JP2015073606A - Clothes dryer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce an amount of use of a combustible refrigerant used as a refrigerant of a heat pump including a rotary compressor without requiring improvement of a lubrication oil of the rotary compressor.SOLUTION: A clothes dryer related to the present embodiment reduces a dissolution amount of a combustible refrigerant with respect to a lubrication oil of a rotary compressor by controlling an operation frequency of the rotary compressor, an opening of a variable throttle valve and a rotational speed of a blower in such a manner that difference between a temperature of the combustible refrigerant discharged from the rotary compressor and a temperature of a condenser is maintained at a predetermined temperature, in a stable period of a drying operation.

Description

  Embodiments described herein relate generally to a clothes dryer.

  As a drying method of the clothes dryer, a heater method and a heat pump method are known. Among them, according to the heat pump type clothes dryer, it is possible to dry at a lower temperature than the heater type, and there are merits such as less shrinkage and damage of clothes and less power consumption. However, the refrigerant generally used in the heat pump is an HFC refrigerant (HFC: Hydro Fluoro Carbon), and this HFC refrigerant has a high global warming potential (GWP). Therefore, in recent years, the use of a flammable refrigerant having a low global warming potential has been studied as an alternative refrigerant (see, for example, Patent Document 1).

International Publication No. 2011/162391

  By the way, in a heat pump type clothes dryer, there is a tendency that a rotary compressor having high refrigerant compression efficiency is adopted as a compressor constituting the heat pump. However, since the inside of the rotary compressor is at a high pressure, there is a problem that the refrigerant easily dissolves in the internal lubricating oil, and therefore the amount of the refrigerant enclosed must be increased. Here, when a flammable refrigerant is employed as the refrigerant used in the heat pump, the amount of the flammable refrigerant used is preferably as small as possible. Therefore, in order to use a combustible refrigerant as a refrigerant of a heat pump provided with a rotary compressor, a measure for reducing the amount of use of the combustible refrigerant is required. As a measure to reduce the amount of flammable refrigerant used, improve the lubricating oil for rotary compressors.Specifically, the flammable refrigerant is incompatible with lubricating oil that is difficult to dissolve, that is, flammable refrigerant. It is known to use lubricating oil.

  Therefore, in the present embodiment, when a flammable refrigerant is used as a refrigerant of a heat pump including a rotary compressor, the use of the flammable refrigerant can be reduced without requiring improvement of the lubricating oil of the rotary compressor. Provide a machine.

  The clothes dryer which concerns on this embodiment is provided with a drying chamber, a heat pump, a ventilation path, an air blower, and a control means. The heat pump constitutes a refrigeration cycle in which a refrigerant is circulated through a compressor, a condenser, a throttle, and an evaporator, a rotary compressor is provided as a compressor, and a variable throttle valve capable of adjusting the opening degree is provided as a throttle. A combustible refrigerant is provided as a refrigerant. The ventilation path is connected to the drying chamber, and a condenser and an evaporator are disposed therein. The blower circulates the air in the drying chamber through the ventilation path. The control means controls operations of the rotary compressor, the variable throttle valve, and the blower. Then, the control means controls the operating frequency of the rotary compressor, the variable throttle valve so that the difference between the temperature of the combustible refrigerant discharged from the rotary compressor and the temperature of the condenser is maintained at a predetermined temperature in the stable period of the drying operation. By controlling the opening degree and the rotational speed of the blower, the amount of the combustible refrigerant dissolved in the lubricating oil of the rotary compressor is reduced.

  Moreover, the clothes dryer which concerns on this embodiment is provided with a drying chamber, a heat pump, a heating means, a ventilation path, an air blower, and a control means. A heat pump constitutes a refrigeration cycle in which refrigerant is circulated through a compressor, a condenser, a constrictor and an evaporator, a rotary compressor is provided as a compressor, a capillary is provided as a constrictor, and a combustible refrigerant is provided as a refrigerant. ing. The heating means heats the capillary. The ventilation path is connected to the drying chamber, and a condenser and an evaporator are disposed therein. The blower circulates the air in the drying chamber through the ventilation path. The control unit controls operations of the rotary compressor, the heating unit, and the blower. The control means uses the operating frequency of the rotary compressor and the heating means so that the difference between the temperature of the combustible refrigerant discharged from the rotary compressor and the temperature of the condenser is maintained at a predetermined temperature in the stable period of the drying operation. By controlling the heating amount of the capillary and the rotation speed of the blower, the amount of the combustible refrigerant dissolved in the lubricating oil of the rotary compressor is reduced.

The figure which shows schematically the in-machine structure of the clothes dryer which concerns on 1st Embodiment. The figure which shows the structural example of the control system of a clothes dryer Flow chart showing an example of control content by clothes dryer FIG. 1 equivalent view according to the second embodiment 2 equivalent diagram 3 equivalent figure

Hereinafter, a plurality of embodiments according to a clothes dryer will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the substantially same element in each embodiment, and description is abbreviate | omitted.
(First embodiment)
For example, FIG. 1 schematically shows an in-machine structure 2 of a laundry dryer 1 which is an example of a clothes dryer. Inside the washing / drying machine 1, a water tank 3, a heat pump 4, a ventilation path 5, a blower 6, and the like are provided. Inside the water tank 3, a rotating tank (not shown) in which clothes and the like are accommodated is rotatably arranged. The water tank 3 functions as a washing tub for washing clothes and the like during the washing operation, and functions as a drying chamber for drying the clothes and the like during the drying operation.

  The heat pump 4 constitutes a refrigeration cycle by connecting the compressor 7, the condenser 8, the constrictor 9, and the evaporator 10 through a refrigerant line. In this case, the compressor 7 is formed of a so-called rotary compressor that compresses the refrigerant by rotating a refrigerant compression member in the sealed container. Accordingly, the inside of the compressor 7 has a high pressure. In this case, the compressor 7 is driven by an inverter. The restrictor 9 includes a variable throttle valve (PMV: Pulse Motor Valve) whose opening can be adjusted by the number of input pulses. Hereinafter, the compressor 7 is referred to as a rotary compressor 7, and the restrictor 9 is referred to as PMV 9. The rotary compressor 7 is provided with an accumulator 7a for separating the refrigerant from gas and liquid. A refrigerant is sealed in a refrigerant pipe line of the heat pump 4. In this case, a flammable refrigerant is used as the refrigerant to be sealed. Combustible refrigerants have a lower global warming potential than commonly used HFC refrigerants. However, since it has combustibility, it is preferable to suppress the amount used, that is, the amount enclosed in the refrigerant pipe as much as possible.

  The ventilation path 5 is connected to the exhaust port 5a and the air supply port 5b of the water tank 3 in communication. Inside the ventilation path 5, a condenser 8 and an evaporator 10 constituting the heat pump 4 are disposed. The blower 6 is provided in a portion located on the leeward side of the condenser 8 in the ventilation path 5. The blower 6 includes a blower fan 6a and a motor 6b that rotates the blower fan 6a. The blower 6 circulates the air in the water tank 3 through the ventilation path 5 by rotating the blower fan 6a. Further, the heat pump 4 is provided with a discharge refrigerant temperature sensor 11 for detecting the temperature of the refrigerant discharged from the rotary compressor 7 and a condenser temperature sensor 12 for detecting the temperature of the condenser 8. . In this case, the condenser temperature sensor 12 is provided at a substantially central portion of the end plate constituting the condenser 8, whereby the temperature of the central portion of the condenser 8 and its surroundings is detected. Yes.

  For example, FIG. 2 shows a configuration example of a control system of the washing / drying machine 1. Here, a configuration related to “refrigerant penetration amount reduction control” described later in detail is shown. The control device 13 is an example of a control unit, and is composed mainly of a microcomputer, for example. The control device 13 controls the overall operation of the washing / drying machine 1 based on a control program stored in advance and an operation signal input via an operation input unit (not shown). The control device 13 receives a temperature detection signal output from the discharged refrigerant temperature sensor 11 and a temperature detection signal output from the condenser temperature sensor 12. In the stable period of the drying operation, the control device 13 determines the temperature of the refrigerant discharged from the rotary compressor 7 and the temperature of the condenser 8 based on the temperature detection signals input from the temperature sensors 11 and 12. The temperature difference is calculated. Then, the control device 13 controls the operating frequency of the rotary compressor 7, the opening degree of the PMV 9, and the rotational speed of the blower fan 6a of the blower 6 so that the temperature difference is maintained within a predetermined temperature range. It is configured.

  Next, an example of control contents in the stable period of the drying operation will be described. In addition, the control apparatus 13 will start the drive of the rotary compressor 7, and the drive of the air blower 6, if the start command of drying operation is input. Thereby, in the heat pump 4, the condenser 8 is heated and the evaporator 10 is cooled by the action of a known refrigeration cycle. Further, the humid air in the water tank 3 is sent to the ventilation path 5, the air is cooled and dehumidified by the evaporator 10, heated by the condenser 8 to become warm air, and returned to the water tank 3. By repeating such circulation, the clothes stored in the rotating tub of the water tub 3 are dried. The stable period of the drying operation is a period of time after the start of the drying operation, the operating frequency of the rotary compressor 7 reaches a predetermined frequency, and the rotational speed of the blower fan 6a of the blower 6 is predetermined. This shows a state where the rotation speed reached has been reached and the drying of the clothes has been stably continued.

  When entering the stable period of the drying operation, the control device 13 starts “refrigerant penetration amount reduction control” shown in FIG. 3, for example. In this control, the control device 13 first determines that the temperature difference T between the refrigerant discharged from the rotary compressor 7 and the temperature of the condenser 8 (hereinafter referred to as “comp / conde temperature difference T”) is a first predetermined value. It is determined whether or not the temperature is higher than T1 (A1). The first predetermined temperature T1 can be appropriately changed and set. In this case, for example, 40 ° C. is set as the first predetermined temperature T1.

  When the compressor / conde temperature difference T is greater than the first predetermined temperature T1 (A1: YES), the control device 13 proceeds to step A10 described later in detail. On the other hand, when the compressor / conde temperature difference T is equal to or lower than the first predetermined temperature T1 (A1: NO), the control device 13 performs an operation for increasing the temperature of the refrigerant discharged from the rotary compressor 7. That is, the control device 13 first reduces the opening of the PMV 9 (A2). When the opening degree of the PMV 9 is reduced, the throttle by the PMV 9 is strengthened, and the amount of refrigerant flowing through the evaporator 10 is reduced. As a result, the degree of superheat of the evaporator 10, that is, the temperature difference between the refrigerant outlet side temperature and the inlet side temperature in the evaporator 10 increases. When the degree of superheat of the evaporator 10 increases, the temperature of the refrigerant flowing into the rotary compressor 7 increases. Along with this, the temperature of the refrigerant discharged from the rotary compressor 7 increases.

  When a predetermined time has elapsed since the opening of the PMV 9 is reduced (A3: YES), the control device 13 determines again whether the comp / conde temperature difference T is larger than the first predetermined temperature T1 (A4). ). The predetermined time can be changed and set as appropriate. When the compressor / conde temperature difference T is larger than the first predetermined temperature T1 (A4: YES), the control device 13 proceeds to step A10 described later in detail. On the other hand, when the compressor / conde temperature difference T is equal to or lower than the first predetermined temperature T1 (A4: NO), the control device 13 checks whether the opening of the PMV 9 is a lower limit value (A5).

  When the opening degree of PMV9 is not the lower limit value, that is, when the opening degree of PMV9 can be further reduced (A5: NO), control device 13 proceeds to step A2 described above to further reduce the opening degree of PMV9. To do. On the other hand, when the opening degree of the PMV 9 is the lower limit value, that is, when the opening degree of the PMV 9 cannot be further reduced (A5: YES), the control device 13 performs control and blower for increasing the operating frequency of the rotary compressor 7. At least any one of the controls for increasing the rotation speed 6 is performed (A6). When the operating frequency of the rotary compressor 7 increases, the degree to which the refrigerant is compressed in the rotary compressor 7 increases, and accordingly, the temperature of the refrigerant discharged from the rotary compressor 7 increases. Further, when the rotational speed of the blower 6 increases, the degree of heat exchange of the refrigerant in the evaporator 10, that is, the degree to which the refrigerant is heated increases, and the temperature of the refrigerant flowing into the rotary compressor 7 increases. Along with this, the temperature of the refrigerant discharged from the rotary compressor 7 increases.

  When a predetermined time elapses after the control device 13 performs at least one of the control for increasing the operating frequency of the rotary compressor 7 and the control for increasing the rotational speed of the blower 6 (A7: YES), again, It is determined whether the compressor / conde temperature difference T is larger than the first predetermined temperature T1 (A8). The predetermined time can be changed and set as appropriate. When the compressor / conde temperature difference T is larger than the first predetermined temperature T1 (A8: YES), the control device 13 proceeds to step A10 described later in detail. On the other hand, when the compressor / conde temperature difference T is equal to or lower than the first predetermined temperature T1 (A8: NO), the control device 13 determines whether the operating frequency of the rotary compressor 7 is the upper limit value and the blower 6 It is confirmed whether or not the rotation speed is an upper limit value (A9).

  When the operating frequency of the rotary compressor 7 is not the upper limit value, that is, when the operating frequency of the rotary compressor 7 can be further increased (A9: NO), the control device 13 or the rotational speed of the blower 6 is the upper limit. If it is not a value, that is, if the rotational speed of the blower 6 can be further increased (A9: NO), the process proceeds to step A6 described above. When the operating frequency of the rotary compressor 7 can be increased, the operating frequency is further increased. When the rotating speed of the blower 6 can be increased, the rotating speed is further increased.

  On the other hand, when the operating frequency of the rotary compressor 7 is the upper limit value, that is, when the operating frequency of the rotary compressor 7 cannot be increased any more (A9: YES), the control device 13 or When the rotational speed is the upper limit value, that is, when the rotational speed of the blower 6 is not increased any more (A9: YES), this control is finished. In this case, for example, the control device 13 may be configured to notify that the refrigerant is easily dissolved in the lubricating oil.

  When the compressor / conde temperature difference T is larger than the first predetermined temperature T1 (A1: YES, A4: YES, A8: YES), the control device 13 proceeds to Step A10. When the control device 13 proceeds to step A10, it determines whether the compressor / conde temperature difference T is equal to or lower than the second predetermined temperature T2. The second predetermined temperature T2 can be appropriately changed and set. In this case, for example, 50 ° C. is set as the second predetermined temperature T2.

  When the compressor / conde temperature difference T is equal to or lower than the second predetermined temperature T2 (A10: YES), the control device 13 ends this control. On the other hand, when the compressor / conde temperature difference T is larger than the second predetermined temperature T2 (A10: NO), the control device 13 performs an operation for lowering the temperature of the refrigerant discharged from the rotary compressor 7. That is, the control device 13 first increases the opening of the PMV 9 (A11). When the opening degree of the PMV 9 increases, the throttle due to the PMV 9 becomes loose, and the amount of refrigerant flowing to the evaporator 10 increases. Thereby, the superheat degree of the evaporator 10, ie, the temperature difference between the temperature on the outlet side of the refrigerant in the evaporator 10 and the temperature on the inlet side becomes small. When the degree of superheat of the evaporator 10 decreases, the temperature of the refrigerant flowing into the rotary compressor 7 decreases. Along with this, the temperature of the refrigerant discharged from the rotary compressor 7 decreases.

  When a predetermined time has elapsed since the opening of the PMV 9 is increased (A12: YES), the control device 13 again determines whether the comp / conde temperature difference T is equal to or lower than the second predetermined temperature T2 (A13). ). The predetermined time can be changed and set as appropriate. When the compressor / conde temperature difference T is equal to or lower than the second predetermined temperature T2 (A13: YES), the control device 13 ends this control. On the other hand, when the compressor / conde temperature difference T is larger than the second predetermined temperature T2 (A13: NO), the control device 13 checks whether or not the opening of the PMV 9 is an upper limit value (A14).

  When the opening degree of PMV9 is not the upper limit value, that is, when the opening degree of PMV9 can be further increased (A14: NO), control device 13 proceeds to step A11 described above and further increases the opening degree of PMV9. To do. On the other hand, when the opening degree of the PMV 9 is the upper limit value, that is, when the opening degree of the PMV 9 cannot be increased any more (A14: YES), the control device 13 reduces the operating frequency of the rotary compressor 7 and the blower. At least one of the controls for decreasing the rotational speed 6 is performed (A15). When the operating frequency of the rotary compressor 7 is lowered, the degree to which the refrigerant is compressed in the rotary compressor 7 is lowered, and accordingly, the temperature of the refrigerant discharged from the rotary compressor 7 is lowered. Further, when the rotational speed of the blower 6 is lowered, the degree of heat exchange of the refrigerant in the evaporator 10, that is, the degree of heating of the refrigerant is lowered, and the temperature of the refrigerant flowing into the rotary compressor 7 is lowered. Along with this, the temperature of the refrigerant discharged from the rotary compressor 7 decreases.

  When a predetermined time has elapsed after performing at least one of the control for lowering the operating frequency of the rotary compressor 7 and the control for lowering the rotational speed of the blower 6 (A16: YES), the control device 13 again It is determined whether the compressor / conde temperature difference T is equal to or lower than a second predetermined temperature T2 (A17). The predetermined time can be changed and set as appropriate. When the compressor / conde temperature difference T is equal to or lower than the second predetermined temperature T2 (A17: YES), the control device 13 ends this control. On the other hand, when the compressor / conde temperature difference T is larger than the second predetermined temperature T2 (A17: NO), the control device 13 determines whether or not the operating frequency of the rotary compressor 7 is the lower limit value and the blower 6 It is confirmed whether or not the rotation speed is a lower limit value (A18).

  When the operation frequency of the rotary compressor 7 is not the lower limit value, that is, when the operation frequency of the rotary compressor 7 can be further decreased (A18: NO), the control device 13 or the rotational speed of the blower 6 is the lower limit. If it is not a value, that is, if the rotational speed of the blower 6 can be further decreased (A18: NO), the process proceeds to step A15 described above. When the operating frequency of the rotary compressor 7 can be lowered, the operating frequency is further lowered. When the rotational speed of the blower 6 can be lowered, the rotational speed is further lowered.

  On the other hand, when the operating frequency of the rotary compressor 7 is the lower limit value, that is, when the operating frequency of the rotary compressor 7 cannot be decreased any more (A18: YES), the control device 13 or If the rotational speed is the lower limit value, that is, if the rotational speed of the blower 6 is not lowered further (A18: YES), this control is terminated. In this case, for example, the control device 13 may be configured to notify that the refrigerant is easily dissolved in the lubricating oil.

  When the compressor / conde temperature difference T is equal to or less than the second predetermined temperature T2 (A10: YES, A13: YES, A17: YES), the control device 13 ends this control. That is, in this state, the compressor / conde temperature difference T is maintained in the range from the first predetermined temperature T1 to the second predetermined temperature T2. Under this condition, even if the lubricating oil of the rotary compressor 7 is a lubricating oil compatible with the flammable refrigerant, the amount of the flammable refrigerant that dissolves in the lubricating oil (the amount of dissolution) may be greatly reduced. This has been confirmed by experiments and analysis by the present inventors.

  According to the washing / drying machine 1 according to the present embodiment, in the stable period of the drying operation, the difference between the temperature of the refrigerant discharged from the rotary compressor 7 and the temperature of the condenser 8 is a predetermined temperature range, in this case, 40 ° C. The operating frequency of the rotary compressor 7, the opening degree of the PMV 9, and the rotational speed of the blower 6 are controlled so as to be maintained in the range of 50 to 50 ° C. Under the condition that the difference between the temperature of the refrigerant discharged from the rotary compressor 7 and the temperature of the condenser 8 is maintained within a predetermined temperature range, the lubricating oil of the rotary compressor 7 is compatible with the combustible refrigerant. Even if the lubricating oil, that is, the lubricating oil in which the flammable refrigerant is easily dissolved, it has been confirmed that the amount of the flammable refrigerant dissolved in the lubricating oil is reduced. Therefore, according to the present embodiment, even when a flammable refrigerant is used as the refrigerant of the heat pump 4 including the rotary compressor 7, the amount of the flammable refrigerant used is not required to improve the lubricating oil of the rotary compressor 7. Can be reduced.

(Second Embodiment)
For example, as shown in FIG. 4, the heat pump 4 includes a capillary mechanism unit 29 as an example of a diaphragm that replaces the PMV 9 described above. The capillary mechanism 29 includes a first capillary 29a and a second capillary 29b connected in parallel to the refrigerant pipe. The first capillary 29a and the second capillary 29b have narrower flow paths than other refrigerant pipes. In this case, the second capillary 29b is provided with a heater 29c which is an example of a heating unit. The heater 29c is fixed in close contact with the second capillary 29b, for example, by soldering.

  For example, as shown in FIG. 5, the energization of the heater 29 c is configured to be controlled by the control device 13. In the stable period of the drying operation, the controller 13 rotates the rotary compressor 7 so that the temperature difference between the temperature of the refrigerant discharged from the rotary compressor 7 and the temperature of the condenser 8 is maintained within a predetermined temperature range. The operating frequency, the heating amount of the second capillary 29b by the heater 29c, and the rotational speed of the blower fan 6a of the blower 6 are controlled.

  Next, an example of “refrigerant penetration reduction control” according to the present embodiment will be described with reference to FIG. When this control is started in the stable period of the drying operation, the control device 13 first determines whether the compressor / conde temperature difference T is greater than the first predetermined temperature T1 (B1). Also in this case, the first predetermined temperature T1 is set at 40 ° C., for example.

  When the compressor / conde temperature difference T is larger than the first predetermined temperature T1 (B1: YES), the control device 13 proceeds to step B10 described later in detail. On the other hand, when the compressor / conde temperature difference T is equal to or lower than the first predetermined temperature T1 (B1: NO), the control device 13 performs an operation for increasing the temperature of the refrigerant discharged from the rotary compressor 7. That is, the control device 13 first turns on the heater 29c and raises its output to a predetermined initial output value (B2). When the output of the heater 29c increases, the heating amount of the second capillary 29b by the heater 29c increases, and the refrigerant flowing in the second capillary 29b is gasified and expanded. When the refrigerant flowing in the second capillary 29b is gasified / expanded, the volume of the refrigerant increases and the flow resistance of the refrigerant increases, so that the refrigerant hardly flows in the second capillary 29b. That is, the aperture becomes stronger. Accordingly, the amount of refrigerant flowing through the evaporator 10 is reduced. Thereby, the superheat degree of the evaporator 10 becomes large, the temperature of the refrigerant | coolant which flows into the rotary compressor 7 rises, and the temperature of the refrigerant | coolant discharged from the rotary compressor 7 rises in connection with this.

  When a predetermined time elapses after increasing the output of the heater 29c (B3: YES), the control device 13 again determines whether the compressor / conde temperature difference T is greater than the first predetermined temperature T1 (B4). ). When the compressor / conde temperature difference T is larger than the first predetermined temperature T1 (B4: YES), the control device 13 proceeds to step B10 described later in detail. On the other hand, when the compressor / conde temperature difference T is equal to or lower than the first predetermined temperature T1 (B4: NO), the control device 13 checks whether or not the output of the heater 29c is the upper limit value (B5).

  When the output of the heater 29c is not the upper limit value, that is, when the output of the heater 29c can be further increased (B5: NO), the control device 13 proceeds to step B2 described above and further increases the output of the heater 29c. To do. On the other hand, if the output of the heater 29c is the upper limit value, that is, if the output of the heater 29c cannot be increased any more (B5: YES), the control device 13 increases the operating frequency of the rotary compressor 7 and the blower. At least one of the controls for increasing the rotational speed 6 is performed (B6). When the operating frequency of the rotary compressor 7 increases, the degree to which the refrigerant is compressed in the rotary compressor 7 increases, and accordingly, the temperature of the refrigerant discharged from the rotary compressor 7 increases. Further, when the rotational speed of the blower 6 increases, the degree of heat exchange of the refrigerant in the evaporator 10, that is, the degree to which the refrigerant is heated increases, and the temperature of the refrigerant flowing into the rotary compressor 7 increases. Along with this, the temperature of the refrigerant discharged from the rotary compressor 7 increases.

  When a predetermined time elapses after the control device 13 performs at least one of the control for increasing the operating frequency of the rotary compressor 7 and the control for increasing the rotational speed of the blower 6 (B7: YES), again, It is determined whether the comp / conde temperature difference T is larger than the first predetermined temperature T1 (B8). When the compressor / conde temperature difference T is larger than the first predetermined temperature T1 (B8: YES), the control device 13 proceeds to step B10 described later in detail. On the other hand, when the compressor / conde temperature difference T is equal to or lower than the first predetermined temperature T1 (B8: NO), the control device 13 determines whether the operating frequency of the rotary compressor 7 is the upper limit value and the blower 6 It is confirmed whether or not the rotation speed is an upper limit value (B9).

  When the operating frequency of the rotary compressor 7 is not the upper limit value (B9: NO), or when the rotational speed of the blower 6 is not the upper limit value (B9: NO), the control device 13 proceeds to the above-described step B6. When the operating frequency of the rotary compressor 7 can be increased, the operating frequency is further increased. When the rotational speed of the blower 6 can be increased, the rotational speed is further increased. On the other hand, the control device 13 performs this control when the operating frequency of the rotary compressor 7 is the upper limit value (B9: YES) or when the rotational speed of the blower 6 is the upper limit value (B9: YES). Exit. In this case, for example, the control device 13 may be configured to notify that the refrigerant is easily dissolved in the lubricating oil.

  When the compressor / conde temperature difference T is larger than the first predetermined temperature T1 (B1: YES, B4: YES, B8: YES), the control device 13 proceeds to Step B10. When the process proceeds to step B10, the control device 13 determines whether or not the compressor / conde temperature difference T is equal to or lower than the second predetermined temperature T2. Also in this case, the second predetermined temperature T2 is set at 50 ° C., for example.

  When the compressor / conde temperature difference T is equal to or lower than the second predetermined temperature T2 (B10: YES), the control device 13 ends this control. On the other hand, when the compressor / conde temperature difference T is larger than the second predetermined temperature T2 (B10: NO), the control device 13 performs an operation for lowering the temperature of the refrigerant discharged from the rotary compressor 7. That is, the control device 13 first lowers the output of the heater 29c (B11). When the output of the heater 29c decreases, the amount of heating of the second capillary 29b by the heater 29c decreases, and the refrigerant flowing in the second capillary 29b liquefies and contracts. When the refrigerant flowing in the second capillary 29b is liquefied and contracted, the volume of the refrigerant is reduced and the flow resistance of the refrigerant is reduced, so that the refrigerant easily flows in the second capillary 29b. That is, the aperture is weakened. Therefore, the amount of refrigerant flowing through the evaporator 10 increases. Thereby, the superheat degree of the evaporator 10 becomes small, the temperature of the refrigerant | coolant which flows into the rotary compressor 7 falls, and the temperature of the refrigerant | coolant discharged from the rotary compressor 7 falls in connection with this.

  When a predetermined time has elapsed since the output of the heater 29c was lowered (B12: YES), the control device 13 again determines whether or not the comp / conde temperature difference T is equal to or lower than the second predetermined temperature T2 (B13). ). When the compressor / conde temperature difference T is equal to or lower than the second predetermined temperature T2 (B13: YES), the control device 13 ends this control. On the other hand, when the compressor / conde temperature difference T is larger than the second predetermined temperature T2 (B13: NO), the control device 13 checks whether or not the output of the heater 29c is the lower limit value (B14).

  When the output of the heater 29c is not the lower limit value, that is, when the output of the heater 29c can be further reduced (B14: NO), the control device 13 proceeds to step B11 described above and further reduces the output of the heater 29c. To do. On the other hand, when the output of the heater 29c is the lower limit value, that is, when the output of the heater 29c cannot be reduced any more (B14: YES), the control device 13 controls the blower to reduce the operating frequency of the rotary compressor 7 and the blower. At least one of the controls for lowering the rotational speed 6 is performed (B15). When the operating frequency of the rotary compressor 7 is lowered, the degree to which the refrigerant is compressed in the rotary compressor 7 is lowered, and accordingly, the temperature of the refrigerant discharged from the rotary compressor 7 is lowered. Further, when the rotational speed of the blower 6 is lowered, the degree of heat exchange of the refrigerant in the evaporator 10, that is, the degree of heating of the refrigerant is lowered, and the temperature of the refrigerant flowing into the rotary compressor 7 is lowered. Along with this, the temperature of the refrigerant discharged from the rotary compressor 7 decreases.

  When a predetermined time has elapsed after performing at least one of the control for lowering the operating frequency of the rotary compressor 7 and the control for lowering the rotational speed of the blower 6 (B16: YES), the control device 13 again It is determined whether the Comp / Conde temperature difference T is equal to or lower than a second predetermined temperature T2 (B17). When the compressor / conde temperature difference T is equal to or lower than the second predetermined temperature T2 (B17: YES), the control device 13 ends this control. On the other hand, when the compressor / conde temperature difference T is larger than the second predetermined temperature T2 (B17: NO), the control device 13 determines whether or not the operating frequency of the rotary compressor 7 is the lower limit value and the blower 6 It is confirmed whether or not the rotation speed is a lower limit value (B18).

  When the operating frequency of the rotary compressor 7 is not the lower limit value (B18: NO), or when the rotational speed of the blower 6 is not the lower limit value (B18: NO), the control device 13 proceeds to the above-described step B15. Then, when the operating frequency of the rotary compressor 7 can be lowered, the operating frequency is further lowered, and when the rotational speed of the blower 6 can be raised, the rotational speed is further lowered. On the other hand, the control device 13 performs this control when the operating frequency of the rotary compressor 7 is the lower limit value (B18: YES) or when the rotational speed of the blower 6 is the lower limit value (B18: YES). Exit. In this case, for example, the control device 13 may be configured to notify that the refrigerant is easily dissolved in the lubricating oil.

  When the compressor / conde temperature difference T is equal to or lower than the second predetermined temperature T2 (B10: YES, B13: YES, B17: YES), the control device 13 ends this control. That is, in this state, the compressor / conde temperature difference T is maintained in the range from the first predetermined temperature T1 to the second predetermined temperature T2. Under this condition, even if the lubricating oil of the rotary compressor 7 is a lubricating oil compatible with the flammable refrigerant, the amount of the flammable refrigerant that dissolves in the lubricating oil (the amount of dissolution) may be greatly reduced. This has been confirmed by experiments and analysis by the present inventors.

  According to the washing / drying machine 1 according to the present embodiment, in the stable period of the drying operation, the difference between the temperature of the refrigerant discharged from the rotary compressor 7 and the temperature of the condenser 8 is a predetermined temperature range, in this case, 40 ° C. The operating frequency of the rotary compressor 7, the heating amount of the second capillary 29b by the heater 29c, and the rotational speed of the blower 6 are controlled so as to be maintained in the range of from 50 to 50 ° C. Under the condition that the difference between the temperature of the refrigerant discharged from the rotary compressor 7 and the temperature of the condenser 8 is maintained within a predetermined temperature range, the lubricating oil of the rotary compressor 7 is compatible with the combustible refrigerant. Even if the lubricating oil, that is, the lubricating oil in which the flammable refrigerant is easily dissolved, it has been confirmed that the amount of the flammable refrigerant dissolved in the lubricating oil is reduced. Therefore, according to the present embodiment, even when a flammable refrigerant is used as the refrigerant of the heat pump 4 including the rotary compressor 7, the amount of the flammable refrigerant used is not required to improve the lubricating oil of the rotary compressor 7. Can be reduced.

Note that the number of capillaries included in the capillary mechanism unit 29 is not limited to two, and may be one, for example, or may be three or more. When the capillary mechanism unit 29 is configured by a single capillary, heating means is provided for the capillary. Further, when the capillary mechanism unit 29 is constituted by a plurality of capillaries, a heating means may be provided in at least one of the capillaries.
Further, a plurality of capillaries may be provided in the capillary mechanism, and the flow rate of the refrigerant flowing through the evaporator 10 may be adjusted by appropriately switching the number of capillaries through which the refrigerant flows, for example, by a switching valve.

  The clothes dryer which concerns on this embodiment is provided with a drying chamber, a heat pump, a ventilation path, an air blower, and a control means. The heat pump constitutes a refrigeration cycle in which a refrigerant is circulated through a compressor, a condenser, a throttle, and an evaporator, a rotary compressor is provided as a compressor, and a variable throttle valve capable of adjusting the opening degree is provided as a throttle. A combustible refrigerant is provided as a refrigerant. The ventilation path is connected to the drying chamber, and a condenser and an evaporator are disposed therein. The blower circulates the air in the drying chamber through the ventilation path. The control means controls operations of the rotary compressor, the variable throttle valve, and the blower. Then, the control means controls the operating frequency of the rotary compressor, the variable throttle valve so that the difference between the temperature of the combustible refrigerant discharged from the rotary compressor and the temperature of the condenser is maintained at a predetermined temperature in the stable period of the drying operation. By controlling the opening degree and the rotational speed of the blower, the amount of the combustible refrigerant dissolved in the lubricating oil of the rotary compressor is reduced.

  Moreover, the clothes dryer which concerns on this embodiment is provided with a drying chamber, a heat pump, a heating means, a ventilation path, an air blower, and a control means. A heat pump constitutes a refrigeration cycle in which refrigerant is circulated through a compressor, a condenser, a constrictor and an evaporator, a rotary compressor is provided as a compressor, a capillary is provided as a constrictor, and a combustible refrigerant is provided as a refrigerant. ing. The heating means heats the capillary. The ventilation path is connected to the drying chamber, and a condenser and an evaporator are disposed therein. The blower circulates the air in the drying chamber through the ventilation path. The control unit controls operations of the rotary compressor, the heating unit, and the blower. The control means uses the operating frequency of the rotary compressor and the heating means so that the difference between the temperature of the combustible refrigerant discharged from the rotary compressor and the temperature of the condenser is maintained at a predetermined temperature in the stable period of the drying operation. By controlling the heating amount of the capillary and the rotation speed of the blower, the amount of the combustible refrigerant dissolved in the lubricating oil of the rotary compressor is reduced.

  According to these clothes dryers according to this embodiment, in the case where a flammable refrigerant is used as a refrigerant of a heat pump including a rotary compressor, the amount of the flammable refrigerant used is reduced without requiring improvement of the lubricating oil of the rotary compressor. can do.

  This embodiment is presented as an example and is not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  In the drawings, 1 is a washing dryer (clothing dryer), 3 is a water tank (drying chamber), 4 is a heat pump, 5 is a ventilation path, 6 is a blower, 7 is a rotary compressor (compressor), 8 is a condenser, 9 Denotes PMV (variable throttle valve, throttle), 10 denotes an evaporator, 29 denotes a capillary mechanism (throttle), 29a and 29b denote capillaries, and 29c denotes a heater (heating means).

Claims (2)

A drying chamber;
A refrigeration cycle that circulates refrigerant through a compressor, a condenser, a constrictor, and an evaporator is configured. A heat pump provided with a functional refrigerant as the refrigerant;
A ventilation path connected to the drying chamber, in which the condenser and the evaporator are disposed;
A blower for circulating air in the drying chamber through the ventilation path;
The rotary compressor, the variable throttle valve, and a control means for controlling the operation of the blower,
The control means is configured such that, in a stable period of the drying operation, an operation frequency of the rotary compressor so that a difference between a temperature of the combustible refrigerant discharged from the rotary compressor and a temperature of the condenser is maintained at a predetermined temperature. A clothes dryer that reduces the amount of the combustible refrigerant dissolved in the lubricating oil of the rotary compressor by controlling the opening of the variable throttle valve and the rotational speed of the blower. A drying chamber;
A refrigeration cycle is configured to circulate refrigerant through a compressor, a condenser, a constrictor, and an evaporator, a rotary compressor is provided as the compressor, a capillary is provided as the constrictor, and a combustible refrigerant is provided as the refrigerant. A heat pump,
Heating means for heating the capillary;
A ventilation path connected to the drying chamber, in which the condenser and the evaporator are disposed;
A blower for circulating air in the drying chamber through the ventilation path;
The rotary compressor, the heating means, and a control means for controlling the operation of the blower,
The control means is configured such that, in a stable period of the drying operation, an operation frequency of the rotary compressor so that a difference between a temperature of the combustible refrigerant discharged from the rotary compressor and a temperature of the condenser is maintained at a predetermined temperature. A clothes dryer that reduces the amount of the combustible refrigerant dissolved in the lubricating oil of the rotary compressor by controlling the heating amount of the capillary by the heating means and the rotational speed of the blower.

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