JP2018141599A - Air conditioning device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning device capable of preventing a rotational frequency of a compressor from lowering more than necessary during temperature protection control of the compressor.SOLUTION: A CPU determines whether or not a taken discharge temperature Td is 110°C or higher, or whether a taken shell temperature Tc is 115°C or higher. When the taken discharge temperature Td is 110°C or higher or the taken shell temperature Tc is not 115°C or higher, rotational frequency holding control is executed. When the taken discharge temperature Td is 110°C or higher or the taken shell temperature Tc is 115°C or higher, the CPU determines whether a flag Fb is 1 or not. Then the CPU executes the rotational frequency holding control when the flag Fb is 1, and executes rotational frequency lowering control when the flag Fb is not 1 and sets the flag Fb to 1.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an air conditioner in which an outdoor unit and an indoor unit are connected by a refrigerant pipe.

  2. Description of the Related Art Conventionally, a compressor, an outdoor heat exchanger, an outdoor expansion valve, and an indoor heat exchanger provided in the indoor unit, which have at least one outdoor unit and at least one indoor unit, are provided in the outdoor unit. In an air conditioner having a refrigerant circuit connected by refrigerant piping, the discharge temperature of the compressor and the temperature of the sealed container of the compressor (hereinafter referred to as shell temperature) are individually determined by the compressor. In order not to exceed the upper limit value, various temperature protection controls using detection values of various temperature sensors and various pressure sensors provided in the refrigeration cycle have been proposed.

  As an example of temperature protection control, the compressor's discharge temperature (hereinafter simply referred to as “discharge temperature”) is reduced by lowering the rotational speed of the compressor or stopping the compressor according to the detected pressure or temperature. Have been proposed to prevent the shell temperature from exceeding the upper limit. For example, the air conditioning apparatus described in Patent Document 1 includes a temperature sensor in an outdoor heat exchanger or an indoor heat exchanger, and the condensation when each heat exchanger functions as a condenser using each of these temperature sensors. The temperature is detected. And in this air conditioner, the control zone of the compressor rotation number which divided the condensation temperature by the predetermined temperature range is defined, and the decrease, the holding, the rise and the return of the condensing temperature from the highest one. Divided into 4 zones.

  In the air conditioning apparatus described above, when the detected condensation temperature is in the lowering zone, the maximum rotation speed of the compressor is limited to a predetermined rotation speed, and the compressor rotation speed is decreased at a predetermined speed to lower the condensation temperature. When the condensation temperature falls and the temperature zone of the holding zone is reached, the compressor speed is held. In this state, when the condensing temperature decreases and the temperature zone of the rising zone is reached, the compressor rotational speed is increased at a predetermined speed with the maximum rotational speed as the upper limit. Further, when the condensation temperature falls to the temperature zone of the return zone, the above-described predetermined rotation speed is canceled and the compressor rotation speed is allowed to increase to a rotation speed higher than the maximum rotation speed, Return to compressor speed control.

  In such temperature protection control, an upper limit of the maximum rotation speed is set for the rotation speed of the compressor, and the rotation speed of the compressor is controlled according to the condensation temperature with the maximum rotation speed as an upper limit from the stage where the condensation temperature is low. Therefore, even when the operating load of the compressor increases rapidly, the discharge temperature can be prevented from exceeding the upper limit value, so that it is possible to prevent the compressor from being damaged and the refrigerant circuit from functioning.

JP 2010-210198 A

  The discharge temperature and shell temperature of the compressor change with changes in the rotation speed of the compressor. Specifically, when the rotation speed of the compressor increases, the discharge temperature and the shell temperature also increase, and when the rotation speed of the compressor decreases, the discharge temperature and the shell temperature also decrease. For this reason, as described in Patent Document 1, when the detected condensing temperature is in the lowering zone, that is, when the discharging temperature of the compressor is a condensing temperature that is likely to exceed the upper limit value, the rotation speed of the compressor It can be said that reducing the temperature at a predetermined speed is an effective means for preventing the discharge temperature from exceeding the upper limit value.

  In order to prevent the discharge temperature and shell temperature from exceeding the upper limit values by controlling the compressor by the method described above, the discharge temperature and shell temperature are detected at relatively short intervals (for example, every 30 seconds). Then, it is necessary to control the rotation speed of the compressor according to the detected discharge temperature and shell temperature. This is because if the interval at which the discharge temperature or shell temperature is detected is long, the discharge temperature or shell temperature rises from the previous detection to the next detection and exceeds the respective upper limit values. This is because the compressor may be damaged by continuing to drive the compressor without lowering the rotational speed until the next detection timing with the high temperature exceeding the upper limit.

  However, generally, changes in discharge temperature and shell temperature are delayed with respect to changes in the rotational speed of the compressor. For this reason, if the discharge temperature or shell temperature is detected at short intervals and the rotation speed of the compressor is controlled according to the detected discharge temperature or shell temperature, the discharge temperature or shell temperature is high and the rotation speed of the compressor is reduced. In such a case, there is a risk that the rotational speed of the compressor may be reduced more than necessary before the discharge temperature or the shell temperature starts to decrease. And if the rotation speed of the compressor was reduced more than necessary during temperature protection control, there was a problem that the air conditioning capability exhibited in the indoor unit was excessively reduced.

  The present invention solves the above-described problems, and an object of the present invention is to provide an air conditioner that can prevent the rotational speed of the compressor from being lowered more than necessary during temperature protection control of the compressor. .

  In order to solve the above-described problems, an air conditioner according to the present invention includes a compressor, a compressor temperature detecting unit that detects a compressor temperature that changes according to the number of rotations of the compressor, and a compressor temperature detecting unit. Control means for controlling the compressor based on the detected compressor temperature is provided. If the compressor temperature is higher than a predetermined first temperature when the compressor temperature is rising, the control means prevents the compressor temperature from exceeding a predetermined second temperature higher than the first temperature. In addition, a temperature protection control including at least a rotation speed holding control for holding the rotation speed of the compressor at the current rotation speed and a rotation speed reduction control for setting the rotation speed of the compressor to a rotation speed by subtracting the rotation speed of the compressor from the current rotation speed at a predetermined rate. Is to execute. And if a control means reaches | attains the 1st temperature range defined by 3rd temperature higher than 1st temperature and compressor temperature lower than 2nd temperature and 4th temperature higher than 3rd temperature and lower than 2nd temperature, Then, the rotational speed reduction control is executed, and thereafter, if the compressor temperature remains in the first temperature zone, the rotational speed holding control is executed.

  According to the air conditioning apparatus of the present invention configured as described above, it is possible to prevent the rotation speed of the compressor from being lowered more than necessary during the temperature protection control of the compressor. Therefore, it is possible to prevent the air conditioning capability exhibited by the indoor unit during the temperature protection control from being excessively reduced.

It is explanatory drawing of the air conditioning apparatus in embodiment of this invention, (A) is a refrigerant circuit figure, (B) is a block diagram of an outdoor unit control means and an indoor unit control means. It is a compressor temperature-rotational speed correlation diagram in the embodiment of the present invention. It is a flowchart explaining the process in the outdoor unit control part in embodiment of this invention.

  Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. As an embodiment, an air conditioning apparatus will be described as an example in which three indoor units are connected in parallel to one outdoor unit, and cooling operation or heating operation can be performed simultaneously in all indoor units. The present invention is not limited to the following embodiments, and can be variously modified without departing from the gist of the present invention.

  As shown in FIG. 1 (A), an air conditioner 1 according to this embodiment includes one outdoor unit 2 and three indoor units connected to the outdoor unit 2 in parallel by a liquid pipe 8 and a gas pipe 9. 5a-5c. Specifically, the liquid pipe 8 has one end connected to the closing valve 25 of the outdoor unit 2 and the other end branched to be connected to the liquid pipe connecting portions 53a to 53c of the indoor units 5a to 5c. The gas pipe 9 has one end connected to the closing valve 26 of the outdoor unit 2 and the other end branched to be connected to the gas pipe connecting portions 54a to 54c of the indoor units 5a to 5c. The refrigerant circuit 100 of the air conditioner 1 is configured as described above.

  First, the outdoor unit 2 will be described. The outdoor unit 2 includes a compressor 21, a four-way valve 22, an outdoor heat exchanger 23, an outdoor expansion valve 24, a closing valve 25 to which one end of the liquid pipe 8 is connected, and one end of the gas pipe 9. A closing valve 26, an outdoor fan 27, and an accumulator 28 are provided. These devices other than the outdoor fan 27 are connected to each other through refrigerant pipes described in detail below to constitute an outdoor unit refrigerant circuit 20 that forms part of the refrigerant circuit 100.

  The compressor 21 is a variable capacity compressor that can vary its operating capacity by being driven by a motor (not shown) whose rotation speed is controlled by an inverter. The refrigerant discharge side of the compressor 21 is connected to a port a of a later-described four-way valve 22 and a discharge pipe 41, and the refrigerant suction side of the compressor 21 is connected to the refrigerant outflow side of the accumulator 28 through a suction pipe 42. Has been.

  The four-way valve 22 is a valve for switching the direction in which the refrigerant flows, and includes four ports a, b, c, and d. The port a is connected to the refrigerant discharge side of the compressor 21 by the discharge pipe 41 as described above. The port b is connected to one refrigerant inlet / outlet of the outdoor heat exchanger 23 by a refrigerant pipe 43. The port c is connected to the refrigerant inflow side of the accumulator 28 by a refrigerant pipe 46. The port d is connected to the closing valve 26 by an outdoor unit gas pipe 45.

  The outdoor heat exchanger 23 exchanges heat between the refrigerant and outside air taken into the outdoor unit 2 by rotation of an outdoor fan 27 described later. As described above, one refrigerant inlet / outlet of the outdoor heat exchanger 23 is connected to the port b of the four-way valve 22 by the refrigerant pipe 43, and the other refrigerant inlet / outlet is connected to the closing valve 25 by the outdoor unit liquid pipe 44.

  The outdoor expansion valve 24 is provided in the outdoor unit liquid pipe 44. The outdoor expansion valve 24 is an electronic expansion valve, and the amount of refrigerant flowing into the outdoor heat exchanger 23 or the amount of refrigerant flowing out of the outdoor heat exchanger 23 is adjusted by adjusting the opening thereof.

  The outdoor fan 27 is formed of a resin material and is disposed in the vicinity of the outdoor heat exchanger 23. The outdoor fan 27 is rotated by a fan motor (not shown) to take outside air from a suction port (not shown) into the outdoor unit 2, and the outdoor air heat exchanged with the refrigerant in the outdoor heat exchanger 23 is sent from the blower outlet (not shown) to the outdoor unit 2. To the outside.

  As described above, the accumulator 28 has the refrigerant inflow side connected to the port c of the four-way valve 22 and the refrigerant pipe 46, and the refrigerant outflow side is connected to the refrigerant intake side of the compressor 21 through the intake pipe 42. The accumulator 28 separates the refrigerant flowing into the accumulator 28 from the refrigerant pipe 46 into a gas refrigerant and a liquid refrigerant, and causes the compressor 21 to suck only the gas refrigerant.

  In addition to the configuration described above, the outdoor unit 2 is provided with various sensors. As shown in FIG. 1A, the discharge pipe 41 includes a discharge pressure sensor 31 that detects a discharge pressure that is a pressure of the refrigerant discharged from the compressor 21, and a temperature of the refrigerant discharged from the compressor 21. A discharge temperature sensor 33 for detecting a certain discharge temperature is provided. Near the refrigerant inlet of the accumulator 28 in the refrigerant pipe 46, a suction pressure sensor 32 that detects the pressure of the refrigerant sucked into the compressor 21 and a suction temperature sensor 34 that detects the temperature of the refrigerant sucked into the compressor 21. And are provided.

  Between the outdoor heat exchanger 23 and the outdoor expansion valve 24 in the outdoor unit liquid pipe 44, the temperature of the refrigerant flowing into the outdoor heat exchanger 23 or the temperature of the refrigerant flowing out of the outdoor heat exchanger 23 is detected. A heat exchanger temperature sensor 35 is provided. An outdoor air temperature sensor 36 that detects the temperature of the outside air flowing into the outdoor unit 2, that is, the outside air temperature, is provided in the vicinity of a suction port (not shown) of the outdoor unit 2. A shell temperature sensor 37 that detects the shell temperature of the compressor 21 is provided on the surface of a sealed container (not shown) of the compressor 21. The shell temperature sensor 37 is disposed on the surface of the hermetic container corresponding to the position of a compression chamber (not shown) stored inside the hermetic container of the compressor 21.

  The outdoor unit 2 includes an outdoor unit control means 200. The outdoor unit control means 200 is mounted on a control board stored in an electrical component box (not shown) of the outdoor unit 2. As shown in FIG. 1B, the outdoor unit control means 200 includes a CPU 210, a storage unit 220, a communication unit 230, and a sensor input unit 240.

  The storage unit 220 includes a ROM and a RAM, and stores a control program for the outdoor unit 2, detection values corresponding to detection signals from various sensors, control states of the compressor 21 and the outdoor fan 27, and the like. The communication unit 230 is an interface that performs communication with the indoor units 5a to 5c. The sensor input unit 240 captures detection results from various sensors of the outdoor unit 2 and outputs them to the CPU 210.

  CPU210 takes in the detection result in each sensor of outdoor unit 2 mentioned above via sensor input part 240. FIG. In addition, the CPU 210 takes in control signals transmitted from the indoor units 5 a to 5 c via the communication unit 230. The CPU 210 performs drive control of the compressor 21 and the outdoor fan 27 based on the detection results and control signals taken in. In addition, the CPU 210 performs switching control of the four-way valve 22 based on the detection results and control signals taken in. Furthermore, the CPU 210 adjusts the opening degree of the outdoor expansion valve 24 based on the acquired detection result and control signal.

  Next, the three indoor units 5a to 5c will be described. The three indoor units 5a to 5c are branched into indoor heat exchangers 51a to 51c, indoor expansion valves 52a to 52c, and liquid pipe connection portions 53a to 53c to which the other ends of the branched liquid pipes 8 are connected. Gas pipe connection parts 54a to 54c to which the other end of the gas pipe 9 is connected and indoor fans 55a to 55c are provided. And these each apparatus except indoor fan 55a-55c is mutually connected by each refrigerant | coolant piping explained in full detail below, and comprises the indoor unit refrigerant circuit 50a-50c which makes a part of refrigerant circuit 100. FIG.

  In addition, since the structure of all the indoor units 5a-5c is the same, in the following description, only the structure of the indoor unit 5a is demonstrated and description is abbreviate | omitted about the other indoor units 5b and 5c. Moreover, in FIG. 1, what changed the end of the number provided to the component apparatus of the indoor unit 5a from a to b and c becomes the component apparatus of the indoor units 5b and 5c corresponding to the component apparatus of the outdoor unit 5a. .

  The indoor heat exchanger 51a exchanges heat between indoor air taken into the indoor unit 5a from a suction port (not shown) by rotation of a refrigerant and an indoor fan 55a described later, and one refrigerant inlet / outlet is a liquid pipe connection portion. 53a is connected to the indoor unit liquid pipe 71a, and the other refrigerant inlet / outlet port is connected to the gas pipe connecting part 54a and the indoor unit gas pipe 72a. The indoor heat exchanger 51a functions as an evaporator when the indoor unit 5a performs a cooling operation, and functions as a condenser when the indoor unit 5a performs a heating operation. Each refrigerant pipe is connected to the liquid pipe connecting portion 53a and the gas pipe connecting portion 54a by welding, a flare nut or the like.

  The indoor expansion valve 52a is provided in the indoor unit liquid pipe 71a. The indoor expansion valve 52a is an electronic expansion valve, and when the indoor heat exchanger 51a functions as an evaporator, that is, when the indoor unit 5a performs a cooling operation, the opening degree of the indoor expansion valve 52a depends on the refrigerant outlet (gas gas) of the indoor heat exchanger 51a. The refrigerant superheat degree at the pipe connecting portion 54a side) is adjusted to be the target refrigerant superheat degree. Further, when the indoor heat exchanger 51a functions as a condenser, that is, when the indoor unit 5a performs a heating operation, the opening of the indoor expansion valve 52a is the refrigerant outlet (liquid pipe connection portion) of the indoor heat exchanger 51a. 53a side) is adjusted so that the refrigerant subcooling degree becomes the target refrigerant subcooling degree. Here, the target refrigerant superheating degree and the target refrigerant supercooling degree are values for exhibiting sufficient heating capacity or cooling capacity in the indoor unit 5a.

  The indoor fan 55a is formed of a resin material and is disposed in the vicinity of the indoor heat exchanger 51a. The indoor fan 55a is rotated by a fan motor (not shown) to take indoor air from the suction port (not shown) into the indoor unit 5a, and the indoor air exchanged with the refrigerant in the indoor heat exchanger 51a from the blower outlet (not shown). Supply indoors.

  In addition to the configuration described above, the indoor unit 5a is provided with various sensors. Between the indoor heat exchanger 51a and the indoor expansion valve 52a in the indoor unit liquid pipe 71a, a liquid side temperature sensor 61a for detecting the temperature of the refrigerant flowing into or out of the indoor heat exchanger 51a is provided. It has been. The indoor unit gas pipe 72a is provided with a gas side temperature sensor 62a that detects the temperature of the refrigerant flowing out of the indoor heat exchanger 51a or flowing into the indoor heat exchanger 51a. Near the suction port (not shown) of the indoor unit 5a, an indoor temperature sensor 63a for detecting the temperature of the indoor air flowing into the indoor unit 5a, that is, the indoor temperature is provided.

  The indoor unit 5a includes an indoor unit control means 500a. The indoor unit control means 500a is mounted on a control board stored in an electrical component box (not shown) of the indoor unit 5a. As shown in FIG. 1B, a CPU 510a, a storage unit 520a, a communication unit 530a, The sensor input unit 540a is provided.

  The storage unit 520a includes a ROM and a RAM, and stores a control program for the indoor unit 5a, detection values corresponding to detection signals from various sensors, setting information regarding air conditioning operation by the user, and the like. The communication unit 530a is an interface that communicates with the outdoor unit 2 and the other indoor units 5b and 5c. The sensor input unit 540a captures detection results from various sensors of the indoor unit 5a and outputs them to the CPU 510a.

  The CPU 510a takes in the detection result of each sensor of the indoor unit 5a described above via the sensor input unit 540a. Further, the CPU 510a takes in a signal including operation information set by operating a remote controller (not shown), a timer operation setting, and the like via a remote control light receiving unit (not shown). Further, the CPU 510a transmits a control signal including an operation start / stop signal and operation information (set temperature, indoor temperature, etc.) to the outdoor unit 2 via the communication unit 530a, and discharge pressure detected by the outdoor unit 2. A control signal including such information is received from the outdoor unit 2 via the communication unit 530a. The CPU 510a performs the opening degree adjustment of the indoor expansion valve 52a and the drive control of the indoor fan 55a based on the acquired detection result and the signal transmitted from the remote controller and the outdoor unit 2.

  Next, the flow of the refrigerant and the operation of each part in the refrigerant circuit 100 during the air conditioning operation of the air-conditioning apparatus 1 in the present embodiment will be described with reference to FIG. In the following description, the case where the indoor units 5a to 5c perform the heating operation will be described, and the detailed description will be omitted when the cooling operation or the defrosting operation is performed. Moreover, the arrow in FIG. 1 (A) has shown the flow of the refrigerant | coolant at the time of heating operation.

  As shown in FIG. 1A, when the indoor units 5a to 5c perform the heating operation, the CPU 210 of the outdoor unit control means 200 is in a state where the four-way valve 22 is indicated by a solid line, that is, the port a and the port of the four-way valve 22 Switching is performed so that d communicates and port b and port c communicate. Thereby, the refrigerant circuit 100 becomes a heating cycle in which the outdoor heat exchanger 23 functions as an evaporator and the indoor heat exchangers 51a to 51c function as condensers.

  The high-pressure refrigerant discharged from the compressor 21 flows through the discharge pipe 41 and flows into the four-way valve 22, and from the four-way valve 22 to the outdoor unit gas pipe 45, the closing valve 26, the gas pipe 9, and the gas pipe connection portions 54 a to 54 c. In this order and flow into the indoor units 5a to 5c. The refrigerant that has flowed into the indoor units 5a to 5c flows through the indoor unit gas pipes 72a to 72c, flows into the indoor heat exchangers 51a to 51c, and is taken into the indoor units 5a to 5c by the rotation of the indoor fans 55a to 55c. Heat exchanges with room air and condenses. As described above, the indoor heat exchangers 51a to 51c function as condensers, and the indoor air that has exchanged heat with the refrigerant in the indoor heat exchangers 51a to 51c is blown into the room from a blowout port (not shown), thereby The room where the machines 5a to 5c are installed is heated.

  The refrigerant flowing out of the indoor heat exchangers 51a to 51c flows through the indoor unit liquid pipes 71a to 71c, passes through the indoor expansion valves 52a to 52c, and is decompressed. The decompressed refrigerant flows through the indoor unit liquid pipes 71 a to 71 c and the liquid pipe connection portions 53 a to 53 c and flows into the liquid pipe 8.

  The refrigerant flowing through the liquid pipe 8 flows into the outdoor unit 2 through the closing valve 25. The refrigerant flowing into the outdoor unit 2 flows through the outdoor unit liquid pipe 44 and is further decompressed when passing through the outdoor expansion valve 24. The refrigerant flowing into the outdoor heat exchanger 23 from the outdoor unit liquid pipe 44 evaporates by exchanging heat with the outside air taken into the outdoor unit 2 by the rotation of the outdoor fan 27. The refrigerant flowing out of the outdoor heat exchanger 23 flows in the order of the refrigerant pipe 43, the four-way valve 22, the refrigerant pipe 46, the accumulator 28, and the suction pipe 42, and is sucked into the compressor 21 and compressed again.

  When the indoor units 5a to 5c perform the cooling operation or the defrosting operation, the CPU 210 indicates that the four-way valve 22 is indicated by a broken line, that is, the port a and the port b of the four-way valve 22 communicate with each other. And so that port d communicates. Thereby, the refrigerant circuit 100 becomes a cooling cycle in which the outdoor heat exchanger 23 functions as a condenser and the indoor heat exchangers 51a to 51c function as evaporators.

  Next, temperature protection control executed by the air conditioner 1 of the present embodiment will be described in detail with reference to FIGS. 1 to 3. Here, the temperature protection control means that the discharge temperature (unit: ° C., hereinafter referred to as discharge temperature Td) of the compressor 21 detected by the discharge temperature sensor 33 is a predetermined discharge temperature of the compressor 21. The compressor 21 has a predetermined shell temperature (unit: ° C., hereinafter referred to as a shell temperature Tc) which is the temperature of the compressor 21 detected by the shell temperature sensor 37 so as not to exceed the upper limit. The rotational speed of the compressor 21 is controlled so as not to exceed the upper limit value of the shell temperature.

  In the above-described temperature protection control, the reason why the shell temperature Tc is controlled in addition to the discharge temperature Td is as follows. For example, when the compressor 21 continues to be driven when the outdoor expansion valve 24 is fully closed, such as when performing a pump-down operation for collecting refrigerant in the outdoor unit 2 or when the outdoor expansion valve 24 is broken, the compressor 21 The amount of refrigerant sucked into 21 decreases and the amount of refrigerant discharged from the compressor 21 also decreases. When this state continues, the refrigerant is not discharged from the compressor 21. In such a state, since there is no refrigerant flowing through the discharge pipe 41, the discharge temperature Td decreases.

  On the other hand, the compressor 21 is in a state where there is no refrigerant or very little refrigerant to be compressed. Therefore, a mechanism portion (not shown) of the compressor 21 is not cooled and the shell temperature Tc rises and exceeds the upper limit value. May be damaged. Therefore, by setting the shell temperature Tc in the temperature protection control as well, it is possible to prevent the compressor 21 from being damaged by suppressing the excessive increase in the shell temperature Tc caused by the decrease in the intake refrigerant described above.

  The rotational speed control of the compressor 21 is executed according to the compressor temperature-rotational speed correlation diagram 300 shown in FIG. The compressor temperature-rotational speed correlation diagram 300 is stored in the storage unit 220 of the outdoor unit control means 200 after performing a test or the like in advance. The discharge temperature Td and the shell temperature Tc correspond to the compressor temperature of the present invention, and the discharge temperature sensor 33 and the shell temperature sensor 37 are the compressor temperature detecting means of the present invention.

  In the compressor temperature-rotational speed correlation diagram 300, the discharge temperature Td is between 80 ° C. and 120 ° C., and the shell temperature Tc is between 85 ° C. and 130 ° C., and is divided into a plurality of temperature zones. A control mode of the rotation speed of the compressor 21 is assigned. Further, when at least one of the discharge temperature Td and the shell temperature Tc is rising in order to prevent hunting of the rotational speed control of the compressor 21 (hereinafter, sometimes simply referred to as “temperature rise”). When the discharge temperature Td and the shell temperature Tc are lowered (hereinafter, sometimes simply described as “temperature drop”), the temperature ranges to be provided and the control modes assigned to the respective temperature zones are different.

  In the compressor temperature-rotational speed correlation diagram 300, a discharge temperature that is a boundary between a temperature range to which normal control is assigned when the temperature rises and a temperature range to which rotational speed holding control that is one of temperature protection controls to be described later is assigned. Td (= 105 ° C.) and shell temperature Tc (110 ° C.) are the first temperatures. If one of the discharge temperature Td and the shell temperature Tc becomes equal to or higher than the first temperature when the temperature rises, the normal control is switched to the temperature protection control.

  Further, the discharge temperature Td (= 80 ° C.) and the shell temperature which are the boundary between the temperature range to which the rotation speed increase control, which is one of the temperature protection controls to be described later, is assigned when the temperature drops and the temperature range to which the normal control is assigned. Tc (85 ° C.) is the fifth temperature. If the discharge temperature Td and the shell temperature Tc are lower than the temperature protection control end temperature when the temperature is lowered, the temperature protection control is switched to the normal control.

  Further, at any time of temperature rise / temperature drop, the highest temperature (120 if the discharge temperature is Td) in the temperature range to which the rotation speed reduction control, which is one of the temperature protection controls described later, is assigned. The second temperature which is a predetermined temperature (for example, 5 ° C.) lower than the upper limit value of the discharge temperature Td of the compressor 21 and the upper limit value of the shell temperature Tc. Temperature. When the discharge temperature Td or the shell temperature Tc is equal to or higher than the second temperature, protection stop control is assigned as the control mode of the compressor 21. In the protection stop control, the operation of the compressor 21 is stopped so that the discharge temperature Td and the shell temperature Tc do not exceed the respective upper limit temperatures.

  The first temperature, the second temperature, and the fifth temperature described above are temperatures determined in advance by performing a test or the like. The increase / decrease in the discharge temperature Td and the shell temperature Tc is determined by comparing the discharge temperature Td and the shell temperature Tc that are taken in periodically in time series.

  First, the temperature zone and the control mode when the temperature rises in the compressor temperature-rotational speed correlation diagram 300 will be described. When the discharge temperature Td and the shell temperature Tc are lower than the respective first temperatures, that is, when the discharge temperature Td is lower than 105 ° C. and the shell temperature Tc is lower than 110 ° C., normal control is assigned as the control mode of the compressor 21. It has been. In the normal control, the compressor 21 is driven and controlled at a rotational speed corresponding to the air conditioning capability required by the indoor units 5a to 5c. If the discharge temperature Td and the shell temperature Tc are lower than the respective first temperatures when the temperature rises, it is unlikely that the discharge temperature Td or the shell temperature Tc is higher than the respective second temperature, so the temperature protection control is performed. Normal control is performed.

  The case where the discharge temperature Td and the shell temperature Tc rise and the discharge temperature Td or the shell temperature Tc becomes equal to or higher than the first temperature is as follows. First, the discharge temperature Td is a temperature range of 105 ° C. or more and less than 110 ° C., and the shell temperature Tc is a temperature range of 110 ° C. or more and less than 115 ° C., which is a second temperature range. As a control mode 21, rotation speed holding control is assigned. In the rotation speed holding control, the rotation speed of the compressor 21 is held at the current rotation speed (the rotation speed is not changed). If the discharge temperature Td or the shell temperature Tc rises to the respective second temperature zone when the temperature rises, the discharge temperature Td or the shell temperature Tc is equal to or higher than the respective second temperature as compared with the case where each is less than the first temperature. Is likely to be. For this reason, in this case, switching from normal control to temperature protection control is performed, and the rotation speed holding control is performed to hold the rotation speed of the compressor 21 at the current rotation speed, thereby increasing the discharge temperature Td and the shell temperature Tc. Suppress.

  Next, a temperature range of 110 ° C. or higher and lower than 115 ° C. is set as the discharge temperature Td, and a temperature range of 115 ° C. or higher and lower than 120 ° C. is set as the first temperature range. In the first temperature range, either the rotation speed holding control or the rotation speed lowering control described below is selected and executed. The method of selecting the rotation speed holding control or the rotation speed reduction control, and the reason and effect thereof will be described in detail later.

  Next, a temperature range of 115 ° C. or higher and lower than 120 ° C. is set for the discharge temperature Td, and a temperature range of 120 ° C. or higher and lower than 130 ° C. is set for the shell temperature Tc. The rotation speed reduction control is assigned as a control mode of the machine 21. In the rotational speed reduction control, the rotational speed of the compressor 21 is decreased at a predetermined rate. For example, a predetermined rotational speed Arps (for example, 6 rps) is subtracted from the current rotational speed every predetermined time (for example, every 30 seconds). Rotational speed. If the discharge temperature Td or the shell temperature Tc rises to the third temperature zone when the temperature rises, the possibility that the discharge temperature Td or the shell temperature Tc will be equal to or higher than the second temperature becomes very high. For this reason, in this case, the rotational speed reduction control is performed to reduce the rotational speed of the compressor 21, thereby stopping the discharge temperature Td and the shell temperature Tc from rising, and reducing the discharge temperature Td and the shell temperature Tc.

  Next, the temperature zone and the control mode at the time of temperature reduction in the compressor temperature-rotational speed correlation diagram 300 will be described. The discharge temperature Td is a temperature range of 115 ° C. or more and less than 120 ° C., and the shell temperature Tc is a temperature range of 120 ° C. or more and less than 130 ° C., which is a fourth temperature range. As the control mode, the same rotation speed reduction control as that at the time of temperature rise is assigned. By reducing the rotational speed of the compressor 21 by performing the rotational speed reduction control, the discharge temperature Td and the shell temperature Tc are prevented from rising again.

  Next, the discharge temperature Td is a temperature range of 105 ° C. or more and less than 115 ° C., and the shell temperature Tc is a temperature range of 110 ° C. or more and less than 120 ° C., which is a fifth temperature range. As the control mode of the machine 21, the same rotation speed holding control as that at the time of temperature rise is assigned. By maintaining the rotation speed of the compressor 21 at the current rotation speed by performing the rotation speed holding control, the discharge temperature Td and the shell temperature Tc are necessary while preventing the discharge temperature Td and the shell temperature Tc from rising again. It suppresses that the air-conditioning capability exhibited by indoor unit 5a-5c falls by the above and falls.

  Next, the discharge temperature Td is a temperature zone of 80 ° C. or more and less than 105 ° C., and the shell temperature Tc is a temperature zone of 85 ° C. or more and less than 1110 ° C., which is a sixth temperature zone. Rotational speed increase control is assigned as a control mode of the machine 21. In the rotation speed increase control, the rotation speed of the compressor 21 is increased at a predetermined rate. For example, a predetermined rotation speed Brps (for example, 1 rps) is set to the current rotation speed every predetermined time (for example, every 30 seconds). The added number of rotations. When the discharge temperature Td and the shell temperature Tc are lowered to the temperature range, it is considered that the rotational speed of the compressor 21 is greatly reduced by the respective controls so far. There is a possibility that the air conditioning capability exhibited by the indoor units 5a to 5c is reduced due to the decrease.

  However, if the rotational speed of the compressor 21 is suddenly increased to increase the air conditioning capacity here, the discharge temperature Td and the shell temperature Tc rapidly increase again in the indoor units 5a to 5c, and the discharge temperature Td or the shell temperature Tc. May rise to their respective second temperatures. For this reason, the air-conditioning capability exhibited by the indoor units 5a to 5c while suppressing the rapid increase in the discharge temperature Td and the shell temperature Tc by slowly increasing the rotation speed of the compressor 21 by performing the rotation speed increase control. To raise.

  When the discharge temperature Td and the shell temperature Tc are less than the fifth temperature, the same normal control as when the temperature rises is assigned as the control mode of the compressor 21. If the discharge temperature Td or the shell temperature Tc is lowered to the temperature in this temperature range, the possibility that the discharge temperature Td or the shell temperature Tc is higher than the second temperature is considerably reduced. Switching to normal control, the compressor 21 is driven and controlled at a rotational speed corresponding to the air conditioning capacity required for the indoor units 5a to 5c.

  In the description of the compressor temperature-rotational speed correlation diagram described above, when the temperature rises, for example, “the discharge temperature Td or the shell temperature Tc is equal to or higher than the first temperature” is described. The temperature Tc is less than the fifth temperature ”. That is, when either the discharge temperature Td or the shell temperature Tc rises to the temperature of each temperature zone when the temperature rises, the control assigned to the temperature zone is executed, and when the temperature falls, the discharge temperature Td and the shell If both of the temperatures Tc drop to the temperature of each temperature zone, the control assigned to the temperature zone is executed.

  The temperature protection control is performed to prevent both the discharge temperature Td and the shell temperature Tc from exceeding the respective upper limit values. Therefore, when the temperature rises, only one of the discharge temperature Td and the shell temperature Tc exceeds the temperature (first temperature to fourth temperature) defining each temperature zone and rises to the next temperature zone. In addition, the control assigned to the next temperature zone is performed to suppress an increase in the discharge temperature Td and the shell temperature Tc. On the other hand, when the temperature drops, only one of the discharge temperature Td and the shell temperature Tc exceeds the temperature (first temperature, third temperature, fourth temperature, and fifth temperature) that defines each temperature zone, and the next. If the control assigned to the next temperature zone is performed when the temperature falls to the temperature zone, the other temperature may rise again. For this reason, when the temperature drops, both the discharge temperature Td and the shell temperature Tc exceed the temperature (first temperature, third temperature, fourth temperature, and fifth temperature) that define each temperature zone and reach the next temperature zone. When it falls, the control assigned to the next temperature zone is performed.

  Further, when the rotation speed reduction control is performed, the predetermined rotation speed A subtracted from the current rotation speed of the compressor 21 and the predetermined rotation to be added to the current rotation speed of the compressor 21 when the rotation speed increase control is performed. The number B is a value obtained by performing a test or the like in advance and stored in the storage unit 220. The predetermined rotational speed A is a value that has been confirmed to be able to decrease the discharge temperature Td and the shell temperature Tc while minimizing the decrease in air conditioning capability exhibited by the indoor units 5a to 5c. In addition, the predetermined rotation speed B is a value that has been confirmed to be able to increase the air conditioning capability exhibited by the indoor units 5a to 5c while suppressing a rapid increase in the discharge temperature Td and the shell temperature Tc.

  Next, the first temperature zone will be described. As described above, the first temperature zone is a temperature zone of 110 ° C. or higher and lower than 115 ° C. for the discharge temperature Td, and a temperature zone of 115 ° C. or higher and lower than 120 ° C. for the shell temperature Tc. The third temperature (110 ° C. for the discharge temperature Td and 115 ° C. for the shell temperature Tc) and the fourth temperature (115 ° C. for the discharge temperature Td and 120 ° C. for the shell temperature Tc) are also the first temperature described above. Similarly to the second temperature and the fifth temperature, the temperature is determined by performing a test or the like in advance.

  One of the rotation speed holding control and the rotation speed decrease control is assigned to the first temperature zone according to the discharge temperature Td or the shell temperature Tc when the temperature rises. Specifically, at least when one of the discharge temperature Td or the shell temperature Tc rises to the first temperature zone for the first time when the temperature rises and the other does not reach the fourth temperature or higher, the rotational speed Degradation control is assigned. On the other hand, after the rotational speed reduction control is performed once in the first temperature zone, the discharge temperature Td and the shell temperature Tc are both temperatures lower than the fourth temperature, and at least the discharge temperature Td or the shell temperature Tc. When one side remains at the temperature of the first temperature zone, the rotation speed holding control is assigned. Thus, the reason for assigning different control modes in the first temperature range is as follows.

  First, when at least one of the discharge temperature Td and the shell temperature Tc rises to the first temperature zone for the first time when the temperature rises, the rotation speed of the compressor 21 is changed by the rotation speed holding control performed so far. Despite the absence, the discharge temperature Td or the shell temperature Tc is rising.

  Therefore, when at least one of the discharge temperature Td or the shell temperature Tc first rises to the temperature in the first temperature zone and the other is not at the temperature equal to or higher than the fourth temperature, the rotation speed reduction control is executed to perform compression. The rotational speed of the machine 21 is lowered to a rotational speed lower by Arps than the rotational speed at the time of the rotational speed holding control that has been performed. As a result, the discharge temperature Td or the shell temperature Tc rises slowly or stops rising.

  However, the discharge temperature Td that is actually detected by the discharge temperature sensor 33 and the shell temperature Tc that is detected by the shell temperature sensor 37 are decreased with a decrease in the rotational speed of the compressor 21. That is, the discharge temperature Td or shell temperature sensor detected by the discharge temperature sensor 33 immediately after at least one of the discharge temperature Td or the shell temperature Tc first rises to the first temperature zone and decreases the rotation speed of the compressor 21. There is a possibility that the shell temperature Tc detected at 37 is not much different from the previously detected discharge temperature Td and shell temperature Tc.

  In such a case, if the discharge temperature Td and the shell temperature Tc are detected after a while after the rotation speed of the compressor 21 is decreased, the discharge temperature decreased due to the decrease in the rotation speed of the compressor 21. Td and shell temperature Tc can be detected. However, in practice, the discharge temperature Td and the shell temperature Tc are detected at short intervals (for example, 30 seconds), and the control mode selected based on the detected discharge temperature Td and shell temperature Tc is again the rotational speed reduction control. If it exists, the rotation speed of the compressor 21 may be lowered more than necessary, and the air conditioning capability exhibited by the indoor units 5a to 5c may be unnecessarily reduced.

  Therefore, in the air conditioner 1 of the present embodiment, at the time of temperature rise, at least one of the discharge temperature Td or the shell temperature Tc first rises to the temperature of the first temperature zone, and the other is the temperature equal to or higher than the fourth temperature. If not, the rotational speed reduction control is executed. Thereafter, both the discharge temperature Td and the shell temperature Tc are lower than the fourth temperature, and at least one of the discharge temperature Td and the shell temperature Tc is in the first temperature range. When the engine speed remains at, the rotational speed holding control is executed. As long as the discharge temperature Td and the shell temperature Tc are both lower than the fourth temperature and at least one of the discharge temperature Td and the shell temperature Tc remains in the first temperature zone, the rotation is continued. Continue number holding control.

  As described above, by changing the control mode of the compressor 21 in the first temperature zone, at least one of the discharge temperature Td and the shell temperature Tc rises to the first temperature zone for the first time, and the rotational speed of the compressor 21 is increased. It is possible to prevent the rotational speed of the compressor 21 from being lowered more than necessary after the reduction. Thereby, it can suppress that the discharge temperature Td and shell temperature Tc exceed 2nd temperature, and the compressor 21 stops, preventing the unnecessary fall of the air-conditioning capability exhibited by the indoor units 5a-5c.

  Next, the flow of processing when the air-conditioning apparatus 1 of the present embodiment performs temperature protection control will be described using FIG. In FIG. 3, ST represents a step, and the number following this represents a step number. Further, FIG. 3 mainly illustrates the processing related to the present invention, and other processing, for example, control of the refrigerant circuit 100 corresponding to the operating conditions such as the set temperature and the air volume instructed by the user. Description of general processing related to the harmony device 1 is omitted.

  When the air conditioning operation is started, first, the CPU 210 sets both the flag Fa and the flag Fb to 0 (ST1). Here, the flag Fa indicates whether the rotation speed control of the compressor 21 is normal control or temperature protection control. The flag Fa = 0 indicates normal control, and the flag Fa = 1 indicates temperature. Each indicates protection control. If the discharge temperature Td or the shell temperature Tc rises and one of the flags Fa becomes equal to or higher than the first temperature (in this embodiment, the discharge temperature Td is 105 ° C. and the shell temperature Tc is 110 ° C.), the flag Fa = 1, the discharge temperature Td and the shell temperature Tc are lowered, and both the discharge temperature Td and the shell temperature Tc are temperature protection control stop temperatures (in this embodiment, the discharge temperature Tc is 80 ° C. and the shell temperature Tc is 85 ° C.) If it is less than that, the flag Fa = 0 is set.

  Further, the flag Fb indicates that when the temperature rises, either the discharge temperature Td or the shell temperature Tc is in the first temperature range (in this embodiment, the discharge temperature Td is a temperature range of 110 ° C. or higher and lower than 115 ° C., and the shell temperature Tc is 115 In the case of the flag Fb = 0, the flag Fb indicates that the discharge temperature Td and the shell temperature Tc have not risen to the first temperature zone. = 1 indicates that either the discharge temperature Td or the shell temperature Tc has risen to the first temperature zone. The flag Fb is set to flag Fb = 1 when either the discharge temperature Td or the shell temperature Tc rises and rises to the first temperature zone, and the discharge temperature Td or the shell temperature Tc decreases, and the discharge temperature Td and If both shell temperatures Tc are less than the first temperature, flag Fb = 0.

  Next, the CPU 210 takes in the discharge temperature Td and the shell temperature Tc (ST2). The CPU 210 periodically captures the discharge temperature Td detected by the discharge temperature sensor 33 and the shell temperature Tc detected by the shell temperature sensor 37 via the sensor input unit 240 (every 30 seconds). The shell temperature Tc is stored in the storage unit 220 in time series.

  Next, the CPU 210 determines whether or not the fetched discharge temperature Td is less than 105 ° C. and the shell temperature Tc is less than 110 ° C. (ST3). If the discharge temperature Td is less than 105 ° C. and the shell temperature Tc is less than 110 ° C. (ST3-Yes), the CPU 210 sets the flag Fb to 0 (ST4). If the process of ST4 is immediately after the start of operation, the flag Fb is set to 0 in ST1, so the CPU 210 maintains the flag Fb being 0, and the flag Fb is set to 1 in the process of ST13 described later. After that, that is, after either one of the discharge temperature Td or the shell temperature Tc becomes a temperature equal to or higher than the third temperature, the CPU 210 changes the flag Fb from 1 to 0.

  Next, the CPU 210 determines whether or not the flag Fa is 1 (ST5). If the flag Fa is not 1 (ST5-No), the CPU 210 executes normal control (ST6) and returns the process to ST2. If the flag Fa is 1 (ST5-Yes), the CPU 210 determines whether or not the fetched discharge temperature Td is less than 80 ° C. and the shell temperature Tc is less than 85 ° C. (ST7).

  If the discharged discharge temperature Td is less than 80 ° C. and the shell temperature Tc is less than 85 ° C. (ST7-Yes), the CPU 210 sets the flag Fa to 0 (ST8), and proceeds to ST6. If the taken-out discharge temperature Td is not less than 80 ° C. and the shell temperature Tc is not less than 85 ° C. (ST7-Yes), that is, the taken-in discharge temperature Td is 80 ° C. or higher, or the taken-in shell temperature Tc is 85 ° C. or higher. If so, the CPU 210 executes the rotation speed increase control (ST9), and returns the process to ST2.

  In ST3, the discharge temperature Td is not less than 105 ° C. and the shell temperature Tc is not less than 110 ° C. (ST3-No), that is, the taken-in discharge temperature Td is 105 ° C. or higher, or the taken-in shell temperature Tc is 110 ° C. If so, the CPU 210 sets the flag Fa to 1 (ST10), and determines whether the captured discharge temperature Td is 110 ° C. or higher or the captured shell temperature Tc is 115 ° C. or higher (ST11). .

  If the taken-in discharge temperature Td is not higher than 110 ° C. or the taken-in shell temperature Tc is not higher than 115 ° C. (ST11-No), that is, the taken-in discharge temperature Td is lower than 110 ° C. and the shell temperature Tc is lower than 115 ° C. If so, the CPU 210 executes rotation speed holding control (ST12), and proceeds to ST16. If the fetched discharge temperature Td is 110 ° C. or higher or the fetched shell temperature Tc is 115 ° C. or higher (ST11-Yes), the CPU 210 determines whether or not the flag Fb is 1 (ST13).

  If the flag Fb is 1 (ST13-Yes), the CPU 210 advances the process to ST12. If the flag Fb is not 1 (ST13-No), the CPU 210 executes the rotational speed reduction control (ST14), sets the flag Fb to 1 (ST15), and returns the process to ST2.

  After completing the process of ST12, the CPU 210 determines whether or not the fetched discharge temperature Td is 115 ° C. or higher or the fetched shell temperature Tc is 120 ° C. or higher (ST16). If the captured discharge temperature Td is not 115 ° C. or higher or the captured shell temperature Tc is not 120 ° C. or higher (ST16-No), that is, the captured discharge temperature Td is lower than 115 ° C. and the shell temperature Tc is lower than 120 ° C. If so, the CPU 210 returns the process to ST2. If the taken-in discharge temperature Td is 115 ° C. or higher or the taken-in shell temperature Tc is 120 ° C. or higher (ST16-Yes), the CPU 210 executes the rotation speed reduction control (ST17).

  Next, the CPU 210 determines whether or not the fetched discharge temperature Td is 120 ° C. or higher or the fetched shell temperature Tc is 130 ° C. or higher (ST18). If the taken-in discharge temperature Td is not higher than 120 ° C. or the taken-in shell temperature Tc is not higher than 130 ° C. (ST18-No), that is, the taken-in discharge temperature Td is lower than 120 ° C. and the shell temperature Tc is lower than 130 ° C. If so, the CPU 210 returns the process to ST2. If the fetched discharge temperature Td is 120 ° C. or higher or the fetched shell temperature Tc is 130 ° C. or higher (ST18-Yes), the CPU 210 executes protection stop control (ST19) and ends the process.

  As described above, the air-conditioning apparatus 1 according to the present embodiment is configured so that when at least one of these temperatures rises to the first temperature zone for the first time when the discharge temperature Td or the shell temperature Tc rises, the compressor Rotational speed reduction control is performed to reduce the rotational speed of 21. Thereafter, neither the discharge temperature Td nor the shell temperature Tc becomes higher than the fourth temperature, and either one remains at the temperature in the first temperature range. When the engine speed is, the rotation speed holding control for holding the rotation speed of the compressor 21 at the current rotation speed is executed.

  Thereby, it is possible to prevent the rotation speed of the compressor 21 from being lowered more than necessary, and the discharge temperature Td and the shell temperature Tc are set while preventing an unnecessary reduction in the air conditioning capability exhibited by the indoor units 5a to 5c. It can suppress that the compressor 21 stops exceeding 2nd temperature.

  In the embodiment described above, the case where both the discharge temperature Td and the shell temperature Tc are detected and the temperature protection control is performed so that both the discharge temperature Td and the shell temperature Tc do not exceed the second temperature has been described. However, the present invention is not limited to this, and temperature protection control may be performed so that only one of the discharge temperature Td and the shell temperature Tc does not exceed the second temperature.

DESCRIPTION OF SYMBOLS 1 Air conditioning apparatus 2 Outdoor unit 21 Compressor 5a-5c Indoor unit 33 Discharge temperature sensor 37 Shell temperature sensor 5a-5c Indoor unit 100 Refrigerant circuit 200 Outdoor unit control part 210 CPU
220 Storage Unit 240 Sensor Input Unit 300 Compressor Temperature-Rotational Speed Correlation Diagram Td Discharge Temperature Tc Shell Temperature

Claims (4)

A compressor, compressor temperature detecting means for detecting a compressor temperature that changes in accordance with the rotational speed of the compressor, and controlling the compressor based on the compressor temperature detected by the compressor temperature detecting means. An air conditioner having a control means,
The control means includes
When the compressor temperature is rising, if the compressor temperature is equal to or higher than a predetermined first temperature, the compressor temperature is not higher than a predetermined second temperature higher than the first temperature. Further, a temperature including at least a rotation speed holding control for holding the rotation speed of the compressor at a current rotation speed and a rotation speed reduction control for setting the rotation speed of the compressor to a rotation speed by subtracting the rotation speed of the compressor from the current rotation speed at a predetermined ratio To perform protection control,
If the compressor temperature reaches a first temperature zone determined by a third temperature higher than the first temperature and lower than the second temperature, and a fourth temperature higher than the third temperature and lower than the second temperature, Performing the rotational speed reduction control,
Thereafter, if the compressor temperature remains in the first temperature zone, the rotation speed holding control is executed.
An air conditioner characterized by that. The control means includes
When the compressor temperature reaches a second temperature range determined by the first temperature and the third temperature, the rotation speed holding control is executed.
The air conditioner according to claim 1. The control means includes
If the compressor temperature reaches a third temperature range determined by the second temperature and the fourth temperature, the rotational speed reduction control is executed.
The air conditioner according to claim 1. The compressor temperature includes at least one of a discharge temperature that is a temperature of refrigerant discharged from the compressor, or a shell temperature that is a temperature of a sealed container of the compressor,
If at least one of the discharge temperature or the shell temperature rises to reach the first temperature zone and the other is not equal to or higher than the fourth temperature, the rotation speed reduction control is executed. And
Thereafter, if the discharge temperature and the shell temperature are lower than the fourth temperature, and either the discharge temperature or the shell temperature remains in the first temperature range, the rotation speed holding control is executed. To
The air conditioner according to any one of claims 1 to 3, wherein

Images