AIR CONDITIONER
In a case where a concentration of refrigeration oil detected by the concentration sensor is less than a first threshold value, the control device operates the heater such that a part of a refrigerant in a liquid state in the compressor is vaporized, and in a case where the concentration of the refrigeration oil detected by the concentration sensor exceeds a second threshold value greater than the first threshold value and a temperature of the refrigeration oil detected by the temperature sensor is less than a specified temperature, the control device operates the heater such that the refrigerant in the liquid state in the compressor is vaporized and the temperature of the refrigeration oil in the compressor is increased.
The present disclosure relates to an air conditioner.
BACKGROUND ARTAn air conditioner includes a compressor that discharges a high-temperature and high-pressure refrigerant to a refrigerant circuit. The compressor is filled with refrigeration oil for maintaining lubricity of a drive unit such as a motor. As a temperature of the refrigeration oil is decreased, viscosity of the refrigeration oil is increased.
When the viscosity of the refrigeration oil is increased, driving torque of the compressor is increased, and a current value of the motor may become excessive. PTL 1 discloses a technique of heating the refrigeration oil until the temperature of the refrigeration oil reaches the pour point in a case where the temperature of the refrigeration oil is lower than the pour point, for the purpose of maintaining appropriate viscosity of the refrigeration oil. Here, a temperature at which a liquid does not flow at all is referred to as solidification point, and a temperature immediately before the solidification point is referred to as pour point.
CITATION LIST Patent Literature
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- PTL 1: WO 2018/138796
The refrigeration oil may be present in the compressor in a state of a mixture of the refrigeration oil and the refrigerant in a liquid state. As the amount of the refrigerant in the liquid state in the compressor is increased, a concentration of the refrigeration oil is decreased. In a constant temperature environment, the viscosity of the mixture is decreased as the concentration of the refrigeration oil is decreased. Therefore, even in a case where the temperature of the refrigeration oil is sufficiently high, in a case where the concentration of the refrigeration oil is too low, the refrigeration oil may not exhibit a function as a lubricant. In addition, even when the concentration of the refrigeration oil is not low, in a case where the temperature of the refrigeration oil is too low, the viscosity of the refrigeration oil is increased, which may abnormally increase the driving torque of the motor of the compressor.
Therefore, the necessity of heating the refrigeration oil should be determined in consideration of not only the temperature of the refrigeration oil but also the concentration of the refrigeration oil.
The technique in the related art decides the necessity of heating the refrigeration oil by using the temperature of the refrigeration oil as an index. However, the technique in the related art does not consider the concentration of the refrigeration oil. Therefore, according to the technique in the related art, even when the concentration and temperature of the refrigeration oil are in a range in which the refrigeration oil can exhibit a lubricating function in the compressor, the refrigeration oil is unnecessarily heated in a case where the temperature of the refrigeration oil does not reach the pour point.
Moreover, in the technique in the related art, in a case where the temperature of the refrigeration oil does not reach the pour point, a heating operation is continued until the temperature of the refrigeration oil reaches the pour point. In order to increase the temperature of the refrigeration oil by heating the refrigeration oil mixed with the refrigerant in the liquid state, it is necessary to vaporize the refrigerant having a lower boiling point out of the refrigeration oil and the refrigerant first. Therefore, in the technique in the related art, power for heating is excessively consumed.
The present disclosure has been made to solve such a problem, and an object of the present disclosure is to provide an air conditioner capable of appropriately maintaining lubricating performance of refrigeration oil in a compressor in consideration of a temperature and a concentration of the refrigeration oil.
Solution to ProblemThe present disclosure relates to an air conditioner. The air conditioner includes a compressor; a first heat exchanger; a second heat exchanger; a decompression device; a circulation path through which a refrigerant circulates through the compressor, the first heat exchanger, the decompression device, and the second heat exchanger in this order; a temperature sensor to detect a temperature of refrigeration oil in the compressor; a concentration sensor to detect a concentration of the refrigeration oil in a mixture of the refrigerant in a liquid state and the refrigeration oil in the compressor; a heater to heat the refrigeration oil in the compressor; and a control device. In a case where a concentration of refrigeration oil detected by the concentration sensor is less than a first threshold value, the control device operates the heater such that a part of a refrigerant in a liquid state in the compressor is vaporized, and in a case where the concentration of the refrigeration oil detected by the concentration sensor exceeds a second threshold value greater than the first threshold value and a temperature of the refrigeration oil detected by the temperature sensor is less than a specified temperature, the control device operates the heater such that the refrigerant in the liquid state in the compressor is vaporized and the temperature of the refrigeration oil in the compressor is increased.
Advantageous Effects of InventionAccording to an air conditioner of the present disclosure, it is possible to provide an air conditioner capable of appropriately maintaining lubricating performance of the refrigeration oil in the compressor in consideration of the temperature and the concentration of the refrigeration oil.
Hereinafter, embodiments of the present disclosure will be described in detail with reference to the drawings. Hereinafter, a plurality of embodiments will be described, but it is planned from the beginning of the application to appropriately combine the configurations described in each embodiment. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and the description thereof will not be repeated.
First EmbodimentFirst heat exchanger 2 is located on a high pressure side in the refrigerant circuit. Therefore, first heat exchanger 2 functions as a condenser. Second heat exchanger 4 is located on a low pressure side in the refrigerant circuit. Therefore, second heat exchanger 4 functions as an evaporator. For example, by disposing first heat exchanger 2 indoors and disposing second heat exchanger 4 outdoors, air conditioner 100 functions as a heating unit that warms an indoor space. Air conditioner 100 may be provided with a switching valve that switches a discharge destination of the refrigerant from compressor 1 between first heat exchanger 2 and second heat exchanger 4.
The refrigeration oil is sealed in compressor 1. The refrigeration oil functions as a lubricant for a drive unit such as a motor in compressor 1. Compressor 1 is provided with a temperature sensor 50, a concentration sensor 51, and a heater 60. Temperature sensor 50 detects the temperature of the refrigeration oil in compressor 1, and transmits a detection value to control device 70. Concentration sensor 51 detects the concentration of the refrigeration oil in compressor 1, and transmits a detection value to control device 70. Heater 60 heats the refrigeration oil in compressor 1.
Temperature sensor 50 may be provided at any position in compressor 1 as long as the temperature of the refrigeration oil in compressor 1 can be detected at the position. Similarly, concentration sensor 51 may be provided at any position in compressor 1 as long as the concentration of the refrigeration oil in compressor 1 can be detected at the position.
Control device 70 includes a processor 71 and a memory 72. Memory 72 includes a read only memory (ROM) and a random access memory (RAM). Processor 71 develops a program stored in the ROM in the RAM or the like, and executes the program. The program stored in the ROM is a program in which a processing procedure of control device 70 is described.
Control device 70 controls each device of air conditioner 100 according to the program stored in memory 72. For example, control device 70 controls compressor 1, decompression device 3, and heater 60. As a result, the frequency at which compressor 1 is operated, the opening degree of a valve of decompression device 3, the timing of the operation of heater 60, and the like are adjusted.
In some cases, a refrigerant in a liquid state is present in compressor 1. For example, in a case where a part of the refrigerant returning from second heat exchanger 4 to compressor 1 is sucked into compressor 1 in a liquid state without being vaporized, or in a case where the temperature of the refrigerant in compressor 1 is decreased while the operation of air conditioner 100 is stopped, the refrigerant in the liquid state is generated in compressor 1.
The refrigerant in the liquid state and the refrigeration oil are mixed in compressor 1 according to the condition such as a temperature. At this time, a target of which the temperature is detected by temperature sensor 50 is more strictly a mixture of the refrigerant in the liquid state and the refrigeration oil. The target heated by heater 60 is more strictly a mixture thereof. The concentration detected by concentration sensor 51 corresponds to a proportion of the refrigeration oil included in the mixture.
That is, concentration sensor 51 detects a component ratio between the refrigeration oil and the refrigerant in the liquid state in compressor 1. In other words, the detection value of concentration sensor 51 is an index indicating how much the refrigeration oil is diluted by the refrigerant. Concentration sensor 51 is, for example, a capacitive sensor that detects the relative permittivity of the refrigeration oil to obtain the component ratio. Heater 60 is, for example, a heating winding.
The amount of the refrigerant in the liquid state in compressor 1 is changed depending on the operation status of air conditioner 100. A part of the refrigeration oil in compressor 1 is discharged to the refrigerant circuit together with the refrigerant discharged from compressor 1. Therefore, the concentration of the refrigeration oil in compressor 1 is not constant. The viscosity of the refrigeration oil in compressor 1 is changed depending on the temperature of the refrigeration oil.
In a case where the viscosity of the refrigeration oil is too high, the driving torque of the motor in compressor 1 is abnormally increased, and the current value of the motor is excessively increased. As a result, an overcurrent may flow in the motor. Further, the supply of the refrigeration oil to bearings and the like of compressor 1 becomes insufficient. In addition, in a case where the concentration of the refrigeration oil is too low, the refrigeration oil cannot exhibit a function as a lubricant, and lubrication failure occurs in compressor 1. Therefore, in order to cause the refrigeration oil to exhibit a function as a lubricant, it is important to control the concentration and the temperature of the refrigeration oil.
For example, when the temperature of the refrigeration oil in compressor 1 continues to be decreased, the temperature eventually reaches the solidification point at which the refrigeration oil does not flow. In the present specification, the temperature higher than the solidification point of the refrigeration oil and immediately before the solidification point is referred to as pour point.
In a case where the temperature of the refrigeration oil detected by temperature sensor 50 is lower than the pour point, it is conceivable to operate heater 60 until the temperature of the refrigeration oil becomes greater than or equal to the pour point. As a result, the fluidity of the refrigeration oil can be enhanced. However, the refrigeration oil may be present in compressor 1 in a state of being diluted to an appropriate concentration by the refrigerant in the liquid state.
Even in a case where the temperature detected by temperature sensor 50 is lower than the pour point, the refrigeration oil diffused in the mixture may function as a lubricant depending on the concentration of the refrigeration oil. Of course, in a case where the concentration of the refrigeration oil is too low, it is necessary to operate heater 60 in order to cause the refrigeration oil to exhibit a function as a lubricant.
However, in this case, it is sufficient to increase the concentration of the refrigeration oil until the refrigeration oil diluted by the refrigerant in the liquid state functions as a lubricant. In other words, it is not necessary to operate heater 60 until all of the refrigerant in the liquid state in the mixture is vaporized and further the temperature of the refrigeration oil is increased.
On the other hand, in a case where the temperature detected by temperature sensor 50 is less than the pour point of the refrigeration oil in a state where the concentration of the refrigeration oil is too high, it is necessary to increase the fluidity of the refrigeration oil by increasing the temperature of the refrigeration oil. In this case, it is necessary to operate heater 60 until all of the refrigerant in the liquid state included in the mixture is vaporized and further the temperature of the refrigeration oil is increased.
Control device 70 determines a state of the refrigeration oil in compressor 1 on the basis of the detection values of temperature sensor 50 and concentration sensor 51, and operates heater 60 appropriately.
In
Appropriate values of Tp, X1, and X2 are selected by the designer in consideration of the types of the refrigeration oil and the refrigerant, the structure of compressor 1, and the like. These values are stored in memory 72 of control device 70. Note that “1” on the vertical axis means that the concentration of the refrigeration oil is 100%, that is, there is no refrigerant in the liquid state diluting the refrigeration oil in compressor 1.
As illustrated in
(1) of
In a case where the position of coordinates (Toil, αoil) specified by temperature Toil and concentration αoil belongs to region (1) or region (2), control device 70 operates heater 60 such that a part of the refrigerant in the liquid state in compressor 1 is vaporized. As a result, concentration αoil exceeds threshold value X1. In this case, control device 70 stops heater 60, for example, when concentration αoil detected by concentration sensor 51 exceeds threshold value X1.
As a result, (Toil, αoil) is moved from region (1) to region (3) or from region (2) to region (4).
An upward arrow extending from region (1) to region (3) in
As illustrated in
(3) of
(4) of
Therefore, in a case where temperature Toil detected by temperature sensor 50 and concentration αoil detected by concentration sensor 51 belong to region (3) or region (4), control device 70 does not operate heater 60 (refer to
Here, the description has been given assuming that, in a case where the (Toil, αoil) belongs to region (1) or region (2), the operation of heater 60 is stopped when concentration αoil detected by concentration sensor 51 exceeds threshold value X1. However, the timing of stopping the operation of heater 60 is not limited thereto.
For example, in a case where (Toil, αoil) belongs to region (1) or region (2), control device 70 may stop heater 60 when concentration αoil detected by concentration sensor 51 reaches any value from threshold value X1 to threshold value X2. However, from the viewpoint of reducing power consumption, it is desirable to stop heater 60 when concentration αoil detected by concentration sensor 51 exceeds threshold value X1.
(5) of
As a result, (Toil, αoil) is moved from region (5) to region (6).
An arrow extending from region (5) to region (6) in
As illustrated in
(6) of
As described above, among regions (1) to (6), the regions as the targets where control device 70 operates heater 60 are (1), (2), and (5). Control device 70 operates heater 60 in a case where (Toil, αoil) belongs to either region (1) or region (2). Moreover, control device 70 stops the operation of heater 60 in a stage where concentration αoil of the refrigeration oil exceeds threshold value X1.
In other words, control device 70 does not operate heater 60 until all of the refrigerant in the liquid state for diluting the refrigeration oil is vaporized. Therefore, according to the present embodiment, it is possible to reduce the power consumption associated with the operation of heater 60 while increasing the concentration of the refrigeration oil until the refrigeration oil diluted by the refrigerant in the liquid state functions as a lubricant.
Further, in a case where (Toil, αoil) belongs to region (5), control device 70 operates heater 60. At this time, control device 70 operates heater 60 until the refrigerant in the liquid state is vaporized so that αoil=1 and further temperature Toil≥pour point Tp is satisfied. As a result, the fluidity of the refrigeration oil can be enhanced. As a result, according to the present embodiment, it is possible to prevent the driving torque of the motor in compressor 1 from being abnormally increased and an overcurrent from flowing in the motor.
As described above, according to the present embodiment, it is possible to provide the air conditioner capable of appropriately maintaining lubricating performance of the refrigeration oil in compressor 1 in consideration of the temperature and the concentration of the refrigeration oil.
First, control device 70 determines whether or not the power supply of compressor 1 is on (step S1). In a case where the power supply of compressor 1 is not on (NO in step S1), control device 70 ends the processing based on the present flowchart.
In a case where the power supply of compressor 1 is on (YES in step S1), control device 70 acquires temperature Toil and concentration αoil of the refrigeration oil in compressor 1 (step S2). Control device 70 acquires temperature Toil from temperature sensor 50. Control device 70 acquires concentration αoil from concentration sensor 51.
Next, control device 70 determines whether or not “concentration αoil≤threshold value X1” is satisfied (step S3). In a case where “concentration αoil≤threshold value X1” is satisfied, control device 70 sets heating condition 1 (step S4), and ends the processing. As a result, heating condition 1 is set corresponding to region (1) and region (2) illustrated in
In a case where “concentration αoil≤threshold value X1” is not satisfied, control device 70 determines whether or not “temperature Toil<pour point Tp” and “concentration αoil≥threshold value X2” are satisfied (step S5). In a case where “temperature Toil<pour point Tp” and “concentration αoil≥threshold value X2” are satisfied, control device 70 sets heating condition 2 (step S6), and ends the processing. As a result, heating condition 2 is set corresponding to region (5) illustrated in
In a case where “temperature Toil<pour point Tp” and “concentration αoil≥threshold value X2” are not satisfied, control device 70 decides not to perform heating (step S7), and ends the processing. As a result, the heating is not performed corresponding to region (3), region (4), and region (6) illustrated in
First, control device 70 determines whether or not heating condition 1 is set (step S11). In a case where heating condition 1 is set, control device 70 operates heater 60 (step S12). Control device 70 operates heater 60 until “concentration αoil>X1” corresponding to heating condition 1 is satisfied. When “concentration αoil>X1” is satisfied (YES in step S13), control device 70 stops the operation of heater 60 (step S14), and ends the processing based on the present flowchart.
In a case of determining NO in step S11, control device 70 determines whether or not heating condition 2 is set (step S15). In a case where heating condition 2 is set, control device 70 operates heater 60 (step S16). Control device 70 operates heater 60 until “concentration αoil=1” and “temperature Toil≥pour point Tp” corresponding to heating condition 2 are satisfied. When heating condition 2 is satisfied (YES in step S17), control device 70 stops the operation of heater 60 (step S14), and ends the processing based on the present flowchart.
Second EmbodimentNext, a second embodiment will be described.
When temperature Toil of the refrigeration oil is decreased, the viscosity of the refrigeration oil is increased. In a case where the viscosity of the refrigeration oil is appropriately high, the lubricating performance of the refrigeration oil can be secured even when concentration αoil of the refrigeration oil is small. Therefore, in the second embodiment, in consideration of the fact that the viscosity of the refrigeration oil is increased when temperature Toil of the refrigeration oil is decreased, threshold value X1 is made smaller as temperature Toil is decreased.
For example,
As is clear from the comparison between
Next, a third embodiment will be described.
As illustrated in step S1A of
As illustrated in step S18 of
That is, in the third embodiment, control device 70 sets the heating condition before turning on the power supply of compressor 1, and operates heater 60 according to the set heating condition. According to the third embodiment, compressor 1 is activated after temperature Toil and concentration oil of the refrigeration oil are adjusted to appropriate values. Therefore, compressor 1 can be operated in an appropriate environment from an activation start time point. As a result, it is possible to more reliably prevent occurrence of a failure such as an overcurrent flowing in the motor of compressor 1.
The third embodiment is similar to the first embodiment except for the timing of turning on the power supply of compressor 1. For example, the processing in steps S2 to S7 in
Next, a fourth embodiment will be described. The fourth embodiment realizes control in consideration of a case where the refrigerant in the liquid state and the refrigeration oil are separated into two layers in compressor 1.
As illustrated in
Hereinafter, the contents of the control corresponding to regions (7) to (9) will be described with reference to
(7) of
Therefore, even in a case where the concentration of the refrigeration oil satisfies αoil>X1, when temperature Toil is less than pour point Tp, the refrigeration oil maintains a high viscosity state. In general, the density of the refrigerant in the liquid state is higher than the density of the refrigeration oil. Therefore, in a case where the refrigerant in the liquid state and the refrigeration oil are separated into two layers in compressor 1, a state is obtained in which the refrigeration oil collects in an upper portion of compressor 1, and the refrigeration oil is not present at the end portion of the shaft in a lower portion of compressor 1. In this state, lubrication failure may occur in compressor 1.
Therefore, at this time, regardless of concentration αoil of the refrigeration oil, control device 70 operates heater 60 until the refrigerant in the liquid state present at the end portion of the shaft of compressor 1 is gasified (concentration αoil=1) and further temperature Toil≥pour point Tp is satisfied (heating condition 2). As a result, the refrigerant in the liquid state pushing the refrigeration oil upward is gasified. As a result, (Toil, αoil) is moved from region (7) to region (9). At this time, the end portion of the shaft in the lower portion of compressor 1 is thus moistened by the refrigeration oil.
An arrow extending from region (7) to region (9) in
(8) of
As a result, (Toil, αoil) is moved from region (8) to region (9). At this time, the end portion of the shaft in the lower portion of compressor 1 is thus moistened by the refrigeration oil.
An arrow extending from region (8) to region (9) in
(9) of
The flowchart illustrated in
Hereinafter, the flowchart illustrated in
After acquiring temperature Toil and concentration αoil of the refrigeration oil in compressor 1 in step S42, control device 70 determines whether or not temperature Toil of the refrigeration oil is less than or equal to a separation temperature Ts (step S48). That is, control device 70 compares acquired temperature Toil of the refrigeration oil with the separation temperature Ts to determine whether or not the refrigeration oil and the refrigerant in the liquid state are separated into two layers in step S48.
Separation temperature Ts used for the determination in step S48 is stored in memory 72 of control device 70. Control device 70 may vary separation temperature Ts according to the concentration detected by concentration sensor 51.
In a case where it is determined that the refrigeration oil and the refrigerant in the liquid state are not separated into two layers, control device 70 proceeds to step S43. The processing in steps S43 to S47 is similar to that in steps S3 to S7 in
In a case where it is determined that the refrigeration oil and the refrigerant in the liquid state are separated into two layers, control device 70 determines whether or not “temperature Toil<pour point Tp” is satisfied (step S49). In a case where “temperature Toil<pour point Tp” is satisfied, control device 70 sets heating condition 2 (step S50), and ends the processing. As a result, heating condition 2 is set corresponding to region (7) illustrated in
In a case where “temperature Toil<pour point Tp” is not satisfied, control device 70 determines whether or not “concentration αoil≤threshold value X1” is satisfied (step S51). In a case where “concentration αoil≤threshold value X1” is satisfied, control device 70 sets heating condition 3 (step S52), and ends the processing. As a result, heating condition 3 is set corresponding to region (8) illustrated in
Hereinafter, the flowchart illustrated in
In a case where it is determined in step S55 that heating condition 2 is not set, control device 70 determines whether or not heating condition 3 is set (step S58). In a case where heating condition 3 is not set, control device 70 ends the processing without operating heater 60.
In a case where heating condition 3 is set, control device 70 operates heater 60 (step S59). Control device 70 operates heater 60 until “concentration αoil=1” corresponding to heating condition 3 is satisfied. When heating condition 3 is satisfied (YES in step S60), control device 70 stops the operation of heater 60 (step S54), and ends the processing based on the present flowchart.
According to the fourth embodiment, the state of the refrigerant and the state of the refrigeration oil can be set to appropriate states according to each of a case where the refrigerant in the liquid state and the refrigeration oil are separated into two layers in compressor 1 and a case where the refrigerant in the liquid state and the refrigeration oil are not separated.
Fifth EmbodimentNext, a fifth embodiment will be described.
As illustrated in
By disposing temperature sensor 50 and concentration sensor 51 at the positions illustrated in
Next, a sixth embodiment will be described.
By disposing temperature sensor 50 and concentration sensor 51 at the positions illustrated in
In each embodiment described above, “exceeding” may be replaced with “greater than or equal to”, and “less than or equal to” may be replaced with “less than”. Conversely, “greater than or equal to” may be replaced with “exceeding”, and “less than” may be replaced with “less than or equal to”.
SUMMARYHereinafter, the present embodiment will be summarized.
(1) The present disclosure relates to an air conditioner (100). The air conditioner includes a compressor (1); a first heat exchanger (2); a second heat exchanger (4); a decompression device (3); a circulation path (5) through which a refrigerant circulates through the compressor, the first heat exchanger, the decompression device, and the second heat exchanger in this order; a temperature sensor (50) to detect a temperature of refrigeration oil in the compressor; a concentration sensor (51) to detect a concentration of the refrigeration oil in a mixture of the refrigerant in a liquid state and the refrigeration oil in the compressor; a heater (60) to heat the refrigeration oil in the compressor; and a control device (70). In a case where a concentration of refrigeration oil detected by the concentration sensor is less than a first threshold value, the control device operates the heater such that a part of a refrigerant in a liquid state in the compressor is vaporized (step S4 and steps S11 to S13), and in a case where the concentration of the refrigeration oil detected by the concentration sensor exceeds a second threshold value greater than the first threshold value and a temperature of the refrigeration oil detected by the temperature sensor is less than a specified temperature, the control device operates the heater such that the refrigerant in the liquid state in the compressor is vaporized and the temperature of the refrigeration oil in the compressor is increased (step S6 and steps S15 to S17).
According to the disclosure described in (1), it is possible to provide the air conditioner capable of appropriately maintaining lubricating performance of the refrigeration oil in the compressor in consideration of the temperature and the concentration of the refrigeration oil.
(2) In a case where the concentration of the refrigeration oil detected by the concentration sensor is less than the first threshold value, the control device ends heating of the refrigeration oil via the heater when the concentration of the refrigeration oil in the compressor exceeds the first threshold value (steps S13 and S14).
According to the disclosure described in (2), the power consumption of the heater can be reduced as compared with a case where the heater is continuously operated even when the concentration of the refrigeration oil in the compressor exceeds the first threshold value.
(3) The specified temperature is a temperature (Tp) corresponding to a pour point of the refrigeration oil (
According to the disclosure described in (3), it is possible to prevent occurrence of a failure in the operation of the compressor due to the refrigeration oil having high viscosity.
(4) The second threshold value is a value designed assuming that an overcurrent flows in a motor of the compressor when the temperature of the refrigeration oil in the compressor is a temperature (Tp) corresponding to the pour point and the concentration of the refrigeration oil in the compressor is the second threshold value.
According to the disclosure described in (4), it is possible to prevent an overcurrent from flowing in the motor of the compressor.
(5) The air conditioner further includes a memory (72) to store the first threshold value, in which the first threshold value (X11) is a value corresponding to a first temperature (T1) of the refrigeration oil, and the memory further stores a third threshold value (X12) corresponding to a second temperature (T2) of the refrigeration oil (
According to the disclosure described in (5), the power consumption of the heater can be reduced.
(6) The control device activates the compressor (step S18) after adjusting the concentration or the temperature of the refrigeration oil in the compressor by operating the heater.
According to the disclosure described in (6), the compressor can be operated in an appropriate environment from an activation start time point. As a result, it is possible to more reliably prevent occurrence of a failure in the operation of the compressor.
(7) The control device operates the heater (steps S48 to S50) regardless of the concentration of the refrigeration oil in the compressor in a case where the refrigerant and the refrigeration oil in the compressor are separated and the temperature of the refrigeration oil detected by the temperature sensor is less than the specified temperature.
According to the disclosure described in (7), the heater operates to gasify the refrigerant in the liquid state pushing the refrigeration oil upward in the compressor. As a result, it is possible to prevent occurrence of the lubrication failure in the compressor.
(8) The control device stops the operation of the heater (steps S57 and S54) in a case where the temperature of the refrigeration oil in the compressor exceeds the specified temperature.
According to the disclosure described in (8), the refrigerant in the liquid state can be sufficiently gasified.
(9) The control device operates the heater (steps S48, S49, S51, and S52) in a case where the refrigerant and the refrigeration oil in the compressor are separated, the temperature of the refrigeration oil detected by the temperature sensor exceeds the specified temperature, and the concentration of the refrigeration oil detected by the concentration sensor is less than the first threshold value.
According to the disclosure described in (9), the heater operates to gasify the refrigerant in the liquid state pushing the refrigeration oil upward in the compressor. As a result, it is possible to prevent occurrence of the lubrication failure in the compressor.
(10) The control device stops the operation of the heater (steps S60 and S54) in a case where the refrigerant in the liquid state in the compressor is vaporized.
According to the disclosure described in (10), the power consumption of the heater can be reduced as compared with a case where the heater is continuously operated even after the refrigerant is vaporized.
(11) The temperature sensor and the concentration sensor are provided in a vicinity of a shaft of the compressor (
According to the disclosure described in (11), the control device can more appropriately maintain the lubricating performance of the refrigeration oil in the compressor in consideration of the temperature and the concentration of the refrigeration oil in a state where the compressor is activated.
(12) The temperature sensor and the concentration sensor are provided at an end portion of a shaft of the compressor (
According to the disclosure described in (12), the control device can more appropriately maintain the lubricating performance of the refrigeration oil in the compressor in consideration of the temperature and the concentration of the refrigeration oil before the compressor is activated.
It should be understood that the embodiments disclosed herein are illustrative in all respects and not restrictive. The scope of the present disclosure is defined not by the above description in the above embodiments but by the claims, and is intended to include meanings equivalent to the claims and all modifications within the scope.
REFERENCE SIGNS LIST
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- 1: compressor, 2: first heat exchanger, 3: decompression device, 4: second heat exchanger, 5: circulation path, 50: temperature sensor, 51: concentration sensor, 52: compression unit, 53: shaft, 54: oil reservoir, 55: motor, 60: heater, 70: control device, 71: processor, 72: memory, 100: air conditioner, A1: area
Claims
1. An air conditioner comprising:
- a compressor;
- a first heat exchanger;
- a second heat exchanger;
- a decompression device;
- a circulation path through which a refrigerant circulates through the compressor, the first heat exchanger, the decompression device, and the second heat exchanger in this order;
- a temperature sensor to detect a temperature of refrigeration oil in the compressor;
- a concentration sensor to detect a concentration of the refrigeration oil in a mixture of the refrigerant in a liquid state and the refrigeration oil in the compressor;
- a heater to heat the refrigeration oil in the compressor; and
- a control device,
- wherein
- in a case where the concentration of the refrigeration oil detected by the concentration sensor is less than a first threshold value, the control device operates the heater such that a part of the refrigerant in the liquid state in the compressor is vaporized, and
- in a case where the concentration of the refrigeration oil detected by the concentration sensor exceeds a second threshold value greater than the first threshold value and the temperature of the refrigeration oil detected by the temperature sensor is less than a specified temperature, the control device operates the heater such that the refrigerant in the liquid state in the compressor is vaporized and the temperature of the refrigeration oil in the compressor is increased.
2. The air conditioner according to claim 1,
- wherein in a case where the concentration of the refrigeration oil detected by the concentration sensor is less than the first threshold value, the control device ends heating of the refrigeration oil via the heater when the concentration of the refrigeration oil in the compressor exceeds the first threshold value.
3. The air conditioner according to claim 1,
- wherein the specified temperature is a temperature corresponding to a pour point of the refrigeration oil.
4. The air conditioner according to claim 3,
- wherein the second threshold value is a value designed assuming that an overcurrent flows in a motor of the compressor when the temperature of the refrigeration oil in the compressor is a temperature corresponding to the pour point and the concentration of the refrigeration oil in the compressor is the second threshold value.
5. The air conditioner according to claim 1, further comprising:
- a memory to store the first threshold value,
- wherein
- the first threshold value is a value corresponding to a first temperature of the refrigeration oil, and
- the memory further stores a third threshold value corresponding to a second temperature of the refrigeration oil.
6. The air conditioner according to claim 1,
- wherein the control device activates the compressor after adjusting the concentration or the temperature of the refrigeration oil in the compressor by operating the heater.
7. The air conditioner according to claim 1,
- wherein the control device operates the heater regardless of the concentration of the refrigeration oil in the compressor in a case where the refrigerant and the refrigeration oil in the compressor are separated and the temperature of the refrigeration oil detected by the temperature sensor is less than the specified temperature.
8. The air conditioner according to claim 7,
- wherein the control device stops the operation of the heater in a case where the temperature of the refrigeration oil in the compressor exceeds the specified temperature.
9. The air conditioner according to claim 1,
- wherein the control device operates the heater in a case where the refrigerant and the refrigeration oil in the compressor are separated, the temperature of the refrigeration oil detected by the temperature sensor exceeds the specified temperature, and the concentration of the refrigeration oil detected by the concentration sensor is less than the first threshold value.
10. The air conditioner according to claim 9,
- wherein the control device stops the operation of the heater in a case where the refrigerant in the liquid state in the compressor is vaporized.
11. The air conditioner according to claim 1,
- wherein the temperature sensor and the concentration sensor are provided in a vicinity of a shaft of the compressor.
12. The air conditioner according to claim 1,
- wherein the temperature sensor and the concentration sensor are provided at an end portion of a shaft of the compressor.
Type: Application
Filed: Sep 8, 2021
Publication Date: Oct 10, 2024
Inventors: Ryota YUASA (Tokyo), Hiroki ISHIYAMA (Tokyo), Masanori SATO (Tokyo), Soichiro KOSHI (Tokyo)
Application Number: 18/293,530