JP7587471B2 - Air conditioner indoor unit - Google Patents

Description

This relates to indoor units of air conditioners.

Patent document 1 (JP Patent Publication 2013-22169) discloses an air conditioner that performs dehumidification without significantly changing the evaporation temperature in response to increases or decreases in load.

However, in the air conditioner of Patent Document 1, when the difference between the indoor humidity and the set humidity is small, excessive dehumidification is performed, resulting in low efficiency.

The indoor unit of an air conditioner according to a first aspect is an indoor unit of an air conditioner that performs at least one of a cooling operation and a dehumidification operation, and includes a heat exchanger and a control unit. The heat exchanger exchanges heat between indoor air and a refrigerant to generate conditioned air. The control unit controls the evaporation temperature of the refrigerant in the heat exchanger when performing at least one of a cooling operation and a dehumidification operation. The control unit performs a first control and a second control. The first control sets the evaporation temperature to be equal to or lower than the dew point temperature of the indoor air. The second control sets the evaporation temperature to be higher than the dew point temperature of the indoor air.

According to the indoor unit of the air conditioner of the first aspect, the indoor unit is configured to be switchable between a first control that sets the evaporation temperature of the refrigerant below the dew point temperature of the indoor air, and a second control that sets the evaporation temperature of the refrigerant above the dew point temperature. By performing the first control, it is possible to increase the capacity of the cooling operation or dehumidification operation. By performing the second control, it is possible to decrease the capacity of the cooling operation or dehumidification operation. Therefore, it is possible to improve efficiency by performing the first control and the second control according to the required capacity.

The indoor unit of the air conditioner according to the second aspect is the indoor unit of the air conditioner according to the first aspect, and the control unit performs the second control during low-load operation in which the load of the cooling operation or dehumidification operation is equal to or lower than a predetermined value.

During low-load operation, the difference between the indoor temperature or humidity and the set temperature or humidity is small, so high cooling or dehumidification capacity is not required. Therefore, by performing at least the second control during low-load operation, excessive operation can be reduced. Therefore, the present disclosure is suitable for indoor units that perform low-load operation.

The indoor unit of the air conditioner according to the third aspect is the indoor unit of the air conditioner according to the second aspect, and the control unit performs the second control when no person is present in the room.

In the indoor unit of the air conditioner according to the third aspect, when the first control is performed, condensation occurs on the heat exchanger. However, when the second control is performed, moisture on the surface of the heat exchanger evaporates, which causes odors. For this reason, when the second control is performed, conditioned air containing odors may be generated.

However, when no one is present, indoor comfort is not required, so by performing the second control during low-load operation, it is easy to realize an indoor unit that increases efficiency.

The indoor unit of the air conditioner according to the fourth aspect is the indoor unit of the air conditioner according to the second aspect, and the control unit performs the second control when low-load operation continues for a predetermined time.

When low-load operation continues for a specified period of time, this is a period of time in which high cooling or dehumidification capacity is not required. By performing the second control in this state, excessive operation can be reduced, making it easy to realize an indoor unit with improved efficiency.

The indoor unit of the air conditioner according to the fifth aspect is the indoor unit of the air conditioner according to the second aspect, and the control unit performs the second control when the discomfort index in the room is in the comfort zone.

In the indoor unit of the air conditioner according to the fifth aspect, when the discomfort index is in the comfort range, there is no problem even if the comfort level decreases slightly. By performing the second control in this state, it is possible to easily realize an indoor unit with improved efficiency.

The indoor unit of the air conditioner according to the sixth aspect is the indoor unit of the air conditioner according to the first aspect to the fifth aspect, and the second control is a control that removes the upper limit value of the evaporation temperature.

The second control removes the upper limit of the evaporation temperature, which is set below the dew point temperature. Therefore, the upper limit of the evaporation temperature is not restricted to exceeding the dew point temperature, so it is possible to perform operation that prioritizes efficiency.

1 is a schematic configuration diagram of an air conditioning apparatus according to an embodiment of the present disclosure. FIG. 2 is an external perspective view of an indoor unit that constitutes the air conditioning apparatus. FIG. 3 is a schematic side cross-sectional view of the indoor unit, taken along line I-O-I in FIG. 2. FIG. 2 is a control block diagram of the air conditioning apparatus. FIG. 4 is a diagram for explaining control of a cooling operation and a dehumidification operation according to an embodiment of the present disclosure. 4 is a flowchart illustrating a method for controlling an evaporation temperature according to an embodiment of the present disclosure. 13 is a diagram for explaining control of a cooling operation and a dehumidifying operation according to a modified example. FIG. 10 is a flowchart showing a method for controlling an evaporation temperature according to a modified example.

(1) Equipment configuration of an air conditioner As shown in Fig. 1, an air conditioner 1 employing an indoor unit 3 according to an embodiment of the present disclosure is a device that conditions the air inside a building or the like by a vapor compression refrigeration cycle. The air conditioner 1 mainly has an outdoor unit 2, an indoor unit 3, and a liquid refrigerant connection pipe 4 and a gas refrigerant connection pipe 5 that connect the outdoor unit 2 and the indoor unit 3. A vapor compression refrigerant circuit 10 of the air conditioner 1 is formed by connecting the outdoor unit 2 and the indoor unit 3 via the liquid refrigerant connection pipe 4 and the gas refrigerant connection pipe 5.

(1-1) Outdoor Unit The outdoor unit 2 is installed outdoors (on the roof of a building, near the exterior wall of a building, etc.). As described above, the outdoor unit 2 is connected to the indoor unit 3 via the liquid refrigerant connection pipe 4 and the gas refrigerant connection pipe 5, and constitutes a part of the refrigerant circuit 10. The outdoor unit 2 mainly has a compressor 21, a four-way switching valve 23, an outdoor heat exchanger 24, and an expansion valve 25.

The compressor 21 is a mechanism that compresses low-pressure refrigerant in the refrigeration cycle until it becomes high pressure. Here, a compressor with a sealed structure is used as the compressor 21, in which a volumetric compression element (not shown), such as a rotary or scroll type, is rotated and driven by a compressor motor 22. In addition, the rotation speed (frequency) of the compressor motor 22 can be controlled by an inverter or the like, and the capacity of the compressor 21 can be controlled.

The four-way switching valve 23 is a valve for switching the direction of refrigerant flow when switching between cooling or dehumidification operation and heating operation. During cooling or dehumidification operation, the four-way switching valve 23 connects the discharge side of the compressor 21 to the gas side of the outdoor heat exchanger 24, and connects the gas side of the indoor heat exchanger 31 (described later) to the suction side of the compressor 21 via the gas refrigerant connection pipe 5 (see the solid line of the four-way switching valve 23 in FIG. 1). During heating operation, the four-way switching valve 23 connects the discharge side of the compressor 21 to the gas side of the indoor heat exchanger 31 via the gas refrigerant connection pipe 5, and connects the gas side of the outdoor heat exchanger 24 to the suction side of the compressor 21 (see the dashed line of the four-way switching valve 23 in FIG. 1).

The outdoor heat exchanger 24 is a heat exchanger that functions as a refrigerant radiator during cooling or dehumidification operation, and as a refrigerant evaporator during heating operation. The liquid side of the outdoor heat exchanger 24 is connected to the expansion valve 25, and the gas side is connected to the four-way switching valve 23.

The expansion valve 25 is an expansion mechanism that can reduce the pressure of the high-pressure liquid refrigerant that has dissipated heat in the outdoor heat exchanger 24 before being sent to the indoor heat exchanger 31 during cooling or dehumidification operation, and can reduce the pressure of the high-pressure liquid refrigerant that has dissipated heat in the indoor heat exchanger 31 before being sent to the outdoor heat exchanger 24 during heating operation. Here, an electric expansion valve with an opening controllable is used as the expansion valve 25.

The outdoor unit 2 is also provided with an outdoor fan 26 that draws in outdoor air into the outdoor unit 2, supplies the outdoor air to the outdoor heat exchanger 24, and then exhausts the air outside the outdoor unit 2. Therefore, the outdoor heat exchanger 24 uses the outdoor air as a cooling or heating source to dissipate heat or evaporate the refrigerant. The outdoor fan 26 is driven to rotate by an outdoor fan motor 27.

In addition, the outdoor unit 2 is provided with various sensors. Specifically, the outdoor unit 2 is provided with a suction pressure sensor 28a that detects the suction pressure of the compressor 21, a suction temperature sensor 28b that detects the suction temperature of the compressor 21, a discharge pressure sensor 29a that detects the discharge pressure of the compressor 21, and a discharge temperature sensor 29b that detects the discharge temperature of the compressor 21.

(1-2) Refrigerant communication pipe The refrigerant communication pipes 4, 5 are refrigerant pipes that are installed on-site when the air conditioning apparatus 1 is installed at the installation location such as a building. One end of the liquid refrigerant communication pipe 4 is connected to the expansion valve 25 side of the outdoor unit 2, and the other end of the liquid refrigerant communication pipe 4 is connected to the liquid side of the indoor heat exchanger 31 of the indoor unit 3. One end of the gas refrigerant communication pipe 5 is connected to the four-way switching valve 23 side of the outdoor unit 2, and the other end of the gas refrigerant communication pipe 5 is connected to the gas side of the indoor heat exchanger 31 of the indoor unit 3.

(1-3) Indoor Unit The indoor unit 3 is installed indoors (inside the building). As described above, the indoor unit 3 is connected to the outdoor unit 2 via the liquid refrigerant connection pipe 4 and the gas refrigerant connection pipe 5, and constitutes a part of the refrigerant circuit 10. As shown in Figures 1 to 3, the indoor unit 3 mainly has a casing 41, an opening and closing member 49, an indoor heat exchanger 31, and an indoor fan 32. Here, a type of indoor unit called a ceiling embedded type is adopted as the indoor unit 3.

As shown in Figures 2 and 3, the casing 41 houses the components inside. The casing 41 is composed of a casing body 41a and a decorative panel 42 arranged below the casing body 41a. As shown in Figure 2, the casing body 41a is inserted into an opening formed in the ceiling U. The decorative panel 42 is arranged to be fitted into the opening in the ceiling U.

As shown in Figures 2 and 3, the casing body 41a is a box-like body with a generally octagonal shape in plan view, with long and short sides alternately formed, and its bottom surface is open. The casing body 41a has a generally octagonal top plate 43 with long and short sides alternately formed in succession, and a side plate 44 extending downward from the periphery of the top plate 43.

The decorative panel 42 forms the underside of the casing 41, is a plate-like body that is generally polygonal (here, generally rectangular) in plan view, and is mainly composed of a panel body 42a that is fixed to the lower end of the casing body 41a. The panel body 42a has, approximately in the center, an intake port 45 that draws in indoor air, and an outlet port 46 that blows conditioned air into the room.

The intake port 45 is a substantially rectangular opening. The intake port 45 is provided with an intake grille 47 and an intake filter 48 for removing dust from the air drawn in through the intake port 45.

The air outlet 46 is formed to surround the periphery of the intake port 45 in a plan view. The air outlet 46 has multiple (four in this case) side air outlets 46a formed along each side of the rectangular panel body 42a, and multiple (four in this case) corner air outlets 46b formed at the corners of the panel body 42a.

The multiple opening/closing members 49 open and close the multiple air outlets 46. When the opening/closing members 49 open the air outlets 46, conditioned air is blown out from the air outlets 46. When the opening/closing members 49 close the air outlets 46, conditioned air is not blown out from the air outlets 46. The opening/closing members 49 can close the entire air outlets 46, close a portion of the air outlets 46, or open the entire air outlets 46. The opening/closing members 49 can also change the direction of the conditioned air blown out from the air outlets 46 into the room.

In this embodiment, an opening/closing member 49 is provided at each of the multiple air outlets 46a. In other words, one opening/closing member 49 opens and closes one air outlet 46a. Here, four opening/closing members 49 are provided at the four side air outlets 46a. On the other hand, no opening/closing member 49 is provided at the corner air outlet 46b.

The opening/closing member 49 is a plate-like member that extends in an elongated manner along the longitudinal direction of the side air outlet 46a. The opening/closing member 49 is configured to be rotated around the longitudinal axis to open and close the air outlet 46. The opening/closing member 49 is also configured to be rotated around the longitudinal axis to change the wind direction angle in the vertical direction.

Inside the casing body 41a, the indoor heat exchanger 31 and the indoor fan 32 are mainly arranged.

The indoor heat exchanger 31 exchanges heat between the indoor air and the refrigerant to generate conditioned air. The indoor heat exchanger 31 is a heat exchanger that functions as a refrigerant evaporator during cooling or dehumidifying operation, and as a refrigerant radiator during heating operation. The liquid side of the indoor heat exchanger 31 is connected to the liquid refrigerant connection pipe 4, and the gas side is connected to the gas refrigerant connection pipe 5.

The indoor heat exchanger 31 is a heat exchanger that is bent and positioned so as to surround the indoor fan 32 in a plan view. The indoor heat exchanger 31 exchanges heat between the indoor air drawn into the casing body 41a by the indoor fan 32 and the refrigerant. In addition, a drain pan 31a is positioned below the indoor heat exchanger 31 to receive drain water generated when moisture in the indoor air is condensed by the indoor heat exchanger 31. The drain pan 31a is attached to the bottom of the casing body 41a.

The indoor fan 32 is a fan that draws indoor air into the casing body 41a through the intake port 45 of the decorative panel 42 and blows it out from the casing body 41a into the room through the exhaust port 46 of the decorative panel 42. For this reason, the indoor heat exchanger 31 uses the indoor air as a cooling or heating source to dissipate heat and evaporate the refrigerant. Here, a centrifugal fan that draws in indoor air from below and blows it out toward the outer periphery in a plan view is used as the indoor fan 32. The indoor fan 32 is driven to rotate by an indoor fan motor 33 provided in the center of the top plate 43 of the casing body 41a. In addition, here, the indoor fan motor 33 can be controlled in rotation speed (frequency) by an inverter or the like, thereby controlling the air volume of the indoor fan 32.

Specifically, the indoor fan 32 has four airflow rates: maximum airflow rate H, medium airflow rate M which is smaller than airflow rate H, small airflow rate L which is smaller than airflow rate M, and minimum airflow rate LL which is smaller than airflow rate L. Here, airflow rate LL is an airflow rate that cannot be set by the resident using the remote control 60 (described below).

In addition, the indoor unit 3 is provided with various sensors. Specifically, the indoor unit 3 is provided with an indoor temperature sensor 34 and an indoor humidity sensor 35 that detect the temperature (indoor temperature Tr) and humidity (indoor humidity Hr) of the indoor air drawn into the indoor unit 3. Here, the indoor temperature sensor 34 and the indoor humidity sensor 35 are disposed near the intake port 45.

The indoor unit 3 is also provided with a human detection sensor 36 that detects the location of a person in the room. Here, an infrared sensor having one or more infrared receiving elements is used as the human detection sensor 36, and is provided at a corner of the decorative panel 42. Note that the human detection sensor 36 does not have to be provided at the corner of the decorative panel 42, and may be provided in another part of the indoor unit 3, or may be provided somewhere in the room other than the indoor unit 3.

(2) Control configuration of the air conditioner As shown in Fig. 4, the air conditioner 1 has a control device 6 in which an outdoor control unit 20, an indoor control unit 30, and a remote control 60 are connected via transmission lines and communication lines in order to control the operation of the constituent devices. The outdoor control unit 20 is provided in the outdoor unit 2. The indoor control unit 30 is provided in the indoor unit 3. The remote control 60 is provided indoors. Note that here, the outdoor control unit 20, the indoor control unit 30, and the remote control 60 are wired connected via transmission lines and communication lines, but they may also be connected wirelessly.

The outdoor control unit 20, indoor control unit 30, and control unit of the remote control 60 of the air conditioning device 1 perform various calculations and processing, and are realized, for example, by a calculation processing device such as a CPU.

(2-1) Outdoor control unit As described above, the outdoor control unit 20 is provided in the outdoor unit 2 and mainly has an outdoor CPU 20a, an outdoor transmission unit 20b, and an outdoor memory unit 20c. The outdoor control unit 20 is configured to be able to receive detection signals from the suction pressure sensor 28a, the suction temperature sensor 28b, the discharge pressure sensor 29a, and the discharge temperature sensor 29b.

The outdoor CPU 20a is connected to the outdoor transmission unit 20b and the outdoor memory unit 20c. The outdoor transmission unit 20b transmits control data and the like between the indoor control unit 30 and the outdoor memory unit 20c. The outdoor CPU 20a transmits and reads/writes control data and the like via the outdoor transmission unit 20b and the outdoor memory unit 20c, while controlling the operation of the compressor 21, four-way switching valve 23, expansion valve 25, outdoor fan 26, and other components provided in the outdoor unit 2.

(2-2) Indoor control unit As described above, the indoor control unit 30 is provided in the indoor unit 3, and mainly has an indoor CPU 30a, an indoor transmission unit 30b, an indoor storage unit 30c, and an indoor communication unit 30d. The indoor control unit 30 is configured to be able to receive detection signals from the indoor temperature sensor 34, the indoor humidity sensor 35, and the human detection sensor 36.

The indoor CPU 30a is connected to the indoor transmission unit 30b, the indoor memory unit 30c, and the indoor communication unit 30d. The indoor transmission unit 30b transmits control data and the like to the outdoor control unit 20. The indoor memory unit 30c stores control data and the like. The indoor communication unit 30d transmits and receives control data and the like to and from the remote control 60. The indoor CPU 30a transmits, reads, writes, and transmits and receives control data and the like via the indoor transmission unit 30b, the indoor memory unit 30c, and the indoor communication unit 30d, while controlling the operation of the indoor fan 32, the opening and closing member 49, and the like, which are components provided in the indoor unit 3.

(2-3) Remote Control As described above, the remote control 60 is provided indoors, and mainly includes a remote control CPU 61 , a remote control storage unit 62 , a remote control communication unit 63 , a remote control operation unit 64 , and a remote control display unit 65 .

The remote control CPU 61 is connected to a remote control storage unit 62, a remote control communication unit 63, a remote control operation unit 64, and a remote control display unit 65. The remote control storage unit 62 stores control data, etc. The remote control communication unit 63 transmits and receives control data, etc. with the indoor communication unit 30d. The remote control operation unit 64 accepts input of control commands, etc. from the occupant. The remote control display unit 65 displays operation, etc. The remote control CPU 61 accepts input of operation commands, control commands, etc. via the remote control operation unit 64, reads and writes control data, etc. to the remote control storage unit 62, and issues control commands, etc. to the indoor control unit 30 via the remote control communication unit 63 while displaying the operation status and control status on the remote control display unit 65.

Thus, the air conditioning device 1 has a control device 6 that controls the operation of the constituent equipment. The control device 6 controls the constituent equipment such as the compressor 21, four-way switching valve 23, expansion valve 25, outdoor fan 26, indoor fan 32, opening and closing member 49, etc. based on detection signals from the suction pressure sensor 28a, suction temperature sensor 28b, discharge pressure sensor 29a, discharge temperature sensor 29b, indoor temperature sensor 34, indoor humidity sensor 35, and human detection sensor 36, and is configured to perform air conditioning operations such as cooling operation, dehumidification operation, and heating operation, as well as various controls.

(3) Operation Next, a description will be given of the operation of the air conditioner 1. The air conditioner 1 of this embodiment performs heating operation, cooling operation, and dehumidification operation as air conditioning operations.

(3-1) Heating operation The heating operation is performed by the control device 6, which receives a heating operation command via the remote control operation unit 64, controlling the operation of the compressor 21, four-way switching valve 23, expansion valve 25, outdoor fan 26, indoor fan 32, opening/closing member 49, etc., which are components of the outdoor unit 2 and the indoor unit 3.

During heating operation, the four-way switching valve 23 is switched so that the outdoor heat exchanger 24 functions as a refrigerant evaporator and the indoor heat exchanger 31 functions as a refrigerant radiator (the state shown by the dashed line of the four-way switching valve 23 in Figure 1).

In the refrigerant circuit 10 in this state, the low-pressure refrigerant in the refrigeration cycle is sucked into the compressor 21, compressed to the high pressure in the refrigeration cycle, and then discharged. The high-pressure refrigerant discharged from the compressor 21 is sent to the indoor heat exchanger 31 through the four-way switching valve 23 and the gas refrigerant connection pipe 5. The high-pressure refrigerant sent to the indoor heat exchanger 31 exchanges heat with the indoor air supplied by the indoor fan 32 in the indoor heat exchanger 31 and dissipates heat. As a result, the indoor air is heated and blown out into the room. The high-pressure refrigerant that has dissipated heat in the indoor heat exchanger 31 is sent to the expansion valve 25 through the liquid refrigerant connection pipe 4 and is reduced in pressure to the low pressure in the refrigeration cycle. The low-pressure refrigerant reduced in pressure in the expansion valve 25 is sent to the outdoor heat exchanger 24. The low-pressure refrigerant sent to the outdoor heat exchanger 24 exchanges heat with the outdoor air supplied by the outdoor fan 26 in the outdoor heat exchanger 24 and evaporates. The low-pressure refrigerant that has evaporated in the outdoor heat exchanger 24 is sucked back into the compressor 21 through the four-way switching valve 23. In this way, during heating operation, the control device 6 causes the refrigerant sealed in the refrigerant circuit 10 to circulate through the compressor 21, indoor heat exchanger 31, expansion valve 25, and outdoor heat exchanger 24 in that order.

During heating operation, the control device 6 performs capacity control to control the capacity of the compressor 21 so that the condensation temperature Tc of the refrigerant in the refrigerant circuit 10 approaches a predetermined target condensation temperature Tcs. The capacity control of the compressor 21 is performed by controlling the rotation speed (frequency) of the motor 22.

The predetermined target condensation temperature is determined, for example, by the temperature difference between the indoor temperature Tr detected by the indoor temperature sensor 34 and the set temperature Trs set by the occupant through the remote control operation unit 64 of the remote control 60.

The refrigerant condensation temperature Tc is obtained by converting the discharge pressure detected by the discharge pressure sensor 29a to the refrigerant saturation temperature. The refrigerant condensation temperature Tc means the temperature obtained by converting the pressure (the refrigerant condensation pressure in the refrigerant circuit 10) representative of the high-pressure refrigerant flowing from the discharge side of the compressor 21 through the indoor heat exchanger 31 to the expansion valve 25 during heating operation, or the refrigerant saturation temperature in the indoor heat exchanger 31 that functions as a refrigerant radiator. Therefore, if a temperature sensor is provided in the indoor heat exchanger 31, the refrigerant temperature detected by this temperature sensor may be used as the refrigerant condensation temperature Tc.

(3-2) Cooling operation The cooling operation is performed by the control device 6, which receives a command for cooling operation via the remote control operation unit 64, controlling the operation of the compressor 21, four-way switching valve 23, expansion valve 25, outdoor fan 26, indoor fan 32, opening/closing member 49, etc., which are components of the outdoor unit 2 and the indoor unit 3.

During cooling operation, the four-way switching valve 23 is switched so that the outdoor heat exchanger 24 functions as a refrigerant radiator and the indoor heat exchanger 31 functions as a refrigerant evaporator (the state shown by the solid line of the four-way switching valve 23 in Figure 1).

In the refrigerant circuit 10 in this state, the low-pressure refrigerant in the refrigeration cycle is sucked into the compressor 21, compressed to the high pressure in the refrigeration cycle, and then discharged. The high-pressure refrigerant discharged from the compressor 21 is sent to the outdoor heat exchanger 24 through the four-way switching valve 23. The high-pressure refrigerant sent to the outdoor heat exchanger 24 exchanges heat with the outdoor air supplied by the outdoor fan 26 in the outdoor heat exchanger 24 and dissipates heat. The high-pressure refrigerant that has dissipated heat in the outdoor heat exchanger 24 is sent to the expansion valve 25 and reduced in pressure to the low pressure in the refrigeration cycle. The low-pressure refrigerant reduced in pressure in the expansion valve 25 is sent to the indoor heat exchanger 31 through the liquid refrigerant connection pipe 4. The low-pressure refrigerant sent to the indoor heat exchanger 31 exchanges heat with the indoor air supplied by the indoor fan 32 in the indoor heat exchanger 31 and evaporates. As a result, the indoor air is cooled and blown out into the room. The low-pressure refrigerant that has evaporated in the indoor heat exchanger 31 is sucked back into the compressor 21 through the gas refrigerant connection pipe 5 and the four-way switching valve 23. In this way, during cooling operation, the control device 6 causes the refrigerant sealed in the refrigerant circuit 10 to circulate through the compressor 21, outdoor heat exchanger 24, expansion valve 25, and indoor heat exchanger 31 in that order.

During cooling operation, the control device 6 performs capacity control to control the capacity of the compressor 21 so that the evaporation temperature Te of the refrigerant in the refrigerant circuit 10 approaches a predetermined target evaporation temperature Teds. The capacity control of the compressor 21 is performed by controlling the rotation speed (frequency) of the motor 22.

The predetermined target evaporation temperature Teds is determined, for example, by the temperature difference between the indoor temperature Tr detected by the indoor temperature sensor 34 and the set temperature Trs set by the occupant through the remote control operation unit 64 of the remote control 60.

The refrigerant evaporation temperature Te is obtained by converting the suction pressure detected by the suction pressure sensor 28a to the saturation temperature of the refrigerant. The refrigerant evaporation temperature Te means the temperature obtained by converting the pressure (evaporation pressure of the refrigerant in the refrigerant circuit 10) representative of the low-pressure refrigerant in the refrigeration cycle that flows from the outlet of the expansion valve 25 through the indoor heat exchanger 31 to the suction side of the compressor 21 during cooling operation to the saturation temperature of the refrigerant, or the saturation temperature of the refrigerant in the indoor heat exchanger 31 that functions as an evaporator of the refrigerant. Therefore, if a temperature sensor is provided in the indoor heat exchanger 31, the temperature of the refrigerant detected by this temperature sensor may be used as the evaporation temperature Te of the refrigerant.

(3-3) Dehumidification operation The dehumidification operation is performed by the control device 6, which has received a command for dehumidification operation via the remote control operation unit 64, controlling the operation of the compressor 21, four-way switching valve 23, expansion valve 25, outdoor fan 26, indoor fan 32, opening/closing member 49, etc., which are components of the outdoor unit 2 and the indoor unit 3.

In dehumidification operation, as in cooling operation, the four-way switching valve 23 is switched so that the outdoor heat exchanger 24 functions as a refrigerant radiator and the indoor heat exchanger 31 functions as a refrigerant evaporator (the state shown by the solid line of the four-way switching valve 23 in Figure 1).

In the refrigerant circuit 10 in this state, the low-pressure refrigerant in the refrigeration cycle is sucked into the compressor 21, compressed to the high pressure in the refrigeration cycle, and then discharged. The high-pressure refrigerant discharged from the compressor 21 is sent to the outdoor heat exchanger 24 through the four-way switching valve 23. The high-pressure refrigerant sent to the outdoor heat exchanger 24 exchanges heat with the outdoor air supplied by the outdoor fan 26 in the outdoor heat exchanger 24 and dissipates heat. The high-pressure refrigerant that has dissipated heat in the outdoor heat exchanger 24 is sent to the expansion valve 25 and reduced in pressure to the low pressure in the refrigeration cycle. The low-pressure refrigerant reduced in pressure in the expansion valve 25 is sent to the indoor heat exchanger 31 through the liquid refrigerant connection pipe 4. The low-pressure refrigerant sent to the indoor heat exchanger 31 exchanges heat with the indoor air supplied by the indoor fan 32 in the indoor heat exchanger 31 and evaporates. As a result, the indoor air is dehumidified and blown out into the room. The low-pressure refrigerant that has evaporated in the indoor heat exchanger 31 is sucked back into the compressor 21 through the gas refrigerant connection pipe 5 and the four-way switching valve 23. In this way, during dehumidification operation, the control device 6 causes the refrigerant sealed in the refrigerant circuit 10 to circulate through the compressor 21, the outdoor heat exchanger 24, the expansion valve 25, and the indoor heat exchanger 31 in that order.

The capacity control of the compressor 21 during dehumidification operation is basically the same as the capacity control of the compressor 21 during cooling operation, except that the target evaporation temperature Tecs is set to the target evaporation temperature Teds. The target evaporation temperature Teds during dehumidification operation is set to a value equal to or lower than the target evaporation temperature Tecs during cooling operation.

(4) Control of Evaporation Temperature in Cooling Operation and Dehumidification Operation The indoor control unit 30 controls the evaporation temperature Te of the refrigerant in the indoor heat exchanger 31 when performing at least one of the cooling operation and the dehumidification operation. The indoor control unit 30 performs a first control and a second control. The first control sets the evaporation temperature Te to a temperature equal to or lower than the dew point temperature of the indoor air. The second control sets the evaporation temperature Te to a temperature higher than the dew point temperature of the indoor air. In other words, the indoor unit 3 is configured to be switchable between the first control, which sets the evaporation temperature Te of the indoor heat exchanger 31 to a temperature equal to or lower than the dew point temperature of the indoor air, and the second control, which sets the evaporation temperature Te to a temperature higher than the dew point temperature, during the cooling operation or the dehumidification operation.

As described above, the evaporation temperature Te is calculated from the suction pressure detected by the suction pressure sensor 28a. The dew point temperature is calculated from the indoor temperature Tr detected by the indoor temperature sensor 34 and the indoor humidity Hr detected by the indoor humidity sensor 35.

Normally, during cooling and dehumidification operations, a first control is performed to set the evaporation temperature Te below the dew point temperature of the indoor air in order to cool and dehumidify the indoor air. However, the indoor control unit 30 of this embodiment allows a second control to set the evaporation temperature Te higher than the dew point temperature of the indoor air when performing at least one of the cooling and dehumidification operations. The second control is a control that removes the upper limit of the evaporation temperature Te. In other words, in the second control, no upper limit is set for the evaporation temperature Te. Here, in the second control, no upper limit is set for the target evaporation temperatures Tecs and Teds.

In addition, the indoor control unit 30 of this embodiment controls the rotation speed of the indoor fan 32 in the second control so that it is smaller than the rotation speed of the indoor fan 32 in the first control. For example, the indoor control unit 30 controls the air volume of the indoor fan 32 in the second control to air volume LL, which cannot be set by the resident using the remote control 60.

The indoor control unit 30 switches between the first control and the second control depending on the load of the cooling operation or the dehumidification operation. In this embodiment, the indoor control unit 30 performs the second control during low-load operation in which the load of the cooling operation or the dehumidification operation is equal to or lower than a predetermined value. During low-load operation, the indoor control unit 30 may perform only the second control, or may switch between both the first control and the second control.

Here, "low-load operation" is an operation in which a substitute value indicating the load during cooling operation or dehumidification operation satisfies a specified condition. Unlike thermo-off, which stops the compressor 21 and stops the circulation of the refrigerant, low-load operation is performed before thermo-off. In addition, low-load operation does not include the start-up of the compressor 21, which starts operation, but is performed when the refrigerant state is stable after startup (operation that continues for a specified period of time).

For example, the substitute value is the rated capacity of the air conditioning device 1, and the specified condition is 45% or less of the rated capacity. In other words, low-load operation occurs when the capacity is 45% or less of the rated capacity. The rated capacity is the same value as the "nominal capacity" listed in the product catalog or instruction manual.

For example, the substitute value during cooling operation is the difference between the set temperature and the room temperature, and the specified condition is that this difference (room temperature Tr - set temperature Trs) is 0.5°C or less (including negative values). In other words, when the room temperature approaches the set temperature and the difference between the set temperature and the room temperature is 0.5°C or less, low-load operation is initiated.

For example, the substitute value during dehumidification operation is the difference between the set humidity and the indoor humidity, and the specified condition is that this difference is 0% or less. In other words, when the indoor humidity approaches the set humidity and the difference between the set humidity and the indoor humidity becomes 0% or less, low-load operation is initiated.

The indoor control unit 30 controls the rotation speed of the indoor fan 32 during low-load operation so that it is lower than the rotation speed of the indoor fan 32 during normal operation, in which the load of cooling operation or dehumidification operation is greater than that during low-load operation. In this embodiment, during low-load operation, the airflow of the indoor fan 32 is controlled to airflow LL, which cannot be set by the resident using the remote control 60.

Next, a specific example of performing the first control and the second control will be described with reference to FIG. 5. In FIG. 5, the target evaporation temperature Tecs during cooling operation and the target evaporation temperature Teds during dehumidification operation are written as target evaporation temperature Tes. In this embodiment, an example will be given in which low-load operation occurs when the rated capacity falls below 45%.

Before time t1, the temperature difference between the indoor temperature Tr and the set temperature Trs (the target indoor temperature set by the remote control operation unit 64) is large, so the air conditioning device 1 is performing normal operation, which is a heavier load than low-load operation. In this case, in order to increase the capacity of the cooling operation or dehumidification operation, the indoor control unit 30 performs a first control in the indoor heat exchanger 31 to set the evaporation temperature Te below the dew point temperature of the indoor air.

Then, at time t1, when the difference between the set temperature Trs and the indoor temperature Tr becomes small, the indoor control unit 30 increases the target evaporation temperature Tes and reduces the rotation speed of the compressor 21. Next, at time t2, the capacity becomes 45% of the rated capacity and low-load operation is entered. During low-load operation, the required capacity for cooling or dehumidification operation is low, so the indoor control unit 30 performs a second control to make the evaporation temperature higher than the dew point temperature of the indoor air. By performing the second control, the capacity of cooling or dehumidification operation can be reduced during low-load operation.

After that, when the operation changes from low-load operation to normal operation, which is a higher load than low-load operation, based on the set temperature Trs, the indoor temperature Tr, the outdoor temperature, etc., the indoor control unit 30 switches from the second control to the first control.

In this way, the indoor control unit 30 of this embodiment performs the second control during low-load operation and the first control during normal operation.

Note that while FIG. 5 shows that the rotation speed of the compressor 21 is further reduced after time t2, the rotation speed may be kept approximately constant. Also, while FIG. 5 shows that the rotation speed of the compressor 21 is kept constant before time t1, the rotation speed may be increased or decreased.

(5) Method for controlling evaporating temperature during cooling operation and dehumidification operation The control of evaporating temperature during cooling operation and dehumidification operation was mentioned in (4) above, but to summarize, the following steps are taken.

First, as shown in FIG. 6, the compressor is started and normal operation, which is a higher load than low-load operation, is performed (step S1). During normal operation (step S1), the indoor control unit 30 performs a first control to set the evaporation temperature Te to a temperature equal to or lower than the dew point temperature of the indoor air.

Next, when the load of the cooling operation or dehumidification operation falls below a predetermined value, the operation switches to low-load operation (step S2). In low-load operation (step S2), the indoor control unit 30 performs a second control that makes the evaporation temperature Te higher than the dew point temperature of the indoor air. Here, as shown in FIG. 5, the indoor control unit 30 switches from the first control to the second control at time t2.

(6) Features (6-1)
The indoor unit 3 of the air conditioner 1 according to this embodiment is an indoor unit of an air conditioner that performs at least one of a cooling operation and a dehumidification operation, and includes an indoor heat exchanger 31 and an indoor control unit 30. The indoor heat exchanger 31 exchanges heat between indoor air and a refrigerant to generate conditioned air. The indoor control unit 30 controls the evaporation temperature of the refrigerant in the indoor heat exchanger 31 when performing at least one of a cooling operation and a dehumidification operation. The indoor control unit 30 performs a first control and a second control. The first control sets the evaporation temperature to be equal to or lower than the dew point temperature of the indoor air. The second control sets the evaporation temperature to be higher than the dew point temperature of the indoor air.

According to the indoor unit 3 of the air conditioning device 1 of this embodiment, the first control, which sets the evaporation temperature of the refrigerant below the dew point temperature of the indoor air, and the second control, which sets the evaporation temperature of the refrigerant above the dew point temperature, are switchable. The first control is performed to demonstrate the capacity of the cooling or dehumidifying operation, but the second control is allowed when the required capacity is low. Therefore, when a high capacity of the cooling or dehumidifying operation is required, the first control is performed, and when a low capacity of the cooling or dehumidifying operation is required, the second control can be performed. In this way, efficiency can be improved by performing the first control and the second control according to the required capacity.

(6-2)
Here, the indoor control unit 30 performs the second control during low-load operation where the load of the cooling operation or dehumidification operation is equal to or lower than a predetermined value.

In recent years, insulation performance has improved, and low-load operation at a load below a specified level may be performed during cooling and dehumidification operations. During low-load operation, the difference between the indoor temperature or humidity and the set temperature or humidity is small, so high cooling or dehumidification capacity is not required. For this reason, by performing at least the second control during low-load operation, excessive cooling or dehumidification operation can be reduced. Therefore, the efficiency of the indoor unit 3 can be further improved.

(7) Modifications (7-1) Modification 1
In the embodiment described above, the indoor control unit 30 performs the second control during low-load operation and the first control during normal operation, but is not limited to this. In this modified example, the indoor control unit 30 performs both the second control and the first control during low-load operation.

Specifically, during low-load operation from time t2 (see FIG. 5) onward, the indoor control unit 30 switches from the second control to the first control a predetermined time after the start of the low-load operation (time t2).

When the second control is performed in which the evaporation temperature Te exceeds the dew point temperature, odor may occur due to the absence of condensation in the indoor heat exchanger 31. If odorous conditioned air is blown into the room from the air outlet 46, it causes discomfort to the occupants. In order to reduce this discomfort, in this modified example, the indoor control unit 30 controls the position of the multiple opening and closing members 49 so as to close at least one of the multiple air outlets 46 when low-load operation continues for a predetermined time. Here, the opening and closing member 49 closes at least one of the multiple side air outlets 46a. This reduces the amount of heat exchange between the refrigerant and the indoor air in the indoor heat exchanger 31, so the control is switched to the first control, which raises the evaporation temperature Te to make the evaporation temperature Te equal to or lower than the dew point temperature of the indoor air. By performing the first control during low-load operation, condensation occurs in the indoor heat exchanger 31, suppressing the generation of odor.

In this modified example, the air outlet 46a is closed by the opening/closing member 49 during low-load operation to switch from the second control to the first control, but this is not limited to this and any other means may be used.

(7-2) Modification 2
In the embodiment described above, the indoor control unit 30 switches from the first control to the second control at time t2 when low-load operation occurs, but it may also switch from the first control to the second control after a predetermined time has elapsed since low-load operation began.

In this modified example, as shown in FIG. 7, when normal operation changes to low-load operation at time t2, the indoor control unit 30 performs the first control. Then, when low-load operation performing the first control continues for a predetermined time and time t3 is reached, the indoor control unit 30 switches to the second control. Note that the predetermined time (time t3-t2) is, for example, one minute or more.

Specifically, as shown in Figures 7 and 8, after low-load operation is started at time t2 (step S2), it is determined whether or not the first control is appropriate (step S3). In step S3 of this modified example, the indoor control unit 30 determines whether or not low-load operation has continued for a predetermined time. If low-load operation has not continued for the predetermined time in step S3, it is determined that the first control is appropriate, and the first control is continued (step S4). On the other hand, if low-load operation has not continued for the predetermined time in step S3, it is determined that the first control is not appropriate, and the second control is performed (step S5).

As explained above, in this modified example, the indoor control unit 30 performs the second control when low-load operation continues for a predetermined time (time t3-t2). When low-load operation continues for a predetermined time, this is a state in which a long period of time continues in which high capacity cooling or dehumidification operation is not required. By performing the second control in this state, as in this modified example, excessive operation can be reduced, thereby further improving efficiency.

(7-3) Modification 3
In the embodiment described above, the indoor control unit 30 switches from the first control to the second control at time t2 when the low-load operation occurs, but it may also switch from the first control to the second control after a predetermined time has elapsed since the low-load operation occurred. In this modified example, the indoor control unit 30 performs the second control when no one is present in the room.

In detail, as shown in FIG. 7, when the indoor control unit 30 enters low-load operation at time t2, it performs the first control. Then, during low-load operation in which the first control is performed, if the human detection sensor 36 detects that no human is present in the room, the indoor control unit 30 switches from the first control to the second control.

Specifically, as shown in Figures 7 and 8, after starting low-load operation at time t2 (step S2), it is determined whether or not the first control is appropriate (step S3). In step S3 of this modified example, the indoor control unit 30 determines whether or not a person is present in the room. If the human detection sensor 36 detects the presence of a person in the room in step S3, it is determined that the first control is appropriate, and the first control is continued (step S4). On the other hand, if the human detection sensor 36 detects the absence of a person in the room in step S3, it is determined that the first control is inappropriate, and the second control is performed (step S5).

When the first control is performed, condensation occurs on the indoor heat exchanger 31. However, when the second control is performed, moisture on the surface of the indoor heat exchanger 31 evaporates, which causes odors. For this reason, with the second control, conditioned air containing odors may be generated.

However, as in this modified example, when no one is present, indoor comfort is not required, so by performing the second control during low-load operation, excessive operation can be reduced, thereby further improving efficiency.

(7-4) Modification 4
In the embodiment described above, the indoor control unit 30 switches from the first control to the second control at time t2 when the low-load operation occurs, but it may also switch from the first control to the second control after a predetermined time has elapsed since the low-load operation occurred. In this modified example, the indoor control unit 30 performs the second control when the discomfort index in the room is in the comfort zone.

In detail, as shown in FIG. 7, when low-load operation occurs at time t2, the indoor control unit 30 performs the first control.

Thereafter, during low-load operation in which the first control is performed, the indoor control unit 30 calculates the indoor discomfort index Di based on the indoor temperature Tr and the indoor humidity Hr. In detail, the indoor discomfort index Di is expressed in the form of a function of the indoor temperature Tr and the indoor humidity Hr, as in the following formula 1 (k1 to k5 are coefficients).
Di=k1×Tr+k2×Hr×(k3×Tr-k4)+k5...(Formula 1)

The indoor control unit 30 acquires the indoor temperature Tr detected by the indoor temperature sensor 34 and the indoor humidity Hr detected by the indoor humidity sensor 35, and calculates the discomfort index Di by inputting the indoor temperature Tr and the indoor humidity Hr into the above formula 1.

If the calculated discomfort index Di is in the discomfort range, the indoor control unit 30 continues the first control. On the other hand, if the calculated discomfort index Di is in the comfort range, the indoor control unit 30 switches to the second control. In FIG. 7, the discomfort index Di is in the discomfort range from time t2 to t3, and becomes in the comfort range at time t3, so the indoor control unit 30 switches from the first control to the second control at time t3.

Specifically, as shown in Figures 7 and 8, after starting low-load operation at time t2 (step S2), it is determined whether or not the first control is appropriate (step S3). In step S3 of this modified example, the indoor control unit 30 determines whether the discomfort index in the room is in the comfort zone. If the discomfort index is not in the comfort zone in step S3, it is determined that the first control is appropriate, and the first control is continued (step S4). On the other hand, if the discomfort index is in the comfort zone in step S3, it is determined that the first control is not appropriate, and the second control is performed (step S5).

When the discomfort index is in the comfort range, a slight decrease in comfort is not a problem. For this reason, in this modified example, the indoor control unit 30 performs the second control when the discomfort index in the room is in the comfort range, thereby ensuring comfort and suppressing a decrease in efficiency.

(7-5) Modification 5
In the above embodiment, an example is given in which low-load operation is started when the rated capacity is 45% or less, but this is not limiting. As described above, the indoor control unit 30 may decide to start low-load operation based on the difference between the set temperature and the indoor temperature, etc.

(7-6) Modification 6
In the above embodiment, the indoor control unit 30 performing the first control during normal operation in which the load is higher than the low-load operation has been described as an example, but is not limited to this. The indoor control unit 30 may perform the second control during normal operation. For example, when the cooling load or dehumidification load is high but the indoor humidity is very low, the indoor control unit 30 performs the first control.

(7-7) Modification 7
In the above embodiment, among the air outlets 46, an opening/closing member 49 is arranged at each of the side air outlets 46a, and no opening/closing member 49 is arranged at the corner air outlets 46b, but this is not limited to the above. For example, in the above embodiment, one opening/closing member 49 is arranged at one side air outlet 46a, but two or more opening/closing members may be arranged at one side air outlet 46a. Also, one or more opening/closing members 49 may be arranged at the corner air outlets 46b.

(7-8) Modification 8
In the above-described embodiment, the state variable of the control target in the capacity control of the compressor 21 during cooling operation and dehumidification operation is the evaporation temperature Te, but this is not limited to this. In this modified example, the state variable of the control target in the capacity control is the evaporation pressure. In this case, a target evaporation pressure equivalent to the target evaporation temperatures Tecs and Teds is used as the control target value. Note that using the evaporation pressure and the target evaporation pressure in this capacity control is the same as using the evaporation temperature Te and the target evaporation temperatures Tecs and Teds.

(7-9) Modification 9
In the above embodiment, the indoor unit 3 of the air conditioner 1 that performs cooling operation, dehumidification operation, and heating operation has been described as an example, but the indoor unit of the present disclosure is not limited to this as long as it performs at least one of the cooling operation and the dehumidification operation. The indoor unit of this modification is, for example, an indoor unit of an air conditioner dedicated to cooling.

(7-10) Modification 10
In the above-described embodiment, a ceiling-embedded indoor unit has been described as an example, but the indoor unit of the present disclosure is not limited to this. The indoor unit of the present disclosure may be of any type, such as a wall-mounted type or a floor-standing type.

(7-11) Modification 11
In the above-described embodiment, an air conditioner 1 including one indoor unit 3 has been described as an example, but the air conditioner of the present disclosure is not limited to this. The air conditioner of the present disclosure can also be applied to a multi-type air conditioner including multiple indoor units 3.

Although the embodiments of the present disclosure have been described above, it will be understood that various changes in form and details are possible without departing from the spirit and scope of the present disclosure as set forth in the claims.

1: Air conditioner 2: Outdoor unit 3: Indoor unit 30: Indoor control unit (control unit)
36: Human detection sensor

JP 2013-22169 A

Claims (4)

An indoor unit of an air conditioner that performs at least one of a cooling operation and a dehumidification operation,
A heat exchanger (31) for exchanging heat between indoor air and a refrigerant to generate conditioned air;
a control unit (30) that controls an evaporation temperature of the refrigerant in the heat exchanger when performing at least one of the cooling operation and the dehumidification operation;
Equipped with
The control unit is
A first control for setting the evaporation temperature to a temperature equal to or lower than a dew point temperature of indoor air;
A second control for increasing the evaporation temperature above a dew point temperature of indoor air;
Do the following:
The control unit performs the second control when at least one of the cooling operation and the dehumidification operation is performed, the load is equal to or lower than a predetermined value, the difference between the indoor humidity and the set humidity is small, and a low-load operation in which high capacity of at least one of the cooling operation and the dehumidification operation is not required continues for a predetermined time ,
The control unit performs the second control when no person is present in the room .
An indoor unit (3) of an air conditioning device (1). An indoor unit of an air conditioner that performs at least one of a cooling operation and a dehumidification operation,
A heat exchanger (31) for exchanging heat between indoor air and a refrigerant to generate conditioned air;
a control unit (30) that controls an evaporation temperature of the refrigerant in the heat exchanger when performing at least one of the cooling operation and the dehumidification operation;
Equipped with
The control unit is
A first control for setting the evaporation temperature to a temperature equal to or lower than a dew point temperature of indoor air;
A second control for increasing the evaporation temperature above a dew point temperature of indoor air;
Do the following:
The control unit performs the second control when at least one of the cooling operation and the dehumidification operation is performed, the load is equal to or lower than a predetermined value, the difference between the indoor humidity and the set humidity is small, and a low-load operation in which high capacity of at least one of the cooling operation and the dehumidification operation is not required continues for a predetermined time ,
The control unit performs the second control when the discomfort index in the room is within a comfort range .
An indoor unit (3) of an air conditioning device (1). The second control is a control that removes the upper limit value of the evaporation temperature.
An indoor unit for an air conditioner according to claim 1 or 2 . An indoor unit of an air conditioner that performs at least one of a cooling operation and a dehumidification operation,
A heat exchanger (31) for exchanging heat between indoor air and a refrigerant to generate conditioned air;
a control unit (30) that controls an evaporation temperature of the refrigerant in the heat exchanger when performing at least one of the cooling operation and the dehumidification operation;
Equipped with
The control unit is
A first control for setting the evaporation temperature to a temperature equal to or lower than a dew point temperature of indoor air;
A second control for increasing the evaporation temperature above a dew point temperature of indoor air;
Do the following:
The control unit performs the second control when at least one of the cooling operation and the dehumidification operation is performed, the load is equal to or lower than a predetermined value, the difference between the indoor humidity and the set humidity is small, and a low-load operation in which high capacity of at least one of the cooling operation and the dehumidification operation is not required continues for a predetermined time ,
The second control is a control that removes the upper limit value of the evaporation temperature .
An indoor unit (3) of an air conditioning device (1).

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