FIG. 7, the boundary between the first adsorbent region 69a and the second adsorbent region 69b is centered on the rotation shaft 63d. The humidification unit 60 can improve the utilization efficiency of the disk-shaped humidification rotor.

(8) Modifications The specific configuration of the present invention can be changed without departing from the gist of the present invention. Next, modifications to which the embodiment of the present invention can be applied will be described.

(8-1) Modification A
In the humidification unit 60 of the embodiment, the main surface of the humidification rotor 63 is partitioned into two adsorbent regions 69a and 69b. However, the main surface of the humidification rotor 63 may be partitioned into three or more adsorbent regions.

  FIG. 8 is a schematic diagram of the humidification rotor 63 viewed along the rotation shaft 63d in the present modification. When the humidification rotor 63 is viewed along the rotating shaft 63d, the main surface of the humidification rotor 63 is divided into three adsorbent regions 169a, 169b, and 169c. The three adsorbent regions 169a, 169b, 169c are composed of one first adsorbent region 169b and two second adsorbent regions 169a, 169c. The two second adsorbent regions 169a and 169c are composed of the same type of adsorbent. The first adsorbent region 169b is composed of a different type of adsorbent from the second adsorbent regions 169a and 169c. In FIG. 8, the first adsorbent region 169b and the second adsorbent regions 169a and 169c are shown as different hatching regions, and the boundaries between the different adsorbent regions 169a, 169b and 169c are shown by dotted lines.

  The first adsorbent region 169b and the second adsorbent regions 169a and 169c are adjacent to each other. One of the two second adsorbent regions 169a and 169c is an adsorbent region 169a that is on the outermost side in the radial direction of the humidifying rotor 63, and the other is an adsorbent region 169c that is on the innermost side in the radial direction of the humidifying rotor 63. It is. The first adsorbent region 169b is a region sandwiched between the two second adsorbent regions 169a and 169c, and is an adsorbent region including the central portion in the radial direction of the humidification rotor 63. That is, the two second adsorbent regions 169 a and 169 c are located inside and outside the first adsorbent region 169 b in the radial direction of the humidification rotor 63.

  The second adsorbent region 169 c on the radially inner side is an annular region surrounding the shaft through hole 67. The first adsorbent region 169b is an annular region surrounding the second adsorbent region 169c on the radially inner side. The second adsorbent region 169a on the radially outer side is an annular region surrounding the first adsorbent region 169b. When the humidification rotor 63 is viewed along the rotation axis 63d, the boundary between the first adsorbent region 169b and the second adsorbent regions 169a and 169c has a circular shape with the rotation axis 63d as the center. .

  In the humidification rotor 63 of this modification, the temperature at which the adsorbent in the first adsorbent region 169b can be released is higher than the temperature at which the adsorbent in the second adsorbent regions 169a, 169c can be released. . The temperature at which the moisture adsorbed by the adsorbent can be released refers to the adsorbent of the humidifying rotor 63 in the process in which the temperature of the humidifying rotor 63 rises, for example, when the air heated by the humidifying heater 71 passes through the humidifying rotor 63. This is the temperature at which the adsorbed moisture begins to be released.

  In the humidification rotor 63 of the present modification, for example, when the heat of the humidification heater 71 is likely to hit the radial center of the disk-shaped humidification rotor 63, the humidification rotor 63 is radially outer (outer peripheral side) and radially inner. An adsorbent capable of releasing the adsorbed water at a higher temperature is provided at the central portion in the radial direction of the humidifying rotor 63 than (center side). That is, the adsorbents of the second adsorbent regions 169 a and 169 c located on the radially outer side (outer peripheral side) and the radially inner side (center side) of the humidifying rotor 63 are the first located in the radial center of the humidifying rotor 63. Compared to the adsorbent in the adsorbent region 169b, the adsorbed moisture can be released at a lower temperature. Therefore, the humidifying rotor 63 can efficiently release the adsorbed moisture by the heat released from the humidifying heater 71. Thereby, the utilization efficiency of the humidification rotor 63 whole improves compared with the case where the humidification rotor 63 is comprised from only one type of adsorbent.

  Therefore, the humidification unit 60 can include the humidification rotor 63 having high utilization efficiency when the heat of the humidification heater 71 is likely to hit the central portion in the radial direction of the disc-shaped humidification rotor 63.

(8-2) Modification B
In the humidification unit 60 of the embodiment, the humidification rotor 63 is composed of two types of adsorbents. However, the humidification rotor 63 may be composed of three or more types of adsorbents. In this case, the number of adsorbent regions on the main surface of the humidification rotor 63 is equal to or greater than the number of adsorbent types used in the humidification rotor 63. The plurality of adsorbent regions may be composed of the same type of adsorbent.

  FIG. 9 is a schematic diagram of the humidification rotor 63 viewed along the rotation shaft 63d in the present modification. When the humidification rotor 63 is viewed along the rotation shaft 63d, the main surface of the humidification rotor 63 is partitioned into three annular adsorbent regions 269a, 269b, and 269c.

  The three adsorbent regions 269a, 269b, and 269c include a first adsorbent region 269a, a second adsorbent region 269b, and a third adsorbent region 269c. Each of the three adsorbent regions 269a, 269b, 269c is composed of one kind of adsorbent. The three adsorbent regions 269a, 269b, and 269c are composed of three different types of adsorbents. In FIG. 9, three adsorbent regions 269a, 269b, and 269c are shown as different hatching regions, and boundaries between the different adsorbent regions 269a, 269b, and 269c are indicated by dotted lines.

  The first adsorbent region 269 a is an adsorbent region located on the outermost side in the radial direction of the humidifying rotor 63. The second adsorbent region 269b is an adsorbent region adjacent to the first adsorbent region 269a inside the first adsorbent region 269a. The third adsorbent region 269c is an adsorbent region adjacent to the second adsorbent region 269b inside the second adsorbent region 269b.

  The third adsorbent region 269 c is an annular region surrounding the shaft through hole 67. The second adsorbent region 269b is an annular region surrounding the third adsorbent region 269c. The first adsorbent region 269a is an annular region surrounding the second adsorbent region 269b. When the humidifying rotor 63 is viewed along the rotation axis 63d, the boundary between the first adsorbent region 269a and the second adsorbent region 269b, and between the second adsorbent region 269b and the third adsorbent region 269c. The boundary has a circular shape with the rotation axis 63d as the center.

  In the humidification rotor 63 shown in FIG. 9, for example, the moisture adsorption capacity of the adsorbent in the first adsorbent region 269a is larger than the moisture adsorption capacity of the adsorbent in the second adsorbent region 269b, and the second The moisture adsorption capacity of the adsorbent in the adsorbent region 269b is larger than the moisture adsorption capacity of the adsorbent in the third adsorbent region 269c.

  In the present modification, as with the humidifying rotor 63 of the embodiment, when the flow rate of air passing through the humidifying rotor 63 increases toward the outer side in the radial direction of the disk-shaped humidifying rotor 63, the moisture adsorption capacities differ from each other. The use efficiency of the humidification rotor 63 can be improved by providing the humidification rotor 63 composed of various kinds of adsorbents.

(8-3) Modification C
In the humidification unit 60 of the embodiment, as shown in FIG. 7, the humidification rotor 63 has a circular shape centered on the rotation shaft 63d when viewed along the rotation shaft 63d. In the humidification rotor 63, the boundary between the adsorbent regions 69a and 69b adjacent to each other has a circular shape centered on the rotation shaft 63d when viewed along the rotation shaft 63d.

  However, the humidification rotor 63 may have a shape other than a circular shape centered on the rotation shaft 63d when viewed along the rotation shaft 63d. In this case, each adsorbent region of the humidification rotor 63 is provided with an adsorbent selected based on the distance from the rotation shaft 63d when viewed along the rotation shaft 63d. Further, the boundary between the adsorbent regions adjacent to each other may have a shape other than a circular shape centered on the rotation shaft 63d when viewed along the rotation shaft 63d. In each adsorbent region of the humidification rotor 63, an appropriate adsorbent is provided according to the characteristics of the air passing through the humidification rotor 63 and the temperature distribution of the humidification rotor 63.

  As an example, the humidification rotor 63 may have an elliptical shape when viewed along the rotation shaft 63d. In this case, from the viewpoint of symmetry, the rotating shaft 63 of the humidifying rotor 63 is located at the midpoint of the line segment connecting the two elliptical focal points of the humidifying rotor 63 when viewed along the rotating shaft 63d. Preferably it is. Further, the boundary between the adsorbent regions adjacent to each other may have the same elliptical shape as the humidification rotor 63 when viewed along the rotation axis 63d.

  As another example, the humidification rotor 63 may have a regular polygonal shape when viewed along the rotation shaft 63d. In this case, from the viewpoint of symmetry, the rotation shaft 63 of the humidification rotor 63 is preferably located at the center of gravity of the regular polygonal shape of the humidification rotor 63 when viewed along the rotation shaft 63d. Further, the boundary between the adsorbent regions adjacent to each other may have the same regular polygonal shape as the humidification rotor 63 when viewed along the rotation axis 63d.

  The characteristics of the air passing through the humidification rotor 63 and the temperature distribution of the humidification rotor 63 tend to change according to the distance of the humidification rotor 63 from the rotating shaft 63d. Therefore, the humidification rotor 63 in this modification also has high utilization efficiency.

(8-4) Modification D
In the humidification unit 60 of the embodiment and the modification C, an adsorbent suitable for each adsorbent region 69a, 69b of the humidification rotor 63 in accordance with the characteristics of the air passing through the humidification rotor 63 and the temperature distribution of the humidification rotor 63. Is provided.

  Therefore, regardless of the shape when viewed along the rotation shaft 63d, the humidification rotor 63 is, for example, according to the flow rate distribution of the air passing through the humidification rotor 63 when viewed along the rotation shaft 63d. It may be partitioned into a plurality of adsorbent regions. That is, each adsorbent region of the humidifying rotor 63 may be provided with an adsorbent suitable for the flow rate of air passing through the region. Specifically, as in the embodiment, when the humidification rotor 63 is viewed along the rotation shaft 63d, the longer the distance from the rotation shaft 63d, the greater the flow rate of air passing through the humidification rotor 63. It is preferable to provide an adsorbent having a larger adsorption capacity in an adsorbent region having a longer distance from the rotating shaft 63d. Thereby, the humidification unit 60 can be provided with the humidification rotor 63 which has high utilization efficiency according to the distribution of the flow rate of the air passing through the humidification rotor 63.

(8-5) Modification E
In the humidification unit 60 of the embodiment and the modification C, an adsorbent suitable for each adsorbent region 69a, 69b of the humidification rotor 63 in accordance with the characteristics of the air passing through the humidification rotor 63 and the temperature distribution of the humidification rotor 63. Is provided.

  Therefore, regardless of the shape when viewed along the rotation shaft 63d, the humidification rotor 63 is, for example, according to the temperature distribution of the air passing through the humidification rotor 63 when viewed along the rotation shaft 63d. It may be partitioned into a plurality of adsorbent regions. That is, each adsorbent region of the humidification rotor 63 may be provided with an adsorbent suitable for the temperature of air passing through the region. Specifically, as in Modification A, when the humidification rotor 63 is viewed along the rotation shaft 63d, the air passing through the humidification rotor 63 is in a region where the distance from the rotation shaft 63d is within a predetermined range. When the temperature is equal to or higher than a predetermined value, it is preferable to provide an adsorbent capable of releasing moisture adsorbed at a higher temperature in the adsorbent region whose distance from the rotation shaft 63d is within the predetermined range. . Thereby, the humidification unit 60 can be provided with the humidification rotor 63 which has high utilization efficiency according to the distribution of the temperature of the air passing through the humidification rotor 63.

  The humidification device according to the present invention includes a humidification rotor having high utilization efficiency.

60 Humidification unit (humidifier)
63 Humidification rotor 63d Rotating shaft 69a First adsorbent region 69b Second adsorbent region 169a Second adsorbent region 169b First adsorbent region 169c Second adsorbent region

Japanese Patent Laid-Open No. 2001-91002

Claims (7)

A humidifying rotor (63) made of an adsorbent that adsorbs moisture in the air and releases moisture adsorbed by being heated to the air,
The humidification rotor is rotatable about a rotation axis (63d), and is divided into a plurality of adsorbent regions (69a, 69b, 169a, 169b) when viewed along the rotation axis,
Specifications of the adsorbents of the adsorbent regions adjacent to each other are different from each other.
Humidifier (60). The humidification rotor is partitioned into a plurality of adsorbent regions according to the distance from the rotation axis when viewed along the rotation axis.
The humidifier according to claim 1. The humidification rotor has a circular shape centered on the rotation axis when viewed along the rotation axis;
The boundary between the adsorbent regions adjacent to each other has a circular shape centered on the rotation axis when viewed along the rotation axis.
The humidifier according to claim 2. The humidifying rotor is
A first adsorbent region (69a) which is the adsorbent region on the outermost side in the radial direction;
A second adsorbent region (69b) that is the adsorbent region that is further inward in the radial direction than the first adsorbent region;
Have
The moisture adsorption capacity of the adsorbent in the first adsorbent region is greater than the moisture adsorption capacity of the adsorbent in the second adsorbent region;
The humidifier according to claim 3. The humidifying rotor is
A first adsorbent region (169b) that is the adsorbent region including the radial center;
A second adsorbent region (169a, 169c), which is the adsorbent region located on the inner side and the outer side in the radial direction with respect to the first adsorbent region;
Have
The temperature at which the adsorbent adsorbed in the first adsorbent region can be released is higher than the temperature at which the adsorbent adsorbed in the second adsorbent region can be released,
The humidifier according to claim 3. The humidification rotor is partitioned into a plurality of adsorbent regions according to the flow rate distribution of air passing through the humidification rotor when viewed along the rotation axis.
The humidifier according to any one of claims 1 to 3. The humidifying rotor is partitioned into a plurality of adsorbent regions according to the temperature distribution of the air passing through the humidifying rotor when viewed along the rotation axis.
The humidifier according to any one of claims 1 to 3.

Images