JP2012032043A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner for efficiently dehumidifying a space in a wall and conditioning air in a room, while saving energy.SOLUTION: The air conditioner 100 simultaneously dehumidifying a space 80 in a wall during cooling a room 4A includes: an indoor unit 3 installed with a suction port 31 and a blowing port 32 facing the room 4A, and a dehumidifier 5 installed with a suction port 56 and a blowing port 55 facing the space 80 in a wall. An indoor heat exchanger 21 of the indoor unit 3 and a dehumidifying heat exchanger 51 of the dehumidifier 5 are connected to the same refrigerant system 10. The air conditioner includes a control means 60 that supplies a refrigerant to the indoor heat exchanger 21 in preference to the dehumidifying heat exchanger 51.

Description

  The present invention relates to an air conditioner that simultaneously cools a conditioned room and dehumidifies a space in a wall.

  Conventionally, for example, in a building such as a general detached house, it is known that condensation occurs in the wall due to moisture in the air. Therefore, in order to prevent decay of wood caused by condensation in the walls, and the growth of mold on the wallboard, flooring, or the back of the tatami on the indoor side, under the floor, in the wall, There is known a dehumidification system that dehumidifies interior spaces such as a ceiling and an attic (see, for example, Patent Document 1). In this type of dehumidification system, air to be dehumidified is blown to a moisture absorption area of a dehumidification rotor, and moisture in the air is absorbed by the dehumidification rotor to perform dehumidification. The dehumidification rotor is regenerated by blowing warm air to another position in the circumferential direction from the moisture absorption area of the dehumidification rotor.

JP 2001-133007 A

However, when the temperature and humidity are high in summer or the like, it is necessary to increase the temperature difference between the moisture absorption area and the regeneration area of the dehumidification rotor in order to maintain the moisture absorption capability of the dehumidification rotor. Therefore, it is necessary to heat the warm air blown to the moisture absorption area to a high temperature, which increases power consumption. In addition to the dehumidifying system that dehumidifies the space in the wall, it is also necessary to operate an air conditioner that performs air conditioning in the living room (conditioned room), which further increases power consumption. Therefore, there is a problem with the recent movement of energy saving and carbon dioxide emission reduction.
An object of the present invention is to provide an air conditioner that solves the above-described problems of the prior art and that can efficiently perform dehumidification of the space in the wall and air conditioning in the conditioned room with energy saving.

  In order to achieve the above object, the present invention is an air conditioner capable of simultaneously dehumidifying a space in a wall during cooling of a room to be conditioned, and is installed with the suction port and the air outlet facing the room to be conditioned. An indoor unit and a dehumidifier installed with the suction port and the air outlet facing the space in the wall, and the indoor heat exchanger of the indoor unit and the heat exchanger for dehumidification of the dehumidifier are the same refrigerant Control means connected to a system and supplying refrigerant prior to the indoor heat exchanger over the dehumidifying heat exchanger is provided.

  In this configuration, the indoor heat exchanger and the dehumidifying heat exchanger may be connected in parallel to the refrigerant system. The control unit may monitor the load on the indoor unit and stop supplying the refrigerant to the dehumidifying heat exchanger when the load on the indoor unit is large. The control means may be configured to increase or decrease the amount of refrigerant supplied to the indoor heat exchanger according to the load of the indoor unit. Moreover, the said control means is good also as a structure which monitors the temperature and humidity of the said wall space, and supplies a refrigerant | coolant to the said heat exchanger for dehumidification according to the temperature and humidity of the said wall space. In addition, the dehumidifier may include a blower provided at the air outlet, and the blower may continue to rotate for a predetermined time after the supply of the refrigerant to the dehumidification heat exchanger is stopped.

  According to the present invention, it is possible to operate the dehumidifier that dehumidifies the interior space using the remaining capacity of the indoor unit when performing the air conditioning of the conditioned room. Air conditioning in the room to be conditioned can be performed at the same time, and energy saving can be achieved.

It is a figure which shows schematic structure of the air conditioning system of this embodiment. It is a figure which shows the structure of the connection part of an indoor unit and a dehumidifier. It is a figure which shows the structure of the connection part at the time of removing a dehumidifier. It is a figure which shows roughly the installation state of an air conditioning unit. It is an external appearance perspective view of an air-conditioning unit. It is a sectional view in plan view of the dehumidifier. It is sectional drawing of an air conditioning unit. It is a flowchart which shows the operation control of a dehumidifier.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 shows a schematic configuration of an air conditioning system (air conditioning apparatus) 100 according to an embodiment to which the present invention is applied. The air conditioner 100 according to the present embodiment includes an outdoor unit 1 and an air conditioning unit 2 connected to the outdoor unit 1 through a refrigerant pipe (refrigerant system) 10. In addition, the air conditioner 100 includes a control unit 60 that controls each part of the air conditioner 100. The controller 60 is connected to a temperature / humidity sensor 57 that detects the temperature and humidity in the wall space 80 (see FIG. 2) of the building 200 where the air conditioner 100 is provided.

  The outdoor unit 1 is installed outdoors, and as shown in FIG. 1, a compressor 11, an accumulator 12, a four-way valve 13, an outdoor heat exchanger 14, and an electric expansion valve 15 are connected by a refrigerant pipe 10. . The air conditioner 100 is provided to be able to switch between a cooling operation and a heating operation by switching the four-way valve 13 of the outdoor unit 1 under the control of the control unit 60. The arrows in the figure indicate the refrigerant flow during the cooling operation. During the cooling operation, the refrigerant discharged from the compressor 11 flows to the outdoor heat exchanger 14 via the four-way valve 13. The refrigerant cooled through the outdoor heat exchanger 14 is supplied to the air conditioning unit 2 through the refrigerant pipe 10 as indicated by arrows in the figure.

As shown in FIG. 1, the air conditioning unit 2 includes an indoor unit 3 and a dehumidifier 5 that are connected to the outdoor unit 1 through a refrigerant pipe 10. The indoor unit 3 includes an indoor heat exchanger 21 and a blower 22 attached to the indoor heat exchanger 21. The indoor unit 3 also includes a first mechanical valve (first control valve) 29 on the refrigerant inlet side of the indoor heat exchanger 21 during the cooling operation of the air conditioner 100. Further, the indoor unit 3 is provided with a suction temperature sensor 31 a that detects the temperature of air sucked through the blower 22. In the air conditioner 100 according to this configuration, the full load of the indoor unit 3 and the full load of the outdoor unit 1 are set to be approximately equal.
The dehumidifier 5 includes a dehumidifying heat exchanger 51 and a dehumidifying blower 52 provided alongside the dehumidifying heat exchanger 51, and is connected to the refrigerant system of the air conditioner 100 in parallel with the indoor unit 3. The dehumidifier 5 also includes a second mechanical valve (first control valve) 53 on the refrigerant inlet side of the dehumidifying heat exchanger 51 during the cooling operation of the air conditioner 100.
The indoor unit 3 and the dehumidifier 5 communicate with the refrigerant pipe 10 via T joints 17a and 17b, respectively. Thus, the dehumidifying heat exchanger 51 and the indoor heat exchanger 21 are connected to the same refrigerant system 10.

  Opening and closing of the first control valve 29 and the second control valve 53 is controlled by the control unit 60. The first control valve 29 and the second control valve 53 may be configured as electromagnetic valves that perform either opening or closing, but in the present embodiment, the first control valve 29 and the second control valve 53 are opened. A mechanical valve that can freely adjust the degree is used. According to this configuration, by adjusting the opening degree of the first control valve 29 and / or the second control valve 53, the refrigerant amount flowing in the indoor heat exchanger 21 and the refrigerant amount flowing in the dehumidifying heat exchanger 51 Can be controlled in an adjustable manner. Therefore, the air conditioning efficiency of the indoor unit 3 and the dehumidification efficiency of the dehumidifier 5 can be controlled according to the load or the temperature or humidity of the surrounding environment. Furthermore, when the indoor unit 3 is thermo-off, the first control valve 29 can be closed to allow the refrigerant to flow only through the dehumidifier 5 to perform the dehumidifying operation. Although not shown, the air conditioning apparatus 100 includes a remote controller, and the user performs operation settings such as heating / cooling / dehumidification of the air conditioning apparatus 100 and temperature settings via the remote controller.

  For example, the dehumidifier 5 can be configured to be retrofitted to an air conditioner including the outdoor unit 1 and the indoor unit 3. In this case, as shown in FIG. 2, one end of an auxiliary pipe 16a extending to the dehumidifier 5 side is connected to the T joints 17a and 17b connected to the inter-unit piping connecting the outdoor unit 1 and the indoor unit 3. Yes. The other end of the auxiliary pipe 16 a has a flare connection port (male port) 116. When the dehumidifier 5 is not connected, the hood 117 is covered with the flare connection port 116, the bonnet 117 is fixed to the flare connection port with the flare nut 118, and the flare connection port 116 is sealed (see FIG. 3). ). On the other hand, the dehumidifier 5 includes a refrigerant pipe 16 b that communicates with the heat exchanger 51 for dehumidification. As shown in FIG. 2, the both ends 16c of the refrigerant pipe 16b are flared with the flare nut 119 inserted.

Next, connection work when retrofitting the dehumidifier 5 will be described. When retrofitting the dehumidifier 5, first, the service valve A in FIG. 1 is closed, the four-way valve 13 is set to a broken line state (cooling operation state), and the compressor 11 is operated. As a result, the refrigerant in the indoor unit 3 is collected in the refrigerant pipe of the outdoor unit 1 and the outdoor heat exchanger 14 (pump down operation). Thereafter, the service valve B is closed. In this way, the refrigerant in the refrigerant pipe on the indoor unit 3 side is collected on the outdoor unit 1 side by the pump-down operation, and is screwed into the auxiliary pipe 16a of the indoor unit 3 in a state where no refrigerant remains on the indoor unit 3 side. The flare nut 118 and the bonnet 117 are removed. 2B, the flare nut 119 of the refrigerant pipe 16b is screwed into the flare connection port 116 to form a connection port 120, and the dehumidifier 5 is connected to the refrigerant system 10. Thereafter, by opening the closed service valves A and B, the refrigerant is supplied to the dehumidifier 5 connected in parallel to the indoor unit 3 to the refrigerant system 10 via the refrigerant pipe 16 (see FIG. 1). Can do.
According to this configuration, the dehumidifier 5 can be optionally retrofitted, and the versatility of the air conditioner 100 is improved.

FIG. 4 is a diagram schematically showing a state where the air conditioning unit 2 is installed in a building 200 such as a general detached house. In the air conditioning unit 2, the indoor unit 3 and the dehumidifier 5 are integrated into a unit and supported by the wall space 80. The indoor unit 3 performs air conditioning such as cooling / heating in the conditioned room 4A. During the cooling operation of the indoor unit 3, the dehumidified air can be supplied to the wall space 80 by the dehumidifier 5 provided in the air conditioning unit 2.
In the present embodiment, the indoor unit 3 and the dehumidifier 5 are integrated and provided as a unit. However, the indoor unit 3 and the dehumidifier 5 may be connected separately by the refrigerant pipes 10 and 16. . Moreover, the indoor unit 3 may be a wall-hanging type indoor unit disposed in the conditioned room 4A in addition to the ceiling-embedded type (cassette type), or may be suspended from the ceiling surface. The ceiling-suspended indoor unit may be used.

The indoor unit 3 includes an indoor air suction port (suction port) 31 and a blower port 32 that are arranged facing the tuned room 4A. The air sucked into the indoor unit 3 from the indoor air suction port 31 is heat-exchanged by the indoor heat exchanger 21 accommodated in the indoor unit 3 as indicated by an arrow X in the figure, and is again conditioned room. 4A is blown out through the air outlet 32.
The dehumidifier 5 includes an in-wall air inlet (inlet) 56 and an in-wall outlet (outlet) 55 that are disposed facing the in-wall space 80. The in-wall space 80 includes the under floor 6, the ceiling back 7, the wall body 8, the attic 9 and the like, and is formed between the living room such as the conditioned room 4A and the outer wall 200A and the roof 200B of the building 200. For example, a heat insulating material (not shown) is arranged in the wall space 80.

  The dehumidified air supplied from the dehumidifier 5 passes through the wall 8 adjacent to the conditioned room 4A from the ceiling 7 where the air conditioning unit 2 is disposed, as indicated by the arrow Y1 in the figure, and below the floor 6 , Passes through the wall 8 again, and is collected by the dehumidifier 5. The dehumidified air supplied from the dehumidifier 5 also passes through the wall 8 adjacent to the living room 4B provided on the floor of the conditioned room 4A from the ceiling 7 where the air conditioning unit 2 is disposed, and the attic. 9 is supplied to the dehumidifier 5 again through the wall 8. The air recovered by the dehumidifier 5 is heat-exchanged by the heat exchanger 51 for dehumidification accommodated in the dehumidifier 5, dehumidified, and supplied to the in-wall space 80 again. As a result, the building 200 can be dehumidified by circulating the dehumidified air supplied from the dehumidifier 5 throughout the wall space 80 of the building 200.

  The temperature / humidity sensor 57 that detects the temperature and humidity in the wall space 80 is provided in the vicinity of the suction port 56 of the dehumidifier 5. According to this configuration, since the temperature / humidity sensor 57 is provided near the dehumidifier 5, the wiring work in the wall space 80 can be easily performed. Further, since the temperature / humidity sensor 57 is provided in the vicinity of the suction port 56, the temperature and humidity fluctuations are smaller than in the case where the temperature / humidity sensor 57 is provided in the vicinity of the in-wall outlet 55. And it can measure humidity more accurately.

  FIG. 5 is an external perspective view of the air conditioning unit 2 as viewed from the lower surface side. The indoor unit 3 that forms the air conditioning unit 2 and the dehumidifier 5 are connected to each other by bolts (screws) 2b so as to be integrated together. The indoor unit 3 includes a substantially box-shaped housing 30, and the lower surface of the housing 30 is configured by a decorative panel 30 </ b> B attached to the housing 30. The dehumidifier 5 includes a substantially box-shaped case (housing) 50, and the case 50 is formed in substantially the same shape as the housing 30 in plan view. The case 50 is placed on the top panel 30A of the housing 30 and fixed to the housing 30 with a bolt or the like (not shown).

  The housing 30 includes a side panel 30 </ b> C that forms four side surfaces of the housing 30. Further, the four corners of the housing 30 are chamfered, and the side panel 30D is disposed. The side panel 30D is provided with fixing brackets 2a and 2a for receiving bolts 2b for connecting the indoor unit 3 and the dehumidifier 5 placed on the indoor unit 3 to suspend the air conditioning unit 2 from the ceiling surface. The four hanging brackets 28 are provided. The air conditioning unit 2 is provided by being inserted into an opening for installation provided on the ceiling surface 101 (see FIG. 7) from the indoor side, and is, for example, a ceiling cassette type (ceiling embedded type) disposed in the space of the ceiling 7. It is an air conditioning unit. The suspension fitting 28 is supported by suspension bolts 102 (see FIG. 7) that hang down from, for example, the beam 103 on the back of the ceiling, and thereby the air conditioning unit 2 is fixed in the space of the ceiling 7. The housing 30 is arranged so that the decorative panel 30 </ b> B that forms the lower surface can be attached in close contact with the ceiling surface 101. The indoor unit 3 may be a four-way ceiling cassette type that blows air in four directions, or may be a two-way ceiling cassette type that blows air in two directions.

The decorative panel 30B includes an indoor air inlet 31 for taking in indoor air at the center thereof. The indoor air inlet 31 may have a filter 34. Around the room air inlet 31, there are four elongated outlets 32 formed to blow out the air after heat exchange along the side of the decorative panel 30B. Each blower outlet 32 is provided with a flap 33 that can adjust the direction of the blown air.
Corner panels 35 are provided at the four corners of the decorative panel 30B so as to be removable toward the lower side of the decorative panel 30B. The corner panel 35 is formed in such a size that the attachment operator's hand can reach the engagement position between the suspension fitting 28 and the suspension bolt 102 when the corner panel 35 is removed.

The case 50 of the dehumidifier 5 includes a side panel 50 </ b> A that forms four sides of the case 50. The case 50 also includes a side panel 50D formed by chamfering the four corners of the case 50. The side panel 50 </ b> D is provided with fixing brackets 2 a and 2 a that receive bolts 2 b that connect the indoor unit 3 and the dehumidifier 5.
One side 50B of the side panel 50A is provided with an in-wall outlet 55 through which the dehumidified air heat-exchanged by the dehumidifying heat exchanger 51 is blown out. The in-wall outlet 55 is provided with an outlet grill 55A. A surface 50C different from the surface 50B provided with the in-wall outlet 55 is provided with an in-wall air inlet 56 for taking in air from the in-wall space 80.

  As shown in FIG. 6, the in-wall air inlet 56 is formed on each of three surfaces 50 </ b> C, 50 </ b> C, and 50 </ b> C different from the surface 50 </ b> B on which the in-wall outlet 55 is provided. The in-wall outlet 55 is provided with a dehumidifying blower 52. The dehumidifying blower 52 includes a fan motor 52a and a propeller fan 52b attached to the rotation shaft of the fan motor 52a. For example, a plurality of dehumidifying fans 52 may be provided side by side at the in-wall outlet 55. The number of the dehumidifying blowers 52 can be set according to the size of the wall space 80 for dehumidifying. Thus, for example, when dehumidifying the wide wall space 80, a plurality of dehumidifying fans 52 are provided side by side, and the dehumidified air can be efficiently circulated in the wall space 80.

Inside the dehumidifier 5, a heat exchanger 51 for dehumidification formed by being bent into a substantially U shape in a plan view is provided. The dehumidifying heat exchanger 51 is disposed along the surfaces 50C, 50C, and 50C. The dehumidifying heat exchanger 51 is provided so as to be separated from each surface 50C by a predetermined distance. The dehumidifying heat exchanger 51 is placed on a drain pan (first drain pan) 54 disposed on the lower surface 23 of the case 50. One end of a partition plate 51B having substantially the same height as the height of the dehumidifying heat exchanger 51 is fixed to each tube plate 51A, 51A of the dehumidifying heat exchanger 51. The other end of the partition plate 51B is fixed to the surface 50B along the in-wall outlet 55.
When the propeller fan 52b is rotated by the fan motor 52a, the ambient air around the dehumidifier 5 is sucked into the dehumidifier 5 from the air intake ports 56A, 56B, and 56C in each wall due to the negative pressure. The air sucked in the directions of the arrows Y1, Y2, Y3 in the drawing from the respective wall air inlets 56A, 56B, 56C is heat-exchanged by the heat exchanger 51 for dehumidification and cooled. Since the humidity in the air is condensed by being cooled, the air after heat exchange is in a low humidity state. Thus, the dehumidified air is blown out from the in-wall outlet 55 in the direction of the arrow Y4 in the figure by the dehumidifying blower 52.

The wall air inlets 56A, 56B, and 56C may be formed by arbitrarily opening a knockout hole formed in the side panel 50A. Alternatively, the wall air inlets 56A, 56B, and 56C are not shown, but are provided with shutters that can be freely opened and closed, and the shutters provided in the wall air inlets 56A, 56B, and 56C in any direction. It is good also as a structure which opens and uses. According to this configuration, since the air suction direction can be changed, the wind flow direction can be changed depending on the installation position of the dehumidifier 5 or the size and direction of the room. Therefore, for example, when the in-wall air suction port 56A is arranged close to a wall or the like, the in-wall air suction port 56A can be closed and air can be sucked from the in-wall air suction ports 56B and 56C. . According to this configuration, by closing the in-wall air inlet 56A, the negative pressure in the in-wall air inlets 56B and 56C increases. Therefore, it is possible to efficiently suck air from the in-wall air suction ports 56B and 56C that are not close to the wall.
Further, since the heat exchanger 51 for dehumidification is arranged with a space between the air inlets 56A, 56B and 56C in the walls, for example, even when the air inlet 56A in the wall is closed, the dehumidifier 5 The air sucked into the air flows into the dehumidifying heat exchanger 51 from the interval between the in-wall air inlet 56A and the dehumidifying heat exchanger 51. Therefore, the air can be efficiently dehumidified without wasting the heat exchange area of the portion facing the in-wall air suction port 56A.
Further, since the partition plate 51B is provided between the tube plate 51A of the dehumidifying heat exchanger 51 and the in-wall outlet 55, the dehumidifying heat exchanger 51 and the in-wall air inlets 56A, 56B, 56C Even if there is a gap between the two, the air sucked into the dehumidifier 5 can be dehumidified through the dehumidifying heat exchanger 51 and blown out into the wall space 80.

As shown in FIG. 7, the water condensed in the dehumidifying heat exchanger 51 is collected in the drain pan 54. A drain tube (drain pipe) 58 is connected to the drain pan 54 to allow the drain water collected by the drain pan 54 to flow to the drain pan (second drain pan) 24 provided in the indoor unit 3. The drain tube 58 is extended from the drain pan 54 of the dehumidifier 5 to the indoor unit 3 through the lower surface 23 of the case 50 and the hole 58 </ b> A passing through the top panel 30 </ b> A of the housing 30, and drain water is supplied to the drain pan 24. It is configured to guide.
A motor base 26 is suspended between the top surface 25 and the lower surface 23 of the case 50. A fan motor 52 a of a dehumidifying blower 52 is fixed to the motor base 26.

A motor 22 a is fixed to the lower surface of the top panel 30 </ b> A of the housing 30, and an impeller 22 b is attached to the shaft of the motor 22 a to constitute the blower 22. The blower 22 is configured to suck air from the rotation axis direction through the suction port 31 and blow it out in the circumferential direction with rotation. Around the blower 22, an indoor heat exchanger 21 bent into a substantially square shape is disposed so as to surround the blower 22. Further, a heat insulator 27 made of, for example, styrene foam is provided on the inner surfaces of the side panel 30C and the side panel 30D. Further, the heat insulator 27 is also provided on the inner surface of the dehumidifier 5.
When the indoor unit 3 sucks indoor air from the suction port 31 by the blower 22 as indicated by an arrow X in the figure, the indoor unit 3 exchanges heat with the refrigerant flowing in the indoor heat exchanger 21, and after heat exchange Is blown out from the air outlet 32 and supplied into the conditioned room 4A for air conditioning in the conditioned room 4A.

  The indoor heat exchanger 21 is fixed in a state where it is placed on a drain pan (second drain pan) 24 disposed along the outer periphery of the indoor air suction port 31. The drain pan 24 is made of, for example, foamed polystyrene. Four outlets 32 are formed along the four sides on the outer periphery of the drain pan 24. The drain pan 24 is provided with a drain pump (not shown) for pumping the drain water stored in the drain pan 24 and discharging it to the outside of the air conditioning unit 2 at a position corresponding to one corner of the indoor heat exchanger 21. . The drain water that has flowed from the drain pan 54 of the dehumidifier 5 to the drain pan 24 of the indoor unit 3 through the drain tube 58 is also discharged outside the air conditioning unit 2 through this drain pump.

  The dehumidifier 5 is operated under the control of the control unit 60, during the cooling operation of the indoor unit 3, or when the indoor unit 3 is thermo-off. The dehumidifier 5 sucks the air in the wall space 80 containing moisture into the dehumidifier 5, condenses moisture in the air by the heat exchanger 51 for dehumidification, and dehumidifies the air with reduced humidity in the wall space 80. Repeat the cycle to blow out again. Thereby, dehumidification of the wall space 80 is performed. The dehumidifying blower 52 may be configured to be able to rotate to circulate the air in the wall space 80, for example, other than during the dehumidifying operation of the dehumidifier 5.

  The load of the dehumidifying operation of the dehumidifier 5 may be adjusted according to the load state of the cooling operation of the indoor unit 3. This is because the amount of refrigerant flowing through the indoor heat exchanger 21 and the amount of refrigerant flowing through the dehumidifying heat exchanger 51 are controlled by the controller 60 with the opening degree of the first control valve 29 and the second control valve 53, respectively. It becomes possible. For example, when the air conditioning unit 2 is thermo-off, the first control valve 29 is closed, the second control valve 53 is opened, and the refrigerant flows through the dehumidifying heat exchanger 51, so that only the dehumidifying operation of the wall space 80 can be performed. Even during the cooling operation of the air conditioning unit 2, for example, when the load on the indoor unit 3 is high, the second control valve 53 is closed to stop the supply of refrigerant to the dehumidifying heat exchanger 51, and the indoor heat exchanger By preferentially supplying the refrigerant to 21, it is possible to operate so as not to lower the air conditioning efficiency in the conditioned room 4A. When the air conditioner unit 2 is in the cooling operation and the indoor unit 3 has a surplus capacity, the opening degree of the first control valve 29 is reduced, the second control valve 53 is opened, and the dehumidification efficiency of the wall space 80 is increased. Can be increased.

Next, operation control of the dehumidifier 5 that is executed when the indoor unit 3 is thermo-ON will be described in detail with reference to FIG.
When the indoor unit 3 is set to thermo-ON from a remote controller (not shown) by the user, the control unit 60 determines whether to start the operation of the dehumidifier 5 as shown in FIG. First, the control unit 60 determines whether or not the air conditioner 100 is in a cooling operation (step S1). When the air conditioning apparatus 100 is not in the cooling operation, it waits until the operation is switched to the cooling. Although illustration is omitted, the operation control of the dehumidifier 5 is terminated simultaneously with the operation of the air conditioner 100 being stopped.

  If it is determined in step S1 that the air-conditioning apparatus 100 is in the cooling operation, the control unit 60 next acquires the wall temperature from the detection result of the temperature / humidity sensor 57, and the wall temperature is dewed. Judge whether it is within the easy temperature range. The temperature at which condensation easily occurs in the wall is, for example, when the temperature in the wall is in the range of 10 ° C. or more and 35 ° C. or less. Therefore, in this embodiment, the control part 60 determines whether it is in the range whose wall temperature is 10 degreeC or more and 35 degrees C or less (step S2). For example, when the temperature in the wall is less than 10 ° C. or exceeds 35 ° C., it is difficult for condensation to occur in the wall. It waits until it becomes in the range below ° C, and does not operate dehumidifier 5. If the controller 60 determines that the temperature in the wall is in the range of 10 ° C. or higher and 35 ° C. or lower (step S2: Yes), the controller 60 then acquires the wall humidity from the detection result of the temperature / humidity sensor 57. In-wall condensation tends to occur when the in-wall humidity is, for example, 70% or more. Therefore, in the present embodiment, the control unit 60 determines whether the humidity in the wall is 70% or more (step S3). When the humidity in the wall is less than 70%, it is difficult for condensation to occur in the wall. Therefore, the control unit 60 returns to step S2 and the temperature in the wall is within a range of 10 ° C. or more and 35 ° C. or less ( In step S2: Yes, the process waits until the humidity in the wall reaches 70% or more (step S3: Yes), and the dehumidifier 5 is not operated.

  When it is determined in step S3 that the humidity in the wall is 70% or more (step S3: Yes), the control unit 60 acquires the detection result of the suction temperature sensor 31a of the indoor unit 3, and the detection result of the suction temperature sensor 31a. However, it is determined whether or not the temperature exceeds a temperature obtained by adding a specified value to the cooling set temperature set by the user from a remote controller (not shown) (step S4). In the present embodiment, when the load on the indoor unit 3 is high, the refrigerant is preferentially flowed to the indoor unit 3 so that the cooling efficiency of the indoor unit 3 is not reduced. Therefore, when the specified value is 2 ° C. and the suction temperature of the indoor unit 3 exceeds the temperature set by the user by 2 ° C. (step S4: Yes), the indoor unit 3 is loaded. It is judged that the state is high. And in order not to reduce the cooling efficiency of the indoor unit 3, the control unit 60 stops the operation of the dehumidifier 5 until the suction temperature is within 2 ° C. of the set temperature of the cooling set by the user. Wait in state. If it is determined that the suction temperature of the indoor unit 3 is within a temperature that is 2 ° C. higher than the cooling temperature set by the user (step S4: No), the dehumidifier is used without reducing the cooling efficiency of the indoor unit 3. 5 can be performed, the control unit 60 starts the operation of the dehumidifier 5 (step S5).

  In step S <b> 5, the control unit 60 opens the second control valve 53 and rotates the dehumidifying blower 52 in order to supply the refrigerant to the dehumidifying heat exchanger 51. When the second control valve 53 is opened, the refrigerant flows into the second refrigerant pipe 16 branched from the refrigerant pipe 10. The opening degree of the second control valve 53 may be adjustable by the suction temperature of the indoor unit 3 detected by the suction temperature sensor 31a. According to this configuration, for example, when the suction temperature is lower than the temperature set by the user, it is determined that the indoor unit 3 has sufficient remaining power. Therefore, the opening degree of the second control valve 53 is increased. It is also possible to control so as to increase the amount of refrigerant flowing through the dehumidifying heat exchanger 51 and improve the dehumidifying efficiency of the dehumidifier 5.

  During the operation of the dehumidifier 5, the control unit 60 monitors the humidity in the wall detected by the temperature / humidity sensor 57 (step S6). While the in-wall humidity exceeds 55%, the control unit 60 continues the operation of the dehumidifier 5. When the humidity in the wall becomes 55% or less, the wall space 80 is in a state where condensation is unlikely to occur. Therefore, when the controller 60 detects that the humidity in the wall has become 55% or less, the controller 60 closes the second control valve 53 and stops the supply of the refrigerant to the dehumidifying heat exchanger 51. The control unit 60 sets a blower operation stop timer in order to stop the dehumidifying blower 52, for example, 5 minutes after a predetermined time has elapsed since the supply of the refrigerant to the dehumidifying heat exchanger 51 is stopped (step S7).

  Next, the control unit 60 waits until a set time (for example, 5 minutes) of the blower operation stop timer elapses (step S8). When detecting that the set time of the blower operation stop timer has elapsed (step S8: Yes), the control unit 60 stops the dehumidifying blower 52 (step S9) and stops the operation of the dehumidifier 5. According to this configuration, the dehumidifying blower 52 remains in the dehumidifying heat exchanger 51 because its rotation continues for a predetermined time (for example, 5 minutes) even after the supply of the refrigerant to the dehumidifying heat exchanger 51 is stopped. The evaporated refrigerant exchanges heat with the air blown by the dehumidifying blower 52 and evaporates. According to this configuration, it is possible to prevent the dehumidifying heat exchanger 51 from being left in a dewed state, and to prevent liquid back to the outdoor unit 1.

  As described above, according to the present embodiment, the indoor unit 3 that performs air conditioning of the conditioned room 4A and the dehumidifier 5 that performs dehumidification of the wall space 80 are connected to the same refrigerant system 10, and the indoor unit Since the refrigerant is supplied with priority over the indoor heat exchanger 21, the refrigerant is supplied with priority over the indoor unit 3 even when the operation load of the indoor unit 3 is high, thereby reducing the air conditioning efficiency of the indoor unit 3. There is no. Therefore, the conditioned air is efficiently supplied to the conditioned room 4A, and the indoor unit 3 and the dehumidifier 5 can be operated without impairing the user's comfort.

  Moreover, according to this embodiment, since the indoor heat exchanger 21 and the dehumidifying heat exchanger 51 are connected in parallel to the refrigerant system 10, it is possible to supply the refrigerant alternatively to one of them. It becomes. Therefore, even when the indoor unit 3 is thermo-off, if the user selects it, the refrigerant can be supplied only to the dehumidifying heat exchanger 51 to dehumidify the in-wall space 80.

  Further, in the air conditioner 100 according to this configuration, the total load of the indoor unit 3 and the total load of the outdoor unit 1 are set to be substantially equal. Therefore, the load on the indoor unit 3 is monitored, and when the load request for the indoor unit 3 is a request close to the full load of the outdoor unit 1, the outdoor unit 1 has no remaining capacity, so heat exchange for dehumidification The refrigerant can be supplied only to the indoor heat exchanger 21 without supplying the refrigerant to the vessel 51. For this reason, air conditioning of the conditioned room 4A is performed without lowering the operation efficiency of the indoor unit 3, so that the user is not uncomfortable.

  In addition, the amount of refrigerant supplied to the indoor heat exchanger 21 increases when the load on the indoor unit 3 is high and decreases when the load on the indoor unit 3 is low. The amount of refrigerant supplied to the exchanger 21 can be adjusted. Therefore, only when the indoor unit 3 has a surplus capacity, the refrigerant remaining in the indoor unit 3 can be supplied to the heat exchanger 51 for dehumidification, and the indoor unit 3 and the dehumidifier 5 can be operated efficiently. Therefore, energy saving efficiency can be improved.

  Further, the dehumidifier 5 is operated only at a temperature and humidity at which condensation is likely to occur in the wall according to the temperature in the wall and the humidity in the wall, and the refrigerant is supplied to the heat exchanger 51 for dehumidification. Therefore, even when the indoor unit 3 has a surplus capacity, when the temperature in the wall and the humidity in the wall are not the temperature and humidity at which condensation is likely to occur in the wall, the operation of the dehumidifier 5 is not performed and energy saving efficiency is improved. Can be improved.

  Further, even after the second control valve 53 is closed and the supply of the refrigerant to the dehumidifying heat exchanger 51 is stopped, the rotation of the dehumidifying blower 52 is continued for a predetermined time, so that the dehumidifying heat exchanger 51 evaporates. It is possible to prevent the remaining refrigerant from remaining, and to prevent the dehumidifying heat exchanger 51 from being left in a dewed state. Therefore, it is possible to prevent the efficiency of the air-conditioning apparatus 100 from being reduced due to the liquid back from the dehumidifying heat exchanger 51, and it is possible to prevent mold and the like from being generated in the wall space.

As mentioned above, although this invention was demonstrated based on embodiment, this invention is not limited to this. In the present embodiment, the dehumidifier 5 is configured to operate when the indoor unit 3 has sufficient power during the cooling operation of the air conditioner 100. However, the present invention is not limited to this, and the indoor unit 3 is not operated when the indoor unit 3 is thermo-off. It is good also as a structure which can supply the refrigerant | coolant only from the outdoor unit 1 to the dehumidifier 5 and can dehumidify the wall space 80 in the state which this operation | movement has stopped. Further, even when the refrigerant is not supplied to the dehumidifying heat exchanger 51 of the dehumidifier 5, the dehumidifying blower 52 may be rotated in order to circulate the air in the wall space 80.
Further, in the present embodiment, when the operation of the dehumidifier 5 is started, the operation of the dehumidifier 5 is continued until the humidity inside the wall becomes 55% or less. Even if the humidity is 55% or more, if the suction temperature of the indoor unit 3 rises to a predetermined value or higher than the set temperature during the operation of the dehumidifier 5, supply of the refrigerant to the heat exchanger 51 for dehumidification is performed. It is good also as a structure which stops and supplies a refrigerant | coolant preferentially to the indoor heat exchanger 21. FIG. Of course, other details and the like can be arbitrarily changed.

DESCRIPTION OF SYMBOLS 1 Outdoor unit 2 Indoor unit 5 Dehumidifier 10 Refrigerant piping (refrigerant system)
16 Second refrigerant piping 21 Indoor heat exchanger 22 Blower 29 First control valve 31 Suction port 31a Suction temperature sensor 32 Blowout outlet 50 Wall space 51 Dehumidification heat exchanger 52 Dehumidification blower 53 Second control valve 55 Blowing in wall Outlet 56 Suction port 57 Temperature / humidity sensor 60 Control unit (control means)
100 Air conditioner

Claims (6)

An air conditioner that can dehumidify the space in the wall at the time of cooling the conditioned room,
An indoor unit installed with the inlet and the outlet facing the conditioned room, and a dehumidifier installed with the inlet and the outlet facing the inner space,
The indoor heat exchanger of the indoor unit and the dehumidifying heat exchanger of the dehumidifier are connected to the same refrigerant system, and the refrigerant is supplied in preference to the indoor heat exchanger over the dehumidifying heat exchanger. An air conditioner comprising control means.   The air conditioner according to claim 1, wherein the indoor heat exchanger and the heat exchanger for dehumidification are connected in parallel to the refrigerant system.   The said control means monitors the load of the said indoor unit, and when the load of the said indoor unit is large, the supply of the refrigerant | coolant to the said heat exchanger for dehumidification is stopped, The Claim 1 or 2 characterized by the above-mentioned. Air conditioner.   The air conditioning apparatus according to any one of claims 1 to 3, wherein the control unit increases or decreases a refrigerant supply amount to the indoor heat exchanger according to a load of the indoor unit.   The said control means monitors the temperature and humidity of the said space in a wall, and supplies a refrigerant | coolant to the said heat exchanger for dehumidification according to the temperature and humidity of the said space in a wall. The air conditioning apparatus according to any one of claims.   The dehumidifier includes a blower provided at the air outlet, and the blower continues to rotate for a predetermined time after the supply of the refrigerant to the dehumidification heat exchanger is stopped. The air conditioning apparatus as described in any one of thru | or 5.

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