JPWO2018037496A1 - Air conditioner - Google Patents

Abstract

The air conditioner includes an outdoor unit and an indoor unit, and the outdoor unit and the indoor unit are connected by piping, and the indoor air conditioned by the refrigerant flowing through the outdoor unit, the indoor unit, and the piping is blown through the duct. The indoor unit controls the indoor side heat exchanger that exchanges heat between the indoor air and the refrigerant, the indoor side fan that supplies the indoor air to the indoor side heat exchanger, and the indoor side fan An indoor control device, and the indoor control device calculates the air volume of the air passing through the indoor heat exchanger or the temperature efficiency of the indoor heat exchanger corresponding to the air volume.

Description

  The present invention relates to an air conditioner that performs air conditioning of a space to be air-conditioned via a duct.

  Conventionally, in an air conditioner that performs air conditioning of a space to be air-conditioned, the air volume is controlled for the purpose of improving energy saving and comfort. For example, in the air conditioner described in Patent Document 1, the air volume of the blower provided in the indoor unit is calculated based on the temperature difference between the suction temperature and the outlet temperature of the heat exchanger in the indoor unit and the current air volume. Is controlling.

  On the other hand, in an indoor unit of a general duct-type air conditioner that sucks air in an air-conditioning target space using a duct, the static pressure range is determined depending on the shape and size of the duct installed on site. Therefore, in such a duct-type air conditioner, an appropriate air volume can be ensured by setting the blower output of the indoor unit assuming that it is used in a static pressure range. .

Japanese Patent Laid-Open No. 7-4724

  However, the actual static pressure due to the duct varies depending on the installation state such as the bending of the duct. For this reason, in the duct type air conditioner, the indoor unit deviates from the range of static pressure assumed, and an appropriate air volume cannot be ensured.

  For example, when the static pressure is larger than expected, the air volume becomes too small, and comfort may be impaired due to a decrease in capacity or a decrease in blowing temperature during cooling operation. Further, for example, when the static pressure is smaller than assumed, the air volume becomes excessive, and condensed water adhering to the heat exchanger and the drain pan during cooling operation may be discharged from the indoor unit together with the blown air.

  This invention is made in view of the said subject, Comprising: Even if it is a case where the static pressure of a duct remove | deviates from the range which assumes, the air conditioning apparatus which can ensure appropriate duct air volume is provided. With the goal.

  The air conditioner of the present invention includes an outdoor unit and an indoor unit, the outdoor unit and the indoor unit are connected by a pipe, and the room is harmonized by a refrigerant flowing through the outdoor unit, the indoor unit, and the pipe. An air conditioner that blows air through a duct, wherein the indoor unit includes an indoor heat exchanger that exchanges heat between indoor air and the refrigerant, and the indoor heat exchanger An indoor fan for supplying air; and an indoor controller for controlling the indoor fan, wherein the indoor controller controls the air volume passing through the indoor heat exchanger or the air volume corresponding to the air volume. The temperature efficiency of the indoor heat exchanger is calculated.

  As described above, according to the air conditioner of the present invention, by calculating the air volume passing through the indoor heat exchanger or the temperature efficiency of the indoor heat exchanger, the static pressure of the duct is assumed to be within a range. Even when it is off, an appropriate duct air volume can be secured.

It is a block diagram which shows an example of the circuit structure of the air conditioning apparatus which concerns on this Embodiment 1. FIG. It is a functional block diagram for demonstrating the function of the indoor side control apparatus of FIG. It is the schematic which shows the example of installation of the indoor unit of FIG. It is the schematic for demonstrating the flow of the refrigerant | coolant in the air_conditioning | cooling operation mode and heating operation mode in the air conditioning apparatus of FIG. It is a flowchart which shows an example of the flow of the air volume check process at the time of the cooling operation by the indoor unit of FIG. It is a flowchart which shows an example of the flow of the air volume check process at the time of the heating operation by the indoor unit of FIG. It is the schematic for demonstrating the relationship between the air volume of the air which passes the indoor side air blower of FIG. 1, and an external static pressure. It is a functional block diagram for demonstrating the function of the indoor side control apparatus which concerns on Embodiment 2. FIG. 10 is a flowchart illustrating an example of a flow of air volume check processing during cooling operation by an indoor unit according to Embodiment 2. 6 is a flowchart illustrating an example of a flow of air volume check processing during heating operation by an indoor unit according to Embodiment 2.

Embodiment 1 FIG.
Hereinafter, the air-conditioning apparatus according to Embodiment 1 of the present invention will be described.

[Circuit configuration of air conditioner]
FIG. 1 is a block diagram illustrating an example of a circuit configuration of the air-conditioning apparatus 100 according to the first embodiment. As shown in FIG. 1, the air conditioning apparatus 100 includes an outdoor unit 1 and an indoor unit 2.

  The outdoor unit 1 includes a compressor 11, a refrigerant flow switching device 12, an outdoor heat exchanger 13, an outdoor blower 14, an outdoor control device 15, a high pressure detector 31, and an outdoor liquid pipe temperature detector 32. I have. The indoor unit 2 includes an expansion device 21, an indoor heat exchanger 22, an indoor blower 23, an indoor control device 24, an intake air temperature detector 33, a blown air temperature detector 34, an indoor liquid tube temperature detector 35, And an indoor gas pipe temperature detector 36 is provided. And the refrigerant circuit through which a refrigerant | coolant flows is formed by connecting the compressor 11, the refrigerant | coolant flow path switching device 12, the outdoor side heat exchanger 13, the expansion device 21, and the indoor side heat exchanger 22 with piping.

  In addition, although the example of FIG. 1 shows the case where one outdoor unit 1 and one indoor unit 2 are connected, the number of outdoor units 1 and indoor units 2 may be two or more, respectively. For example, a plurality of indoor units 2 may be connected to one outdoor unit 1. For example, one or a plurality of indoor units 2 may be connected to a plurality of outdoor units 1.

(Outdoor unit)
The compressor 11 sucks the low-temperature and low-pressure refrigerant, compresses the sucked refrigerant, and discharges it in a high-temperature and high-pressure state. The compressor 11 includes, for example, an inverter compressor that controls a capacity that is a refrigerant delivery amount per hour by arbitrarily changing a drive frequency.

  The refrigerant flow switching device 12 is a four-way valve, for example, and switches between a cooling operation and a heating operation by switching the direction in which the refrigerant flows. The refrigerant flow switching device 12 is not limited to the above-described four-way valve, and for example, other valves may be used in combination.

  The outdoor heat exchanger 13 performs heat exchange between the outdoor air supplied by the outdoor blower 14 such as a fan and the refrigerant. Specifically, the outdoor heat exchanger 13 functions as a condenser that evaporates the refrigerant during the cooling operation and cools the indoor air in the air-conditioning target space by the heat of vaporization at that time. In addition, the outdoor heat exchanger 13 functions as an evaporator that radiates heat of the refrigerant to room air and condenses the refrigerant during heating operation.

  The outdoor control device 15 controls the overall operation of the outdoor unit 1 based on various information received from each part of the outdoor unit 1. Specifically, the outdoor control device 15 is configured to switch the compressor frequency of the compressor 11, the switching of the flow path of the refrigerant flow switching device 12, the outdoor side based on information from various sensors provided in the refrigerant circuit, for example. The number of rotations of the blower 14 is controlled.

  The outdoor control device 15 is connected to the indoor control device 24 of the indoor unit 2 through a transmission line, and can exchange data such as control information with each other. Such an outdoor control device 15 is configured by, for example, a microcomputer, software executed on an arithmetic device such as a CPU (Central Processing Unit), or hardware such as a circuit device that realizes various functions.

  The high-pressure detector 31 is provided in the discharge-side piping of the compressor 11 and detects the pressure of the high-pressure refrigerant discharged from the compressor 11. The outdoor liquid pipe temperature detector 32 is provided in the liquid pipe 16 on the downstream side of the outdoor heat exchanger 13 during the cooling operation, and detects the temperature of the refrigerant flowing through the liquid pipe 16.

(Indoor unit)
The expansion device 21 pressurizes and expands the refrigerant. The throttle device 21 is configured by a valve capable of controlling the opening degree, such as an electronic expansion valve.

  The indoor heat exchanger 22 performs heat exchange between the indoor air supplied by the indoor blower 23 such as a fan and the refrigerant. Thereby, heating air or cooling air, which is conditioned air supplied to the indoor space, is generated. The indoor heat exchanger 22 functions as an evaporator during the cooling operation. Moreover, the indoor side heat exchanger 22 functions as a condenser during the heating operation.

  The indoor blower 23 is controlled in air speed by the indoor control device 24 and supplies indoor air to the indoor heat exchanger 22. A plurality of notches are set in the indoor fan 23. The indoor fan 23 can vary the wind speed of the indoor air supplied to the indoor heat exchanger 22 for each notch set based on the control of the indoor controller 24.

  The indoor-side control device 24 controls the overall operation of the indoor unit 2 based on various information received from each part of the indoor unit 2 and settings by the user's operation on the remote controller 3. Specifically, the indoor side control device 24 controls, for example, the rotational speed of the indoor side blower 23 based on control information from the outdoor side control device 15 or information from various sensors provided in the refrigerant circuit. .

  The indoor control device 24 is connected to the outdoor control device 15 of the outdoor unit 1 through a transmission line, and can transmit and receive data such as control information to each other. Furthermore, the indoor control device 24 is connected to the remote controller 3 by a transmission line, and can transmit and receive data to and from each other.

  Such an indoor side control device 24 is composed of, for example, software executed on an arithmetic device such as a microcomputer or CPU, and hardware such as a circuit device that realizes various functions.

  The intake air temperature detector 33 is provided on the upstream side of air, that is, on the intake side. The intake air temperature detector 33 detects the temperature of the indoor air sucked by the indoor fan 23. The blown air temperature detector 34 is provided on the downstream side of the air, that is, the blowout side. The blown air temperature detector 34 detects the temperature of the conditioned air that is blown out in harmony with the indoor heat exchanger 22.

  The indoor liquid tube temperature detector 35 is provided in the liquid pipe 25 between the expansion device 21 and the indoor heat exchanger 22, and detects the temperature of the refrigerant flowing through the liquid pipe 25. The indoor side gas pipe temperature detector 36 is provided in the gas pipe 26 on the downstream side of the indoor side heat exchanger 22 during the cooling operation, and detects the temperature of the refrigerant flowing through the gas pipe 26.

  The remote controller 3 is connected to the indoor control device 24. The remote controller 3 is for performing various settings such as operation mode setting, temperature setting, air volume setting, and the like in the air conditioner 100 and controlling the operation of the air conditioner 100 when operated by the user. . The remote controller 3 transmits an operation signal corresponding to the operation of the user to the indoor control device 24.

(Configuration of indoor control device)
FIG. 2 is a functional block diagram for explaining functions of the indoor side control device 24 of FIG. As shown in FIG. 2, the indoor control device 24 includes a refrigerant flow rate calculation unit 41, an enthalpy calculation unit 42, a refrigerant side capacity calculation unit 43, an air volume calculation unit 44, a comparison processing unit 45, a drive control unit 46, and a notification processing unit. 47 and a storage unit 48.

  The refrigerant flow rate calculation unit 41 receives the outdoor high pressure detected by the high pressure detector 31, the indoor liquid tube temperature detected by the indoor liquid tube temperature detector 35, and the opening degree of the expansion device 21. Is done. The refrigerant flow rate calculation unit 41 is based on the input outdoor high pressure and the indoor liquid tube temperature, and the flow rate coefficient Cv, which is a coefficient related to the opening degree of the expansion device 21 and the opening degree, stored in the storage unit 48. The refrigerant flow rate of the refrigerant flowing through the indoor heat exchanger 22 is calculated with reference to the table showing the relationship between The refrigerant flow rate calculation unit 41 outputs the calculated refrigerant flow rate to the refrigerant side capacity calculation unit 43.

  The enthalpy calculation unit 42 detects the outdoor high pressure detected by the high pressure detector 31, the outdoor liquid temperature detected by the outdoor liquid temperature detector 32, and the indoor liquid temperature detector 35. The indoor side liquid pipe temperature and the indoor side gas pipe temperature detected by the indoor gas pipe temperature detector 36 are input. The enthalpy calculating unit 42 is based on the input outdoor high pressure, outdoor liquid pipe temperature, indoor liquid pipe temperature, and indoor gas pipe temperature, and refrigerant on the inflow / outflow side in the indoor heat exchanger 22. The entrance and exit enthalpy difference which is the side enthalpy difference is calculated. The enthalpy calculating unit 42 outputs the calculated inlet / outlet enthalpy difference to the refrigerant side capacity calculating unit 43.

  The refrigerant side capacity calculation unit 43 is based on the refrigerant flow rate of the indoor side heat exchanger 22 input from the refrigerant flow rate calculation unit 41 and the inlet / outlet enthalpy difference of the indoor side heat exchanger 22 input from the enthalpy calculation unit 42. The refrigerant side capacity of the indoor side heat exchanger 22 is calculated. The refrigerant side capacity calculation unit 43 outputs the calculated refrigerant side capacity to the air volume calculation unit 44.

  The air volume calculation unit 44 uses the refrigerant side capability of the indoor heat exchanger 22 calculated by the refrigerant side capability calculation unit 43, the intake air temperature detected by the intake air temperature detector 33, and the blown air temperature detector 34. The detected blown air temperature is input. The air volume calculation unit 44 calculates the air volume of the air passing through the indoor heat exchanger 22 based on the refrigerant side capacity, the intake air temperature, and the blown air temperature of the input indoor heat exchanger 22. The air volume calculation unit 44 outputs the calculated air volume to the comparison processing unit 45.

  The comparison processing unit 45 reads the range of the rated air volume stored in advance in the storage unit 48, and inputs the input air volume passing through the indoor heat exchanger 22 and the range of the rated air volume read from the storage unit 48. Based on this, a process is performed to determine whether the duct airflow is an appropriate airflow. The range of the rated air volume is a range of the air volume of the air passing through the indoor heat exchanger 22 for obtaining an appropriate duct air volume. The range of the rated air volume is set in advance in consideration of, for example, the cool air feeling of the blown air, the discharge of the condensed water from the indoor unit 2 and the like.

  As a result of the determination process, the comparison processing unit 45 generates control information for adjusting the output of the indoor blower 23 and outputs the control information to the drive control unit 46 when it is determined that the duct air volume is not an appropriate air volume. . In addition, when the comparison processing unit 45 determines that the duct air volume is not an appropriate air volume and determines that the output adjustment of the indoor blower 23 cannot be performed, the comparison processing unit 45 generates information indicating abnormality, and the notification processing unit 47 Output.

  The drive control unit 46 receives control information from the comparison processing unit 45. The drive control unit 46 generates a drive signal for driving the indoor fan 23 based on the received control information, and outputs the drive signal to the indoor fan 23.

  The notification processing unit 47 receives information indicating an abnormality from the comparison processing unit 45. The notification processing unit 47 generates a control signal for displaying, for example, a notification indicating an abnormality on the remote controller 3 based on the received information, and outputs the control signal to the remote controller 3. Such notification is not limited to being displayed on the remote controller 3. For example, when a display unit for displaying various types of information is provided in the outdoor unit 1 or the indoor unit 2, a control signal is transmitted to the outdoor unit 1 or the indoor unit 2, and the outdoor unit 1 or the indoor unit 2 is displayed. It may be displayed on the unit 2.

  The storage unit 48 stores various information such as programs and data necessary for various processes performed by the indoor control device 24. For example, the storage unit 48 stores in advance information indicating a table used in the refrigerant flow rate calculation unit 41 and a set air volume range used in the comparison processing unit 45. The storage unit 48 supplies the stored table to the refrigerant flow rate calculation unit 41 based on a request from the refrigerant flow rate calculation unit 41. The storage unit 48 also supplies the comparison processing unit 45 with information indicating the stored range of the set air volume based on a request from the comparison processing unit 45. Furthermore, the storage unit 48 can also receive and store setting information for the indoor blower 23 according to the result of the determination process from the comparison processing unit 45.

[Indoor unit installation example]
Next, an installation example of the indoor unit 2 in the air-conditioning apparatus 100 according to Embodiment 1 will be described. FIG. 3 is a schematic diagram showing an installation example of the indoor unit 2 of FIG.

  The indoor unit 2 is installed, for example, in a space 5 such as the back of the ceiling that is different from the indoor space 4 that is an air-conditioning target space such as a living room or a server room. The remote controller 3 is installed in the indoor space 4.

  The indoor unit 2 is formed with a suction port 2a for sucking indoor air and a blower outlet 2b for blowing out conditioned air heat-exchanged by the indoor heat exchanger 22. One end of a duct 6a is connected to the suction port 2a. The other end of the duct 6 a is connected to a suction port 7 a of the ceiling 7 that partitions the indoor space 4 and the space 5. One end of a duct 6b is connected to the outlet 2b. The other end of the duct 6 b is connected to the air outlet 7 b of the ceiling 7.

  Thereby, the indoor unit 2 sucks the air in the indoor space 4 through the air inlet 7a and the duct 6a using the indoor fan 23, and the air conditioned by the indoor heat exchanger 22 is discharged from the air outlet 7b. The air can be blown out into the indoor space 4 through the duct 6b.

[Operation of air conditioner]
Next, the operation of the refrigerant in the cooling operation mode and the heating operation mode in the air-conditioning apparatus 100 having the above configuration will be described.

  FIG. 4 is a schematic diagram for explaining the flow of refrigerant in the cooling operation mode and the heating operation mode in the air-conditioning apparatus 100 of FIG. 1. In FIG. 4, the state shown by the solid line of the refrigerant flow switching device 12 is the state in the cooling operation mode, and the flow direction of the refrigerant is shown by the solid line. Moreover, the state shown with the dotted line of the refrigerant | coolant flow path switching apparatus 12 is a state in heating operation mode, and the flow direction of a refrigerant | coolant is shown with a dotted line.

(Cooling operation mode)
First, the operation of the refrigerant in the cooling operation mode will be described. In the cooling operation mode, the refrigerant flow switching device 12 is switched to the state shown by the solid line in FIG. The low-temperature and low-pressure refrigerant is compressed by the compressor 11 and discharged as a high-temperature and high-pressure gas refrigerant.

  The high-temperature and high-pressure gas refrigerant discharged from the compressor 11 flows into the outdoor heat exchanger 13 through the refrigerant flow switching device 12. The high-temperature and high-pressure gas refrigerant that has flowed into the outdoor heat exchanger 13 condenses while exchanging heat with the outdoor air and dissipates heat, and then flows out of the outdoor heat exchanger 13 as a supercooled high-pressure liquid refrigerant. The high-pressure liquid refrigerant that has flowed out of the outdoor heat exchanger 13 flows out of the outdoor unit 1 and flows into the indoor unit 2 through the liquid-side piping.

  The high-pressure liquid refrigerant that has flowed into the indoor unit 2 is decompressed by the expansion device 21 to become a low-temperature and low-pressure gas-liquid two-phase refrigerant, and flows into the indoor heat exchanger 22. The low-temperature and low-pressure gas-liquid two-phase refrigerant that has flowed into the indoor side heat exchanger 22 exchanges heat with the indoor air, absorbs heat and evaporates, thereby cooling the indoor air and becomes a low-temperature and low-pressure gas refrigerant to exchange indoor heat. Out of the vessel 22.

  The low-temperature and low-pressure gas refrigerant that has flowed out of the indoor-side heat exchanger 22 flows out of the indoor unit 2 and flows into the outdoor unit 1 through the gas-side piping. The low-temperature and low-pressure gas refrigerant that has flowed into the outdoor unit 1 passes through the refrigerant flow switching device 12 and is sucked into the compressor 11.

(Heating operation mode)
Next, the operation of the refrigerant in the heating operation mode will be described. In the heating operation mode, the refrigerant flow switching device 12 is switched to a state indicated by a dotted line in FIG. The low-temperature and low-pressure refrigerant is compressed by the compressor 11 and discharged as a high-temperature and high-pressure gas refrigerant.

  The high-temperature and high-pressure gas refrigerant discharged from the compressor 11 flows out of the outdoor unit 1 through the refrigerant flow switching device 12. The high-temperature and high-pressure gas refrigerant flowing out of the outdoor unit 1 flows into the indoor unit 2 through the gas side pipe.

  The high-temperature and high-pressure gas refrigerant that has flowed into the indoor unit 2 flows into the indoor heat exchanger 22. The high-temperature and high-pressure gas refrigerant that has flowed into the indoor heat exchanger 22 condenses while exchanging heat with room air and dissipates heat, and becomes a supercooled high-pressure liquid refrigerant that flows out of the indoor heat exchanger 22.

  The high-pressure liquid refrigerant that has flowed out of the indoor heat exchanger 22 is decompressed by the expansion device 21 to become a low-temperature and low-pressure gas-liquid two-phase refrigerant and flows out of the indoor unit 2. The low-temperature and low-pressure gas-liquid two-phase refrigerant that has flowed out of the indoor unit 2 flows into the outdoor unit 1 through the liquid side pipe.

  The low-temperature and low-pressure gas-liquid two-phase refrigerant that has flowed into the outdoor unit 1 flows into the outdoor heat exchanger 13. The low-temperature and low-pressure gas-liquid two-phase refrigerant that has flowed into the outdoor heat exchanger 13 exchanges heat with outdoor air, absorbs and evaporates, and flows out of the outdoor heat exchanger 13 as low-temperature and low-pressure gas refrigerant.

  The low-temperature and low-pressure gas refrigerant flowing out of the outdoor heat exchanger 13 passes through the refrigerant flow switching device 12 and is sucked into the compressor 11.

[Air flow check processing]
The air conditioner 100 according to Embodiment 1 has an air volume check operation mode as an operation mode in addition to the above-described cooling operation mode and heating operation mode. In the air volume check process in the air volume check operation mode, during the cooling operation or the heating operation, for example, an operation unit (not shown) such as a switch provided in the remote controller 3 or the indoor unit 2 is operated, and the air volume check operation mode is selected. Done in case.

(During cooling operation)
Hereinafter, processing in the air volume check operation mode during the cooling operation will be described. FIG. 5 is a flowchart showing an example of the flow of air volume check processing during the cooling operation by the indoor unit 2 of FIG.

  First, when the remote controller 3 or the like is operated and the air volume check operation mode is selected, the air volume check operation is started (step S1). Next, the indoor side control device 24 controls the indoor side blower 23 to operate at the maximum wind speed (step S2). Specifically, the indoor side control device 24 generates control information for setting the wind speed notch of the indoor side blower 23 at a stage where the wind speed becomes maximum, and via the drive control unit 46 of the indoor side control device 24. It transmits with respect to the indoor side air blower 23. FIG.

  Next, the indoor side control device 24 determines whether or not a preset time has elapsed (step S3). Here, the reason for waiting for the set time to elapse after the indoor blower 23 is operated at the maximum wind speed is to stabilize the operation of the air conditioner 100. If it is determined that the set time has elapsed (step S3; Yes), the process proceeds to step S4. On the other hand, if it is determined that the set time has not elapsed (step S3; No), the process returns to step S3, and the process of step S3 is repeated until the set time has elapsed.

  When the set time has elapsed, the air volume calculation unit 44 of the indoor control device 24 calculates the air volume of the air passing through the indoor heat exchanger 22. The amount of air passing through the indoor side heat exchanger 22 can be calculated based on the air side capacity of the indoor side heat exchanger 22, the intake air temperature, and the blown air temperature. Moreover, it can be considered that the air-side capability of the indoor heat exchanger 22 is equivalent to the refrigerant-side capability of the indoor heat exchanger 22. Therefore, in the first embodiment, the refrigerant side capability of the indoor heat exchanger 22 is calculated, and the indoor side is calculated based on the calculated refrigerant side capability and the intake air temperature and the blown air temperature in the indoor heat exchanger 22. The air volume of the blower 23 is calculated.

  First, in step S <b> 4, the refrigerant side capacity calculation unit 43 of the indoor side control device 24 calculates the refrigerant side capacity of the indoor side heat exchanger 22. Specifically, the refrigerant-side capacity calculation unit 43 is based on the refrigerant flow rate that is the flow rate of the refrigerant flowing through the indoor heat exchanger 22 and the refrigerant-side enthalpy difference on the inflow / outflow side of the indoor heat exchanger 22. The refrigerant side capacity of the inner heat exchanger 22 is calculated.

  Here, a method for calculating the refrigerant flow rate in the indoor heat exchanger 22 will be described. The refrigerant flow rate calculation unit 41 of the indoor side control device 24 calculates the refrigerant flow rate in the indoor side heat exchanger 22 based on the differential pressure before and after the expansion device 21 of the indoor unit 2 and the opening degree of the expansion device 21. .

  A method for calculating the differential pressure across the expansion device 21 will be described. As the primary pressure that is the upstream pressure of the refrigerant in the expansion device 21, the value of the high-pressure detector 31 provided on the discharge side of the compressor 11 in the outdoor unit 1 can be used. The secondary pressure, which is the pressure downstream of the refrigerant in the expansion device 21, uses the value of the indoor liquid tube temperature detector 35 provided between the expansion device 21 and the indoor heat exchanger 22. Can be acquired. This is because the refrigerant is in a gas-liquid two-phase state on the secondary side of the expansion device 21, and the pressure on the secondary side can be calculated as the saturation pressure of the refrigerant temperature at that point.

  The primary pressure of the expansion device 21 may be installed at any position as long as it is between the compressor 11 in the outdoor unit 1 and the expansion device 21 in the indoor unit 2. That is, the high pressure detector 31 may be provided not only in the outdoor unit 1 but also in the indoor unit 2.

  Further, in the expansion device 21, the effective flow path area increases as the opening degree increases. Therefore, the value of the flow coefficient Cv related to the opening degree of the expansion device 21 increases. Therefore, in the first embodiment, for example, a table indicating the relationship between the opening degree of the expansion device 21 and the flow coefficient Cv is stored in advance in the storage unit 48 of the indoor control device 24. The method for obtaining the flow coefficient Cv is not limited to this example. For example, an arithmetic expression for calculating the flow coefficient Cv based on the opening degree of the expansion device 21 is stored in the storage unit 48 in advance. May be.

  The refrigerant flow rate calculation unit 41 calculates the refrigerant flow rate in the indoor heat exchanger 22 based on the differential pressure across the expansion device 21 calculated as described above and the flow coefficient Cv corresponding to the opening degree. The refrigerant flow rate of the exchanger 22 is calculated.

  Further, the enthalpy calculating unit 42 of the indoor side control device 24 calculates the inlet / outlet enthalpy difference, which is the refrigerant side enthalpy difference on the inlet / outlet side in the indoor heat exchanger 22, and the temperature and pressure on the inlet / outlet side in the indoor heat exchanger 22. Calculate based on

  A method of calculating the entrance / exit enthalpy difference in the indoor heat exchanger 22 will be described. The enthalpy of the refrigerant can generally be calculated based on temperature and pressure. Therefore, the enthalpy on the refrigerant inflow side in the indoor heat exchanger 22 is calculated from the inlet enthalpy at the entrance of the indoor unit 2. This is because the refrigerant on the inflow side of the indoor unit 2 is in the supercooling region, and the change in enthalpy with respect to the pressure change due to the expansion device 21 or the like is negligible. Therefore, the inlet enthalpy is calculated as the enthalpy of the saturation point of the temperature.

  Further, the enthalpy on the refrigerant outflow side in the indoor heat exchanger 22 is calculated from the outlet enthalpy at the outlet of the indoor unit 2. At this time, the outlet enthalpy uses the pressure as the saturation pressure of the liquid pipe temperature obtained by the indoor side liquid pipe temperature detector 35, and the temperature as the gas pipe temperature obtained by the indoor side gas pipe temperature detector 36. Calculate using temperature.

  The enthalpy calculating unit 42 calculates the refrigerant side enthalpy difference on the inflow / outlet side in the indoor heat exchanger 22 based on the difference between the inlet enthalpy and the outlet enthalpy calculated in this way. And the refrigerant | coolant side capability calculation part 43 calculates a refrigerant | coolant side capability by multiplying the calculated refrigerant | coolant flow volume by the refrigerant | coolant side enthalpy difference.

  Next, in step S <b> 5, the air volume calculation unit 44 calculates the air volume of the air passing through the indoor heat exchanger 22. Specifically, the air volume calculation unit 44 determines the air side capacity of the indoor side heat exchanger 22 based on the refrigerant side capacity calculated in step S4 and the intake air temperature and the blown air temperature of the indoor side heat exchanger 22. calculate. The air side capacity can be calculated, for example, by multiplying the difference between the intake air temperature and the blown air temperature by the air volume of the air passing through the indoor heat exchanger 22.

  Here, as described above, the air side capability of the indoor heat exchanger 22 can be considered to be equivalent to the refrigerant side capability calculated in step S4. Therefore, the air volume calculation unit 44 calculates the air volume of the air passing through the indoor heat exchanger 22 so that the air side capacity value becomes the calculated refrigerant side capacity value based on the refrigerant side capacity calculated in step S4. calculate.

  Next, the comparison processing unit 45 of the indoor control device 24 compares the air volume calculated in step S5 with the range of the rated air volume stored in the storage unit 48 to determine whether or not the duct air volume is excessive. Is determined (step S6). If the calculated air volume is within the range of the rated air volume (step S6; No), it is determined that the duct air volume is not excessive, and the process proceeds to step S7.

  Next, the comparison processing unit 45 compares the air volume calculated in step S5 with the rated air volume range to determine whether or not the duct air volume is too small (step S7). If the calculated air volume is within the range of the rated air volume (step S7; No), it is determined that the duct air volume is appropriate, and the process proceeds to step S8. And the indoor side control apparatus 24 stops an air volume check driving | operation (step S8), and a series of processes are complete | finished.

  On the other hand, in step S6, when the calculated air volume is larger than the rated air volume range (step S6; Yes), it is determined that the duct air volume is excessive, and the process proceeds to step S9. The comparison processing unit 45 determines whether or not the wind speed can be lowered (step S9).

  If it is determined that the wind speed can be reduced (step S9; Yes), the process proceeds to step S10. The comparison processing unit 45 controls the indoor blower 23 via the drive control unit 46 of the indoor control device 24 so as to lower the wind speed notch of the indoor blower 23 by one step, and adjusts the blower output (step S10). . Then, the process returns to step S3. On the other hand, when it is determined that the wind speed notch of the indoor blower 23 is in the minimum stage and the wind speed cannot be lowered (step S9; No), the process proceeds to step S13.

  In step S7, when the calculated air volume is smaller than the range of the rated air volume (step S7; Yes), it is determined that the duct air volume is too small, and the process proceeds to step S11. The comparison processing unit 45 determines whether or not the wind speed can be increased (step S11).

  If it is determined that the wind speed can be increased (step S11; Yes), the process proceeds to step S12. The comparison processing unit 45 controls the indoor blower 23 via the drive control unit 46 so as to increase the wind speed notch of the indoor blower 23 by one step, and adjusts the blower output (step S12). Then, the process returns to step S3. On the other hand, when it is determined that the wind speed notch of the indoor fan 23 is at the maximum level and the wind speed cannot be increased (step S11; No), the process proceeds to step S13.

  In step S <b> 13, the comparison processing unit 45 of the indoor control device 24 transmits information indicating abnormality to the remote controller 3, for example, via the notification processing unit 47. Based on the information received from the indoor side control device 24, the remote controller 3 displays that the static pressure in the ducts 6a and 6b is outside the set range by the indoor unit 2, and notifies the user or the contractor. Then, a series of processing ends.

(During heating operation)
Next, processing in the air volume check operation mode during heating operation will be described. FIG. 6 is a flowchart showing an example of the flow of air volume check processing during heating operation by the indoor unit 2 of FIG.

  First, when the remote controller 3 or the like is operated and the air volume check operation mode is selected, the air volume check operation is started (step S21). Next, the indoor side control device 24 controls the indoor side blower 23 to operate at the maximum wind speed (step S22).

  Next, the indoor side control device 24 determines whether or not a preset time has elapsed (step S23). If it is determined that the set time has elapsed (step S23; Yes), the process proceeds to step S24. On the other hand, if it is determined that the set time has not elapsed (step S23; No), the process returns to step S23, and the process of step S23 is repeated until the set time has elapsed.

  When the set time has elapsed, the refrigerant side capacity calculation unit 43 calculates the refrigerant side capacity of the indoor heat exchanger 22 (step S24). Specifically, the refrigerant side capacity calculation unit 43 calculates the refrigerant side capacity based on the refrigerant flow rate of the indoor side heat exchanger 22 and the refrigerant side enthalpy difference on the inflow / outlet side of the indoor side heat exchanger 22.

  The refrigerant flow rate of the indoor heat exchanger 22 is calculated by the refrigerant flow rate calculation unit 41 as in the cooling operation. Further, the refrigerant-side enthalpy difference on the inflow / outlet side in the indoor heat exchanger 22 is calculated by the enthalpy calculating unit 42 based on the difference between the inlet enthalpy and the outlet enthalpy in the indoor heat exchanger 22.

  The inlet enthalpy can be calculated based on the outdoor high pressure obtained by the high pressure detector 31 and the gas pipe temperature obtained by the indoor gas pipe temperature detector 36. The outlet enthalpy can be calculated as the enthalpy of the saturation point of the liquid pipe temperature obtained by the indoor liquid pipe temperature detector 35. And the refrigerant | coolant side capability calculation part 43 calculates a refrigerant | coolant side capability by multiplying the calculated refrigerant | coolant flow volume by the refrigerant | coolant side enthalpy difference.

  Next, the air volume calculation unit 44 calculates the air volume of the air passing through the indoor heat exchanger 22 (step S25). Specifically, the air volume calculation unit 44 determines the air-side capability of the indoor heat exchanger 22 based on the refrigerant-side capability calculated in step S24 and the intake air temperature and the blown air temperature of the indoor heat exchanger 22. calculate. Then, the air volume calculation unit 44 calculates the air volume of the indoor unit 2 based on the refrigerant side capacity calculated in step S24 so that the air side capacity value becomes the refrigerant side capacity value.

  Next, as in the cooling operation, the comparison processing unit 45 compares the air volume calculated in step S25 with the range of the rated air volume to determine whether the duct air volume is excessive (step S26). ). When the calculated air volume is within the range of the rated air volume (step S26; No), it is determined that the air volume is not excessive, and the process proceeds to step S27.

  The comparison processing unit 45 determines whether or not the duct air volume is excessively small by comparing the air volume calculated in step S25 with the range of the rated air volume (step S27). If the calculated air volume is within the range of the rated air volume (step S27; No), it is determined that the duct air volume is appropriate, and the process proceeds to step S28. And the indoor side control apparatus 24 stops an air volume check driving | operation (step S28), and a series of processes are complete | finished.

  On the other hand, when the calculated air volume is larger than the rated air volume range in step S26 (step S26; Yes), it is determined that the duct air volume is excessive, and the process proceeds to step S29. The comparison processing unit 45 determines whether or not the wind speed can be lowered (step S29).

  If it is determined that the wind speed can be reduced (step S29; Yes), the process proceeds to step S30. The comparison processing unit 45 controls the indoor fan 23 via the drive controller 46 so as to lower the wind speed notch of the indoor fan 23 by one step, and adjusts the fan output (step S30). Then, the process returns to step S23. On the other hand, when it is determined that the wind speed notch of the indoor blower 23 is in the minimum stage and the wind speed cannot be lowered (step S29; No), the process proceeds to step S33.

  If the calculated air volume is smaller than the rated air volume range in step S27 (step S27; Yes), it is determined that the duct air volume is too small, and the process proceeds to step S31. The indoor control device 24 determines whether or not the wind speed can be increased (step S31).

  If it is determined that the wind speed can be increased (step S31; Yes), the process proceeds to step S32. The comparison processing unit 45 controls the indoor fan 23 via the drive controller 46 so as to increase the wind speed notch of the indoor fan 23 by one level, and adjusts the fan output (step S32). Then, the process returns to step S23. On the other hand, when it is determined that the wind speed notch of the indoor blower 23 is at the maximum level and the wind speed cannot be increased (step S31; No), the process proceeds to step S33.

  In step S <b> 33, the comparison processing unit 45 transmits information indicating abnormality to, for example, the remote controller 3 via the notification processing unit 47. Then, a series of processing ends.

  Note that the air volume check operation for performing the air volume check process is preferably performed when the indoor unit 2 is installed and a test operation or the like is performed. In addition, even after the installation of the indoor unit 2, for example, when the length of the duct, the number of outlets, etc. are changed, by performing the air flow check operation, even if the external static pressure outside the indoor unit 2 changes, The duct air volume can be secured appropriately.

  FIG. 7 is a schematic diagram for explaining the relationship between the air volume of the air passing through the indoor fan 23 of FIG. 1 and the external static pressure. In FIG. 7, a solid line “a” indicates a characteristic when the indoor fan 23 is operating at a predetermined output set in advance. A solid line A and dotted lines B and C indicate load curves when the output of the indoor fan 23 is changed when the duct shape is the same.

  Assuming that the intersection point x between the solid line a and the load curve A is a reference point, the rated air volume of the air passing through the indoor fan 23 is “V1”, and the rated external static pressure is “P1”. On the other hand, when the external static pressure determined by the duct resistance is larger than the reference, the operating point moves to the left side of the reference point x, for example, the position of the intersection z between the solid line a and the load curve B. At this time, the air volume of the air passing through the indoor fan 23 is “V3”, which is smaller than the rated air volume V1. Further, when the external static pressure is smaller than the reference, the operation point moves to the right side of the reference point x, for example, the position of the intersection y between the solid line a and the load curve C. At this time, the air volume of the air passing through the indoor fan 23 is “V2”, which is larger than the rated air volume V1.

  From such characteristics, if the air volume of the air passing through the indoor fan 23 is known, the static pressure outside the machine can be detected. Therefore, when there is a difference between the actual static pressure and the set static pressure of the indoor unit 2 serving as a reference, the duct can be easily adjusted by displaying it on the remote controller 3 or the like, for example. .

  As described above, the air-conditioning apparatus 100 according to Embodiment 1 is a case where the static pressure of the duct deviates from the assumed range by calculating the air volume of the air passing through the indoor heat exchanger 22. However, the static pressure of the duct is detected, and an appropriate duct air volume can be secured.

  Further, in the first embodiment, the static pressure of the duct is calculated based on the calculated air volume of the air passing through the indoor heat exchanger 22, and the calculated static pressure of the duct is displayed on the remote controller 3 or the like. The duct can be easily adjusted. Further, in the first embodiment, the output of the indoor blower 23 is adjusted when it is determined that the duct air volume is excessive or small based on the calculated air volume of the air passing through the indoor heat exchanger 22. Therefore, an appropriate duct air volume can be ensured. Furthermore, when the output of the indoor fan 23 cannot be adjusted, an abnormality is notified to the user, so that a quick response can be performed when an abnormality occurs.

Embodiment 2. FIG.
Next, an air conditioner according to Embodiment 2 of the present invention will be described. The second embodiment is different from the first embodiment described above in that the air volume is more easily calculated. In the following description, portions common to the above-described first embodiment are denoted by the same reference numerals and description thereof is omitted.

  Since air conditioner 100 in the second embodiment has the configuration shown in FIGS. 1 and 2 as in the first embodiment, the description thereof is omitted here.

[Configuration of indoor control unit]
FIG. 8 is a functional block diagram for explaining functions of the indoor control device 24 according to the second embodiment. As shown in FIG. 8, it includes a temperature efficiency calculation unit 49, a comparison processing unit 45, a drive control unit 46, a notification processing unit 47, and a storage unit 48.

  The temperature efficiency calculation unit 49 is detected by the outdoor high pressure detected by the high pressure detector 31, the indoor liquid tube temperature detected by the indoor liquid tube temperature detector 35, and the intake air temperature detector 33. The intake air temperature and the blown air temperature detected by the blown air temperature detector 34 are input. The temperature efficiency calculation unit 49 calculates the temperature efficiency of the indoor heat exchanger 22 based on the input outdoor high pressure, the indoor liquid tube temperature, the intake air temperature, and the blown air temperature. The temperature efficiency calculation unit 49 outputs the calculated temperature efficiency to the comparison processing unit 45.

  The temperature efficiency indicates the efficiency of heat exchange performed between the refrigerant flowing through the indoor heat exchanger 22 and the air supplied by the indoor fan 23. The temperature efficiency has a certain relationship with the air volume of the indoor heat exchanger 22. Therefore, the air volume of the indoor heat exchanger 22 can be estimated by calculating the temperature efficiency.

  The comparison processing unit 45 reads the reference temperature efficiency range, which is a value of the temperature efficiency corresponding to the rated air volume range, stored in the storage unit 48, and stores the input temperature efficiency of the indoor heat exchanger 22 and the stored temperature efficiency. Based on the reference temperature efficiency range read from the unit 48, a process for determining whether or not the duct airflow is an appropriate airflow is performed. As a result of the determination process, the comparison processing unit 45 generates control information for adjusting the output of the indoor blower 23 and outputs the control information to the drive control unit 46 when it is determined that the duct air volume is not an appropriate air volume. . In addition, when the comparison processing unit 45 determines that the duct air volume is not an appropriate air volume and determines that the output adjustment of the indoor blower 23 cannot be performed, the comparison processing unit 45 generates information indicating abnormality, and the notification processing unit 47 Output.

  For example, the storage unit 48 stores in advance information indicating the range of the reference temperature efficiency used in the comparison processing unit 45. Based on the request from the comparison processing unit 45, the storage unit 48 supplies information indicating the stored reference temperature efficiency range to the comparison processing unit 45.

[Air flow check processing]
(During cooling operation)
Processing in the air volume check operation mode during cooling operation will be described. FIG. 9 is a flowchart showing an example of the flow of air volume check processing during cooling operation by the indoor unit 2 according to the second embodiment.

  First, when the remote controller 3 or the like is operated and the air volume check operation mode is selected, the air volume check operation is started (step S41). The indoor side control device 24 controls the indoor side blower 23 to operate at the maximum wind speed (step S42).

  Next, the indoor side control device 24 determines whether or not a preset time has elapsed (step S43). If it is determined that the set time has elapsed (step S43; Yes), the process proceeds to step S44. On the other hand, if it is determined that the set time has not elapsed (step S43; No), the process returns to step S43, and the process of step S43 is repeated until the set time has elapsed.

When the set time has elapsed, the temperature efficiency calculation unit 49 calculates the temperature efficiency of the indoor heat exchanger 22 (step S44). Specifically, the temperature efficiency calculation unit 49, a suction air temperature T _in sensed by the suction air temperature detector 33, and the outlet air temperature T _out detected by the outlet air temperature detector 34, the indoor side liquid pipe Based on the liquid piping temperature T ₁ detected by the temperature detector 35, the temperature efficiency η _c of the indoor heat exchanger 22 during the cooling operation is calculated. The temperature efficiency η _c can be calculated based on the equation (1).

[Equation 1]
η _c = (T _in −T _out ) / (T _in −T _l ) (1)

Here, there is the following relationship between the temperature efficiency η _c calculated as described above and the air volume. For example, when the air volume increases, the temperature efficiency η _c decreases, and when the air volume decreases, the temperature efficiency η _c increases.

Therefore, in the second embodiment, previously stored in the storage unit 48 the range of the reference temperature efficiency eta is the value of temperature efficiency eta _c corresponding to the range of the rated air volume. Then, the comparison processing unit 45 compares the temperature efficiency η _c calculated in step S44 with the range of the reference temperature efficiency η (step S45).

From the comparison in step S45, for example, when the temperature efficiency η _c is within the range of the reference temperature efficiency η corresponding to the rated air volume, it can be determined that the duct air volume is appropriate. In addition, when the temperature efficiency η _c is smaller than the range of the reference temperature efficiency η corresponding to the rated air volume, it can be determined that the duct air volume is excessive. Furthermore, when the temperature efficiency η _c is larger than the range of the reference temperature efficiency η corresponding to the rated air volume, it can be determined that the duct air volume is too small.

The comparison processing unit 45 determines whether or not the duct air volume is excessive based on the magnitude relationship between the temperature efficiency η _c calculated in step S44 and the reference temperature efficiency η (step S46). When the calculated temperature efficiency η _c is within the range of the reference temperature efficiency η (step S46; No), it is determined that the duct air volume is not excessive, and the process proceeds to step S47.

Next, the comparison processing unit 45 determines whether or not the duct air volume is too small based on the magnitude relationship between the temperature efficiency η _c and the reference temperature efficiency η (step S47). When the calculated temperature efficiency η _c is within the range of the reference temperature efficiency η (step S47; No), it is determined that the duct air volume is appropriate, and the process proceeds to step S48. And the indoor side control apparatus 24 stops an air volume check driving | operation (step S48), and a series of processes are complete | finished.

On the other hand, when the temperature efficiency η _c is smaller than the range of the reference temperature efficiency η in step S46 (step S46; Yes), it is determined that the duct air volume is excessive, and the process proceeds to step S49. The comparison processing unit 45 determines whether or not the wind speed can be reduced (step S49).

  If it is determined that the wind speed can be reduced (step S49; Yes), the process proceeds to step S50. The indoor side control device 24 controls the indoor side blower 23 so as to lower the wind speed notch of the indoor side blower 23 by one step, and adjusts the blower output (step S50). Then, the process returns to step S43. On the other hand, when it is determined that the wind speed notch of the indoor blower 23 is in the minimum stage and the wind speed cannot be lowered (step S49; No), the process proceeds to step S53.

In step S47, when the temperature efficiency η _c is larger than the range of the reference temperature efficiency η (step S47; Yes), it is determined that the duct air volume is too small, and the process proceeds to step S51. The comparison processing unit 45 determines whether or not the wind speed can be increased (step S51).

  If it is determined that the wind speed can be increased (step S51; Yes), the process proceeds to step S52. The comparison processing unit 45 controls the indoor blower 23 via the drive control unit 46 so as to increase the wind speed notch of the indoor blower 23 by one level, and adjusts the blower output (step S52). Then, the process returns to step S43. On the other hand, when it is determined that the wind speed notch of the indoor blower 23 is at the maximum stage and the wind speed cannot be increased (step S51; No), the process proceeds to step S53.

  In step S <b> 53, the comparison processing unit 45 transmits information indicating abnormality to, for example, the remote controller 3 via the notification processing unit 47. Based on the information received from the indoor side control device 24, the remote controller 3 displays that the static pressure in the ducts 6a and 6b is outside the set range by the indoor unit 2, and notifies the user or the contractor. Then, a series of processing ends.

(During heating operation)
Next, processing in the air volume check operation mode during heating operation will be described. FIG. 10 is a flowchart showing an example of the flow of air volume check processing during heating operation by the indoor unit 2 according to the second embodiment.

  First, when the remote controller 3 or the like is operated and the air volume check operation mode is selected, the air volume check operation is started (step S61). The indoor side control device 24 controls the indoor side blower 23 to operate at the maximum wind speed (step S62).

  Next, the indoor side control device 24 determines whether or not a preset time has elapsed (step S63). If it is determined that the set time has elapsed (step S63; Yes), the process proceeds to step S64. On the other hand, if it is determined that the set time has not elapsed (step S63; No), the process returns to step S63, and the process of step S63 is repeated until the set time has elapsed.

When the set time has elapsed, the temperature efficiency calculation unit 49 calculates the temperature efficiency of the indoor heat exchanger 22 (step S64). Specifically, the temperature efficiency calculation unit 49, a suction air temperature T _in sensed by the suction air temperature detector 33, and the outlet air temperature T _out detected by the outlet air temperature detector 34, the condensing temperature T _c Based on the above, the temperature efficiency η _h of the indoor heat exchanger 22 during the heating operation is calculated. The temperature efficiency η _h can be calculated based on the equation (2).

[Equation 2]
η _h = (T _out −T _in ) / (T _c −T _in ) (2)

The condensation temperature _Tc can be calculated based on the pressure detected by the high pressure detector 31, for example. Further, for example, a pressure detector can be provided on the indoor unit 2 side, and the calculation can be performed based on the pressure detected by the pressure detector.

The comparison processing unit 45 compares the temperature efficiency η _c calculated in step S64 with the reference temperature efficiency η previously stored in the storage unit 48 (step S65). From the comparison in step S65, for example, when the temperature efficiency η _h is within the range of the reference temperature efficiency η corresponding to the rated air volume, it can be determined that the duct air volume is appropriate. Further, when the temperature efficiency η _h is smaller than the range of the reference temperature efficiency η corresponding to the rated air volume, the duct air volume is excessive, and when the temperature efficiency η _h is larger than the range of the reference temperature efficiency η, the duct air volume is excessively small. It can be judged that there is.

The comparison processing unit 45 determines whether or not the duct air volume is excessive based on the magnitude relationship between the reference temperature efficiency η and the calculated temperature efficiency η _h (step S66). When the temperature efficiency η _h is within the range of the reference temperature efficiency η (step S66; No), it is determined that the duct air volume is not excessive, and the process proceeds to step S67.

Next, the comparison processing unit 45 determines whether or not the duct air volume is too small based on the magnitude relationship between the reference temperature efficiency η and the temperature efficiency η _h (step S67). If the temperature efficiency η _c is within the range of the reference temperature efficiency η (step S67; No), it is determined that the duct air volume is appropriate, and the process proceeds to step S68. And the indoor side control apparatus 24 stops an air volume check driving | operation (step S68), and a series of processes are complete | finished.

On the other hand, when the temperature efficiency η _c is smaller than the range of the reference temperature efficiency η in step S66 (step S66; Yes), it is determined that the duct air volume is excessive, and the process proceeds to step S69. The comparison processing unit 45 determines whether or not the wind speed can be reduced (step S69).

  If it is determined that the wind speed can be reduced (step S69; Yes), the process proceeds to step S70. The indoor side control device 24 controls the indoor side blower 23 via the drive control unit 46 so as to lower the wind speed notch of the indoor side blower 23 by one step, and adjusts the blower output (step S70). Then, the process returns to step S63. On the other hand, when it is determined that the wind speed notch of the indoor blower 23 is at the minimum stage and the wind speed cannot be lowered (step S69; No), the process proceeds to step S73.

In step S67, if the temperature efficiency η _c is larger than the range of the reference temperature efficiency η (step S67; Yes), it is determined that the air volume is too small, and the process proceeds to step S71. The comparison processing unit 45 determines whether or not the wind speed can be increased (step S71).

  If it is determined that the wind speed can be increased (step S71; Yes), the process proceeds to step S72. The comparison processing unit 45 controls the indoor blower 23 via the drive control unit 46 so as to increase the wind speed notch of the indoor blower 23 by one step, and adjusts the blower output (step S72). Then, the process returns to step S63. On the other hand, when it is determined that the wind speed notch of the indoor fan 23 is at the maximum level and the wind speed cannot be increased (step S71; No), the process proceeds to step S73.

  In step S <b> 73, the comparison processing unit 45 transmits information indicating abnormality to, for example, the remote controller 3 via the notification processing unit 47. Based on the information received from the indoor side control device 24, the remote controller 3 displays that the static pressure in the ducts 6a and 6b is outside the set range by the indoor unit 2, and notifies the user or the contractor. Then, a series of processing ends.

  As described above, the air-conditioning apparatus 100 according to Embodiment 2 calculates the temperature efficiency of the indoor heat exchanger 22 corresponding to the air volume passing through the indoor heat exchanger 22. Thereby, similarly to Embodiment 1, even if it is a case where the static pressure of a duct remove | deviates from the range which assumes, the static pressure of a duct is detected and appropriate duct air volume can be ensured.

  In the second embodiment, the indoor side heat exchange is based on the intake air temperature and the blown air temperature of the indoor side heat exchanger 22 and the high-pressure pressure or the indoor side liquid pipe temperature of the refrigerant discharged from the compressor 11. The temperature efficiency of the vessel 22 is calculated. As a result, fewer parameters are used than in the first embodiment, so that the determination of the duct air volume can be easily calculated.

  Further, in the present second embodiment, as in the first embodiment, the static pressure of the duct is calculated based on the calculated air volume passing through the indoor heat exchanger 22, and the calculated static pressure of the duct is controlled remotely. Since it is displayed on the controller 3 or the like, the duct can be easily adjusted. Furthermore, in the second embodiment, as in the first embodiment, when it is determined that the duct air volume is excessive or small based on the calculated air volume of the air passing through the indoor heat exchanger 22, Since the output of the indoor fan 23 is adjusted, an appropriate duct air volume can be secured. Furthermore, when the output of the indoor blower 23 cannot be adjusted, the user is notified of the abnormality, so that a quick response can be performed when the abnormality occurs.

  As mentioned above, although Embodiment 1 and Embodiment 2 of this invention were demonstrated, this invention is not limited to Embodiment 1 and Embodiment 2 which were mentioned above, The range which does not deviate from the summary of this invention Various modifications and applications can be made.

  For example, in Embodiments 1 and 2, it has been described that the air volume check process is performed after the indoor air blower 23 is operated at the maximum wind speed. However, the present invention is not limited to this, and the indoor air blower 23 is operated at the minimum air speed. An air volume check process may be performed.

  Further, by performing the air volume check process described in the first and second embodiments, for example, clogging of a filter (not shown) provided on the air suction side of the indoor heat exchanger 22 or the indoor heat exchanger 22 is performed. It is also possible to detect an abnormality due to clogging or the like due to dirt. When the filter or the heat exchanger is clogged in this way, the air path resistance due to dirt or the like increases as the duct static pressure increases. Therefore, such an abnormality can be detected by the air volume check process described above. Note that the air volume check processing for detecting such an abnormality is preferably performed, for example, during regular maintenance.

  1 outdoor unit, 2 indoor unit, 2a inlet, 2b outlet, 3 remote controller, 4 indoor space, 5 space, 6a, 6b duct, 7 ceiling, 11 compressor, 12 refrigerant flow switching device, 13 outdoor heat Exchanger, 14 outdoor fan, 15 outdoor controller, 16 liquid piping, 21 throttle device, 22 indoor heat exchanger, 23 indoor fan, 24 indoor controller, 25 liquid piping, 26 gas piping, 31 high pressure Pressure detector, 32 outdoor liquid tube temperature detector, 33 intake air temperature detector, 34 blown air temperature detector, 35 indoor liquid tube temperature detector, 36 indoor gas tube temperature detector, 41 refrigerant flow rate calculation unit , 42 Enthalpy calculation unit, 43 Refrigerant-side capacity calculation unit, 44 Air volume calculation unit, 45 Comparison processing unit, 46 Drive control unit, 47 Notification processing unit, 48 Storage unit, 49 Temperature efficiency calculation unit, 100 air conditioner.

The air conditioner of the present invention includes an outdoor unit and an indoor unit, the outdoor unit and the indoor unit are connected by a pipe, and the room is harmonized by a refrigerant flowing through the outdoor unit, the indoor unit, and the pipe. An air conditioner that blows air through a duct, wherein the indoor unit includes an indoor heat exchanger that exchanges heat between indoor air and the refrigerant, and the indoor heat exchanger An indoor fan for supplying air; and an indoor controller for controlling the indoor fan, wherein the indoor controller controls the air volume passing through the indoor heat exchanger or the air volume corresponding to the air volume. calculating the temperature efficiency of the indoor heat exchanger, based on the air volume or the temperature efficiency of the air passing through the calculated the chamber inner heat exchanger, the air volume of the duct is appropriately der Whether the judged, when the air volume of the duct is determined to be too large or too small, and adjusts the output of the indoor blower.

Claims (10)

An outdoor unit and an indoor unit are provided, and the outdoor unit and the indoor unit are connected by a pipe. An air conditioner that performs
The indoor unit is
An indoor heat exchanger that exchanges heat between indoor air and the refrigerant;
An indoor fan that supplies the indoor air to the indoor heat exchanger;
An indoor control device for controlling the indoor blower,
The indoor control device is:
An air conditioner that calculates an air volume of air passing through the indoor heat exchanger or a temperature efficiency of the indoor heat exchanger corresponding to the air volume. The outdoor unit is
A compressor for compressing the refrigerant;
A high pressure detector for detecting the high pressure of the refrigerant discharged from the compressor,
The indoor unit is
A suction air temperature detector for detecting a suction air temperature of the air sucked into the indoor heat exchanger;
A blown air temperature detector for detecting a blown air temperature of the air blown out from the indoor heat exchanger;
An indoor liquid tube temperature detector that detects an indoor liquid tube temperature that is a temperature of a refrigerant flowing into or out of the indoor heat exchanger;
The indoor control device is:
The air conditioning apparatus according to claim 1, wherein the temperature efficiency is calculated based on the intake air temperature, the blown air temperature, and the high pressure or the indoor side liquid pipe temperature. The indoor control device is:
The air conditioning apparatus according to claim 2, wherein the temperature efficiency is calculated based on the intake air temperature, the blown air temperature, and the indoor side liquid pipe temperature during cooling operation. The indoor control device is:
The air conditioner according to claim 2 or 3, wherein the temperature efficiency is calculated based on the intake air temperature, the blown air temperature, and the high pressure during heating operation. The outdoor unit is
A compressor for compressing the refrigerant;
An outdoor heat exchanger that exchanges heat between outdoor air and the refrigerant;
A high-pressure detector that detects the pressure of refrigerant discharged from the compressor;
An outdoor liquid pipe temperature detector that detects an outdoor liquid pipe temperature that is a temperature of a refrigerant flowing into or out of the outdoor heat exchanger;
The indoor unit is
A throttling device for decompressing the refrigerant;
A suction air temperature detector for detecting a suction air temperature of the air sucked into the indoor heat exchanger;
A blown air temperature detector for detecting a blown air temperature of the air blown out from the indoor heat exchanger;
An indoor side that is provided between the indoor heat exchanger and the expansion device and detects an indoor liquid pipe temperature that is a temperature of a refrigerant flowing into or out of the indoor heat exchanger. A liquid tube temperature detector;
The indoor side which is provided on the opposite side of the indoor side liquid pipe temperature detector with respect to the indoor side heat exchanger and is the temperature of the refrigerant flowing out from the indoor side heat exchanger or flowing into the indoor side heat exchanger An indoor gas pipe temperature detector for detecting the gas pipe temperature;
The indoor control device is:
Based on the indoor side liquid pipe temperature, the indoor side gas pipe temperature, the high pressure, the outdoor liquid pipe temperature, and the opening degree of the expansion device, the refrigerant side capacity of the indoor heat exchanger is determined. Calculate
The air conditioner according to claim 1, wherein the air volume is calculated based on the refrigerant side capacity, the intake air temperature, and the blown air temperature. The refrigerant side capacity is
The refrigerant flow rate of the refrigerant flowing through the indoor heat exchanger calculated based on the indoor liquid pipe temperature, the high pressure, and the opening of the expansion device;
6. The flow rate is calculated based on the enthalpy difference on the inflow / outflow side of the indoor heat exchanger calculated based on the indoor liquid tube temperature, the indoor gas tube temperature, the high pressure and the outdoor liquid tube temperature. The air conditioning apparatus described in 1. The indoor unit is
A remote controller for controlling the operation of the air conditioner according to the operation of the user is connected,
The indoor control device is:
Calculate the static pressure of the duct based on the calculated air volume,
The air conditioning apparatus according to claim 5 or 6, wherein the calculated static pressure of the duct is displayed on the remote controller. The indoor control device is:
Based on the calculated air volume of the air passing through the indoor heat exchanger or the temperature efficiency, it is determined whether the air volume of the duct is appropriate,
The air conditioning apparatus according to any one of claims 1 to 7, wherein when the air volume of the duct is determined to be excessive or excessive, the output of the indoor fan is adjusted. The indoor control device is:
When the air volume of the air passing through the indoor heat exchanger is larger than the range of the set air volume, or the reference temperature efficiency indicating the temperature efficiency of the indoor heat exchanger corresponding to the set air volume range If the air volume is smaller than the range, the air volume is determined to be excessive,
When the air volume of the air passing through the indoor heat exchanger is smaller than the set air volume range, or when the temperature efficiency is larger than the reference temperature efficiency range, it is determined that the air volume is too small. The air conditioning apparatus according to claim 8. The indoor control device is:
When it is determined that the amount of air passing through the indoor heat exchanger is excessive or excessive, and the output of the indoor fan is maximum or minimum, the user is notified of an abnormality. The air conditioning apparatus according to claim 8 or 9.

Images