JP6106449B2 - Outside air treatment device - Google Patents

Description

  The present invention relates to an outside air processing apparatus that processes outdoor air and supplies dehumidified air or humidified air into a room of a target room.

  As an air conditioner used for small and medium-sized buildings, a building multi-air conditioner using a heat pump and a packaged air conditioner are often used. These air conditioners use chlorofluorocarbon refrigerant and harmonize the air in each room with one outdoor unit and one or more indoor units, and the temperature of each room is controlled for each indoor unit. . In this case, since the air blowing type of the air conditioner is an internal circulation type, it is necessary to take in outside air in order to maintain the oxygen concentration in the room. Therefore, many outside air processing apparatuses are employed.

  The outside air processing device takes in a constant amount of outside air into the room and releases the same amount of air from the room to the outside. If the outside air is directly taken into the room, for example, high-temperature and high-humidity air is introduced in the summer, and low-temperature and low-humidity air is introduced in the winter. For this reason, an outside air processing apparatus using a total heat exchanger is used.

  As a conventional example of an outside air treatment apparatus using a total heat exchanger, for example, one disclosed in Japanese Patent Application Laid-Open No. 2010-151376 (Patent Document 1) is known. Patent Document 1 discloses that by combining a heat pump and a rotary desiccant, the performance of dehumidification and humidification is improved, and condensation of the evaporator is suppressed, so that drain treatment is unnecessary.

  More specifically, in Patent Document 1, heat exchangers are provided on the upstream side and the downstream side of the flow path on the dehumidifying side (moisture adsorption side) of the desiccant and the flow path on the regeneration side (moisture release side), respectively. At the time of cooling and dehumidifying operation, one heat exchanger upstream of the regeneration side is a condenser, and the other three heat exchangers are evaporators. An expansion valve is provided for each evaporator, and the opening degree of each expansion valve is adjusted according to the temperature and humidity of the air passing through the evaporator. Thereby, the circulation amount of a refrigerant | coolant can be adjusted and the dew condensation produced in the air which passes an evaporator can be prevented.

JP 2010-151376 A

  As described above, in the outside air processing apparatus shown in Patent Document 1, one of the heat exchangers arranged on the upstream side and the downstream side of the desiccant is a condenser, and three are evaporators. The air flowing through the air flow path is dehumidified and humidified. However, although it is shown that the expansion valve is adjusted so that the air passing through the evaporator does not condense, a specific control method is not mentioned. Accordingly, it is not possible to reliably prevent the occurrence of condensation in the evaporator. For this reason, moisture may condense in the evaporator, resulting in drainage. Therefore, it is necessary to take drainage measures such as drain piping, and the appearance of an outside air treatment device that can prevent the occurrence of condensation more reliably is desired. It was.

  The present invention has been made to solve such a conventional problem, and an object of the present invention is to provide outside air that can more reliably prevent condensation that occurs in a heat exchanger used as an evaporator. It is to provide a processing apparatus.

In order to achieve the above object, the present invention relates to a flow path of air from the outdoor to the indoor in an outdoor air processing apparatus that supplies the dehumidified air or humidified air by processing the outdoor air into the room of the target room. The first air flow path, the second air flow path serving as a flow path of air from the room to the outside, the first air flow path, and the first air flow path. Moisture adsorption means (for example, desiccant 8) that adsorbs moisture in the air flowing through one of the channel and the second air channel and releases moisture to the air flowing through the other channel, and circulates the refrigerant A refrigerant circuit, and the refrigerant circuit includes a compressor that compresses the refrigerant, a first heat exchanger that is disposed upstream of the moisture adsorbing means in the second air flow path, and a downstream side. The third heat exchanger arranged and the moisture adsorption means of the first air flow path. In the second heat exchanger disposed on the flow side, the fourth heat exchanger disposed on the downstream side, and the dehumidifying mode for supplying dehumidified air to the room, the refrigerant output from the compressor is the first heat exchanger. Output switching means (for example, a four-way valve 3) for switching to supply the refrigerant output from the compressor to the second heat exchanger in the humidification mode in which the humidified air is supplied to the heat exchanger and supplied indoors. A first expansion valve provided between the first heat exchanger and the second heat exchanger, and a second expansion valve provided between the third heat exchanger and the fourth heat exchanger Control means (for example, main control unit 31) for controlling the opening degree of the first expansion valve and the second expansion valve and controlling the output switching means, and the control means further comprises dehumidification In the mode, the refrigerant output from the compressor is supplied to the output side of the first heat exchanger. Et al., Path through the second heat exchanger and the first expansion valve, and sets the flow path of the refrigerant to circulate path through said fourth heat exchanger and the second expansion valve, And based on the degree of superheat of the refrigerant circuit, a total expansion valve opening that is a total opening of the first expansion valve and the second expansion valve is obtained, and the temperature of the air passing through the second heat exchanger, And based on the dew point temperature, a deviation expansion valve opening which is a difference opening between the first expansion valve and the second expansion valve is obtained so that the temperature of the air passing through the second heat exchanger does not reach the dew point, Further, based on the total expansion valve opening and the deviation expansion valve opening, the opening of the first expansion valve and the opening of the second expansion valve are calculated and output from the compressor in the humidification mode. The refrigerant to be passed from the output side of the second heat exchanger through the first expansion valve and the first heat exchanger, and the front The refrigerant flow path is set so as to circulate the path passing through the second expansion valve and the third heat exchanger, and the total expansion valve opening is obtained based on the degree of superheat of the refrigerant circuit, Based on the temperature of the air passing through the first heat exchanger and the dew point temperature, the deviation expansion valve opening is obtained so that the temperature of the air passing through the first heat exchanger does not reach the dew point, and this total expansion is further obtained. Based on the valve opening and the deviation expansion valve opening, the opening of the first expansion valve and the opening of the second expansion valve are calculated, and the calculated opening of the first expansion valve and the second opening are calculated. The opening degree of the first expansion valve and the second expansion valve is adjusted so as to be the opening degree of the expansion valve.

  In the outside air processing apparatus according to the present invention, in the dehumidifying mode, the opening degrees of the first expansion valve and the second expansion valve are controlled so that the outlet air temperature of the second heat exchanger functioning as an evaporator does not reach the dew point. In the humidification mode, the opening of the first expansion valve and the second expansion valve is controlled so that the outlet air temperature of the first heat exchanger functioning as an evaporator does not reach the dew point. It can prevent that the air which flows through a path and a 2nd air flow path condenses within a heat exchanger. Therefore, it is not necessary to take a drain countermeasure, the apparatus scale can be simplified, and the cost can be reduced.

  Further, based on the degree of superheat of the refrigerant that has passed through the heat exchanger functioning as an evaporator (the second heat exchanger 5 in the dehumidifying mode and the first heat exchanger 4 in the humidifying mode), the total expansion valve opening is set. Further, the deviation expansion valve opening is obtained based on the temperature of the air passing through the heat exchanger and the dew point temperature. Then, based on the obtained total expansion valve opening and deviation expansion valve opening, the first expansion valve opening and the second expansion valve opening are set. Therefore, dew condensation in the heat exchanger can be prevented and dehumidification and humidification can be performed efficiently.

  Furthermore, the output of the compressor 1 is controlled based on the temperature of the air passing through the heat exchanger functioning as a condenser (the first heat exchanger 4 in the dehumidifying mode and the second heat exchanger 5 in the humidifying mode). Therefore, the temperature of the air that has passed through the heat exchanger can be maintained at a predetermined value. Accordingly, the regeneration air temperature on the moisture release side of the moisture adsorbing means can be stabilized, so that the moisture adsorption ability can be stabilized, and consequently the dehumidification ability can be increased.

  In addition, the third heat exchanger is stopped in the dehumidifying mode, and the fourth heat exchanger is stopped in the humidifying mode. Therefore, the stopped heat exchanger can be used as a refrigerant storage liquid receiver. It is not necessary to provide a vessel, and the apparatus configuration can be simplified.

  Furthermore, if the humidification mode is omitted and only the dehumidification mode is configured, it is possible to prevent the occurrence of condensation, simplify the device configuration, and cool and dehumidified air in a room that requires only dehumidification operation. It is extremely useful when supplying.

It is a flowchart which shows typically the flow of the air of the air conditioning system containing the external air processing apparatus which concerns on 1st Embodiment of this invention. It is the figure which showed typically the refrigerant circuit of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a block diagram which shows the electric constitution of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a flowchart which shows the flow of the refrigerant | coolant at the time of dehumidification mode of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a flowchart which shows the flow of the refrigerant | coolant at the time of humidification mode of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a figure which shows the data detection by each sensor by operation | movement of the four-way valve in a dehumidification mode and a humidification mode, and a 1st, 2nd solenoid valve of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a flowchart which shows the process sequence of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a flowchart which shows the process sequence of the compressor control in the dehumidification mode of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a flowchart which shows the process sequence of the expansion valve opening degree control in the dehumidification mode of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a flowchart which shows the process sequence of the compressor control in the humidification mode of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a flowchart which shows the process sequence of the expansion valve opening degree control in the humidification mode of the external air processing apparatus which concerns on 1st Embodiment of this invention. It is a flowchart which shows typically the flow of the refrigerant | coolant of the external air processing apparatus which concerns on 2nd Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[Description of First Embodiment]
FIG. 1 is a block diagram schematically showing a configuration of an air conditioning system including an outside air processing apparatus according to a first embodiment of the present invention and its peripheral devices, and (a) shows an air flow in a dehumidifying mode. , (B) shows the air flow in the humidification mode. As shown in FIG. 1, the air conditioning system includes a first air flow path 12 that goes from the outside of a room that is a target of air conditioning control to the room, and a second air flow path 13 that goes from the room to the outside. .

  The first air flow path 12 is a flow path for supplying outdoor air into the room by an SA (Supply Air) fan 10 provided on the downstream side. The total heat exchanger 11 and the second heat exchanger 5 are provided. The outdoor air is supplied into the room via the rotary desiccant 8 (moisture adsorption means), the fourth heat exchanger 7 and the SA fan 10.

  The second air flow path 13 is a flow path for exhausting indoor air to the outside by an EA (Exhaust Air) fan 9 provided on the downstream side. The total heat exchanger 11 and the first heat exchanger 4. The indoor air is discharged to the outside through the desiccant 8, the third heat exchanger 6, and the EA fan 9.

  In the dehumidifying mode shown in FIG. 1A, the second heat exchanger 5 and the fourth heat exchanger 7 function as an evaporator, the first heat exchanger 4 functions as a condenser, and the third heat exchanger 6 is stopped. Moreover, the area | region where the 1st air flow path 12 of the desiccant 8 passes is made into the dehumidification side, and the area | region where the 2nd air flow path 13 passes is made into the reproduction | regeneration side.

  And outdoor air (OA; Out Air) passes through the total heat exchanger 11, and temperature is lowered | hung, and it is further lowered | hung in the 2nd heat exchanger 5 which functions as an evaporator after that. Next, the moisture is removed by passing through the dehumidifying side of the desiccant 8 (that is, the humidity is lowered), and the temperature is lowered by the fourth heat exchanger 7 functioning as an evaporator and supplied to the room. . Accordingly, the room is supplied with dehumidified air at a low temperature. As a result, in the summer, low-humidity air can be supplied indoors.

  On the other hand, the temperature of indoor air (RA; Return Air) rises by passing through the total heat exchanger 11, and then passes through the first heat exchanger 4 functioning as a condenser, thereby further increasing the temperature. Rises. Since the air whose temperature has risen can contain a large amount of moisture, it passes through the regeneration side of the desiccant 8 to absorb moisture adsorbed on the dehumidifying side of the desiccant 8 (that is, remove the moisture of the desiccant 8). And EA fan 9 discharges the room. At this time, the operation of the third heat exchanger 6 is stopped, and the third heat exchanger 6 functions as a liquid receiver for accumulating the refrigerant as will be described later.

  Further, in the humidifying mode shown in FIG. 1B, the operation is opposite to that in the dehumidifying mode described above. That is, the 1st heat exchanger 4 and the 3rd heat exchanger 6 function as an evaporator, the 2nd heat exchanger 5 functions as a condenser, and the 4th heat exchanger 7 will be in a halt condition. Moreover, the area | region where the 1st air flow path 12 of the desiccant 8 passes is made into the reproduction | regeneration side, and the area | region where the 2nd air flow path 13 passes is made into the dehumidification side.

  Then, the temperature of the indoor air (RA) is lowered by passing through the total heat exchanger 11, and then the temperature is further lowered by the first heat exchanger 4 functioning as an evaporator. Next, the moisture is removed by passing through the dehumidifying side of the desiccant 8, and the temperature is lowered by the third heat exchanger 6 functioning as an evaporator and discharged outside the room.

  On the other hand, the temperature of the outdoor air (OA) rises by passing through the total heat exchanger 11, and then further rises by passing through the second heat exchanger 5 that functions as a condenser. Since the air whose temperature has risen can contain a large amount of moisture, it passes through the regeneration side of the desiccant 8 to absorb moisture adsorbed on the dehumidifying side of the desiccant 8 (that is, remove the moisture of the desiccant 8). And supplied to the room by the SA fan 10. At this time, the operation of the fourth heat exchanger 7 is stopped. Therefore, air with increased temperature and increased humidity is supplied to the room. As a result, high-humidity air can be supplied indoors in winter.

  Next, the outside air processing apparatus according to the present embodiment will be described in more detail with reference to FIG. As shown in FIG. 2, the outside air processing apparatus 100 according to the present embodiment includes a refrigerant circuit that circulates refrigerant and a desiccant 8. The refrigerant circuit includes a compressor 1 that compresses and outputs a refrigerant under the control of an inverter 27 (see FIG. 3), and an accumulator 2 that is provided upstream of the compressor 1 and temporarily accumulates the refrigerant that is supplied to the compressor 1. And a four-way valve 3 (output switching means) for switching so that the compressed refrigerant delivered from the compressor 1 is output to either the first air flow path 12 side or the second air flow path 13 side heat exchanger. It is equipped with. Further, the refrigerant circuit includes a first heat exchanger 4 provided on the upstream side of the desiccant 8 in the second air flow path 13, a third heat exchanger 6 provided on the downstream side of the desiccant 8, and the first air flow path. The second heat exchanger 5 provided on the upstream side of the twelve desiccants 8 and the fourth heat exchanger 7 provided on the downstream side of the desiccant 8 are provided.

  The refrigerant circuit includes a first solenoid valve 14, a second solenoid valve 15, a first check valve 16, a second check valve 17, a first expansion valve 18, a second expansion valve 19, and Various sensors are provided.

  The first electromagnetic valve 14 is provided between the first heat exchanger 4 and the third heat exchanger 6 and is controlled to be opened in the dehumidifying mode and closed in the humidifying mode as will be described later. The second electromagnetic valve 15 is provided between the second heat exchanger 5 and the fourth heat exchanger 7 and is controlled to be closed in the dehumidifying mode and to be opened in the humidifying mode as will be described later.

  The first check valve 16 is provided between the first heat exchanger 4 and the third heat exchanger 6 and allows the refrigerant to flow from the third heat exchanger 6 to the first heat exchanger 4 side. Act to block the opposite flow. The second check valve 17 is provided between the second heat exchanger 5 and the fourth heat exchanger 7 and allows the refrigerant to flow from the fourth heat exchanger 7 to the second heat exchanger 5 side. Act to block the opposite flow.

  The first expansion valve 18 is provided between the first heat exchanger 4 and the second heat exchanger 5 and controls the flow rate while reducing the pressure of the refrigerant flowing between the first and second heat exchangers 4 and 5. To do. The 2nd expansion valve 19 is provided between the 3rd heat exchanger 6 and the 4th heat exchanger 7, and is the 1st heat exchanger 4 to the 4th heat exchanger 7, or the 2nd heat exchanger. The flow rate of the refrigerant is controlled while lowering the pressure of the refrigerant flowing from 5 to the third heat exchanger 6. In addition, the flow of the refrigerant | coolant of the 1st expansion valve 18 and the 2nd expansion valve 19 shall be controllable in any direction.

  Furthermore, a first air temperature sensor 23 that measures the air temperature on the outlet side of the first heat exchanger 4, a second air temperature sensor 24 that measures the air temperature on the outlet side of the second heat exchanger 5, and a first A first refrigerant temperature sensor 25 that measures the refrigerant temperature on one end side of the heat exchanger 4 and a second refrigerant temperature sensor 26 that measures the refrigerant temperature on one end side of the second heat exchanger 5 are provided. Also, a first dew point temperature sensor 21 that measures the dew point temperature of the air on the inlet side of the first heat exchanger 4 and a second dew point temperature sensor 22 that measures the dew point temperature of the air on the inlet side of the second heat exchanger 5. And a suction refrigerant temperature sensor 20 for measuring the refrigerant temperature on the inlet side of the accumulator 2.

  Furthermore, the detection signal of each sensor mentioned above is acquired, and based on the acquired detection signal, the compressor 1, the four-way valve 3, the first electromagnetic valve 14, the second electromagnetic valve 15, the first expansion valve 18, and the second expansion valve. A main control unit 31 (control means) for controlling the valve 19 is provided. The main control unit 31 also controls the operations of the EA fan 9, the SA fan 10, and the desiccant 8 driving rotary motor 8a shown in FIG.

  Here, the main control unit 31 can be configured as an integrated computer including a central processing unit (CPU) and storage means such as a RAM, a ROM, and a hard disk.

  FIG. 3 is a block diagram showing a detailed configuration of the main control unit 31. As shown in FIG. 3, the main control unit 31 includes a sensor input unit 31a for inputting detection signals of various sensors, an EA fan 9, an SA fan 10, a rotary motor 8a, a four-way valve 3, a first electromagnetic valve 14, and Openings of the first operation part 31b for controlling the second electromagnetic valve 15, the compressor output part 31c for controlling the inverter 27 for driving the compressor 1, the first expansion valve 18 and the second expansion valve 19 A second operation unit 31d for adjusting the angle.

  Next, with reference to FIG. 4 and FIG. 5, the flow of the refrigerant in the dehumidifying mode and in the humidifying mode will be described in detail. FIG. 4 is a flowchart showing the refrigerant flow in the dehumidifying mode. In the dehumidifying mode, the four-way valve 3 is switched as shown in FIG. That is, the refrigerant output from the compressor 1 is introduced into the first heat exchanger 4 that functions as a condenser, and the refrigerant output from the first heat exchanger 4 is further branched into two systems.

  Of these, the refrigerant flowing to the first branch side is introduced into the second heat exchanger 5 functioning as an evaporator via the first expansion valve 18. Then, the refrigerant output from the second heat exchanger 5 is returned to the accumulator 2 via the four-way valve 3. Here, since the second electromagnetic valve 15 is closed and the second check valve 17 is provided, the refrigerant that has passed through the first expansion valve 18 is introduced to the fourth heat exchanger 7 side. Without being returned to the accumulator 2.

  On the other hand, the refrigerant flowing to the second branch side is supplied to the fourth heat exchanger 7 functioning as an evaporator via the first electromagnetic valve 14 and the second expansion valve 19, and further, the fourth heat The refrigerant output from the exchanger 7 is returned to the accumulator 2 via the second check valve 17 and the four-way valve 3. Furthermore, a part of the refrigerant that has passed through the first electromagnetic valve 14 is accumulated in the third heat exchanger 6. That is, the third heat exchanger 6 whose function as a heat exchanger is stopped functions as a liquid receiver that accumulates refrigerant. At this time, the piping from the compressor 1 through the first heat exchanger 4 to the upstream of the first expansion valve 18 and the second expansion valve 19 becomes a high-pressure refrigerant circuit, and the first expansion valve 18 and the second expansion valve 19 The piping from the downstream to the compressor 1 is a low-pressure refrigerant circuit.

  Describing the above flow in more detail, in the dehumidifying mode, the compressed refrigerant output from the compressor 1 is high-temperature and high-pressure, so that it is introduced into the first heat exchanger 4 acting as a condenser. The heat exchange with the air introduced into the second air flow path 13 is performed. Therefore, the temperature of the air flowing through the second air flow path 13 rises and the refrigerant condenses. And a part of refrigerant | coolant output from the 1st heat exchanger 4 is decompressed and expanded by passing the 1st expansion valve 18, and temperature falls. The refrigerant whose temperature has been reduced is introduced into the second heat exchanger 5 to reduce the temperature of the air passing through the first air flow path 12 with evaporation (the temperature of the air before passing through the desiccant 8). 3 is returned to the accumulator 2.

  On the other hand, the remainder of the refrigerant output from the first heat exchanger 4 is decompressed and expanded by passing through the second expansion valve 19, and the temperature decreases. The refrigerant whose temperature has been lowered is introduced into the fourth heat exchanger 7 to reduce the temperature of the air passing through the first air flow path 12 with evaporation (the temperature of the air after passing through the desiccant 8). 3 is returned to the accumulator 2. Thus, since the temperature of the air flowing through the first air flow path 12 can be lowered, the cooled and dehumidified air can be supplied into the room. Here, in this embodiment, the output of the compressor 1 is controlled so that the air temperature that has passed through the first heat exchanger 4 becomes a preset predetermined temperature, and the air that passes through the second heat exchanger 5. The degree of opening of the first expansion valve 18 and the second expansion valve 19 is controlled so as to prevent condensation. A detailed control method will be described later.

  Next, with reference to FIG. 5, the flow of the refrigerant in the humidification mode will be described. In the humidification mode, the four-way valve 3 is switched as shown in FIG. That is, the refrigerant output from the compressor 1 is introduced into the second heat exchanger 5 functioning as a condenser, and the refrigerant output from the second heat exchanger 5 is branched into two systems.

  Of these, the refrigerant flowing to the first branch side is introduced into the first heat exchanger 4 functioning as an evaporator via the first expansion valve 18. The refrigerant output from the first heat exchanger 4 is returned to the accumulator 2 via the four-way valve 3. Here, since the first electromagnetic valve 14 is closed and the first check valve 16 is provided, the refrigerant that has passed through the first expansion valve 18 is introduced to the third heat exchanger 6 side. Without being returned to the accumulator 2.

  On the other hand, the refrigerant flowing to the second branch side is supplied to the third heat exchanger 6 functioning as an evaporator via the second electromagnetic valve 15 and the second expansion valve 19, and further to the third heat exchange. The refrigerant output from the vessel 6 is returned to the accumulator 2 via the first check valve 16 and the four-way valve 3. Further, a part of the refrigerant that has passed through the second electromagnetic valve 15 is accumulated in the fourth heat exchanger 7. That is, the 4th heat exchanger 7 in which the function as a heat exchanger is stopped functions as a liquid receiver which accumulates refrigerant. At this time, the piping from the compressor 1 through the second heat exchanger 5 to the upstream of the first expansion valve 18 and the second expansion valve 19 becomes a high-pressure refrigerant circuit, and the first expansion valve 18 and the second expansion valve 19 The piping from the downstream to the compressor 1 is a low-pressure refrigerant circuit.

  Describing the above flow in more detail, in the humidification mode, the compressed refrigerant output from the compressor 1 is at high temperature and high pressure, so that it is introduced into the second heat exchanger 5 acting as a condenser. The heat exchange with the air introduced into the first air flow path 12 is performed. Therefore, the temperature of the air flowing through the first air flow path 12 rises and the refrigerant condenses. And a part of refrigerant | coolant output from the 2nd heat exchanger 5 is pressure-reduced and expanded by passing the 1st expansion valve 18, and temperature falls. The refrigerant whose temperature has been reduced is introduced into the first heat exchanger 4 to reduce the temperature of the air passing through the second air flow path 13 with evaporation (the temperature of the air before passing through the desiccant 8). 3 is returned to the accumulator 2.

  On the other hand, the remainder of the refrigerant output from the second heat exchanger 5 is decompressed and expanded by passing through the second expansion valve 19, and the temperature decreases. The refrigerant whose temperature has been lowered is introduced into the third heat exchanger 6 to reduce the temperature of the air passing through the second air flow path 13 with evaporation (the temperature of the air after passing through the desiccant 8). 3 is returned to the accumulator 2. In this way, the temperature of the air flowing through the first air flow path 12 can be raised, so that heated and humidified air can be supplied indoors. Here, in this embodiment, the output of the compressor 1 is controlled so that the air temperature that has passed through the second heat exchanger 5 becomes a preset temperature, and the air that has passed through the first heat exchanger 4. The degree of opening of the first expansion valve 18 and the second expansion valve 19 is controlled so as to prevent condensation. A detailed control method will be described later.

  Next, specific control of the opening degree of the first expansion valve 18 and the second expansion valve 19 and the switching procedure of the four-way valve 3, the first electromagnetic valve 14, and the second electromagnetic valve 15 will be described in detail. FIG. 6 is a diagram illustrating the operation of the four-way valve 3 and the first and second electromagnetic valves 14 and 15 in the dehumidifying mode and the humidifying mode, and data detection by each sensor.

  As shown in FIG. 6 (a), in the dehumidifying mode, the four-way valve 3 connects the discharge side to the first heat exchanger 4 and the suction side to the second and fourth heat exchangers 5 and 7 side. Connecting. That is, it connects like the four-way valve 3 shown in FIG. Further, the first electromagnetic valve 14 is opened and the second electromagnetic valve 15 is closed. On the other hand, in the humidification mode, the four-way valve 3 connects the discharge side to the second heat exchanger 5 and connects the suction side to the first and third heat exchangers 4 and 6 side. That is, it connects like the four-way valve 3 shown in FIG. Further, the first electromagnetic valve 14 is closed and the second electromagnetic valve 15 is opened.

  Further, as shown in FIG. 6B, in the dehumidifying mode, the first air temperature TA1t detected by the first air temperature sensor 23 is acquired for the output control of the compressor 1, and the total expansion is obtained. In order to control the valve opening, the suction refrigerant temperature TRSt detected by the suction refrigerant temperature sensor 20 and the second refrigerant temperature TR2t detected by the second refrigerant temperature sensor 26 are acquired. Further, a second air temperature TA2t detected by the second air temperature sensor 24 and a second dew point temperature TW2t detected by the second dew point temperature sensor 22 are acquired for controlling the deviation expansion valve opening. The “total expansion valve opening” is the total opening of the first expansion valve 18 and the second expansion valve 19, and the “deviation expansion valve opening” is determined from the opening of the first expansion valve 18. The difference opening degree which reduced the opening degree of the 2nd expansion valve 19 is shown.

  Further, in the humidification mode, the second air temperature TA2t detected by the second air temperature sensor 24 is acquired for the output control of the compressor 1, and the suction is performed for the control of the total expansion valve opening degree. The suction refrigerant temperature TRSt detected by the refrigerant temperature sensor 20 and the first refrigerant temperature TR1t detected by the first refrigerant temperature sensor 25 are acquired. Further, a first air temperature TA1t detected by the first air temperature sensor 23 and a first dew point temperature TW1t detected by the first dew point temperature sensor 21 are acquired for controlling the deviation expansion valve opening degree.

  Next, a processing procedure of the outside air processing apparatus 100 according to the first embodiment will be described with reference to a flowchart shown in FIG. First, in step S11, the main control unit 31 activates the EA fan 9 and the SA fan 10. At this time, since the EA fan 9 and the SA fan 10 blow with substantially the same output, almost the same amount of air flows through the first air flow path 12 and the second air flow path 13. Further, the compressor 1 is started at the initial rotational speed R. Moreover, the rotation motor 8a for rotating the desiccant 8 is started. Further, the opening degree of the first expansion valve 18 is set to V1t, the opening degree of the second expansion valve 19 is set to V2t, and the total opening degree (total expansion valve opening degree) of the first expansion valve 18 and the second expansion valve 19 is set. VSt. That is, it is expressed by the following equation (1).

VSt = V1t + V2t (1)
Further, a difference opening degree (deviation expansion valve opening degree) between the first expansion valve 18 and the second expansion valve 19 is defined as VDt. That is, it is expressed by the following equation (2).

VDt = V1t-V2t (2)
In step S <b> 12, the main control unit 31 determines whether or not an operation switch (not shown) for starting the outside air processing device 100 is turned on.

  If the operation switch is turned on (ON in step S12), the main control unit 31 acquires detection signals of various sensors in step S13. That is, the first air temperature TA1t detected by the first air temperature sensor 23, the second air temperature TA2t detected by the second air temperature sensor 24, the first dew point temperature TW1t detected by the first dew point temperature sensor 21, A second dew point temperature TW2t detected by the second dew point temperature sensor 22, a first refrigerant temperature TR1t detected by the first refrigerant temperature sensor 25, a second refrigerant temperature TR2t detected by the second refrigerant temperature sensor 26, and Each detection signal of the suction refrigerant temperature TRSt detected by the suction refrigerant temperature sensor 20 is acquired.

  In step S14, the main control unit 31 determines which one of the dehumidification mode and the humidification mode is selected by the operator. This operation is selected by a selector switch (not shown). When the dehumidifying mode is selected, the process proceeds to step S16, and when the humidifying mode is selected, the process proceeds to step S19.

  When the dehumidifying mode is selected, in step S16, the main control unit 31 connects the discharge side of the four-way valve 3 to the first heat exchanger 4 side and the suction side to the second and fourth heat exchangers 5. , 7 to control the connection. Further, the first electromagnetic valve 14 is opened and the second electromagnetic valve 15 is closed.

  Thereafter, in step S17, the main control unit 31 controls the compressor 1 in the dehumidification mode, and in step S18, the main control unit 31 controls the first and second expansion valves 18, 19 in the dehumidification mode. Control the opening. Detailed control of steps S17 and S18 will be described later. When the process of step S18 is completed, the process returns to step S12.

  On the other hand, when the humidification mode is selected in step S14, in step S19, the main control unit 31 connects the discharge side of the four-way valve 3 to the second heat exchanger 5 side, and the suction side is the first, first, It controls so that it may connect with the 3rd heat exchanger 4 and 6 side. Further, the first electromagnetic valve 14 is closed and the second electromagnetic valve 15 is opened.

  Thereafter, in step S20, the main control unit 31 controls the compressor 1 in the humidification mode. Further, in step S21, the main control unit 31 controls the first and second expansion valves 18, 19 in the humidification mode. Control the opening. Detailed control of steps S20 and S21 will be described later. When the process of step S21 is completed, the process returns to step S12.

  Thereafter, when the operation switch is turned off in the process of step S12 (OFF in step S12), in step S15, the main control unit 31 determines that the EA fan 9, the SA fan 10, the rotary motor 8a, and the compressor 1 is stopped.

  Next, a processing procedure for controlling the compressor 1 in the dehumidifying mode shown in step S17 of FIG. 7 will be described with reference to a flowchart shown in FIG. First, in step S31, the main control unit 31 preliminarily determines the air temperature of the second air flow path 13 (temperature on the output side of the first heat exchanger 4; TA1t) measured by the first air temperature sensor 23, The set default value (Tdh) is compared.

  If Tdh> TA1t, in step S32, the main control unit 31 increases the output of the inverter 1 by increasing the output of the inverter 27. That is, the output R of the compressor 1 is set to R + ΔR. As a result, the temperature of the refrigerant output from the compressor 1 rises, so that the air temperature TA1t flowing through the second air flow path 13 can be raised, and as a result, the temperature TA1t can be brought close to the predetermined value Tdh.

  On the other hand, if Tdh <TA1t, in step S33, the main control unit 31 decreases the output of the compressor 1 by decreasing the output of the inverter 27. That is, the output R of the compressor 1 is set to R−ΔR. Thereby, since the temperature of the refrigerant | coolant output from the compressor 1 falls, the air temperature TA1t which flows through the 2nd air flow path 13 can be lowered | hung, and this temperature TA1t can be closely approached default value Tdh by extension.

  Thus, in the process of step S17 shown in FIG. 7, the first heat exchanger 4 is controlled by controlling the output of the compressor 1 according to the temperature TA1t of the air that has passed through the first heat exchanger 4. The temperature of the passed air can be maintained at a constant temperature (predetermined value Tdh). For this reason, the temperature of the air entering the regeneration side of the desiccant 8 shown in FIG. 1A can be maintained at a constant temperature.

  Next, the processing procedure of the expansion valve control in the dehumidifying mode shown in step S18 of FIG. 7 will be described with reference to the flowchart shown in FIG. First, in step S51, the main control unit 31 determines the temperature difference between the suction refrigerant temperature TRSt measured by the suction refrigerant temperature sensor 20 and the second refrigerant temperature TR2t measured by the second refrigerant temperature sensor 26 (this is calculated as follows). , Current superheat degree TSHdt). That is, the current superheat degree TSHdt indicates the temperature difference between the inlet and outlet of the refrigerant passing through the second heat exchanger 5. That is, this is the degree of superheat of the second heat exchanger 5.

  Next, in step S52, the main control unit 31 determines the total expansion valve opening degree VSt so that the current superheat degree TSHdt obtained in step S51 becomes the preset target superheat degree TSH. As the determination method, for example, a well-known control method such as PID control can be adopted. Here, the total expansion valve opening VSt is the total opening of the opening V1t of the first expansion valve 18 and the opening V2t of the second expansion valve 19. That is, “VSt = V1t + V2t” (1).

  Here, the second heat exchanger 5 and the fourth heat exchanger 7 belong to the low pressure side of the refrigerant circuit in the dehumidifying mode, and the refrigerant pressure is substantially the same. Accordingly, the refrigerant temperature at the inlet of the second heat exchanger 5 and the refrigerant temperature at the inlet of the fourth heat exchanger 7 are substantially the same. That is, the current superheat degree TSHdt represents the superheat degree of the entire refrigerant circuit, and the load change of the first air passage 12 is controlled by controlling the current superheat degree TSHdt to be the target superheat degree TSH. The refrigerant circuit can be stably operated against (changes in temperature and humidity).

  Next, in step S53, the main control unit 31 calculates the difference between these values as the current condensation degree TWdt (= TA2t−TW2t) based on the second air temperature TA2t and the second dew point temperature TW2t.

  In step S54, the main control unit 31 compares the current condensation degree TWdt with the preset first target condensation degree TW1 and second target condensation degree TW2. However, 0 <TW1 <TW2. If TWdt <TW1, the process proceeds to step S55. If TWdt> TW2, the process proceeds to step S56. If TW1 <TWdt <TW2, the process proceeds to step S57. Proceed.

  Here, the second air temperature TA2t is the temperature of the air output from the second heat exchanger 5, and the second dew point temperature TW2t is the dew point temperature of the air entering the second heat exchanger 5, so 2 When the air temperature TA2t is lowered to the second dew point temperature TW2t (TA2t = TW2t, TWdt = 0), condensation occurs in the second heat exchanger 5. Therefore, the opening degree of the first and second expansion valves 18 and 19 is controlled so as to avoid the occurrence of dew condensation and to achieve an air temperature with a sufficient margin. In the present embodiment, the first target condensation degree TW1 (> 0) and the second target condensation degree TW2 (> TW1) are set in advance, and the deviation expansion valve is set so that the current condensation degree TWdt is a value between them. Set the opening VDt.

  Therefore, in step S55, the main control unit 31 decreases the deviation expansion valve opening VDt. That is, VDt is set to “VDt−ΔV”. In step S56, the main controller 31 increases the deviation expansion valve opening VDt. That is, VDt is set to “VDt + ΔV”. At this time, as the control method, for example, a known control method such as step control can be used.

  In step S57, the main control unit 31 uses the total expansion valve opening VSt obtained in the process of step S52 and the deviation expansion valve opening VDt obtained in the processes of steps S54 to S56. ) To calculate the first expansion valve opening V1t and the second expansion valve opening V2t.

  In step S58, the main control unit 31 controls the opening degrees of the first expansion valve 18 and the second expansion valve 19 so as to obtain the opening degrees obtained in the process of step S57. Thus, by controlling the opening degree of the first expansion valve 18 and the second expansion valve 19, the temperature of the air that has passed through the first heat exchanger 4 is maintained at a predetermined value in the dehumidifying mode, and the second It is possible to prevent the air passing through the heat exchanger 5 from being lowered to the dew point temperature, thereby preventing the occurrence of condensation in the second heat exchanger 5. Furthermore, the cooled and dehumidified air can be supplied indoors.

  Next, the control procedure of the compressor 1 in the humidification mode shown in step S20 of FIG. 7 will be described with reference to the flowchart shown in FIG. First, in step S71, the main control unit 31 preliminarily determines the air temperature of the first air flow path 12 (temperature on the output side of the second heat exchanger 5; TA2t) measured by the second air temperature sensor 24, The set default value (Tah) is compared.

  If Tah> TA2t, in step S72, the main control unit 31 increases the output of the compressor 1 by increasing the output of the inverter 27. That is, the output R of the compressor 1 is set to R + ΔR. As a result, the temperature of the refrigerant output from the compressor 1 rises, so that the air temperature TA2t flowing through the first air passage 12 can be raised, and this temperature TA2 can be brought close to the predetermined value Tah.

  On the other hand, if Tah <TA2t, in step S73, the main control unit 31 decreases the output of the compressor 1 by decreasing the output of the inverter 27. That is, the output R of the compressor 1 is set to R−ΔR. As a result, the temperature of the refrigerant output from the compressor 1 is lowered, so that the air temperature TA2t flowing through the second air flow path 13 can be lowered, and as a result, the air temperature TA2t can be brought close to the predetermined value Tah. .

  Thus, in the process of step S20 shown in FIG. 7, the second heat exchanger 5 is controlled by controlling the output of the compressor 1 in accordance with the temperature TA2t of the air that has passed through the second heat exchanger 5. The temperature of the passed air can be maintained at a constant temperature (predetermined value Tah). For this reason, the temperature of the air entering the regeneration side of the desiccant 8 shown in FIG. 1B can be maintained at a constant temperature.

  Next, the procedure of the expansion valve control in the humidification mode shown in step S21 of FIG. 7 will be described with reference to the flowchart shown in FIG. First, in step S91, the main control unit 31 determines the temperature difference between the suction refrigerant temperature TRSt measured by the suction refrigerant temperature sensor 20 and the first refrigerant temperature TR1t measured by the first refrigerant temperature sensor 25 (this). , Current superheat degree TSHat). That is, the current superheat degree TSHat indicates a temperature difference between the inlet and the outlet of the refrigerant passing through the first heat exchanger 4. That is, this is the degree of superheat of the first heat exchanger 4.

  Next, in step S92, the main control unit 31 determines the total expansion valve opening VSt so that the current superheat degree TSHat obtained in step S91 becomes the preset target superheat degree TSH. As the determination method, for example, a well-known control method such as PID control can be adopted. Here, the total expansion valve opening VSt is the total opening of the opening V1t of the first expansion valve 18 and the opening V2t of the second expansion valve 19. That is, “VSt = V1t + V2t” (1).

  Here, the 1st heat exchanger 4 and the 3rd heat exchanger 6 belong to the low voltage | pressure side of a refrigerant circuit at the time of this humidification mode, and a refrigerant | coolant pressure is substantially the same. Accordingly, the refrigerant temperature at the inlet of the first heat exchanger 4 and the refrigerant temperature at the inlet of the third heat exchanger 6 are substantially the same. That is, the current superheat degree TSHat represents the superheat degree of the entire refrigerant circuit, and the load change of the second air flow path 13 is controlled by controlling the current superheat degree TSHat to be the target superheat degree TSH. The refrigerant circuit can be stably operated against (changes in temperature and humidity).

  Next, in step S93, the main control unit 31 calculates the difference between these values as the current dew degree TWat (= TA1t−TW1t) based on the first air temperature TA1t and the first dew point temperature TW1t.

  In step S94, the current condensation degree TWat is compared with the first target condensation degree TW1 and the second target condensation degree TW2. However, 0 <TW1 <TW2. If TWat <TW1, the process proceeds to step S95. If TWat> TW2, the process proceeds to step S96. If TW1 <TWat <TW2, the process proceeds to step S97. Proceed.

  Here, the first air temperature TA1t is the temperature of the air output from the first heat exchanger 4, and the first dew point temperature TW1t is the dew point temperature of the air entering the first heat exchanger 4, so When the 1 air temperature TA1t decreases to the first dew point temperature TW1t (TA1t = TW1t, TWat = 0), dew condensation occurs in the first heat exchanger 4. Therefore, the opening degree of the first and second expansion valves 18 and 19 is controlled so as to avoid the occurrence of dew condensation and to achieve an air temperature with a sufficient margin. In this embodiment, the first target condensation degree TW1 (> 0) and the second target condensation degree TW2 (> TW1) are set in advance, and the deviation expansion valve is set so that the current condensation degree TWat is a numerical value between them. Set the opening VDt.

  Accordingly, in step S95, the main control unit 31 decreases the deviation expansion valve opening VDt. That is, VDt is set to “VDt−ΔV”. In step S96, the main control unit 31 increases the deviation expansion valve opening VDt. That is, VDt is set to “VDt + ΔV”. At this time, as the control method, for example, a known control method such as step control can be used.

  In step S97, the main control unit 31 uses the total expansion valve opening degree VSt obtained in the process of step S92 and the deviation expansion valve opening degree VDt obtained in the processes of steps S94 to S96 to calculate the expressions (1) and ( 2), the first expansion valve opening V1t and the second expansion valve opening V2t are calculated.

  In step S98, the main control unit 31 controls the opening degrees of the first expansion valve 18 and the second expansion valve 19 so that the opening degrees obtained in the process of step S97 are obtained. Thus, by controlling the opening degree of the first expansion valve 18 and the second expansion valve 19, the air temperature that has passed through the second heat exchanger 5 is maintained at a predetermined value in the humidification mode, and the first It is possible to prevent the air passing through the heat exchanger 4 from being lowered to the dew point temperature, and to prevent the occurrence of condensation in the first heat exchanger 4. Furthermore, air that has been heated and humidified can be supplied indoors.

  Thus, in the outside air processing apparatus 100 according to the first embodiment, the heat exchanger functions as an evaporator (the second heat exchanger 5 in the dehumidifying mode and the first heat exchanger 4 in the humidifying mode). The superheat degree of the refrigerant to be obtained is obtained, and the total expansion valve opening VSt of the first expansion valve 18 and the second expansion valve 19 is set so that the current superheat degree becomes the target superheat degree.

  Further, based on the temperature of the air passing through the evaporator and the dew point temperature, a deviation between the opening degree of the first expansion valve 18 and the opening degree of the second expansion valve 19 so that the degree of condensation is within a predetermined range. Determine the expansion valve opening VDt. Based on the total expansion valve opening degree VSt and the deviation expansion valve opening degree VDt, the opening degree of the first expansion valve 18 and the opening degree of the second expansion valve 19 are calculated so as to be the opening degree. The opening degree of the first expansion valve 18 and the second expansion valve 19 is controlled.

  Therefore, in the dehumidifying mode, control is performed so that the temperature of the air passing through the second heat exchanger 5 does not decrease to the dew point (so as not to reach the dew point), so that condensation occurs in the second heat exchanger 5. This can prevent the occurrence of drainage. Similarly, in the humidification mode, the temperature of the air passing through the first heat exchanger 4 is controlled so as not to decrease to the dew point, so that condensation can be prevented from occurring in the first heat exchanger 4 and drainage is generated. You can avoid that.

  Thereby, it is not necessary to provide a drain pan in the apparatus, the apparatus configuration can be simplified, and a reduction in size and weight can be achieved. Furthermore, since drain piping is not required, piping work is not required, and costs can be reduced.

  Further, in the dehumidifying mode, the air temperature passing through the second heat exchanger 5 is controlled to cool to just before the dew point, and in the humidifying mode, the air temperature passing through the first heat exchanger 4 is cooled to just before the dew point. Therefore, the temperature of the air entering the dehumidifying side of the desiccant 8 downstream of each heat exchanger can be lowered to a temperature that does not condense, and the moisture adsorbing ability of the desiccant 8 is improved, so that the dehumidifying ability is improved in the dehumidifying mode. In the humidification mode, the humidification ability is improved.

  In addition, since one of the four heat exchangers is stopped, the stopped heat exchanger can be used as a liquid receiver for accumulating the refrigerant. Specifically, in the dehumidifying mode, as shown in FIG. 4, the third heat exchanger 6 is stopped, so that the third heat exchanger 6 can be used as a liquid receiver. On the other hand, in the humidification mode, as shown in FIG. 5, the fourth heat exchanger 7 can be used as a liquid receiver. For example, when the load on the refrigerant circuit is light and the operation is performed with the output of the compressor 1 lowered to a low level, liquid refrigerant accumulates in the heat exchanger acting as a condenser, and the high pressure side pressure of the refrigerant circuit increases. Can be prevented. Furthermore, it is not necessary to provide a separate liquid receiver, and the apparatus configuration can be further simplified and the cost can be reduced.

  Further, the output of the compressor 1 so that the outlet temperature of the air of the heat exchanger functioning as a condenser (the first heat exchanger 4 in the dehumidifying mode and the second heat exchanger 5 in the humidifying mode) becomes a predetermined temperature. Therefore, the regeneration air temperature on the moisture release side of the desiccant 8 (moisture adsorption means) is stabilized, the moisture adsorption ability is also stabilized, and the dehumidification ability can be enhanced.

  In the present embodiment, the first expansion valve opening V1t and the second expansion valve opening V2t are calculated by assuming that the first expansion valve 18 and the second expansion valve 19 are equivalent. The heat exchangers 4 and 5 and the third and fourth heat exchangers 6 and 7 are not limited to equivalent heat exchangers. If they have different capacities, the first expansion valve 18 and the second expansion valve 19 are used. This can be done by multiplying the calculated expansion valve opening by a coefficient for correcting the capacity.

[Description of Second Embodiment]
Next, a second embodiment of the present invention will be described. FIG. 12 is a flowchart showing the configuration of the outside air processing apparatus according to the second embodiment. As illustrated, the outside air processing apparatus 101 according to the second embodiment includes a first heat exchanger 4, a second heat exchanger 5, and a fourth heat exchanger 7. And in 1st Embodiment mentioned above, while providing the function of both dehumidification and humidification, the external air processing apparatus 101 which concerns on 2nd Embodiment differs in the point provided with the function only of dehumidification. . Details will be described below.

  First, the flow of air will be described. An outside air processing device 101 shown in FIG. 12 includes a desiccant 8 disposed across the first air flow path 12 and the second air flow path 13. And the air which flows through the 2nd air flow path 13 passes the 1st heat exchanger 4 which functions as a condenser, passes the reproduction | regeneration side of the desiccant 8, and is discharged | emitted outside the room. Further, the air flowing through the first air flow path 12 passes through the dehumidifying side of the desiccant 8 after passing through the second heat exchanger 5 that functions as an evaporator, and further, a fourth heat exchanger that functions as an evaporator. 7 is supplied to the room. A liquid receiver 41 for accumulating the refrigerant is provided on the outlet side of the first heat exchanger 4.

  The first expansion valve 18 provided between the first heat exchanger 4 and the second heat exchanger, and the second expansion valve provided between the liquid receiver 41 and the fourth heat exchanger 7. 19 is provided. Furthermore, a first air temperature sensor 23 that measures the temperature of the air that has passed through the first heat exchanger 4, a second dew point temperature sensor 22 that measures the dew point temperature of the air entering the second heat exchanger 5, and a second And a second air temperature sensor 24 for measuring the temperature of the air output from the heat exchanger 5.

  Further, a second refrigerant temperature sensor 26 that measures the temperature of the refrigerant supplied to the second heat exchanger 5, a suction refrigerant temperature sensor 20 that measures the temperature of the refrigerant returned to the accumulator 2, and a main control unit 31 are provided. ing.

  And the external air processing apparatus 101 which concerns on 2nd Embodiment operate | moves similarly to the operation | movement of the dehumidification mode of the external air processing apparatus 100 shown in the above-mentioned 1st Embodiment, and supplies the dehumidified air indoors. That is, as shown in FIG. 12, the compressed refrigerant output from the compressor 1 is supplied to the first heat exchanger 4, and the refrigerant that has passed through the second heat exchanger 5 and the fourth heat exchanger 7 is the accumulator. Therefore, the connection state of the four-way valve in the “dehumidification mode” shown in FIG. 6A is the same. That is, this is equivalent to a state in which the discharge side of the compressor 1 is connected to the first heat exchanger and the suction side is connected to the second and fourth heat exchangers 5 and 7.

  Further, when compared with FIG. 4 showing the flow in the dehumidifying mode of the first embodiment, since the portion of the first electromagnetic valve 14 shown in FIG. 4 is connected, it is equivalent to the open state, and the second Since the part of the solenoid valve 15 is blocked, it is equivalent to the closed state. Furthermore, various temperature data used in the dehumidifying mode shown in FIG. 6B can be acquired. That is, the first air temperature TA1t can be obtained from the measurement result of the first air temperature sensor 23, the suction refrigerant temperature TRSt can be obtained from the measurement result of the suction refrigerant temperature sensor 20, and the second refrigerant temperature TR2t can be obtained from the second refrigerant temperature. The second air temperature TA2t can be obtained from the measurement result of the second air temperature sensor 24, and the second dew point temperature TW2t can be obtained from the measurement result of the second dew point temperature sensor 22. can do.

  Therefore, the cooled and dehumidified air can be supplied into the room by the same processing procedure as that shown in FIGS.

  In this way, in the outside air processing apparatus 101 according to the second embodiment, as in the dehumidification mode of the first embodiment described above, it is possible to prevent condensation from occurring in the second heat exchanger 5, so that the drain pan Drain measures such as installation and drain piping can be eliminated. For this reason, the scale of the apparatus can be reduced, and the cost can be reduced. In addition, since the configuration can be simplified as compared with the outside air processing apparatus 101 shown in the first embodiment, it is extremely useful when supplying cooled and dehumidified air to a room that requires only dehumidifying operation.

  As mentioned above, although the outside air processing apparatus of this invention was demonstrated based on embodiment of illustration, this invention is not limited to this, The structure of each part is replaced with the thing of the arbitrary structures which have the same function. Can do.

  The present invention can be used to prevent the occurrence of condensation in the outside air processing apparatus.

DESCRIPTION OF SYMBOLS 1 Compressor 2 Accumulator 3 Four-way valve 4 1st heat exchanger 5 2nd heat exchanger 6 3rd heat exchanger 7 4th heat exchanger 8 Desiccant 8a Rotating motor 9 EA fan 10 SA fan 11 Total heat exchanger 12 1st DESCRIPTION OF SYMBOLS 1 Air flow path 13 2nd air flow path 14 1st solenoid valve 15 2nd solenoid valve 16 1st check valve 17 2nd check valve 18 1st expansion valve 19 2nd expansion valve 20 Suction refrigerant temperature sensor 21 1st Dew point temperature sensor 22 2nd dew point temperature sensor 23 1st air temperature sensor 24 2nd air temperature sensor 25 1st refrigerant temperature sensor 26 2nd refrigerant temperature sensor 27 Inverter 31 Main control part 31a Sensor input part 31b 1st operation part 31c Compression Machine output unit 31d Second operation unit 41 Liquid receiver 100, 101 Outside air processing device

Claims (4)

In the outside air processing apparatus that supplies the dehumidified air or humidified air by processing the outside air into the room of the target room,
A first air flow path serving as an air flow path from the outdoor to the indoor;
A second air flow path serving as a flow path of air from the room toward the outside;
It is disposed across the first air flow path and the second air flow path, adsorbs moisture of the air flowing through one of the first air flow path and the second air flow path, and the other flow Moisture adsorption means for releasing moisture into the air flowing through the road;
A refrigerant circuit for circulating the refrigerant,
The refrigerant circuit is
A compressor for compressing the refrigerant;
A first heat exchanger disposed upstream of the moisture adsorbing means in the second air flow path, and a third heat exchanger disposed downstream.
A second heat exchanger disposed upstream of the moisture adsorbing means in the first air flow path, and a fourth heat exchanger disposed downstream.
In the dehumidifying mode for supplying dehumidified air to the room, the refrigerant output from the compressor is supplied to the first heat exchanger, and in the humidifying mode for supplying humidified air to the room, the refrigerant is output from the compressor. Output switching means for switching to supply refrigerant to the second heat exchanger;
A first expansion valve provided between the first heat exchanger and the second heat exchanger; and a second expansion valve provided between the third heat exchanger and the fourth heat exchanger;
Control means for controlling the opening degree of the first expansion valve and the second expansion valve, and for controlling the output switching means,
Furthermore, the control means includes
During dehumidification mode,
The refrigerant output from the compressor is routed from the output side of the first heat exchanger through the first expansion valve and the second heat exchanger, and the second expansion valve and the fourth heat exchange. A total expansion valve having a total opening of the first expansion valve and the second expansion valve based on the degree of superheat of the refrigerant circuit. Based on the temperature of the air passing through the second heat exchanger and the dew point temperature, the first expansion valve and the first expansion valve are arranged so that the temperature of the air passing through the second heat exchanger does not reach the dew point. The difference expansion valve opening, which is the difference opening between the two expansion valves, is obtained, and further, based on the total expansion valve opening and the deviation expansion valve opening, the opening of the first expansion valve, and the second Calculate the opening of the expansion valve,
During humidification mode,
The refrigerant output from the compressor is routed from the output side of the second heat exchanger through the first expansion valve and the first heat exchanger, and the second expansion valve and the third heat exchange. The temperature of the air passing through the first heat exchanger is determined by setting the flow path of the refrigerant so as to circulate the path passing through the cooler, and obtaining the total expansion valve opening based on the degree of superheat of the refrigerant circuit. Based on the dew point temperature, the deviation expansion valve opening is obtained so that the temperature of the air passing through the first heat exchanger does not reach the dew point, and further, the total expansion valve opening and the deviation expansion valve opening And calculating the opening of the first expansion valve and the opening of the second expansion valve,
An outside air processing apparatus , wherein the opening degrees of the first expansion valve and the second expansion valve are adjusted so as to be the calculated opening degrees of the first expansion valve and the second expansion valve . The control means includes
In the dehumidifying mode, the output of the compressor is set so that the temperature of the air that has passed through the first heat exchanger becomes a preset predetermined temperature,
2. The outside air processing device according to claim 1 , wherein the output of the compressor is set so that the temperature of the air that has passed through the second heat exchanger becomes a predetermined temperature set in advance in the humidification mode . In the outside air processing apparatus that supplies the dehumidified air or humidified air by processing the outside air into the room of the target room,
A first air flow path serving as an air flow path from the outdoor to the indoor;
A second air flow path serving as a flow path of air from the room toward the outside;
It is disposed across the first air flow path and the second air flow path, adsorbs moisture of the air flowing through one of the first air flow path and the second air flow path, and the other flow Moisture adsorption means for releasing moisture into the air flowing through the road;
A refrigerant circuit for circulating the refrigerant,
The refrigerant circuit is
A compressor for compressing the refrigerant;
A first heat exchanger disposed upstream of the moisture adsorbing means in the second air flow path, and a third heat exchanger disposed downstream.
A second heat exchanger disposed upstream of the moisture adsorbing means in the first air flow path, and a fourth heat exchanger disposed downstream.
In the dehumidifying mode for supplying dehumidified air to the room, the refrigerant output from the compressor is supplied to the first heat exchanger, and in the humidifying mode for supplying humidified air to the room, the refrigerant is output from the compressor. Output switching means for switching to supply refrigerant to the second heat exchanger;
A first expansion valve provided between the first heat exchanger and the second heat exchanger; and a second expansion valve provided between the third heat exchanger and the fourth heat exchanger;
Control means for controlling the opening degree of the first expansion valve and the second expansion valve, and for controlling the output switching means,
Furthermore, the control means includes
In the dehumidifying mode, the refrigerant output from the compressor is routed from the output side of the first heat exchanger through the first expansion valve and the second heat exchanger, and the second expansion valve and the Circulate the route through the 4th heat exchanger,
In the humidification mode, the refrigerant output from the compressor is routed from the output side of the second heat exchanger to the path passing through the first expansion valve and the first heat exchanger, and the second expansion valve and the Set the refrigerant flow path to circulate the path through the third heat exchanger,
Further, in the dehumidifying mode, the third heat exchanger is stopped so that the temperature of the air passing through the second heat exchanger does not reach the dew point, and in the humidifying mode, the fourth heat exchanger is Stop and adjust the opening degree of the first expansion valve and the second expansion valve so that the temperature of the air passing through the first heat exchanger does not reach the dew point.
An outside air processing device characterized by the above . In the outside air processing apparatus that supplies the dehumidified air by processing the outside air into the room of the target room,
A first air flow path serving as an air flow path from the outdoor to the indoor;
A second air flow path serving as a flow path of air from the room toward the outside;
Moisture adsorption that is arranged across the first air flow path and the second air flow path, adsorbs moisture in the air flowing through the first air flow path, and releases moisture to the air flowing through the second air flow path Means,
A refrigerant circuit for circulating the refrigerant,
The refrigerant circuit is
A compressor for compressing the refrigerant;
A first heat exchanger disposed upstream of the moisture adsorbing means in the second air flow path;
A second heat exchanger disposed upstream of the moisture adsorbing means in the first air flow path, and a fourth heat exchanger disposed downstream.
A first expansion valve provided between the first heat exchanger and the second heat exchanger; and a second expansion valve provided between the first heat exchanger and the fourth heat exchanger;
Control means for controlling the opening degree of the first expansion valve and the second expansion valve,
The control means includes
The refrigerant output from the compressor is routed from the output side of the first heat exchanger through the first expansion valve and the second heat exchanger, and the second expansion valve and the fourth heat exchange. Form a route through the vessel and circulate
Furthermore, based on the degree of superheat of the refrigerant circuit, a total expansion valve opening that is a total opening of the first expansion valve and the second expansion valve is obtained, and the temperature of the air passing through the second heat exchanger, And based on the dew point temperature, a deviation expansion valve opening which is a difference opening between the first expansion valve and the second expansion valve is obtained so that the temperature of the air passing through the second heat exchanger does not reach the dew point, Further, based on the total expansion valve opening and the deviation expansion valve opening, the opening of the first expansion valve and the opening of the second expansion valve are calculated,
Adjusting the opening of the first expansion valve and the second expansion valve so as to be the calculated opening of the first expansion valve and the opening of the second expansion valve;
An outside air processing device characterized by the above .

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