JP6911400B2 - Humidity control device - Google Patents

Description

The present invention relates to a humidity control device including a suction rotor.

Conventionally, a humidity control device that controls the humidity of air (humidity control) using an adsorption rotor is known. For example, Patent Document 1 discloses an air conditioner including a rotary dehumidifier (adsorption rotor) having an adsorption means capable of adsorbing moisture in the air. This rotary dehumidifier is arranged so as to straddle the air supply passage and the exhaust passage. Then, in this air conditioner, the outdoor air sucked into the air supply passage passes through the air supply passage portion (the portion on the air supply passage side) of the rotary dehumidifier, is dehumidified by the adsorption means, and is blown into the room. The indoor air sucked into the exhaust passage passes through the exhaust passage portion (the portion on the exhaust passage side) of the rotary dehumidifier, dries the adsorption means, and is blown out to the outside.

Japanese Unexamined Patent Publication No. 2006-250414

However, in the air conditioner of Patent Document 1, the air passing direction in the air supply passage portion of the rotary dehumidifier (adsorption rotor) and the air passing direction in the exhaust passage portion of the rotary dehumidifier are opposite to each other. Therefore, the pressure difference between the air supply passage and the exhaust passage tends to be large in the vicinity of the rotary dehumidifier, and the partition wall separating the air supply passage and the exhaust passage in the vicinity of the rotary dehumidifier (for example, the partition wall separating the air supply passage and the exhaust passage). Air easily leaks from one of the air supply passage and the exhaust passage to the other in the gap between the rotary dehumidifier and the dehumidifier. The more air leaks (air leaks from one of the air supply passage and the exhaust passage to the other) in the vicinity of the rotary dehumidifier, the lower the humidity control performance.

Therefore, an object of the present invention is to provide a humidity control device capable of suppressing a decrease in humidity control performance due to air leakage in the vicinity of the suction rotor.

The first invention includes a casing (20) in which a first air passage (21) and a second air passage (22) through which air flows are formed, respectively.
The adsorbent is supported and rotatably configured, and is arranged so as to allow air to pass in the axial direction so as to straddle the first air passage (21) and the second air passage (22). The region on the air passage (21) side becomes the adsorption region (41) that adsorbs the moisture in the air to the adsorbent to dehumidify the air, and the region on the second air passage (22) side is the moisture from the adsorbent into the air. The first air passage (21) and the first air passage (21), which are rotatably configured to allow air to pass in the axial direction, and a suction rotor (40) which serves as a regeneration region (42) for desorbing and regenerating the adsorbent. It is arranged so as to straddle the second air passage (22), and the region on the first air passage (21) side becomes a heat dissipation region (51) that dissipates heat to the air, and the region on the second air passage (22) side. A heating rotor (50) serving as a heat absorbing region (52) that absorbs heat from air, and a control unit (80) that controls the rotation speeds of the suction rotor (40) and the heating rotor (50) are provided. Ri and the air passage direction in the pass direction and the playback area of the air in the suction region (41) (42) Do the same direction, the sensible heat rotor (50), said in the first air passage (21) The heat dissipation region (51) is located on the downstream side of the suction region (41) of the suction rotor (40), and the heat absorption region (52) in the second air passage (22) is the suction rotor (40). It is arranged so as to be located on the downstream side of the reproduction region (42), and is configured so that the suction rotor (40) and the heat-generating rotor (50) rotate around, and the control unit (80) is the suction rotor. The first rotation speed range (RR1) including the dehumidification peak rotation speed (RDP) corresponding to the peak value (DP) of the dehumidification amount on the dehumidification characteristic line (L1) showing the relationship between the dehumidification amount and the rotation speed of (40). Within the first rotation speed control for controlling the rotation speeds of the suction rotor (40) and the heating rotor (50), and within the second rotation speed range (RR2) lower than the first rotation speed range (RR1). In the second rotation speed control for controlling the rotation speeds of the suction rotor (40) and the heating rotor (50), and in the third rotation speed range (RR3) higher than the first rotation speed range (RR1). The humidity control device is characterized in that it performs a third rotation speed control for controlling the rotation speeds of the suction rotor (40) and the sensible heat rotor (50).

In the first invention, since the air passing direction in the suction region (41) of the suction rotor (40) and the air passage direction in the regeneration region (42) are the same direction, the suction rotor (40) With the first air passage (21) in the vicinity of the suction rotor (40) than when the air passage direction in the suction region (41) and the air passage direction in the regeneration region (42) are opposite to each other. The pressure difference with the second air passage (22) can be reduced. As a result, in the vicinity of the suction rotor (40) (for example, the gap between the partition wall separating the first air passage (21) and the second air passage (22) and the suction rotor (40)), the first air passage (for example) It is possible to prevent air from leaking from one of the 21) and the second air passage (22) to the other .

Further, in the first invention, the heat absorbed from the air passing through the endothermic region (52) of the sensible heat rotor (50) (that is, the air passing through the regeneration region (42) of the adsorption rotor (40)) is generated. It can be discharged to the air passing through the heat dissipation region (51) of the sensible heat rotor (50).

Further, in the first invention, the dehumidifying characteristic line (L1) gradually increases the amount of dehumidification in the range from the minimum rotation speed to the dehumidification peak rotation speed (RDP) as the rotation speed increases, and the dehumidification peak rotation speed. In the range from (RDP) to the maximum rotation speed, the dehumidification amount gradually decreases as the rotation speed increases (a curve that becomes convex upward). That is, in the suction rotor (40), the amount of dehumidification of the suction rotor (40) gradually increases as the number of rotations of the suction rotor (40) increases in the range from the minimum rotation speed to the dehumidification peak rotation speed (RDP). It has a dehumidifying characteristic that the amount of dehumidification of the suction rotor (40) gradually decreases as the number of rotations of the suction rotor (40) increases in the range from the dehumidification peak rotation speed (RDP) to the maximum rotation speed. Further, the sensible heat rotor (50) exchanges sensible heat of the sensible heat rotor (50) according to an increase in the sensible heat rotor (50) in the range from the minimum rotation speed to the sensible heat peak rotation speed (RSP). The rate gradually increases, and the sensible heat exchange rate of the sensible heat rotor (50) gradually decreases as the number of rotations of the sensible heat rotor (50) increases in the range from the sensible heat peak rotation speed (RSP) to the maximum rotation speed. It has a sensible heat characteristic. The sensible heat peak rotation speed (RSP) is the rotation speed corresponding to the peak value (SP) of the sensible heat exchange rate.

The second invention is characterized in that, in the first invention, the suction rotor (40) and the sensible heat rotor (50) are integrally formed to form a processing rotor (30). It is a damp device.

In the second invention, the suction rotor (40) and the sensible heat rotor (50) are integrally formed to form the processing rotor (30), whereby the suction rotor (40) and the sensible heat rotor (50) are formed. The installation space for the suction rotor (40) and the sensible heat rotor (50) (the space required to install the suction rotor (40) and the sensible heat rotor (50)) is smaller than when they are formed separately. it is possible.

In the third aspect of the invention, the first or second inventions in Oite, includes a refrigerant circuit (60) having a compressor (61) and the condenser (62) and the evaporator (64), the condenser (62) is arranged on the upstream side of the regeneration region (42) of the suction rotor (40) in the second air passage (22), and the evaporator (64) is located in the first air passage (21). It is a humidity control device characterized in that it is arranged on the downstream side of the suction region (41) of the suction rotor (40).

In the third 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 transferred to the air passing through the condenser (62). (That is, the air supplied to the regeneration region (42) of the suction rotor (40)) can be discharged.

According to the first invention, it is possible to reduce air leakage (air leakage from one of the first air passages (21) and the second air passage (22) to the other) in the vicinity of the suction rotor (40). , It is possible to suppress the deterioration of humidity control performance due to air leakage in the vicinity of the suction rotor (40).

Further, according to the first 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 absorbed. Since the heat can be discharged to the air passing through the heat dissipation region (51) of the sensible heat rotor (50), the heat remaining in the air passing through the regeneration region (42) of the adsorption rotor (40) is released to the sensible heat rotor (50). ) Can be used on the downstream side of the heat dissipation area (51).

Further, according to the first invention, the humidity control capacity of the suction rotor (40) and the sensible heat rotor (50) are obtained by switching between the first rotation speed control, the second rotation speed control, and the third rotation speed control. ) Can be balanced with the sensible heat capacity to control the humidity of the air.

According to the second invention, the number of parts of the humidity control device can be reduced. Further, since the installation space of the suction rotor (40) and the sensible heat rotor (50) can be reduced, the humidity control device can be miniaturized .

According to the third invention, the air 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). Since it can be discharged to (that is, the air supplied to the regeneration region (42) of the suction rotor (40)), the heat remaining in the air that has passed through the suction region (41) of the suction rotor (40) is sucked by the suction rotor. It can be used in the reproduction area (42) of (40).

FIG. 1 is a schematic view illustrating the configuration of a humidity control device according to an embodiment. FIG. 2 is a schematic view illustrating the configuration of the processing rotor. FIG. 3 is a graph illustrating the dehumidifying characteristics of the adsorption rotor and the sensible heat characteristics of the sensible heat rotor. FIG. 4 is a schematic view illustrating the configuration of a modification 1 of the humidity control device. FIG. 5 is a schematic view illustrating the configuration of the second modification of the humidity control device.

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

(Humidity control device)
FIG. 1 illustrates the configuration of the humidity control device (10) according to the embodiment. The humidity control device (10) controls the humidity (humidity control) in the room, and includes a casing (20), a processing rotor (30), a refrigerant circuit (60), a first fan (71), and the like. It is equipped with a second fan (72) and a controller (80). In this example, the humidity control device (10) constitutes a dehumidifying device that dehumidifies the room.

〔casing〕
The casing (20) houses the processing rotor (30), the refrigerant circuit (60), the first fan (71), and the second fan (72). Further, the casing (20) is formed with a first air passage (21) and a second air passage (22). In this example, the casing (20) is formed in the shape of a rectangular parallelepiped box, and its internal space is divided into a first air passage (21) and a second air by a first partition wall (25) and a second partition wall (26). It is divided into an aisle (22) and a storage room (23). Specifically, the first partition wall (25) separates the first air passage (21) and the second air passage (22), and the second partition wall (26) stores the first air passage (21). It is separated from the room (23).

<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 outlet (21b) communicating with the indoor space, and the air sucked from the indoor space. It is configured to blow out (indoor air (RA)) as supply air (SA) into the indoor space. 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 sucked from the indoor space (indoor air (indoor air (22)). RA)) is configured to be blown out into the outdoor space as exhaust air (EA).

[Processing rotor]
The processing rotor (30) is configured to be rotatable around a rotation shaft (O), and is rotationally driven by a drive mechanism (not shown). The processing rotor (30) is arranged so as to straddle 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 vents (not shown) penetrating in the axial direction, and the first air passage (21) and the second air passage (21) and the second are so that air can flow through the vents. It is located across the air passage (22).

Further, an adsorbent is supported on a portion of the processing rotor (30) on one end side in the axial direction. The adsorbent is not supported on the remaining portion of the processing rotor (30) (that is, the portion on the other end side in the axial direction). As a result, the portion of the processing rotor (30) on one end side in the axial direction (the portion on which the adsorbent is supported) constitutes the suction rotor (40), and the portion of the treatment rotor (30) on the other end side in the axial direction (suction). The portion on which the agent is not supported) constitutes the sensible heat rotor (50). That is, in this example, the suction rotor (40) and the sensible heat rotor (50) are integrally formed to form the processing rotor (30), and the suction rotor (40) and the sensible heat rotor (50) are It is configured to take you around. The processing rotor (30) is located upstream of the portion of the first air passage (21) and the second air passage (22) that becomes the suction rotor (40) and becomes the sensible heat rotor (50). It is arranged like this.

<Suction rotor>
The adsorption rotor (40) carries an adsorbent. Further, the suction rotor (40) is configured to be rotatable around a 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 placed on the side. Specifically, the suction rotor (40) has a large number of vents (not shown) penetrating in the axial direction, and the first air passage (21) and the second air passage (21) and the second are so that air can flow through the vents. It is arranged so as to straddle the air passage (22).

Further, in the adsorption rotor (40), the region on the first air passage (21) side becomes the adsorption region (41) for adsorbing the moisture in the air to the adsorbent to dehumidify the air, and the region on the second air passage (22) side. Region is a regeneration region (42) that regenerates the adsorbent by desorbing water from the adsorbent into the air. As the suction rotor (40) rotates, the portion of the suction rotor (40) on the first air passage (21) side moves toward the second air passage (22) side, and the suction rotor (40) The portion on the second air passage (22) side moves toward the first air passage (21) side.

<Sensible heat rotor>
The sensible heat rotor (50) is configured to be rotatable around a 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 vents (not shown) penetrating in the axial direction, and the first air passage (21) and the first air passage (21) and the first air passage (21) so as to allow air to flow through the vents. 2 It is arranged so as to straddle the air passage (22).

Further, in the sensible heat rotor (50), the region on the first air passage (21) side serves as a heat dissipation region (51) that dissipates heat to the air, and the region on the second air passage (22) side serves as an endothermic region (heat absorption region) that absorbs heat from the air. 52). As the sensible heat rotor (50) rotates, the portion of the sensible heat rotor (50) on the first air passage (21) side moves toward the second air passage (22) side, and the sensible heat rotor (50) ( The portion of 50) on the second air passage (22) side moves toward the first air passage (21) side.

Further, the sensible heat rotor (50) is arranged on the downstream side of the suction rotor (40) in the first air passage (21) and the second air passage (22). Specifically, in the sensible heat rotor (50), the heat dissipation region (51) is located on the downstream side of the suction region (41) of the suction rotor (40) in the first air passage (21), and the second air In the passage (22), the endothermic region (52) is arranged so as to be located on the downstream side of the regeneration region (42) of the suction rotor (40).

<Structure of processing rotor>
As shown in FIG. 2, in this example, the processing rotor (30) is formed in a disk shape. That is, the suction rotor (40) and the sensible heat rotor (50) are formed in a disk shape. For example, the processing rotor (30) is composed of metal fibers such as copper and aluminum, carbon fibers, plant fibers such as pulp, ceramic fibers, glass fibers, and the like, and has a large number of vents (30) that penetrate in the axial direction. It is composed of a disk-shaped base material on which (not shown) is formed. Then, the axial end side portion of the base material and the adsorbent (the adsorbent supported on the axial end end side portion of the base material) form the adsorption rotor (40), and the axial end side of the base material is formed. (The part where the adsorbent is not supported) constitutes the sensible heat rotor (50). That is, in this example, the adsorption rotor (40) is composed of a disc-shaped base material and an adsorbent supported on the base material, and the sensible heat rotor (50) is made of a disc-shaped base material. It is configured.

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

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

[Refrigerant circuit]
The refrigerant circuit (60) has a compressor (61), a condenser (62), an expansion mechanism (63), and an evaporator (64). In the refrigerant circuit (60), the compressor (61), the condenser (62), the expansion mechanism (63), and the 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) is connected. ) And the liquid end of the evaporator (64), and the liquid end of the evaporator (64) and the suction pipe of the compressor (61) are connected. Then, in the refrigerant circuit (60), the refrigerant circulates and a vapor compression refrigeration cycle is performed.

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

<Condenser>
The condenser (62) is configured to exchange heat between the refrigerant and air. That is, in the condenser (62), the refrigerant passing through the condenser (62) and the air passing through the condenser (62) exchange heat. For example, the condenser (62) is composed of 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 composed of an electronic expansion valve. In this example, the expansion mechanism (63) is located in the second air passage (22).

<Evaporator>
The evaporator (64) is configured to exchange heat between the refrigerant and 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 composed of a fin-and-tube heat exchanger.

<Refrigerant flow in the refrigerant circuit>
In the refrigerant circuit (60), the refrigerant discharged from the compressor (61) dissipates heat to the air in the condenser (62) and condenses. This heats the air passing through the condenser (62). The refrigerant flowing out of the condenser (62) is depressurized in the expansion mechanism (63), and endothermic from the air in the evaporator (64) to evaporate. This cools the air passing through the evaporator (64). The refrigerant flowing out of the evaporator (64) is sucked into the compressor (61).

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

<Arrangement of evaporator>
The evaporator (64) is arranged on the downstream side of the suction region (41) of the suction rotor (40) in the first air passage (21). In this example, in the first air passage (21), the heat dissipation region (51) of the sensible heat rotor (50) is arranged on the downstream side of the suction region (41) of the suction rotor (40), and the sensible heat rotor (50). An evaporator (64) is arranged on the downstream side of the heat dissipation area (51) of the above.

〔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 a first air passage (21) so that air flows from the first suction port (21a) to the first outlet (21b) in the first air passage (21). ) Transport the air inside. For example, the first fan (71) is composed of a sirocco fan. In this example, the suction region (41) of the suction rotor (40), the heat dissipation region (51) of the sensible heat rotor (50), and the evaporator (from the upstream side to the downstream side of the first air passage (21)). 64) and the first fan (71) are arranged in order.

The second fan (72) is provided in the second air passage (22) and is configured to convey the air in the second air passage (22). Specifically, the second fan (72) has a second air passage (22) so that air flows from the second suction port (22a) to the second outlet (22b) in the second air passage (22). ) Transport the air inside. For example, the second fan (72) is composed of a sirocco fan. In this example, the endothermic region (42) of the condenser (62) and the adsorption rotor (40) and the endothermic region (50) of the sensible heat rotor (50) are directed from the upstream side to the downstream side of the second air passage (22). 52) and the second fan (72) are arranged in order.

[Various sensors]
In addition, various sensors such as a temperature sensor that detects the temperature of air and the refrigerant, a humidity sensor that detects the humidity of the air, and a pressure sensor that detects the pressure of the refrigerant are attached to each part of the humidity control device (10) (not shown). Is provided. Then, the detection signals (signals indicating the 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 control device (10) by controlling each part of (10) (specifically, the processing rotor (30), the refrigerant circuit (60), the first fan (71), and the second fan (72)). It is configured to do. For example, the controller (80) is composed of an arithmetic processing unit such as a CPU and a storage unit such as a memory for storing programs and information for operating the arithmetic processing unit.

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

[Air flow in humidity control device]
Next, the air flow in the humidity control device (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) dissipates heat from the suction region (41) of the suction rotor (40) and the sensible heat rotor (50). It passes through the region (51), the evaporator (64), and the first fan (71) in order, and is blown out from the first air passage (21) through the first outlet (21b).

In the adsorption region (41) of the adsorption rotor (40), the moisture in the air passing through the adsorption region (41) is adsorbed by the adsorbent in the adsorption region (41). As a result, the air passing through the adsorption region (41) is dehumidified. Further, the heat of adsorption of the adsorbent in the adsorption region (41) heats the air passing through the adsorption region (41). As a result, the temperature of the air passing through the adsorption region (41) rises.

In the heat radiating region (51) of the sensible heat rotor (50), the heat radiating region (51) radiates heat to the air passing through the heat radiating region (51). As a result, the temperature of the air passing through the heat dissipation region (51) rises.

In the evaporator (64), the refrigerant flowing through the evaporator (64) absorbs heat from the air passing through the evaporator (64). This lowers the temperature of the air passing through the evaporator (64).

In this example, the indoor air (RA) sucked into the first air passage (21) is dehumidified in the suction region (41) of the suction rotor (40) and passes through the suction region (41) of the suction rotor (40). Air is heated in the heat dissipation region (51) of the sensible heat rotor (50), and the air that has passed through the heat dissipation region (51) of the sensible heat rotor (50) is cooled in the evaporator (64) to heat the evaporator (64). The passed air is blown into the indoor space as supply air (SA). In this way, the dehumidified air 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) is sensible heat with the regeneration region (42) of the condenser (62) and the adsorption rotor (40). It passes through the endothermic region (52) of the rotor (50) and the second fan (72) in order, and is 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) dissipates heat to the air passing through the condenser (62). This raises 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). As a result, the air passing through the regenerated region (42) is humidified, and the adsorbent in the regenerated 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). As a result, 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 that has passed through the condenser (62) is the regeneration region (42) of the adsorption rotor (40). ), 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 heat absorption region (52) of the sensible heat rotor (50). The air that has passed through the heat absorption 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 device (10) is discharged to the outdoor space.

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

[Dehumidifying and sensible heat characteristics]
Next, with reference to FIG. 3, the dehumidifying characteristics of the suction rotor (40) and the sensible heat characteristics of the sensible heat rotor (50) will be described. In FIG. 3, the dehumidifying characteristic line (L1) shows the relationship between the rotation speed of the suction rotor (40) and the dehumidifying amount of the suction rotor (40), and the sensible heat characteristic line (L2) is 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 amount of dehumidification of the adsorption rotor (40) corresponds to the amount of water adsorbed from the air to the adsorbent in the adsorption region (41) of the adsorption rotor (40), and the actual heat exchange rate of the sensible heat rotor (50) is , Corresponds to the ratio of the amount of heat released to the air from the heat radiating region (51) out of the amount of heat stored in the heat radiating region (51) of the sensible heat rotor (50).

As shown in FIG. 3, the dehumidification characteristic line (L1) shows that the dehumidification amount gradually increases in the range from the minimum rotation speed (for example, zero) to the dehumidification peak rotation speed (RDP) as the rotation speed increases, and the dehumidification peak. In the range from the rotation speed (RDP) to the maximum rotation speed, the dehumidification amount gradually decreases as the rotation speed increases (the curve becomes convex upward). The dehumidification peak rotation speed (RDP) is the rotation speed corresponding to the peak value (DP) of the dehumidification amount. That is, in the suction rotor (40), the amount of dehumidification of the suction rotor (40) gradually increases as the number of rotations of the suction rotor (40) increases in the range from the minimum rotation speed to the dehumidification peak rotation speed (RDP). It has a dehumidifying characteristic that the amount of dehumidification of the suction rotor (40) gradually decreases as the number of rotations of the suction rotor (40) increases in the range from the dehumidification peak rotation speed (RDP) to the maximum rotation speed.

As shown in FIG. 3, the sensible heat characteristic line (L2) gradually increases the sensible heat exchange rate as the rotation speed increases in the range from the minimum rotation speed (for example, zero) to the sensible heat peak rotation speed (RSP). However, in the range from the sensible heat peak rotation speed (RSP) to the maximum rotation speed, the sensible heat exchange rate gradually decreases as the rotation speed increases (the curve becomes convex upward). The sensible heat peak rotation speed (RSP) is a rotation speed corresponding to the peak value (SP) of the sensible heat exchange rate. That is, the sensible heat rotor (50) exchanges sensible heat of the sensible heat rotor (50) in response to an increase in the sensible heat rotor (50) in the range from the minimum rotation speed to the sensible heat peak rotation speed (RSP). The rate gradually increases, and the sensible heat exchange rate of the sensible heat rotor (50) gradually decreases as the number of rotations of the sensible heat rotor (50) increases in the range from the sensible heat peak rotation speed (RSP) to the maximum rotation speed. It has a sensible heat characteristic. In the example of FIG. 3, the sensible heat peak rotation speed (RSP) is lower than the dehumidification peak rotation speed (RDP).

[Rotation speed control by controller]
Next, the rotation 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 rotation speed control based on the temperature, relative humidity, absolute humidity, etc. of the indoor air (RA), or the operation of the humidity control device (10). It may be configured to control the rotation speed in response to an instruction by a person.

In FIG. 3, the first rotation speed range (RR1) corresponds to the peak value (DP) of the dehumidification amount on the dehumidification characteristic line (L1) indicating the relationship between the dehumidification amount of the suction rotor (40) and the rotation speed. It is a 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 rotation speed range higher than the first rotation speed range (RR1). In this example, the sensible heat peak rotation speed (RSP) is included in the second rotation speed range (RR2).

<First rotation speed control>
In the first rotation speed control, the controller (80) controls the rotation speed of the processing rotor (30) within the first rotation speed range (RR1) (that is, the rotation speed of the suction rotor (40) and the sensible heat rotor (50), or less. Similarly). As shown in FIG. 3, the dehumidifying amount of the suction rotor (40) in the first rotation speed range (RR1) is that of the suction rotor (40) in the second rotation speed range (RR2) and the third rotation speed range (RR3). It is more than the amount of dehumidification. That is, in the first rotation speed control, the humidity of the air can be controlled in a state where the humidity control capacity of the suction rotor (40) is relatively high. Therefore, in the first rotation speed control, when it is required to control the humidity of the air in a state where the humidity control capacity of the suction rotor (40) is relatively high (for example, the dehumidifying load in the room is relatively high). If this is the case, it is effective when dehumidifying the room with priority given to improving the dehumidifying capacity in summer).

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

<Second rotation 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 rotation speed range (RR2) (in this example, particularly from the sensible heat peak rotation speed (RSP) to the second rotation speed range (RR2)). The sensible heat exchange rate of the sensible heat rotor (50) in the range up to the sensible heat rotor (50) that defines the upper limit of It is higher than the sensible heat exchange rate. That is, in the second rotation speed control, the humidity of the air can be adjusted in a state where the sensible heat capacity of the sensible heat rotor (50) is relatively high. Therefore, in the second rotation speed control, when it is required to control the humidity of the air in a state where the sensible heat capacity of the sensible heat rotor (50) is relatively high (for example, the temperature in the room does not become too low). It is effective when dehumidifying the room as described above, when controlling the humidity indoors in the middle season or winter, etc.).

The amount of dehumidification of the suction rotor (40) in the second rotation speed range (RR2) is smaller than the amount of dehumidification of the suction 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 rotation speed range (RR3) is the sensible heat exchange rate of the sensible heat rotor (50) in the first rotation speed range (RR1). The sensible heat exchange rate of the sensible heat rotor (50) in the second rotation speed range (RR2) (in this example, the rotation speed that defines the upper limit of the second rotation speed range (RR2) from the sensible heat peak rotation speed (RSP) in particular. It is lower than the sensible heat exchange rate of the sensible heat rotor (50) in the range up to. That is, in the third rotation speed control, the humidity of the air can be adjusted in a state where the sensible heat capacity of the sensible heat rotor (50) is relatively low. Therefore, in the third rotation speed control, when it is required to control the humidity of the air in a state where the sensible heat capacity of the sensible heat rotor (50) is relatively low (for example, the temperature in the room does not become too high). When dehumidifying the room as described above, it is effective when dehumidifying the room with priority given to suppressing the increase in the cooling load in the room in summer).

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

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

[Effect of the embodiment]
As described above, in the humidity control device (10) according to this embodiment, the air passing direction in the suction region (41) of the suction rotor (40) and the air passage direction in the regeneration region (42) of the suction rotor (40). Is in the same direction. Therefore, the air passage direction in the suction region (41) of the suction rotor (40) and the air passage direction in the regeneration region (42) are opposite to each other in the vicinity of the suction rotor (40). The pressure difference between the 1 air passage (21) and the 2nd air passage (22) can be reduced. As a result, in the vicinity of the suction rotor (40) (for example, the gap between the first partition wall (25) and the suction rotor (40) that separate the first air passage (21) and the second air passage (22)). It is possible to prevent air from leaking from one of the first air passage (21) and the second air passage (22) to the other. Therefore, it is possible to suppress the deterioration of humidity control performance due to air leakage (air leakage from one of the first air passage (21) and the second air passage (22) to the other) in the vicinity of the suction rotor (40). can.

Further, a condenser (62) is arranged on the upstream side of the regeneration region (42) of the suction rotor (40) in the second air passage (22), and the suction region of the suction rotor (40) is arranged in the first air passage (21). By arranging the evaporator (64) on the downstream side 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 expelled into the air passing through the condenser (62) (ie, the air supplied to the regeneration region (42) of the adsorption rotor (40)). As a result, the heat remaining in the air that has passed through the adsorption region (41) of the adsorption rotor (40) can be utilized 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 by utilizing 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 region (51) is located on the downstream side of the suction region (41) of the suction rotor (40), and in the second air passage (22), the heat absorption region (52) is located. By arranging the exothermic rotor (50) so as to be located on the downstream side of the regeneration region (42) of the adsorption rotor (40), the air passing through the endothermic region (52) of the exothermic rotor (50) (that is, that is). The heat absorbed from the regeneration region (42) of the adsorption rotor (40) can be released to the air passing through the heat dissipation region (51) of the sensible heat rotor (50). As a result, 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 arranged on the downstream side of the suction rotor (40) in the first air passage (21) and the second air passage (22), and the sensible heat rotor (50) is arranged. An evaporator (64) is arranged on the downstream side of the heat dissipation area (51) of the above. 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 passes through the heat dissipation region (51) of the sensible heat rotor (50) (that is, the evaporator (64)). Can be released into the air). As a result, the temperature of the air supplied to the evaporator (64) can be raised, so that the evaporation temperature of the refrigerant in the evaporator (64) can be raised. As a result, the input of the compressor (61) can be reduced, and the coefficient of performance (COP) of the humidity control device (10) can be improved. In addition, the generation of frost in the evaporator (64) can be suppressed in a low temperature environment (for example, when the temperature of the indoor air (RA) is 10 ° C. or lower).

Further, since the heat remaining in the air passing through the regeneration region (42) of the adsorption rotor (40) can be discharged 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 passing through the suction region (41) of the suction rotor (40) but also the heat remaining in the air passing through the regeneration region (42) of the suction rotor (40). The heat that is present can also be recovered. As a result, not only the heat remaining in the air passing through the adsorption region (41) of the adsorption rotor (40) but also the heat remaining in the air passing through the regeneration region (42) of the adsorption rotor (40) is adsorbed. It can be effectively used for the regeneration of the adsorbent in the regeneration region (42) of the rotor (40).

Further, by integrally forming the suction rotor (40) and the sensible heat rotor (50) to form the processing rotor (30), the suction rotor (40) and the sensible heat rotor (50) are formed separately. The number of parts of the humidity control device (10) can be reduced more than in the case. Further, since the installation space for the suction rotor (40) and the sensible heat rotor (50) (the space required for installing the suction rotor (40) and the sensible heat rotor (50)) can be reduced, humidity control can be performed. The device (10) can be miniaturized.

Further, by switching between the first rotation speed control, the second rotation speed control, and the third rotation speed control, the humidity control capacity of the suction rotor (40) and the sensible heat capacity of the sensible heat rotor (50) are balanced. Can be switched to control the humidity of the air.

(Other embodiments)
In the above description, the case where the suction rotor (40) and the sensible heat rotor (50) are integrally formed to form the processing rotor (30) has been described as an example, but as shown in FIG. 4, suction is performed. The rotor (40) and the sensible heat rotor (50) may be formed separately. For example, the suction rotor (40) and the sensible heat rotor (50) may be configured to be connected to a common shaft member and rotate around. Alternatively, the suction rotor (40) and the sensible heat rotor (50) may be connected to different shaft members.

Further, the case where the humidity control device (10) constitutes a dehumidifying device for dehumidifying the room is given as an example, but even if the humidity control device (10) constitutes a humidifying device for humidifying the room. good. For example, as shown in FIG. 5, the first suction port (21a) is communicated with the outdoor space, the first outlet (21b) is communicated with the outdoor space, and the air sucked from the outdoor space (outdoor air (OA)). ) Is used as exhaust air (EA) to blow out into the outdoor space, the first air passage (21) is configured, the second suction port (22a) is communicated with the outdoor space, and the second outlet (22b) is referred to as the indoor space. The second air passage (22) may be configured so as to communicate and blow out the air sucked from the outdoor space (outdoor air (OA)) into the indoor space as the 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 by the adsorption rotor (40). The air that has passed through the regeneration region (42) of the adsorption rotor (40) is humidified in the region (42) and regenerates the adsorbent in the regeneration region (42), and the air that has passed through the regeneration region (42) of the adsorption rotor (40) is in the heat absorption region (52) of the sensible heat rotor (50). The air that has been cooled and passed through the heat absorption region (52) of the sensible heat rotor (50) is blown into the indoor space as supply air (SA).

In addition, the above embodiments and modifications may be combined as appropriate. The above embodiments and modifications are essentially preferred examples and are not intended to limit the scope of the invention, its applications, or its uses.

As described above, the above-mentioned humidity control device is useful as a humidity control device for controlling humidity (humidity control) in a room.

10 Humidity control device 20 Casing 21 First air passage 22 Second air passage 30 Processing rotor 40 Suction rotor 41 Suction area 42 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 unit)
RR1 1st rotation speed range RR2 2nd rotation speed range RR3 3rd rotation speed range RDP Dehumidification peak rotation speed RSP Sensible heat peak rotation speed

Claims (3)

A casing (20) in which a first air passage (21) and a second air passage (22) through which air flows are formed, and a casing (20).
The adsorbent is supported and rotatably configured, and is arranged so as to allow air to pass in the axial direction so as to straddle the first air passage (21) and the second air passage (22). The region on the air passage (21) side becomes the adsorption region (41) that adsorbs the moisture in the air to the adsorbent to dehumidify the air, and the region on the second air passage (22) side is the moisture from the adsorbent into the air. And the adsorption rotor (40), which serves as a regeneration region (42) for regenerating the adsorbent by desorbing the adsorbent .
It is rotatably configured and is arranged across the first air passage (21) and the second air passage (22) so that air can pass in the axial direction, and is arranged on the first air passage (21) side. Is a heat dissipation region (51) that dissipates heat to the air, and the region on the second air passage (22) side is an endothermic region (52) that absorbs heat from the air.
A control unit (80) for controlling the rotation speeds of the suction rotor (40) and the sensible heat rotor (50) is provided.
The Ri and the air passage direction in the adsorption region (41) and the air passage direction in the playback area (42) Do the same direction,
In the sensible heat rotor (50), the heat dissipation region (51) is located on the downstream side of the suction region (41) of the suction rotor (40) in the first air passage (21), and the second air In the passage (22), the endothermic region (52) is arranged so as to be located on the downstream side of the regeneration region (42) of the adsorption rotor (40).
The suction rotor (40) and the sensible heat rotor (50) are configured to rotate together.
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 on the dehumidification characteristic line (L1) showing the relationship between the dehumidification amount and the rotation speed of the suction rotor (40). The first rotation speed control for controlling the rotation speeds of the suction rotor (40) and the dehumidifying rotor (50) in (RR1), and
Second rotation speed control for controlling the rotation speeds of the suction rotor (40) and the sensible heat rotor (50) within the second rotation speed range (RR2) lower than the first rotation speed range (RR1).
The third rotation speed control for controlling the rotation speeds of the suction rotor (40) and the sensible heat rotor (50) is performed within the third rotation speed range (RR3) higher than the first rotation speed range (RR1). <br/> A humidity control device characterized by this. In claim 1 ,
A humidity control device characterized in that the suction rotor (40) and the sensible heat rotor (50) are integrally formed to form a processing rotor (30). In claim 1 or 2 ,
Equipped with a refrigerant circuit (60) having a compressor (61), a condenser (62) and an evaporator (64).
The condenser (62) is arranged on the upstream side of the regeneration region (42) of the suction rotor (40) in the second air passage (22).
The evaporator (64) is a humidity control device characterized in that the evaporator (64) is arranged on the downstream side of the suction region (41) of the suction rotor (40) in the first air passage (21).

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