JP2023070468A - Air-conditioning device - Google Patents

Abstract

To enable effective dehumidifying ventilation operation.SOLUTION: The air-conditioning device comprises: a humidity adjusting element (20) having an adsorption member that adsorbs moisture in air; and a blowing unit (26) that blows, to an indoor space (I), processed air generated as a result of the adsorption of moisture contained in outdoor air by the adsorption member. The temperature of the processed air is higher than the temperature of the indoor air.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to air conditioners.

Patent Literature 1 discloses a humidity control device. The humidity control apparatus selectively performs dehumidification/ventilation operation, humidification/ventilation operation, and cooling operation. During the dehumidification/ventilation operation, the adsorption operation and the regeneration operation are alternately performed. In the adsorption operation, when the outdoor air is supplied to the indoor space, the moisture in the air is adsorbed by the adsorbent, thereby supplying dry air to the indoor space. In the regeneration operation, the moisture adsorbed by the adsorbent is released from the adsorbent and then discharged to the outside of the room. The adsorbent is heated during the regeneration operation. After completion of the regeneration operation, the adsorbent is sufficiently cooled from the viewpoint of enhancing the ability of the adsorbent to adsorb moisture. An adsorption operation is performed using a sufficiently cooled adsorbent. The cooling operation is automatically performed when a predetermined condition is satisfied during the dehumidification/ventilation operation.

JP 2010-139144 A

The dehumidifying ventilation operation is usually performed during the humid and warm season when people feel uncomfortable. However, if the indoor space is cooled by the cooling operation during the dehumidification/ventilation operation, the room temperature may drop too much. In this case, when the room is ventilated, high-humidity air enters the room, and the dehumidification capacity of the indoor space by the humidity control device becomes insufficient. Further, in this case, it is conceivable to perform a reheat dehumidifying operation that can dehumidify the room while suppressing a decrease in room temperature. However, the mechanism for performing the reheat dehumidification operation is complicated, and the condensation temperature rises due to heat output, resulting in a decrease in efficiency.

An object of the present disclosure is to enable effective dehumidification and ventilation operation.

A first aspect is directed to an air conditioner. The air conditioner includes a humidity control element (20) having an adsorption member that adsorbs moisture in the air, and a treated air generated by adsorbing moisture contained in outdoor air with the adsorption member. and a blower section (26) for sending the air to the room, and the temperature of the treated air is higher than the temperature of the indoor air.

In the first aspect, the dehumidification ventilation operation can be effectively performed.

According to a second aspect, in the first aspect, the temperature of the treated air is higher than the temperature of the outdoor air.

In the second aspect, the temperature of the process air supplied to the indoor space (I) becomes higher than the temperature of the outdoor air, thereby preventing the indoor space (I) from being too cold.

In a third aspect, in the first or second aspect, the adsorption member includes a rotor (22) carrying a moisture adsorbent, and heat accumulated in the rotor (22) warms the outdoor air. The process air is generated by being

In the third aspect, the heat stored in the rotor (22) allows the temperature of the process air to be higher than the atmosphere.

A fourth aspect is the third aspect, further comprising a measuring section for measuring the temperature of the rotor (22), and when the temperature of the rotor (22) measured by the measuring section is higher than a predetermined temperature, the above The operation of sending the treated air to the indoor space (I) by the air blower (26) is not carried out.

In the fourth aspect, it is possible to prevent the temperature of the treated air sent to the indoor space (I) from becoming too high.

In a fifth aspect, in the third aspect or the fourth aspect, the heat is transferred to the indoor space (I) after a predetermined time has passed or within a predetermined time after the end of the process of accumulating heat in the rotor (22). Sending treated air.

In a fifth aspect, the temperature of the process air sent to the indoor space (I) can be adjusted.

According to a sixth aspect, in any one of the third to fifth aspects, the temperature of the process air is determined according to the temperature of the rotor (22).

In a sixth aspect, the temperature of the process air can be determined according to the temperature of the rotor (22).

According to a seventh aspect, in any one of the third to sixth aspects, the rotation speed of the rotor (22) differs between during the humidification operation and during the dehumidification operation.

In the seventh aspect, the rotation speed of the rotor (22) can be varied according to the operation characteristics during humidification operation and dehumidification operation.

According to an eighth aspect, in the seventh aspect, the rotation speed of the rotor (22) is faster during the dehumidifying operation than during the humidifying operation.

In the eighth aspect, dehumidifying operation can be effectively performed.

In a ninth aspect, in any one of the third to eighth aspects, when the rotor (22) is regenerated, the entire circumference of the rotor (22) is regenerated in batch mode, and the After the regeneration treatment, the treated air is sent to the indoor space (I) through the rotor (22) while the rotor (22) is not heated.

In the ninth aspect, the residual heat of the rotor (22) warms the outdoor air to generate the process air.

According to a tenth aspect, in the ninth aspect, air that has passed through the rotor (22) is sent outside during the regeneration process.

In the tenth aspect, the water adsorbed by the rotor (22) can be discharged to the outside of the room.

According to an eleventh aspect, in any one of the third to tenth aspects, the rotor (22) carries a predetermined functional material as an adsorbent.

In the eleventh aspect, moisture can be adsorbed by the rotor (22).

According to a twelfth aspect, in any one of the third to eleventh aspects, a heater (25) for heating air supplied to the rotor (22) is provided, and the rotor (22) is positioned at a predetermined position. placed in

In the twelfth aspect, the rotor (22) can be warmed by the heater (25).

FIG. 1 is a schematic overall configuration diagram of an air conditioner according to an embodiment. FIG. 2 is a configuration diagram showing refrigerant piping and air flow of an air conditioner. FIG. 3 is a longitudinal sectional view of the air conditioning indoor unit. FIG. 4 is a block diagram including the main elements of the air conditioner. FIG. 5 is a flow chart when the dehumidifying/ventilating operation is performed by the control unit. FIG. 6 is a schematic overall configuration diagram of an air conditioner of a modified example.

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the drawings. Note that the present disclosure is not limited to the embodiments shown below, and various modifications are possible without departing from the technical idea of the present disclosure. Each drawing is for the purpose of conceptually explaining the present disclosure, and therefore dimensions, ratios or numbers may be exaggerated or simplified as necessary for ease of understanding.

Exemplary embodiments are described in detail below on the basis of the drawings.

(1) Overview of Configuration of Air Conditioner The air conditioner (1) adjusts the temperature and humidity of the air in the target space. The target space in this example is the indoor space (I). As shown in FIG. 1, the air conditioner (1) has an air conditioner outdoor unit (10) and an air conditioner indoor unit (30). The air conditioning outdoor unit (10) is installed outdoors, and the air conditioning indoor unit (30) is installed indoors. The air conditioner (1) is a pair type having one air conditioner indoor unit (30) and one air conditioner outdoor unit (10). An air conditioner (1) has a humidity control unit (20) as a humidity control element. An air conditioner (1) has a function of humidifying and dehumidifying air. The air conditioner (1) further has a function of ventilating the indoor space (I).

As shown in FIGS. 1 and 2, an air conditioner (1) has a hose (2), a liquid connection pipe (3), and a gas connection pipe (4). The air conditioning indoor unit (30) and the humidity control unit (20) are connected to each other via a hose (2). The air conditioning indoor unit (30) and the air conditioning outdoor unit (10) are connected to each other via a liquid communication pipe (3) and a gas communication pipe (4). This constitutes an air conditioning element (5) including a refrigerant circuit (R). The refrigerant circuit (R) is filled with refrigerant. The refrigerant is difluoromethane. However, the refrigerant is not limited to difluoromethane. The refrigerant circuit (R) performs a vapor compression refrigeration cycle.

The refrigerant circuit (R) mainly has a compressor (12), an outdoor heat exchanger (14), an expansion valve (15), a four-way switching valve (16), and an indoor heat exchanger (34). .

The refrigerant circuit (R) performs the first refrigerating cycle and the second refrigerating cycle according to switching of the four-way switching valve (16). The first refrigerating cycle is a refrigerating cycle in which the indoor heat exchanger (34) functions as an evaporator and the outdoor heat exchanger (14) functions as a radiator. The second refrigerating cycle is a refrigerating cycle in which the indoor heat exchanger (34) functions as a radiator and the outdoor heat exchanger (14) functions as an evaporator.

(2) Detailed configuration (2-1) Air conditioner outdoor unit As shown in FIGS. 2 and 4, the air conditioner outdoor unit (10) includes an outdoor casing (11), a compressor (12), and an outdoor fan (13). , an outdoor heat exchanger (14), an expansion valve (15), and a four-way switching valve (16).

A partition plate (18) is provided inside the outdoor casing (11). The partition plate (18) partitions the interior of the outdoor casing (11) into a first space (S1) and a second space (S2). A compressor (12) and an outdoor heat exchanger (14) are provided in the first space (S1). Strictly speaking, the first space (S1) is provided with a compressor (12), an outdoor fan (13), an outdoor heat exchanger (14), an expansion valve (15), and a four-way switching valve (16). The outdoor casing (11) is formed with an outdoor inlet (11a) and an outdoor outlet (11b). The outdoor suction port (11a) is formed on the rear side of the outdoor casing (11). The outdoor air inlet (11a) is an opening for sucking outdoor air (outdoor air). The outdoor outlet (11b) is formed on the front side of the outdoor casing (11). The outdoor air outlet (11b) is an opening for blowing out the air that has passed through the outdoor heat exchanger (14). An outdoor air passageway (11c) is formed inside the outdoor casing (11) from the outdoor inlet (11a) to the outdoor outlet (11b).

The compressor (12) sucks and compresses low-pressure gas refrigerant. The compressor (12) is driven by a first motor (M1). The compressor (12) is a variable displacement compressor in which power is supplied from an inverter circuit to the first motor (M1). The compressor (12) is configured such that its operating capacity can be changed by adjusting the operating frequency (rotational speed) of the first motor (M1). The compressor (12) is of a so-called high-pressure dome type filled with high-pressure refrigerant. During operation of the compressor (12), heat generated from the compressor (12) is released to its surroundings.

The outdoor fan (13) is arranged in the outdoor air passageway (11c). The outdoor fan (13) is rotated by driving the second motor (M2). Air carried by the outdoor fan (13) is sucked into the outdoor casing (11) through the outdoor suction port (11a). This air flows through the outdoor air passageway (11c) and is blown out of the outdoor casing (11) from the outdoor outlet (11b). The outdoor fan (13) conveys outdoor air so as to pass through the outdoor heat exchanger (14).

The outdoor heat exchanger (14) is arranged upstream of the outdoor fan (13) in the outdoor air passageway (11c). The outdoor heat exchanger (14) of this example is a fin-and-tube heat exchanger. The outdoor heat exchanger (14) exchanges heat between refrigerant flowing therein and outdoor air conveyed by the outdoor fan (13).

The expansion valve (15) reduces the pressure of the refrigerant. The expansion valve (15) is an electrically operated expansion valve whose degree of opening is adjustable. The decompression mechanism may be a temperature-sensitive expansion valve, an expander, a capillary tube, or the like. The expansion valve (15) may be connected to the liquid line of the refrigerant circuit (R), and may be provided in the air conditioning indoor unit (30).

The four-way switching valve (16) has a first port (P1), a second port (P2), a third port (P3) and a fourth port (P4). The first port (P1) is connected to the discharge of the compressor (12). The second port (P2) is connected to the intake of the compressor (12). The third port (P3) is connected to the gas end of the outdoor heat exchanger (14). The fourth port (P4) is connected to the gas communication pipe (4).

The four-way switching valve (16) is switched between a first state (shown by solid lines in FIG. 2) and a second state (shown by dashed lines in FIG. 2). The four-way switching valve (16) in the first state allows communication between the first port (P1) and the third port (P3) and communication between the second port (P2) and the fourth port (P4). The four-way switching valve (16) in the second state allows communication between the first port (P1) and the fourth port (P4) and communication between the second port (P2) and the third port (P3).

(2-2) Humidity Control Unit The humidity control unit (20) is installed outdoors. The humidity control unit (20) of this example is integrated with the air conditioner outdoor unit (10). The humidity control unit (20) sends the humidity-controlled air to the air conditioning indoor unit (30). The humidity control unit (20) has an outdoor casing (11), a humidity control rotor (22), a first fan (26), a heater (25), and a first switching damper (24). The outdoor casing (21) is shared by the air conditioning outdoor unit (10) and the humidity control unit (20).

The above-described second space (S2) is defined inside the outdoor casing (11). A humidity control rotor (22) and a heater (25) are provided in the second space (S2). Strictly speaking, the second space (S2) is provided with a humidity control rotor (22), a first fan (26), a heater (25), and a first switching damper (24). A humidity control inlet (21a), a connection port (21b), and an outdoor exhaust port (21c) are formed in the outdoor casing (11). The humidity control suction port (21a) is an opening for drawing outdoor air. A first passageway (27) extending from the humidity control inlet (21a) to the connection port (21b) is formed inside the outdoor casing (11). A hose (2) is connected to the connection port (21b).

A discharge passageway (28) is connected to the first passageway (27). The discharge passage (28) continues from the middle portion of the first passageway (27) to the outdoor exhaust port (21c). The inflow end of the discharge passage (28) is connected to the downstream side of the humidity control rotor (22) in the first passageway (27) (more precisely, the downstream side of the first fan (26)).

Air flowing through the first passageway (27) passes through the humidity control rotor (22). The humidity control rotor (22) is an adsorption member that adsorbs moisture in the air. The humidity control rotor (22) is, for example, a disk-shaped humidity control rotor having a honeycomb structure. The humidity control rotor (22) carries, as an adsorbent, a predetermined functional material that improves absorption of infrared rays. The humidity control rotor (22) holds an adsorbent such as high polymer, silica gel, zeolite, alumina. The adsorbent has the property of adsorbing moisture in the air. Moisture absorbents have the property of desorbing adsorbed moisture when heated. The humidity control rotor (22) is placed at a predetermined position where the infrared rays generated by the heater (25) can reach, and is heated by the heater (25).

The humidity control rotor (22) is rotated by driving the third motor (M3). The humidity control rotor (22) has a humidity control area (22A) located in the first passageway (27). In the humidity control region (22A), a regeneration operation for desorbing moisture adsorbed on the adsorbent into the air and an adsorption operation for adsorbing moisture in the air on the adsorbent are performed.

The first fan (26) is arranged downstream of the humidity control area (22A) in the first passageway (27). The first fan (26) conveys outdoor air so as to pass through the humidity control area (22A) of the humidity control rotor (22). The first fan (26) is rotated by driving the fourth motor (M4). The first fan (26) is configured to be able to switch the air volume in a plurality of steps by adjusting the rotational speed of the fourth motor (M4).

The heater (25) is arranged upstream of the humidity control area (22A) in the first passageway (27). The heater (25) heats air flowing through the first passageway (27). The heater (25) has a variable output. The temperature of the air passing through the heater (25) changes according to the output of the heater (25).

The first switching damper (24) is provided at a connecting portion of the first passageway (27) to the discharge passageway (28). The channel switching mechanism may be composed of a channel switching valve, a shut, or the like. The first switching damper (24) switches between a first state (the state indicated by the solid line in FIG. 2) and a second state (the state indicated by the broken line in FIG. 2). The first switching damper (24) in the first state allows communication between the first passageway (27) and the interior of the hose (2) and blocks communication between the first passageway (27) and the discharge passageway (28). The first switching damper (24) in the second state isolates the first passageway (27) from the interior of the hose (2) and allows the first passageway (27) to communicate with the discharge passageway (28).

(2-3) Air Conditioner Indoor Unit As shown in FIGS. 1 to 3, the air conditioner indoor unit (30) is installed indoors. The air conditioning indoor unit (30) is a wall-mounted type that is installed on the wall (WL) of the room that forms the indoor space (I). The air conditioning indoor unit (30) includes an indoor casing (31), an indoor fan (32), an air filter (33), an indoor heat exchanger (34), a drain pan (35), and a wind direction adjusting section (36). and

The indoor casing (31) houses an indoor fan (32), an air filter (33), an indoor heat exchanger (34) and a drain pan (35). The indoor casing (31) is formed with an indoor suction port (31a) and an indoor outlet (31b). The indoor suction port (31a) is arranged above the indoor casing (31). The indoor air intake (31a) is an opening for sucking indoor air. The indoor outlet (31b) is arranged below the indoor casing (31). The indoor air outlet (31b) is an opening for blowing off heat-exchanged air or humidity-conditioning air. The interior of the indoor casing (31) is provided with an indoor air passageway (31c) extending from the indoor air inlet (31a) to the indoor air outlet (31b).

The indoor fan (32) is arranged substantially in the center of the indoor air passageway (31c). The indoor fan (32) is, for example, a cross-flow fan. The indoor fan (32) is rotated by driving the fifth motor (M5). The indoor fan (32) takes indoor air into the indoor air passageway (31c) and conveys it. The air carried by the indoor fan (32) is sucked into the indoor casing (31) through the indoor suction port (31a). This air flows through the indoor air passageway (31c) and is blown out of the indoor casing (31) from the indoor outlet (31b).

The indoor fan (32) conveys indoor air so as to pass through the indoor heat exchanger (34). The air blown out from the indoor air outlet (31b) is supplied to the indoor space (I). The indoor fan (32) is configured such that the air volume can be switched in a plurality of steps by adjusting the rotation speed of the fifth motor (M5).

The air filter (33) is arranged upstream of the indoor heat exchanger (34) in the indoor air passageway (31c). The air filter (33) is attached to the indoor casing (31) so that substantially all of the air supplied to the indoor heat exchanger (34) passes through. The air filter (33) collects dust in the air sucked through the indoor air inlet (31a).

The indoor heat exchanger (34) is arranged upstream of the indoor fan (32) in the indoor air passageway (31c). The indoor heat exchanger (34) of this example is a fin-and-tube heat exchanger. The indoor heat exchanger (34) exchanges heat between the refrigerant therein and indoor air conveyed by the indoor fan (32).

The drain pan (35) is arranged on the lower front side and the lower rear side of the indoor heat exchanger (34). The drain pan (35) receives condensed water generated inside the indoor casing (31) of the air conditioning indoor unit (30). Condensed water generated on the surface of the fins of the indoor heat exchanger (34) flows down due to its own weight along the surface and is received by the drain pan (35).

The airflow direction adjusting section (36) adjusts the direction of the air blown out from the indoor air outlet (31b). The wind direction adjusting part (36) has a flap (37). The flap (37) is shaped like a long plate extending along the longitudinal direction of the indoor outlet (31b). The flap (37) is rotated by being driven by a motor. The flap (37) opens and closes the indoor outlet (31b) as it rotates.

The flap (37) is configured so that the angle of inclination can be changed stepwise. The positions to which the flap (37) in this example is adjusted include six positions. These six positions include a closed position and five open positions. The five open positions include the generally horizontal blow position shown in FIG. The flap (37) in the closed position substantially closes the indoor outlet (31b). A gap may be formed between the flap (37) in the closed position and the indoor outlet (31b).

(2-4) Remote Controller The remote controller (40) is placed indoors at a position where the user can operate it. The remote controller (40) has a display section (41) and an input section (42). The display (41) displays predetermined information. The display section (41) is composed of, for example, a liquid crystal monitor. The predetermined information is information indicating the operating state, set temperature, and the like of the air conditioner (1). An input unit (42) receives an input operation for performing various settings from a user. The input section (42) is composed of, for example, a plurality of physical switches. The user can set the operation mode, target temperature, target humidity, etc. of the air conditioner (1) by operating the input section (42) of the remote controller (40).

(2-5) Sensors As shown in FIGS. 2 and 4, the air conditioner (1) has a plurality of sensors. The plurality of sensors includes a sensor for refrigerant and a sensor for air. The refrigerant sensor includes a sensor that detects the temperature and pressure of the high-pressure refrigerant and a sensor that detects the temperature and pressure of the low-pressure refrigerant (not shown).

The sensors for air include an outside air temperature sensor (51), an outside air humidity sensor (52), an inside air temperature sensor (53) and an inside air humidity sensor (54). The outside air temperature sensor (51) is provided in the air conditioning outdoor unit (10). The outdoor air temperature sensor (51) detects the temperature of outdoor air. The outside air humidity sensor (52) is provided in the humidity control unit (20). The outside air humidity sensor (52) detects the humidity of the outside air. The outdoor air humidity sensor (52) of this example detects the relative humidity of the outdoor air, but may also detect the absolute humidity. The inside air temperature sensor (53) and the inside air humidity sensor (54) are provided in the air conditioning indoor unit (30). The inside air temperature sensor (53) detects the temperature of the inside air. A room air humidity sensor (54) detects the humidity of the room air. The room air humidity sensor (54) detects the relative humidity of the room air, but may also detect the absolute humidity.

(2-6) Control Section As shown in FIGS. 2 and 4, the air conditioner (1) has a control section (C). The controller (C) controls the operation of the refrigerant circuit (R). The control section (C) controls operations of the air conditioner outdoor unit (10), the humidity control unit (20), and the air conditioner indoor unit (30). The controller (C) includes an outdoor controller (OC), an indoor controller (IC), and a remote controller (40). The outdoor controller (OC) is provided in the air conditioner outdoor unit (10). The indoor controller (IC) is provided in the air conditioner indoor unit (30). Each of the indoor controller (IC) and the outdoor controller (OC) includes an MCU (Micro Control Unit), an electric circuit, and an electronic circuit. The MCU includes a CPU (Central Processing Unit), a memory, and a communication interface. Various programs for the CPU to execute are stored in the memory.

A detection value of the outside air temperature sensor (51) and a detection value of the outside air humidity sensor (52) are input to the outdoor control unit (OC).

The outdoor controller (OC) is connected to the compressor (12), the outdoor fan (13), the expansion valve (15) and the four-way switching valve (16). The outdoor control unit (OC) sends control signals for executing and stopping the operation of the air conditioning outdoor unit (10) to the compressor (12), the outdoor fan (13), the expansion valve (15), and the four-way switching valve. Output to (16). The outdoor control unit (OC) controls the operating frequency of the first motor (M1) of the compressor (12), the rotation speed of the second motor (M2) of the outdoor fan (13), the state of the four-way switching valve (16), and the expansion Controls the opening of the valve (15).

The outdoor controller (OC) is further connected to the humidity control rotor (22), the first fan (26), the heater (25), and the first switching damper (24). The outdoor control section (OC) sends control signals for executing and stopping the operation of the humidity control unit (20) to the humidity control rotor (22), the first fan (26), the heater (25), and the first fan (26). Output to switching damper (24). The outdoor control unit (OC) controls the number of revolutions of the third motor (M3) of the humidity control rotor (22) and the fourth motor (M4) of the first fan (26), the humidity control rotor (22) and the first It controls the operation of the switching damper (24) and the output of the heater (25).

A detection value of the inside air temperature sensor (53) and a detection value of the inside air humidity sensor (54) are input to the indoor control unit (IC).

The indoor controller (IC) is communicably connected to the remote controller (40). The indoor controller (IC) is connected to the indoor fan (32). The indoor controller (IC) outputs a control signal to the indoor fan (32) to start and stop the operation of the air conditioning indoor unit (30). The indoor controller (IC) controls the rotation speed of the fifth motor (M5) of the indoor fan (32). The indoor controller (IC) is communicably connected to the outdoor controller (OC).

A remote controller (40) is communicably connected to an indoor controller (IC). The remote controller (40) transmits an instruction signal instructing the operation of the air conditioner (1) to the indoor controller (IC) according to the user's operation on the input section (42). Upon receiving an instruction signal from the remote controller (40), the indoor controller (IC) transmits the instruction signal to the outdoor controller (OC). The indoor controller (IC) controls the operation of each device of the air conditioning indoor unit (30) according to the instruction signal. When the outdoor controller (OC) receives an instruction signal from the indoor controller (IC), it controls the operation of each device of the air conditioning outdoor unit (10) and the humidity control unit (20).

(3) Operation Operation The operation modes executed by the air conditioner (1) include cooling operation, heating operation, air supply operation, dehumidification operation, humidification operation, cooling dehumidification operation, and heating and humidification operation. The controller (C) executes these operations based on instruction signals from the remote controller (40).

(3-1) Cooling operation Cooling operation is an operation in which indoor air is cooled by the indoor heat exchanger (34) as an evaporator. The humidity control unit (20) is stopped. In cooling operation, the controller (C) operates the compressor (12), the outdoor fan (13), and the indoor fan (32). The controller (C) sets the four-way switching valve (16) to the first state. The control section (C) appropriately adjusts the degree of opening of the expansion valve (15). In the cooling operation, a first refrigeration cycle is performed in which the compressed refrigerant releases heat in the outdoor heat exchanger (14) and evaporates in the indoor heat exchanger (34).

In cooling operation, the controller (C) adjusts the target evaporation temperature of the indoor heat exchanger (34) so that the room temperature detected by the room temperature sensor (53) converges to the set temperature. The control section (C) controls the rotation speed of the compressor (12) such that the evaporation temperature of the refrigerant in the indoor heat exchanger (34) converges to the target evaporation temperature. In the cooling operation, the air conveyed by the indoor fan (32) is cooled as it passes through the indoor heat exchanger (34). The air cooled by the indoor heat exchanger (34) is supplied to the indoor space (I) from the indoor outlet (31b) of the air conditioning indoor unit (30).

(3-2) Heating operation The heating operation is an operation in which the indoor air is heated by the indoor heat exchanger (34) as a radiator. The humidity control unit (20) is stopped. In heating operation, the controller (C) operates the compressor (12), the outdoor fan (13), and the indoor fan (32). The controller (C) sets the four-way switching valve (16) to the second state. The control section (C) appropriately adjusts the degree of opening of the expansion valve (15). In the heating operation, a second refrigeration cycle is performed in which refrigerant compressed by the compressor (12) releases heat in the indoor heat exchanger (34) and evaporates in the outdoor heat exchanger (14).

In heating operation, the controller (C) adjusts the target condensing temperature of the indoor heat exchanger (34) so that the room temperature detected by the room temperature sensor (53) converges to the set temperature. The control section (C) controls the rotation speed of the compressor (12) such that the condensation temperature of the refrigerant in the indoor heat exchanger (34) converges to the target condensation temperature. In the heating operation, the air conveyed by the indoor fan (32) is heated as it passes through the indoor heat exchanger (34). The air heated by the indoor heat exchanger (34) is supplied to the indoor space (I) from the indoor outlet (31b) of the air conditioning indoor unit (30).

(3-3) Air supply operation The air supply operation is an operation for supplying outdoor air to the room. In the air supply operation, outdoor air is sent to the air conditioner indoor unit (30) through the hose (2), as indicated by the solid arrow in FIG. In the air supply operation, the controller (C) stops the heater (25), the humidity control rotor (22), and the second fan (23) and operates the first fan (26). The control section (C) sets the first switching damper (24) to the first state. In the air supply operation, the outdoor air conveyed by the first fan (26) is sent to the air conditioning indoor unit (30) through the hose (2), and is discharged from the air outlet (31b) of the air conditioning indoor unit (30) into the indoor space. (I). The air supply operation may be performed simultaneously with the cooling operation or the heating operation.

(3-4) Dehumidification operation In the dehumidification operation, the air dehumidified by the humidity control unit (20) is supplied indoors. In this embodiment, dehumidified air is intermittently supplied indoors. The humidity control unit (20) performs the first action, the second action, and the post-regeneration operation. The first action is to adsorb moisture in the air to the humidity control rotor (22) and to supply the air dehumidified by the humidity control rotor (22) into the room. The second action is to regenerate the humidity control rotor (22) and to discharge the air used for regeneration to the outside of the room. The post-regeneration operation will be described later.

Specifically, in the first action, the control section (C) operates the first fan (26), stops the heater (25), and places the first switching damper (24) in the first state. Air conveyed by the first fan (26) flows through the first passageway (27) and passes through the humidity control area (22A) of the humidity control rotor (22). Moisture in the air is adsorbed by the adsorbent in the humidity control region (22A). The air dehumidified in the humidity control area (22A) is sent to the air conditioner indoor unit (30) through the hose (2), and supplied to the indoor space (I) from the indoor outlet (31b) of the air conditioner indoor unit (30). .

Note that the execution time of the first action is the time required for the portion (the humidity conditioning region (22A)) positioned in the first passageway (27) at the start of the first action to go around at least once as the humidity conditioning rotor (22) rotates. is preferred. As a result, moisture can be adsorbed by the adsorbent around the entire periphery of the humidity control rotor (22) in one first operation.

In the second operation (regeneration process for the rotor (22)), the control section (C) operates the first fan (26) and the heater (25) to set the first switching damper (24) to the second state. Air conveyed by the first fan (26) flows through the first passageway (27), is heated by the heater (25), and then flows through the humidity control area (22A) of the humidity control rotor (22). The adsorbent is regenerated in the humidity conditioning area (22A). Specifically, the moisture adsorbed by the adsorbent is desorbed and released into the air. The air used to regenerate the humidity control rotor (22) flows from the first passageway (27) through the discharge passageway (28) as indicated by the dashed arrow in FIG. 2, and is discharged to the outside of the room.

Note that the execution time of the second action is the time required for the portion positioned in the first passageway (27) (humidity conditioning region (22A)) to make at least one revolution as the humidity conditioning rotor (22) rotates at the start of the second action. is preferred. As a result, the adsorbent around the entire circumference of the humidity control rotor (22) can be regenerated in one second operation. In the present embodiment, the entire circumference of the humidity control rotor (22) is regenerated in batch mode.

(3-5) Humidification operation Humidification operation is an operation to supply air humidified by the humidity control unit (20) to the room. In this embodiment, humidified air is intermittently supplied indoors. The humidity control unit (20) alternately and repeatedly performs the third operation and the fourth operation. The third operation is an operation of causing the humidity control rotor (22) to adsorb moisture in the air and discharging the air that has passed through the humidity control rotor (22) to the outside of the room. The fourth action is to regenerate the humidity control rotor (22) and to supply air to which moisture has been added from the humidity control rotor (22) into the room.

Specifically, in the third operation, the control section (C) operates the first fan (26), stops the heater (25), and places the first switching damper (24) in the second state. Air conveyed by the first fan (26) flows through the first passageway (27) and passes through the humidity control area (22A) of the humidity control rotor (22). Moisture in the air is adsorbed by the adsorbent in the humidity control region (22A). As indicated by the dashed arrow in FIG. 2, the air that has added moisture to the adsorbent in the humidity control area (22A) flows from the first passageway (27) through the discharge passageway (28) and is discharged to the outside of the room.

Note that the execution time of the third action is the time required for the portion positioned in the first passage (27) (humidity conditioning region (22A)) to make at least one revolution as the humidity conditioning rotor (22) rotates at the start of the third movement. is preferred. As a result, moisture can be adsorbed by the adsorbent around the entire circumference of the humidity control rotor (22) in one third operation.

In the fourth operation, the control section (C) operates the first fan (26) and the heater (25) and places the first switching damper (24) in the first state. Air conveyed by the first fan (26) flows through the first passageway (27), is heated by the heater (25), and then flows through the humidity control region (22A) of the humidity control rotor (22). The adsorbent is regenerated in the humidity conditioning area (22A). Specifically, the moisture adsorbed by the adsorbent is desorbed and released into the air. The air containing moisture detached from the humidity control rotor (22) is sent to the air conditioner indoor unit (30) through the hose (2), and is discharged from the indoor air outlet (31b) of the air conditioner indoor unit (30) to the indoor space (I). supplied.

Note that the execution time of the fourth action is the time required for the portion positioned in the first passage (27) (humidity-conditioning region (22A)) to make at least one revolution as the humidity-conditioning rotor (22) rotates at the start of the fourth action. is preferred. As a result, moisture can be desorbed into the air from the adsorbent around the entire circumference of the humidity control rotor (22) in one fourth operation.

(3-6) Dehumidifying Cooling Operation In the dehumidifying cooling operation, the above-described cooling operation and dehumidifying operation are performed simultaneously. Specifically, the air is dehumidified by the humidity control unit (20) and cooled by the indoor heat exchanger (34) functioning as an evaporator.

(3-7) Humidification/heating operation In the humidification/heating operation, the heating operation and the humidification operation described above are performed simultaneously. Specifically, the air is humidified by the humidity control unit (20) and heated by the indoor heat exchanger (34) functioning as a radiator.

(4) Dehumidification/Ventilation Operation In the dehumidification/ventilation operation, the processing of steps S10 to S30 shown in FIG. 5 is executed by the control section (C). The dehumidifying/ventilating operation is a process of ventilating and dehumidifying the indoor space (I).

As shown in FIGS. 2, 4 and 5, in step S10, the controller (C) performs the first dehumidifying operation. In the first operation, outdoor air conveyed by the first fan (26) is dehumidified by the humidity control rotor (22) and then supplied indoors. The humidity control rotor (22) dehumidifies the outdoor air by absorbing moisture contained in the outdoor air.

In step S10, the controller (C) may perform the dehumidifying cooling operation by simultaneously performing the cooling operation when performing the first operation.

In step S20, the control section (C) performs the second action after the first action of the dehumidifying operation is finished. In the second operation, the moisture adsorbed by the humidity control rotor (22) is heated by the heater (25) and heated by the heated air (heated outdoor air) conveyed by the first fan (26). 22), it flows from the first passageway (27) through the discharge passage (28) together with the heated air as indicated by the dashed arrow in FIG. 2, and is discharged to the outside of the room. In the second operation, the heated air is supplied to the humidity control rotor (22), thereby increasing the temperature of the humidity control rotor (22) and making the temperature of the humidity control rotor (22) higher than the temperature of the outdoor air. .

In step S30, the control unit (C) performs post-regeneration operation after the second operation is completed. In post-regeneration operation, the first operation is performed after the second operation of the dehumidifying operation is completed, while the humidity adjusting rotor (22) is not cooled (the temperature of the humidity adjusting rotor (22) is higher than the temperature of the outdoor air). indicate what to do. In this embodiment, the control section (C) performs the post-regeneration operation immediately after the second operation is finished.

When the post-regeneration operation is performed, although the heater (25) is stopped and the humidity control rotor (22) is not heated, the humidity control rotor (22) is subjected to the second operation of step S20. Sometimes residual heat remains due to being heated by the heater (25). As a result, in the operation after regeneration, the temperature of the humidity control rotor (22) is higher than the temperature of the outdoor air.

During post-regeneration operation, when the outdoor air conveyed by the first fan (26) passes through the humidity conditioning rotor (22) to become treated air, the humidity conditioning rotor (22) absorbs moisture while conditioning the air. It is warmed by residual heat possessed by the wet rotor (22). The temperature of the process air is higher than the temperature of the outdoor air. The humidity of the process air is lower than the humidity of the outdoor air. The treated air is sent to the air conditioning indoor unit (30) through the hose (2) by the first fan (26), and supplied to the indoor space (I) from the indoor outlet (31b) of the air conditioning indoor unit (30). The indoor space (I) is ventilated by supplying the treated air to the indoor space (I).

The temperature of the process air is determined according to the temperature of the rotor (22). The higher the temperature of the rotor (22), the higher the temperature of the process air.

Note that when the operation after regeneration in step S30 ends, the process may proceed to step S20 and the second operation (regeneration process for the rotor (22)) may be performed.

(5) Effect As described above, the air conditioner (1) has a humidity control unit (20) having a humidity control rotor (22) that adsorbs moisture in the air, and An air blower (26) for sending treated air generated by adsorbing contained moisture to the indoor space (I). The outdoor air is warmed by the heat accumulated in the humidity control rotor (22) to become process air. The temperature of the process air is higher than the temperature of the room air (the temperature of the air existing in the room space (I) just before the process air is supplied). As a result, when performing the first action of the dehumidifying operation in step S10, when the air in the indoor space (I) is cooled by the cooling operation in order to lower the humidity in the indoor space (I), the temperature of the indoor space (I) is Even if the temperature (room temperature) drops too much, the post-regeneration operation is performed in step S30 to generate treated air warmed by the residual heat of the humidity control rotor (22), thereby reducing the temperature of the indoor space (I) that has dropped too much. The process air can be supplied to the air. According to this, it is possible to supply the processing air having a temperature higher than that of the indoor air or the outdoor air to the indoor space (I), so that it is possible to prevent the temperature of the indoor space (I) from dropping too much. As a result, the dehumidification/ventilation operation can be effectively performed.

Since the treated air has moisture adsorbed by the humidity control rotor (22) in the post-regeneration operation, even if it is supplied to the indoor space (I), it is possible to suppress an increase in the humidity of the indoor space (I). As a result, the state in which the humidity in the indoor space (I) is lowered by the first operation of the dehumidifying operation in step S10 can be effectively ensured even when the post-regeneration operation is performed in step S30. As a result, the dehumidification/ventilation operation can be effectively performed.

Since the post-regeneration operation of step S30 is performed in a state in which the humidity control rotor (22) is not cooled after the second operation of step S20 is completed, the post-regeneration operation is started after the second operation is completed. It is possible to shorten the time up to and smoothly perform the dehumidifying and ventilating operation.

As the time during which the post-regeneration operation is performed in step S30 elapses, the outdoor air continues to hit the humidity adjusting rotor (22). The humidity control rotor (22) cools down. As a result, the ability of the humidity control rotor (22) to adsorb moisture in the outdoor air increases, and the humidity of the treated air generated from the humidity control rotor (22) decreases accordingly. The humidified air can be supplied to the indoor space (I), and the indoor space (I) can be effectively dehumidified.

In post-regeneration operation, by supplying indoor air or treated air having a temperature higher than that of outdoor air into the indoor space (I), the cooling load is intentionally increased and the cooling capacity of the air conditioner (1) is increased. can promote dehumidification of the indoor space (I).

If, after the regeneration operation in step S20, the air is not allowed to pass through the humidity control rotor (22), the natural cooling of the humidity control rotor (22) to the same temperature as the outdoor air is prevented. If the configuration is such that the outdoor air is supplied to the indoor space (I) through the humidity control rotor (22) after waiting, a waiting time for natural cooling of the humidity control rotor (22) occurs. The amount of treatment (water adsorption amount) per unit time of (22) decreases, and the dehumidification efficiency of the indoor space (I) decreases. During the waiting time for natural cooling of the humidity control rotor (22) (the time during which the humidity control rotor (22) does not exhibit the moisture adsorption function), high humidity outdoor air is introduced into the indoor space (I) through the gap. may enter and increase the humidity in the indoor space (I). In contrast, as in the present embodiment, after the regeneration operation in step S20, the state in which the humidity control rotor (22) has not cooled down (the state in which the temperature of the humidity control rotor (22) has not decreased to the temperature of the outdoor air) ), by starting the post-regeneration operation in step S30 and supplying the treated air having a higher temperature than the room air to the indoor space (I), after the regeneration operation in step S20, humidity conditioning It is possible to suppress the occurrence of time during which the rotor (22) does not exhibit the moisture adsorption function. As a result, according to the present embodiment, it is possible to suppress a decrease in the throughput per unit time of the humidity control rotor (22), and furthermore, after the regeneration operation in step S20, the humidity in the indoor space (I) increases. can be suppressed.

<Other embodiments>
(A) The air conditioner (1) may include a measuring section that measures the temperature of the rotor (22). In this case, as shown in FIG. 5, after the second operation (see step S20), in step S30, the controller (C) determines that the temperature of the rotor (22) measured by the measuring unit is higher than the predetermined temperature. If it is higher, the operation (post-regeneration operation) of sending the treated air to the indoor space (I) by the first fan (26) is not performed, and the temperature of the rotor (22) measured by the measuring unit is below the predetermined temperature. , an operation (post-regeneration operation) of sending the treated air to the indoor space (I) by the first fan (26). The predetermined temperature is determined using the indoor environment and the indoor environment target value, and is higher than the outdoor air temperature. The measurement unit includes, for example, a temperature sensor. The measuring unit may directly measure the temperature of the rotor (22), but it may also measure the temperature of a member (for example, a member supporting the rotor (22)) located close to the rotor (22), or the temperature of the rotor ( 22) may be measured as the temperature of the rotor (22). As a result, in step S30, it is possible to prevent the treated air supplied to the indoor space (I) from becoming too hot due to the post-regeneration operation.

(B) The control unit (C) transfers heat to the indoor space (I) after a predetermined time has passed or within a predetermined time after the process of accumulating heat in the rotor (22) (the second operation of step S20) is completed. A process of sending air (operation after regeneration in step S30) may be performed. As a result, the temperature of the rotor (22) naturally cools down as time elapses after the end of the process of accumulating heat in the rotor (22). can be adjusted according to changes in temperature. For example, in order to supply the treated air to the indoor space (I) before the temperature of the rotor (22) becomes 10 degrees or less relative to the outdoor air temperature, the control unit (C) controls the rotor (22) to Within 10 minutes after the end of the process of accumulating heat in the indoor space (I), the process of sending the process air to the indoor space (I) is performed.

(C) The rotation speed of the rotor (22) may be different during the humidification operation and during the dehumidification operation. The rotation speed of the rotor (22) may be faster during the dehumidifying operation than during the humidifying operation. Since the outdoor air temperature is higher in the dehumidifying operation scene than in the humidifying operation scene, the amount of temperature swing of the adsorbent becomes smaller, and the amount of water handled per unit volume becomes smaller. This is because it is necessary to rotate it to increase its ability. As a result, the dehumidifying operation can be effectively performed.

(D) As another embodiment, when the outdoor air is heated by the residual heat of the humidity control rotor (22) to generate the treated air in step S30, the outdoor air is heated by the residual heat of the humidity control rotor (22). When the amount of heating is insufficient, the heater (25) may be operated within a range in which the adsorbent of the humidity control rotor (22) does not lose its ability to adsorb moisture (the humidity control rotor (22) is heated by the heater (25). heating may be performed).

(E) (E-1) Basic Configuration The air conditioner (1) of the modification shown in FIG. 6 continuously supplies air humidified by the humidity control unit (20) into the room. In addition, the air conditioner (1) intermittently supplies air dehumidified by the humidity control unit (20) into the room. Differences from the above-described embodiment will be described below. In addition, in FIG. 6, illustration of the air conditioning indoor unit (30) and the air conditioning outdoor unit (10) is omitted for the sake of convenience.

The air conditioner (1) of the modification has a discharge passage (28) and a first switching damper (24), like the embodiment. As in the embodiment, the outdoor casing (11) of Modification 3 includes a humidity control inlet (21a), a connection port (21b), a moisture absorption side intake (61a), and a moisture absorption side exhaust port (61b). is formed. A first passageway (27) is formed from the humidity control intake port (21a) to the connection port (21b), and a second passageway (62) is formed from the moisture absorption side intake port (61a) to the moisture absorption side exhaust port (61b). be done.

A heater (25), a humidity control area (22A) of the humidity control rotor (22), and a first fan (26) are arranged in the first passageway (27) in order from the upstream side to the downstream side of the air flow. be done. The adsorption region (22C) of the humidity control rotor (22) and the second fan (23) are arranged in the second passageway (62) in this order from the upstream side to the downstream side of the air flow.

(E-2) Dehumidifying operation In the dehumidifying operation of the air conditioner (1) of the modification, dehumidified air is intermittently supplied indoors. The humidity control unit (20) performs the first action, the second action, and the post-regeneration operation, as in the embodiment shown in FIG. Specifically, in the first action, the control section (C) operates the first fan (26), stops the second fan (23), stops the heater (25), stops the first switching damper ( 24) as the first state. Air conveyed by the first fan (26) flows through the first passageway (27) and passes through the humidity control area (22A) of the humidity control rotor (22). Moisture in the air is adsorbed by the adsorbent in the humidity control region (22A). The air dehumidified in the humidity control area (22A) is sent to the air conditioner indoor unit (30) through the hose (2), and supplied to the indoor space (I) from the indoor outlet (31b) of the air conditioner indoor unit (30). .

In the second operation, the control section (C) operates the first fan (26) and the heater (25), stops the second fan (23), and places the first switching damper (24) in the second state. . Air conveyed by the first fan (26) flows through the first passageway (27), is heated by the heater (25), and then flows through the humidity control region (22A) of the humidity control rotor (22). The adsorbent is regenerated in the humidity conditioning area (22A). Specifically, the moisture adsorbed by the adsorbent is desorbed and released into the air. The air used to regenerate the humidity control rotor (22) flows from the first passageway (27) through the discharge passageway (28) and is discharged to the outside of the room, as indicated by the dashed arrow in FIG.

In the post-regeneration operation, after the second action is completed, the first action is performed in a state in which the humidity adjusting rotor (22) is not cooled (a state in which residual heat remains in the humidity adjusting rotor (22)). By performing the post-regeneration operation, the same effects as in the above-described embodiment can be obtained.

(E-3) Dehumidifying Cooling Operation In the dehumidifying cooling operation, the cooling operation of the embodiment described above and the dehumidifying operation of the modified example described above are performed simultaneously. Specifically, the air is dehumidified by the humidity control unit (20) and cooled by the indoor heat exchanger (34) functioning as an evaporator.

(E-4) Humidification operation In the humidification operation of the air conditioner (1) of the modified example, the control unit (C) operates the first fan (26) and the second fan (23) to operate the humidity control rotor (22). is rotationally driven to turn on the heater (25). A control part (C) makes a 1st switching damper (24) a 1st state.

Outdoor air flowing through the second passageway (62) flows through the adsorption region (22C) of the humidity control rotor (22). Moisture in the air is adsorbed by the adsorbent in the adsorption region (22C). The air that has added moisture to the humidity control rotor (22) is discharged to the outside of the room through the second passageway (62).

At the same time, the outdoor air flowing through the first passageway (27) is heated by the heater (25) and then flows through the humidity control area (22A) of the humidity control rotor (22). Moisture desorbed from the adsorbent is released into the air in the humidity control region (22A). The air humidified by the humidity control rotor (22) is sent to the air conditioner indoor unit (30) through the hose (2) and supplied to the indoor space (I) from the indoor air outlet (31b) of the air conditioner indoor unit (30). be.

(E-5) Humidification/heating operation In the humidification/heating operation, the heating operation of the embodiment described above and the humidification operation of the modified example described above are simultaneously performed. Specifically, the air is humidified by the humidity control unit (20) and heated by the indoor heat exchanger (34) functioning as a radiator.

Although the embodiments and modifications ((A) to (E) above) have been described above, it is understood that various changes in form and detail are possible without departing from the spirit and scope of the claims. would be Moreover, the elements of the above embodiments, modifications, and other embodiments may be appropriately combined or replaced.

The descriptions of "first", "second", "third", etc. described above are used to distinguish the words and phrases to which these descriptions are given, and the number and order of the words and phrases are also limited. not something to do.

INDUSTRIAL APPLICABILITY As described above, the present disclosure is useful for air conditioners.

C control unit
I Interior space
1 Air conditioner
20 humidity control unit (humidity control element)
22 humidity control rotor (rotor)
25 heater
26 1st fan (air blower)

Claims (12)

a humidity control element (20) having an adsorption member that adsorbs moisture in the air;
a blowing unit (26) for sending treated air generated by adsorbing moisture contained in outdoor air with the adsorption member to the indoor space (I),
The air conditioner, wherein the temperature of the treated air is higher than the temperature of the indoor air. In claim 1,
The air conditioner, wherein the temperature of the treated air is higher than the temperature of the outdoor air. In claim 1 or claim 2,
The adsorption member includes a rotor (22) carrying a moisture adsorbent,
An air conditioner, wherein the process air is generated by warming the outdoor air with heat accumulated in the rotor (22). In claim 3,
A measuring unit for measuring the temperature of the rotor (22),
An air conditioner, wherein when the temperature of the rotor (22) measured by the measuring unit is higher than a predetermined temperature, the operation of sending the treated air to the indoor space (I) by the air blowing unit (26) is not performed. Device. In claim 3 or claim 4,
An air conditioner, wherein the treated air is sent to the indoor space (I) after a predetermined time has passed or within a predetermined time after the end of the process of accumulating heat in the rotor (22). In any one of claims 3 to 5,
An air conditioner, wherein the temperature of the treated air is determined according to the temperature of the rotor (22). In any one of claims 3 to 6,
An air conditioner, wherein the rotational speed of the rotor (22) differs between humidifying operation and dehumidifying operation. In claim 7,
The air conditioner, wherein the rotation speed of the rotor (22) is faster during the dehumidification operation than during the humidification operation. In any one of claims 3 to 8,
When the rotor (22) is regenerated, the entire circumference of the rotor (22) is regenerated in a batch process, and the rotor (22) is rotated in an unheated state after the regeneration. An air conditioner that sends the treated air to the indoor space (I) through the air conditioner. In claim 9,
An air conditioner that sends air that has passed through the rotor (22) to the outside of the room during the regeneration process. In any one of claims 3 to 10,
The air conditioner, wherein the rotor (22) carries a predetermined functional material as an adsorbent. In any one of claims 3 to 11,
A heater (25) for heating the air supplied to the rotor (22),
The air conditioner, wherein the rotor (22) is arranged at a predetermined position.

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