JP2018146217A - Humidity adjustment device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress deterioration of humidity adjustment performance due to air leakage in the vicinity of an adsorption rotor.SOLUTION: In a casing (20), a first air passage (21) and a second air passage (22) are formed. An adsorption rotor (40) is configured to be rotatable with adsorbent carried, and is arranged over the first air passage (21) and the second air passage (22) so that air passes in an axis direction, where a region on the first air passage (21) is an adsorption region (41), and a region on the second air passage (22) is a regeneration region (42). An air passage direction in the adsorption region (41) is identical to an air passage direction in the regeneration region (42).SELECTED DRAWING: Figure 1

Description

  The present invention relates to a humidity control apparatus including an adsorption rotor.

  2. Description of the Related Art Conventionally, a humidity control apparatus that performs humidity control (humidity control) using an adsorption rotor is known. For example, Patent Literature 1 discloses an air conditioner including a rotary dehumidifier (adsorption rotor) having an adsorption unit capable of adsorbing moisture in the air. This rotary dehumidifier is disposed across the air supply passage and the exhaust passage. In this air conditioner, the outdoor air sucked into the air supply passage passes through the air supply passage portion (portion on the air supply passage side) of the rotary dehumidifier and is dehumidified by the adsorbing means and blown into the room. The room air sucked into the exhaust passage passes through the exhaust passage portion (portion on the exhaust passage side) of the rotary dehumidifier, dries the adsorbing means, and is blown out of the room.

JP 2006-250414 A

  However, in the air conditioner of Patent Document 1, the air passage direction in the air supply passage portion of the rotary dehumidifier (adsorption rotor) is opposite to the air passage direction in the exhaust passage portion of the rotary dehumidifier. Therefore, the pressure difference between the air supply passage and the exhaust passage tends to increase in the vicinity of the rotary dehumidifier, and the vicinity of the rotary dehumidifier (for example, a partition wall that partitions the air supply passage and the exhaust passage) Air is likely to leak from one of the supply passage and the exhaust passage to the other in the gap between the rotary dehumidifier. And humidity control performance will become low, so that the air leak in the vicinity of a rotary dehumidifier (the air leak from one side of an air supply passage and an exhaust passage to the other) increases.

  Then, this invention aims at providing the humidity control apparatus which can suppress the fall of the humidity control performance resulting from the air leak in the vicinity of an adsorption | suction rotor.

  The first invention comprises a casing (20) formed with a first air passage (21) and a second air passage (22) through which air flows, respectively, and an adsorbent supported thereon so as to be rotatable. So that the air passes through the first air passage (21) and the second air passage (22), and the region on the first air passage (21) side absorbs moisture in the air. An adsorption area (41) for dehumidifying air by adsorbing to the adsorbent, and an area on the second air passage (22) side desorbing moisture from the adsorbent into the air to regenerate the adsorbent ( 42), and the air passage direction in the adsorption region (41) and the air passage direction in the regeneration region (42) are the same direction. It is a humidity control device.

  In the first aspect of the invention, since the air passage direction in the adsorption region (41) of the adsorption rotor (40) and the air passage direction in the regeneration region (42) are the same direction, the adsorption rotor (40) The first air passage (21) in the vicinity of the adsorption rotor (40) than the case where the air passage direction in the adsorption region (41) and the air passage direction in the regeneration region (42) are opposite to each other. A pressure difference with the second air passage (22) can be reduced. As a result, the first air passage (in the vicinity of the partition wall separating the first air passage (21) and the second air passage (22) and the adsorption rotor (40)) in the vicinity of the adsorption rotor (40) ( 21) and the second air passage (22) can be made difficult to leak air from one to the other.

  According to a second invention, in the first invention, the second invention is configured to be rotatable and straddles the first air passage (21) and the second air passage (22) so that air passes in the axial direction. The region on the first air passage (21) side becomes a heat dissipation region (51) that radiates heat to the air, and the region on the second air passage (22) side becomes a heat absorption region (52) that absorbs heat from the air. The sensible heat rotor (50) includes a sensible heat rotor (50), wherein the heat dissipation area (51) is disposed downstream of the adsorption area (41) of the adsorption rotor (40) in the first air passage (21). And the heat absorption region (52) is disposed in the second air passage (22) so as to be located downstream of the regeneration region (42) of the adsorption rotor (40). It is a humidity control device.

  In the second aspect of the invention, the heat absorbed from the air passing through the heat absorption region (52) of the sensible heat rotor (50) (that is, the air passing through the regeneration region (42) of the adsorption rotor (40)) is sensible heat. It can discharge | release to the air which passes the thermal radiation area | region (51) of a rotor (50).

  A third invention is characterized in that, in the second invention, the adsorption rotor (40) and the sensible heat rotor (50) are integrally formed to constitute a processing rotor (30). Wet device.

  In the third aspect of the present invention, the adsorption rotor (40) and the sensible heat rotor (50) are formed by integrally forming the adsorption rotor (40) and the sensible heat rotor (50) to constitute the processing rotor (30). The installation space for the adsorption rotor (40) and the sensible heat rotor (50) (the space required to install the adsorption rotor (40) and the sensible heat rotor (50)) is smaller than when forming separately. be able to.

  According to a fourth aspect of the present invention, in the second or third aspect of the present invention, the suction rotor (40) includes a controller (80) that controls the number of rotations of the adsorption rotor (40) and the sensible heat rotor (50). And the sensible heat rotor (50), and the control unit (80) is configured so that the dehumidification characteristic line (L1) indicates the relationship between the dehumidification amount and the rotation speed of the adsorption rotor (40). The rotational speeds of the adsorption rotor (40) and the sensible heat rotor (50) are controlled within the first rotational speed range (RR1) including the dehumidifying peak rotational speed (RDP) corresponding to the dehumidifying amount peak value (DP). The first rotational speed control and the second rotational speed range (RR2) lower than the first rotational speed range (RR1) control the rotational speeds of the adsorption rotor (40) and the sensible heat rotor (50). 2 rotation speed control and within the third rotation speed range (RR3) higher than the first rotation speed range (RR1). There are a the suction rotor (40) and the humidity controller which is characterized in that the third rotational speed control for controlling the rotational speed of the sensible heat rotor (50).

  In the fourth aspect of the invention, the dehumidification characteristic line (L1) indicates that the dehumidification amount gradually increases with the increase in the rotational speed in the range from the minimum rotational speed to the dehumidifying peak rotational speed (RDP), and the dehumidifying peak rotational speed (RDP) ) To the maximum number of revolutions, the dehumidification amount gradually decreases as the number of revolutions increases (curved curve). That is, in the adsorption rotor (40), the dehumidification amount of the adsorption rotor (40) gradually increases in accordance with the increase in the rotation speed of the adsorption rotor (40) in the range from the minimum rotation speed to the dehumidification peak rotation speed (RDP). In the range from the dehumidification peak rotation speed (RDP) to the maximum rotation speed, the dehumidification amount is such that the dehumidification amount of the adsorption rotor (40) gradually decreases as the rotation speed of the adsorption rotor (40) increases. In the sensible heat rotor (50), the sensible heat exchange of the sensible heat rotor (50) in response to the increase in the number of rotations of the sensible heat rotor (50) in the range from the minimum speed to the sensible heat peak speed (RSP). The sensible heat exchange rate of the sensible heat rotor (50) gradually decreases as the sensible heat rotor (50) increases in rotation speed in the range from the sensible heat peak rotation speed (RSP) to the maximum rotation speed. It has sensible heat characteristics. The sensible heat peak rotational speed (RSP) is a rotational speed corresponding to the peak value (SP) of the sensible heat exchange rate.

  According to a fifth invention, in any one of the first to fourth inventions, a refrigerant circuit (60) having a compressor (61), a condenser (62), and an evaporator (64) is provided. The condenser (62) is disposed upstream of the regeneration region (42) of the adsorption rotor (40) in the second air passage (22), and the evaporator (64) is connected to the first air passage (21 The humidity control device is disposed downstream of the suction region (41) of the suction rotor (40).

  In the fifth aspect of the invention, the heat absorbed from the air passing through the evaporator (64) (that is, the air passing through the adsorption region (41) of the adsorption rotor (40)) is passed through the condenser (62). (That is, air supplied to the regeneration region (42) of the adsorption rotor (40)).

  According to the first invention, air leakage in the vicinity of the adsorption rotor (40) (air leakage from one of the first air passage (21) and the second air passage (22) to the other) can be reduced. And the fall of the humidity control performance resulting from the air leak in the vicinity of an adsorption | suction rotor (40) can be suppressed.

  According to the second invention, the heat absorbed from the air passing through the heat absorption region (52) of the sensible heat rotor (50) (that is, the air passing through the regeneration region (42) of the adsorption rotor (40)) is sensible heat. Since the heat can be released to the air passing through the heat dissipation area (51) of the rotor (50), the heat remaining in the air that has passed through the regeneration area (42) of the adsorption rotor (40) is transferred to the sensible heat rotor (50). It can utilize in the downstream of a thermal radiation area | region (51).

  According to the third aspect, the number of parts of the humidity control device can be reduced. Moreover, since the installation space for the adsorption rotor (40) and the sensible heat rotor (50) can be reduced, the humidity control apparatus can be reduced in size.

  According to the fourth aspect of the present invention, the humidity control capability of the adsorption rotor (40) and the sensible heat rotor (50) are changed by switching between the first rotation speed control, the second rotation speed control, and the third rotation speed control. The humidity can be adjusted by switching the balance with the sensible heat capacity.

  According to the fifth aspect of the invention, the air that has passed through the condenser (62) receives heat absorbed from the air passing through the evaporator (64) (that is, the air that has passed through the adsorption region (41) of the adsorption rotor (40)). (That is, air supplied to the regeneration area (42) of the adsorption rotor (40)), so that the heat remaining in the air that has passed through the adsorption area (41) of the adsorption rotor (40) can be removed. It can be used in the playback area (42) of (40).

FIG. 1 is a schematic view illustrating the configuration of a humidity control apparatus according to an embodiment. FIG. 2 is a schematic view illustrating the configuration of the processing rotor. FIG. 3 is a graph illustrating the dehumidification characteristic of the adsorption rotor and the sensible heat characteristic of the sensible heat rotor. FIG. 4 is a schematic view illustrating the configuration of Modification 1 of the humidity control apparatus. FIG. 5 is a schematic view illustrating the configuration of Modification 2 of the humidity control apparatus.

  Hereinafter, embodiments will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and description thereof will not be repeated.

(Humidity control device)
FIG. 1 illustrates the configuration of the humidity control apparatus (10) according to the embodiment. The humidity control device (10) performs indoor humidity control (humidity control). The casing (20), the processing rotor (30), the refrigerant circuit (60), the first fan (71), A second fan (72) and a controller (80) are provided. In this example, the humidity control device (10) constitutes a dehumidifying device for dehumidifying the room.

〔casing〕
The casing (20) accommodates the processing rotor (30), the refrigerant circuit (60), the first fan (71), and the second fan (72). The casing (20) has a first air passage (21) and a second air passage (22). In this example, the casing (20) is formed in a rectangular parallelepiped box shape, and the internal space of the casing (20) is defined by the first partition wall (25) and the second partition wall (26) and the first air passage (21) and the second air. It is partitioned into a passage (22) and a storage chamber (23). Specifically, the first partition wall (25) partitions the first air passage (21) and the second air passage (22), and the second partition wall (26) stores the first air passage (21). The room (23) is separated.

<Air passage>
Air flows through the first air passage (21) and the second air passage (22), respectively. In this example, the first air passage (21) has a first suction port (21a) communicating with the indoor space and a first air outlet (21b) communicating with the indoor space, and the air sucked from the indoor space. (Indoor air (RA)) is supplied to the indoor space as supply air (SA). The second air passage (22) has a second suction port (22a) communicating with the indoor space and a second air outlet (22b) communicating with the outdoor space, and the air (room air ( RA)) is blown out to the outdoor space as exhaust air (EA).

[Processing rotor]
The processing rotor (30) is configured to be rotatable about the rotation axis (O), and is rotationally driven by a drive mechanism (not shown). The processing rotor (30) is disposed across the first air passage (21) and the second air passage (22) so that air passes in the axial direction. Specifically, the processing rotor (30) has a large number of vent holes (not shown) penetrating in the axial direction, and the first air passage (21) and the second air passage so that air flows through these vent holes. It is disposed across the air passage (22).

  Further, an adsorbent is carried on a portion on one end side in the axial direction of the processing rotor (30). The remaining part of the processing rotor (30) (that is, the part on the other end side in the axial direction) does not carry the adsorbent. As a result, the portion on one end side in the axial direction of the processing rotor (30) (the portion on which the adsorbent is carried) constitutes the suction rotor (40), and the portion on the other end side in the axial direction of the processing rotor (30) (suction) The portion where the agent is not supported) constitutes the sensible heat rotor (50). That is, in this example, the adsorption rotor (40) and the sensible heat rotor (50) are integrally formed to constitute the processing rotor (30), and the adsorption rotor (40) and the sensible heat rotor (50) are formed. It is configured to go around. The processing rotor (30) is positioned upstream of the portion where the adsorption rotor (40) becomes the sensible heat rotor (50) in the first air passage (21) and the second air passage (22). Are arranged as follows.

<Suction rotor>
The adsorption rotor (40) carries an adsorbent. The adsorption rotor (40) is configured to be rotatable about the rotation axis (O), and straddles the first air passage (21) and the second air passage (22) so that air passes in the axial direction. Arranged. Specifically, the adsorption rotor (40) has a large number of vent holes (not shown) penetrating in the axial direction, and the first air passage (21) and the second air passage so that air flows through these vent holes. It is disposed across the air passage (22).

  In the adsorption rotor (40), the area on the first air passage (21) side becomes an adsorption area (41) for desorbing air by adsorbing moisture in the air to the adsorbent, and on the second air passage (22) side. This region is a regeneration region (42) for regenerating the adsorbent by desorbing moisture from the adsorbent into the air. As the adsorption rotor (40) rotates, the portion of the adsorption rotor (40) on the first air passage (21) side moves toward the second air passage (22), and the adsorption rotor (40) A portion on the second air passage (22) side moves toward the first air passage (21).

<Sensible heat rotor>
The sensible heat rotor (50) is configured to be rotatable about the rotation axis (O), and straddles the first air passage (21) and the second air passage (22) so that air passes in the axial direction. It is arranged. Specifically, the sensible heat rotor (50) has a large number of ventilation holes (not shown) penetrating in the axial direction, and the first air passage (21) and the first air passage (21) are arranged so that air flows through these ventilation holes. It is arranged across the two air passages (22).

  In the sensible heat rotor (50), the region on the first air passage (21) side becomes a heat dissipation region (51) that radiates heat to the air, and the region on the second air passage (22) side absorbs heat from the air ( 52). As the sensible heat rotor (50) rotates, a portion of the sensible heat rotor (50) on the first air passage (21) side moves toward the second air passage (22) side, and a sensible heat rotor ( The portion of 50) on the second air passage (22) side moves toward the first air passage (21) side.

  The sensible heat rotor (50) is disposed downstream of the adsorption rotor (40) in the first air passage (21) and the second air passage (22). Specifically, in the sensible heat rotor (50), the heat radiation area (51) is located downstream of the adsorption area (41) of the adsorption rotor (40) in the first air passage (21), and the second air In the passage (22), the heat absorption region (52) is disposed on the downstream side of the regeneration region (42) of the adsorption rotor (40).

<Processing rotor structure>
As shown in FIG. 2, in this example, the processing rotor (30) is formed in a disk shape. That is, the adsorption rotor (40) and the sensible heat rotor (50) are formed in a disk shape. For example, the processing rotor (30) has a large number of vent holes (which are made of metal fibers such as copper and aluminum, carbon fibers, plant fibers such as pulp, ceramic fibers, glass fibers, etc. and penetrate in the axial direction ( (Not shown) is formed of a disk-shaped substrate on which is formed. The portion on one end side in the axial direction of the base material and the adsorbent (the adsorbent carried on the portion on one end side in the axial direction of the base material) constitute the suction rotor (40), and the other end side in the axial direction of the base material This part (the part where the adsorbent is not carried) constitutes the sensible heat rotor (50). That is, in this example, the adsorption rotor (40) is composed of a disk-shaped base material and an adsorbent carried on the base material, and the sensible heat rotor (50) is composed of a disk-shaped base material. It is configured.

  The adsorbent may be composed of zeolite, silica gel, activated carbon, an organic polymer material having a hydrophilic functional group, or a material having not only a function of adsorbing moisture but also a function of absorbing moisture (so-called (Sorbent).

  In addition, the sensible heat rotor (50) (in this example, the portion on the other end side in the axial direction of the processing rotor (30) on which the adsorbent is not supported) is made of powder of a high heat conductive material (for example, copper or aluminum). It may be supported, powder of high specific heat material (for example, lead) may be supported, or sensible heat storage agent (for example, soil, crushed brick, crushed rock, etc.) may be supported. .

[Refrigerant circuit]
The refrigerant circuit (60) includes a compressor (61), a condenser (62), an expansion mechanism (63), and an evaporator (64). In the refrigerant circuit (60), a compressor (61), a condenser (62), an expansion mechanism (63), and an evaporator (64) are connected in order to form a closed circuit. Specifically, the discharge pipe of the compressor (61) and the gas end of the condenser (62) are connected, the liquid end of the condenser (62) and the expansion mechanism (63) are connected, and the expansion mechanism (63 ) And the liquid end of the evaporator (64) are connected, and the liquid end of the evaporator (64) and the suction pipe of the compressor (61) are connected. In the refrigerant circuit (60), the refrigerant circulates to perform a vapor compression refrigeration cycle.

<Compressor>
The compressor (61) is configured to compress and discharge the sucked refrigerant. For example, the compressor (61) is configured by a variable capacity compressor (rotary type, swing type, scroll type compressor, etc.) whose operating frequency can be adjusted by an inverter circuit (not shown). In this example, the compressor (61) is disposed in the storage chamber (23).

<Condenser>
The condenser (62) is configured to exchange heat between the refrigerant and the air. That is, in the condenser (62), heat is exchanged between the refrigerant passing through the condenser (62) and the air passing through the condenser (62). For example, the condenser (62) is a fin-and-tube heat exchanger.

<Expansion mechanism>
The expansion mechanism (63) is configured to reduce the pressure of the refrigerant. For example, the expansion mechanism (63) is configured by an electronic expansion valve. In this example, the expansion mechanism (63) is disposed in the second air passage (22).

<Evaporator>
The evaporator (64) is configured to exchange heat between the refrigerant and the air. That is, in the evaporator (64), the refrigerant passing through the evaporator (64) and the air passing through the evaporator (64) exchange heat. For example, the evaporator (64) is configured by a fin-and-tube heat exchanger.

<Flow of refrigerant in refrigerant circuit>
In the refrigerant circuit (60), the refrigerant discharged from the compressor (61) dissipates heat to the air and condenses in the condenser (62). Thereby, the air passing through the condenser (62) is heated. The refrigerant flowing out of the condenser (62) is depressurized in the expansion mechanism (63), and absorbs heat from the air and evaporates in the evaporator (64). Thereby, the air passing through the evaporator (64) is cooled. The refrigerant that has flowed out of the evaporator (64) is sucked into the compressor (61).

<Condenser arrangement>
The condenser (62) is disposed upstream of the regeneration region (42) of the adsorption rotor (40) in the second air passage (22). In this example, in the second air passage (22), the regeneration region (42) of the adsorption rotor (40) is disposed on the downstream side of the condenser (62), and downstream of the regeneration region (42) of the adsorption rotor (40). An endothermic region (52) of the sensible heat rotor (50) is disposed on the side.

<Evaporator arrangement>
The evaporator (64) is disposed downstream of the adsorption region (41) of the adsorption rotor (40) in the first air passage (21). In this example, in the first air passage (21), the heat radiation area (51) of the sensible heat rotor (50) is disposed downstream of the adsorption area (41) of the adsorption rotor (40), and the sensible heat rotor (50). An evaporator (64) is disposed downstream of the heat dissipation area (51).

〔fan〕
The first fan (71) is provided in the first air passage (21) and is configured to convey the air in the first air passage (21). Specifically, the first fan (71) has the first air passage (21) so that air flows from the first suction port (21a) toward the first air outlet (21b) in the first air passage (21). ) Carry the air inside. For example, the first fan (71) is a sirocco fan. In this example, from the upstream side to the downstream side of the first air passage (21), the adsorption region (41) of the adsorption rotor (40), the heat radiation region (51) of the sensible heat rotor (50), and the evaporator ( 64) and the first fan (71) are arranged in this order.

  The 2nd fan (72) is provided in the 2nd air passage (22), and is constituted so that the air in the 2nd air passage (22) may be conveyed. Specifically, the second fan (72) has the second air passage (22) such that air flows from the second suction port (22a) to the second air outlet (22b) in the second air passage (22). ) Carry the air inside. For example, the second fan (72) is configured by a sirocco fan. In this example, from the upstream side to the downstream side of the second air passage (22), the regeneration region (42) of the condenser (62) and the adsorption rotor (40) and the heat absorption region ( 52) and the second fan (72) are arranged in order.

[Various sensors]
Each part of the humidity control device (10) includes various sensors (not shown) such as a temperature sensor that detects the temperature of air and refrigerant, a humidity sensor that detects the humidity of air, and a pressure sensor that detects the pressure of refrigerant. Is provided. Then, detection signals (signals indicating detection results) of these various sensors are transmitted to the controller (80).

[Controller (control unit)]
The controller (80) is a humidity control device based on detection signals from various sensors (not shown) provided in each part of the humidity control device (10) and instructions from the operator of the humidity control device (10). Control the operation of the humidity controller (10) by controlling each part of (10) (specifically, the processing rotor (30), refrigerant circuit (60), first fan (71) and second fan (72)) Is configured to do. For example, the controller (80) includes an arithmetic processing unit such as a CPU and a storage unit such as a memory that stores programs and information for operating the arithmetic processing unit.

  In this example, the controller (80) is configured to perform rotation speed control for controlling the rotation speed of the processing rotor (30) (that is, the rotation speed of the adsorption rotor (40) and the sensible heat rotor (50)). . The rotational speed control by the controller (80) will be described in detail later.

[Air flow in humidity controller]
Next, the flow of air in the humidity control apparatus (10) will be described with reference to FIG.

<Air flow in the first air passage>
In the first air passage (21), the air sucked into the first air passage (21) through the first suction port (21a) is radiated from the adsorption region (41) of the adsorption rotor (40) and the sensible heat rotor (50). It passes through the region (51), the evaporator (64), and the first fan (71) in this order, and is blown out from the first air passage (21) through the first air outlet (21b).

  In the adsorption region (41) of the adsorption rotor (40), moisture in the air passing through the adsorption region (41) is adsorbed by the adsorbent in the adsorption region (41). Thereby, the air passing through the adsorption region (41) is dehumidified. Further, the air passing through the adsorption region (41) is heated by the adsorption heat of the adsorbent in the adsorption region (41). Thereby, the temperature of the air passing through the adsorption region (41) increases.

  In the heat radiation area (51) of the sensible heat rotor (50), the heat radiation area (51) radiates heat to the air passing through the heat radiation area (51). Thereby, the temperature of the air passing through the heat radiation area (51) increases.

  In the evaporator (64), the refrigerant flowing through the evaporator (64) absorbs heat from the air passing through the evaporator (64). Thereby, the temperature of the air which passes an evaporator (64) falls.

  In this example, the indoor air (RA) sucked into the first air passage (21) is dehumidified in the adsorption region (41) of the adsorption rotor (40) and passes through the adsorption region (41) of the adsorption rotor (40). Air is heated in the heat dissipation area (51) of the sensible heat rotor (50), and the air that has passed through the heat dissipation area (51) of the sensible heat rotor (50) is cooled in the evaporator (64). The passed air is blown out into the indoor space as supply air (SA). In this way, the air dehumidified in the humidity control device (10) is supplied to the indoor space.

<Air flow in the second air passage>
In the second air passage (22), the air sucked into the second air passage (22) through the second suction port (22a) becomes the regeneration region (42) of the condenser (62) and the adsorption rotor (40) and the sensible heat. The heat absorption region (52) of the rotor (50) and the second fan (72) pass through in order, and are blown out from the second air passage (22) through the second air outlet (22b).

  In the condenser (62), the refrigerant flowing through the condenser (62) radiates heat to the air passing through the condenser (62). This increases the temperature of the air passing through the condenser (62).

  In the regeneration region (42) of the adsorption rotor (40), moisture is desorbed from the adsorbent in the regeneration region (42) to the air passing through the regeneration region (42). Thereby, the air passing through the regeneration region (42) is humidified, and the adsorbent in the regeneration region (42) is regenerated.

  In the endothermic region (52) of the sensible heat rotor (50), the endothermic region (52) absorbs heat from the air passing through the endothermic region (52). Thereby, the temperature of the air passing through the endothermic region (52) is lowered.

  In this example, the indoor air (RA) sucked into the second air passage (22) is heated in the condenser (62), and the air passing through the condenser (62) is regenerated in the regeneration region (42) of the adsorption rotor (40). ) And the adsorbent in the regeneration region (42) is regenerated, and the air that has passed through the regeneration region (42) of the adsorption rotor (40) is cooled in the endothermic region (52) of the sensible heat rotor (50), The air that has passed through the endothermic region (52) of the sensible heat rotor (50) is blown out into the outdoor space as exhaust air (EA). In this way, the air humidified in the humidity control apparatus (10) is discharged to the outdoor space.

<Air passing direction in adsorption rotor and sensible heat rotor>
In the humidity control apparatus (10) according to this embodiment, the air passage direction in the adsorption region (41) of the adsorption rotor (40) is the same as the air passage direction in the regeneration region (42) of the adsorption rotor (40). It has become the direction. The air passage direction in the heat dissipation region (51) of the sensible heat rotor (50) and the air passage direction in the heat absorption region (52) of the sensible heat rotor (50) are the same direction.

[Dehumidification characteristics and sensible heat characteristics]
Next, the dehumidification characteristic of the adsorption rotor (40) and the sensible heat characteristic of the sensible heat rotor (50) will be described with reference to FIG. In FIG. 3, the dehumidification characteristic line (L1) indicates the relationship between the rotation speed of the adsorption rotor (40) and the dehumidification amount of the adsorption rotor (40), and the sensible heat characteristic line (L2) indicates the sensible heat rotor (50). The relationship between the number of rotations and the sensible heat exchange rate of the sensible heat rotor (50) is shown. The dehumidification amount of the adsorption rotor (40) corresponds to the amount of moisture adsorbed from the air to the adsorbent in the adsorption region (41) of the adsorption rotor (40), and the sensible heat exchange rate of the sensible heat rotor (50) is This corresponds to the ratio of the amount of heat released from the heat dissipation region (51) to the air out of the amount of heat accumulated in the heat dissipation region (51) of the sensible heat rotor (50).

  As shown in FIG. 3, the dehumidification characteristic line (L1) indicates that the dehumidification amount gradually increases as the rotational speed increases in the range from the minimum rotational speed (for example, zero) to the dehumidifying peak rotational speed (RDP). In the range from the rotational speed (RDP) to the maximum rotational speed, the dehumidification amount gradually decreases as the rotational speed increases (curved curve). The dehumidifying peak rotational speed (RDP) is a rotational speed corresponding to the dehumidifying amount peak value (DP). That is, in the adsorption rotor (40), the dehumidification amount of the adsorption rotor (40) gradually increases in accordance with the increase in the rotation speed of the adsorption rotor (40) in the range from the minimum rotation speed to the dehumidification peak rotation speed (RDP). In the range from the dehumidification peak rotation speed (RDP) to the maximum rotation speed, the dehumidification amount is such that the dehumidification amount of the adsorption rotor (40) gradually decreases as the rotation speed of the adsorption rotor (40) increases.

  As shown in FIG. 3, the sensible heat characteristic line (L2) has a sensible heat exchange rate that gradually increases with an increase in the rotational speed in the range from the minimum rotational speed (for example, zero) to the sensible heat peak rotational speed (RSP). In the range from the sensible heat peak rotational speed (RSP) to the maximum rotational speed, the sensible heat exchange rate gradually decreases as the rotational speed increases (curved upward curve). The sensible heat peak rotational speed (RSP) is the rotational speed corresponding to the peak value (SP) of the sensible heat exchange rate. That is, in the sensible heat rotor (50), the sensible heat exchange of the sensible heat rotor (50) in accordance with the increase in the number of rotations of the sensible heat rotor (50) in the range from the minimum speed to the sensible heat peak speed (RSP). The sensible heat exchange rate of the sensible heat rotor (50) gradually decreases as the sensible heat rotor (50) increases in rotation speed in the range from the sensible heat peak rotation speed (RSP) to the maximum rotation speed. It has sensible heat characteristics. In the example of FIG. 3, the sensible heat peak rotational speed (RSP) is lower than the dehumidifying peak rotational speed (RDP).

[Rotational speed control by controller]
Next, the rotational speed control by the controller (80) will be described with reference to FIG. In this example, the controller (80) is configured to selectively perform the first rotation speed control, the second rotation speed control, and the third rotation speed control. For example, the controller (80) may be configured to switch the rotational speed control based on the temperature of the room air (RA), relative humidity, absolute humidity, or the like, or operate the humidity controller (10). It may be configured to perform the rotational speed control in response to an instruction from the person.

  In FIG. 3, the first rotation speed range (RR1) corresponds to the dehumidification amount peak value (DP) in the dehumidification characteristic line (L1) indicating the relationship between the dehumidification amount and the rotation speed of the adsorption rotor (40). This is the rotation speed range including the dehumidification peak rotation speed (RDP). The second rotation speed range (RR2) is a rotation speed range lower than the first rotation speed range (RR1). The third rotation speed range (RR3) is a higher rotation speed range than the first rotation speed range (RR1). In this example, the sensible heat peak rotational speed (RSP) is included in the second rotational speed range (RR2).

<First rotation speed control>
In the first rotation speed control, the controller (80) causes the rotation speed of the processing rotor (30) within the first rotation speed range (RR1) (that is, the rotation speed of the adsorption rotor (40) and the sensible heat rotor (50), The same). As shown in FIG. 3, the dehumidification amount of the adsorption rotor (40) in the first rotation speed range (RR1) is the same as that of the adsorption rotor (40) in the second rotation speed range (RR2) and the third rotation speed range (RR3). More than the amount of dehumidification. That is, in the first rotation speed control, the humidity of the air can be adjusted in a state where the humidity adjustment capability of the adsorption rotor (40) is relatively high. Therefore, in the first rotation speed control, when it is required to adjust the humidity of the air while the humidity adjustment capability of the adsorption rotor (40) is relatively high (for example, the indoor dehumidification load is relatively high). This is effective in the case where indoor dehumidification is given priority in the summer when the dehumidifying capacity is improved.

  The sensible heat exchange rate of the sensible heat rotor (50) in the first rotational speed range (RR1) is the sensible heat exchange rate of the sensible heat rotor (50) in the second rotational speed range (RR2) (in this example, in particular Lower than the sensible heat rotor (50) sensible heat exchange rate in the range from the sensible heat peak rotational speed (RSP) to the rotational speed that defines the upper limit of the second rotational speed range (RR2), and the third rotational speed range ( It is higher than the sensible heat exchange rate of the sensible heat rotor (50) in RR3).

<Second rotational speed control>
In the second rotation speed control, the controller (80) controls the rotation speed of the processing rotor (30) within the second rotation speed range (RR2). As shown in FIG. 3, the sensible heat exchange rate of the sensible heat rotor (50) in the second rotational speed range (RR2) (in this example, particularly from the sensible heat peak rotational speed (RSP) to the second rotational speed range (RR2)). The sensible heat exchange rate of the sensible heat rotor (50) in the range up to the rotational speed that defines the upper limit of the sensible heat rotor (50) in the first rotational speed range (RR1) and the third rotational speed range (RR3) It is higher than the sensible heat exchange rate. That is, in the second rotational speed control, the humidity of the air can be adjusted while the sensible heat capacity of the sensible heat rotor (50) is relatively high. Therefore, in the second rotational speed control, when it is required to adjust the humidity of the air while the sensible heat capacity of the sensible heat rotor (50) is relatively high (for example, the indoor temperature does not become too low). Thus, it is effective in the case of dehumidifying indoors, such as in the case of adjusting indoor humidity in the intermediate period or winter season).

  The dehumidification amount of the adsorption rotor (40) in the second rotation speed range (RR2) is smaller than the dehumidification amount of the adsorption rotor (40) in the first rotation speed range (RR1).

<Third rotation speed control>
In the third rotation speed control, the controller (80) controls the rotation speed of the processing rotor (30) within the third rotation speed range (RR3). As shown in FIG. 3, the sensible heat exchange rate of the sensible heat rotor (50) in the third rotational speed range (RR3) is the sensible heat exchange rate of the sensible heat rotor (50) in the first rotational speed range (RR1) and The sensible heat exchange rate of the sensible heat rotor (50) in the second rotational speed range (RR2) (in this example, the rotational speed that prescribes the upper limit of the second rotational speed range (RR2) in particular from the sensible heat peak rotational speed (RSP)) The sensible heat exchange rate of the sensible heat rotor (50) in the range up to. That is, in the third rotational speed control, the humidity of the air can be adjusted with the sensible heat capacity of the sensible heat rotor (50) being relatively low. Therefore, in the third rotation speed control, when it is required to adjust the humidity of the air with the sensible heat capacity of the sensible heat rotor (50) being relatively low (for example, the indoor temperature does not become too high). As described above, the dehumidification of the room is effective in the case of dehumidifying the room with priority given to the suppression of the increase in the cooling load of the room in summer.

  The dehumidification amount of the adsorption rotor (40) in the third rotation speed range (RR3) is smaller than the dehumidification amount of the adsorption rotor (40) in the first rotation speed range (RR1).

  For example, as shown in FIG. 3, the first rotational speed (R1) included in the second rotational speed range (RR2) corresponds to the first dehumidification amount (D1) and the first sensible heat exchange rate (S1). ing. That is, when the rotation speed of the adsorption rotor (40) and the sensible heat rotor (50) is set to the first rotation speed (R1), the dehumidification amount of the adsorption rotor (40) becomes the first dehumidification amount (D1). The sensible heat exchange rate of the sensible heat rotor (50) is the first sensible heat exchange rate (S1). Further, the second rotational speed (R2) included in the third rotational speed range (RR3) is a second sensible heat exchange rate (S2) lower than the first dehumidification amount (D1) and the first sensible heat exchange rate (S1). ). That is, comparing the first rotation speed (R1) and the second rotation speed (R2), the dehumidification amount of the adsorption rotor (40) is the same at the first rotation speed (R1) and the second rotation speed (R2). However, the sensible heat exchange rate of the sensible heat rotor (50) is lower at the second rotational speed (R2) than at the first rotational speed (R1).

[Effects of the embodiment]
As described above, in the humidity control apparatus (10) according to this embodiment, the air passage direction in the adsorption region (41) of the adsorption rotor (40) and the air passage direction in the regeneration region (42) of the adsorption rotor (40). Are in the same direction. For this reason, in the vicinity of the adsorption rotor (40), the air passage direction in the adsorption region (41) of the adsorption rotor (40) and the air passage direction in the regeneration region (42) are opposite to each other. The pressure difference between the first air passage (21) and the second air passage (22) can be reduced. Thus, in the vicinity of the adsorption rotor (40) (for example, the gap between the first partition wall (25) and the adsorption rotor (40) separating the first air passage (21) and the second air passage (22)). Air can be made difficult to leak from one of the first air passage (21) and the second air passage (22) to the other. Therefore, it is possible to suppress a decrease in humidity control performance due to air leakage in the vicinity of the adsorption rotor (40) (air leakage from one of the first air passage (21) and the second air passage (22) to the other). it can.

  In addition, a condenser (62) is disposed upstream of the regeneration region (42) of the adsorption rotor (40) in the second air passage (22), and the adsorption region of the adsorption rotor (40) in the first air passage (21). By disposing the evaporator (64) downstream of (41), the heat absorbed from the air passing through the evaporator (64) (that is, the air passing through the adsorption region (41) of the adsorption rotor (40)). Can be discharged into the air passing through the condenser (62) (ie the air supplied to the regeneration zone (42) of the adsorption rotor (40)). Thereby, the heat remaining in the air that has passed through the adsorption region (41) of the adsorption rotor (40) can be used in the regeneration region (42) of the adsorption rotor (40). That is, the adsorbent in the regeneration region (42) of the adsorption rotor (40) can be regenerated using the heat remaining in the air that has passed through the adsorption region (41) of the adsorption rotor (40).

  Further, in the first air passage (21), the heat dissipation area (51) is located downstream of the adsorption area (41) of the adsorption rotor (40), and in the second air path (22), the heat absorption area (52) is located. By disposing the sensible heat rotor (50) so as to be located downstream of the regeneration region (42) of the adsorption rotor (40), air passing through the heat absorption region (52) of the sensible heat rotor (50) (ie, Heat absorbed from the air that has passed through the regeneration region (42) of the adsorption rotor (40) can be released to the air that passes through the heat dissipation region (51) of the sensible heat rotor (50). Thereby, the heat remaining in the air that has passed through the regeneration region (42) of the adsorption rotor (40) can be utilized on the downstream side of the heat dissipation region (51) of the sensible heat rotor (50).

  Specifically, in this example, the sensible heat rotor (50) is disposed downstream of the adsorption rotor (40) in the first air passage (21) and the second air passage (22), and the sensible heat rotor (50). An evaporator (64) is disposed downstream of the heat dissipation area (51). Therefore, the heat remaining in the air that has passed through the regeneration region (42) of the adsorption rotor (40) is supplied to the air (that is, the evaporator (64)) that passes through the heat dissipation region (51) of the sensible heat rotor (50). Air). Thereby, since the temperature of the air supplied to an evaporator (64) can be raised, the evaporation temperature of the refrigerant | coolant in an evaporator (64) can be made high. As a result, the input of the compressor (61) can be reduced, and the coefficient of performance (COP) of the humidity control apparatus (10) can be improved. Moreover, generation | occurrence | production of the frost in an evaporator (64) can be suppressed in a low temperature environment (for example, when the temperature of indoor air (RA) is 10 degrees C or less).

  Also, the heat remaining in the air that has passed through the regeneration region (42) of the adsorption rotor (40) can be released to the air supplied to the evaporator (64) via the sensible heat rotor (50). In the evaporator (64), not only the heat remaining in the air that has passed through the adsorption region (41) of the adsorption rotor (40) but also the air that has passed through the regeneration region (42) of the adsorption rotor (40) You can also recover the heat. As a result, not only the heat remaining in the air passing through the adsorption area (41) of the adsorption rotor (40) but also the heat remaining in the air passing through the regeneration area (42) of the adsorption rotor (40) is adsorbed. It can be effectively used for regeneration of the adsorbent in the regeneration region (42) of the rotor (40).

  Moreover, the adsorption rotor (40) and the sensible heat rotor (50) are integrally formed to form the processing rotor (30), thereby forming the adsorption rotor (40) and the sensible heat rotor (50) separately. More than the case, the number of parts of the humidity control device (10) can be reduced. In addition, the installation space for the adsorption rotor (40) and the sensible heat rotor (50) (the space required to install the adsorption rotor (40) and the sensible heat rotor (50)) can be reduced, so humidity control The device (10) can be reduced in size.

  Further, by switching between the first rotation speed control, the second rotation speed control, and the third rotation speed control, the balance between the humidity control capacity of the adsorption rotor (40) and the sensible heat capacity of the sensible heat rotor (50) is achieved. The air humidity can be adjusted by switching between

(Other embodiments)
In the above description, the case where the adsorption rotor (40) and the sensible heat rotor (50) are integrally formed to form the processing rotor (30) is taken as an example. However, as shown in FIG. The rotor (40) and the sensible heat rotor (50) may be formed separately. For example, the adsorption rotor (40) and the sensible heat rotor (50) may be connected to a common shaft member and rotated. Alternatively, the adsorption rotor (40) and the sensible heat rotor (50) may be connected to different shaft members.

  Moreover, although the case where the humidity control apparatus (10) comprised the dehumidification apparatus which dehumidifies a room was given as an example, even if the humidity control apparatus (10) comprises a humidification apparatus which humidifies a room, Good. For example, as shown in FIG. 5, the first suction port (21a) communicates with the outdoor space, the first air outlet (21b) communicates with the outdoor space, and the air sucked from the outdoor space (outdoor air (OA) ) As exhaust air (EA) and the first air passage (21) is configured to blow out into the outdoor space, the second suction port (22a) communicates with the outdoor space, and the second air outlet (22b) is connected to the indoor space. The second air passage (22) may be configured to be communicated and blown out into the indoor space by using the air sucked from the outdoor space (outdoor air (OA)) as supply air (SA). In such a configuration, the indoor air (RA) sucked into the second air passage (22) is heated in the condenser (62), and the air passing through the condenser (62) is regenerated in the adsorption rotor (40). The air that has been humidified in the region (42) and regenerates the adsorbent in the regeneration region (42) and passes through the regeneration region (42) of the adsorption rotor (40) in the heat absorption region (52) of the sensible heat rotor (50). Air that has been cooled and passed through the heat absorption region (52) of the sensible heat rotor (50) is blown out into the indoor space as supply air (SA).

  Moreover, you may implement combining the above embodiment and modification suitably. The above embodiments and modifications are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

  As described above, the humidity control device described above is useful as a humidity control device that performs indoor humidity control (humidity control).

DESCRIPTION OF SYMBOLS 10 Humidity control apparatus 20 Casing 21 1st air passage 22 2nd air passage 30 Processing rotor 40 Adsorption rotor 41 Adsorption area | region 42 Reproduction | regeneration area 50 Sensible heat rotor 51 Heat dissipation area 52 Endothermic area 60 Refrigerant circuit 61 Compressor 62 Condenser 63 Expansion mechanism 64 Evaporator 71 1st fan 72 2nd fan 80 Controller (control part)
RR1 First rotational speed range RR2 Second rotational speed range RR3 Third rotational speed range RDP Dehumidification peak rotational speed RSP Sensible heat peak rotational speed

Claims (5)

A casing (20) formed with a first air passage (21) and a second air passage (22) through which air flows, respectively;
The adsorbent is supported and is configured to be rotatable, and is disposed across the first air passage (21) and the second air passage (22) so that air passes in the axial direction. The area on the air passage (21) side becomes an adsorption area (41) for desorbing air by adsorbing moisture in the air to the adsorbent, and the area on the second air passage (22) side is moisture from the adsorbent to the air. An adsorption rotor (40) that serves as a regeneration region (42) for desorbing the adsorbent and regenerating the adsorbent,
The humidity control apparatus characterized in that the air passage direction in the adsorption region (41) and the air passage direction in the regeneration region (42) are the same direction. In claim 1,
The first air passage (21) and the second air passage (22) are arranged so as to be rotatable, and the air passes in the axial direction. The first air passage (21) side A sensible heat rotor (50) in which the region is a heat dissipation region (51) that radiates heat to the air, and the region on the second air passage (22) side is a heat absorption region (52) that absorbs heat from the air,
In the first sensible heat rotor (50), the heat release area (51) is located downstream of the adsorption area (41) of the adsorption rotor (40) in the first air passage (21), and the second air The humidity control apparatus, wherein the heat absorption region (52) is disposed in the passage (22) so as to be located downstream of the regeneration region (42) of the adsorption rotor (40). In claim 2,
The humidity control apparatus, wherein the adsorption rotor (40) and the sensible heat rotor (50) are integrally formed to constitute a processing rotor (30). In claim 2 or 3,
A controller (80) for controlling the rotational speed of the adsorption rotor (40) and the sensible heat rotor (50);
The adsorption rotor (40) and the sensible heat rotor (50) are configured to rotate around,
The control unit (80)
The first rotation speed range including the dehumidification peak rotation speed (RDP) corresponding to the peak value (DP) of the dehumidification amount in the dehumidification characteristic line (L1) indicating the relationship between the dehumidification amount and the rotation speed of the adsorption rotor (40). A first rotational speed control for controlling the rotational speed of the adsorption rotor (40) and the sensible heat rotor (50) in (RR1);
A second rotational speed control for controlling the rotational speeds of the adsorption rotor (40) and the sensible heat rotor (50) within a second rotational speed range (RR2) lower than the first rotational speed range (RR1);
Third rotation speed control for controlling the rotation speeds of the adsorption rotor (40) and the sensible heat rotor (50) within a third rotation speed range (RR3) higher than the first rotation speed range (RR1) is performed. A humidity control apparatus characterized by that. In any one of Claims 1-4,
A refrigerant circuit (60) having a compressor (61), a condenser (62) and an evaporator (64);
The condenser (62) is disposed on the upstream side of the regeneration region (42) of the adsorption rotor (40) in the second air passage (22),
The humidity control apparatus, wherein the evaporator (64) is disposed downstream of the adsorption region (41) of the adsorption rotor (40) in the first air passage (21).

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