JP2022056004A - Heat capacity estimation system, refrigerant cycle device and heat capacity estimation method - Google Patents

Abstract

To provide a heat capacity estimation system capable of reducing time required for defrosting operation.SOLUTION: A heat capacity estimation system 200 estimates heat capacity of a predetermined section of a refrigerant cycle device 100. The heat capacity estimation system 200 comprises a calculation section 61 and a first estimation section 71. The calculation section 61 calculates amounts of potential heat of a user side heat exchanger 31 and gas communication piping GP from a start time of the defrosting operation to a time when a temperature of the gas communication piping GP or a degree of superheat of a refrigerant is reduced to a predetermined value or a time when an absolute value of a reduction amount of the temperature of the gas communication piping GP or the degree of superheat of the refrigerant within a predetermined period exceeds a predetermined value. The defrosting operation is to defrost a heat source side heat exchanger 13 by supplying the refrigerant discharged from a compressor 11 to the heat source side heat exchanger 13. The first estimation section 71 estimates the heat capacity of the predetermined section on the basis of the amounts of potential heat calculated with the calculation section 61. The predetermined section includes the gas communication piping GP.SELECTED DRAWING: Figure 6

Description

The present invention relates to a heat capacity estimation system that estimates the heat capacity of a predetermined portion of a refrigerant cycle device, a heat capacity estimation method that estimates the heat capacity of a predetermined portion of a refrigerant cycle device, and a refrigerant cycle device.

Conventionally, as described in Patent Document 1 (Japanese Unexamined Patent Publication No. 2003-302131), the outdoor unit is provided by utilizing the connecting pipe connecting the outdoor unit and the indoor unit and the heat storage of the heat exchanger of the indoor unit. A refrigerant cycle device that performs a defrost operation to defrost the heat exchanger is used.

The refrigerant cycle device that performs the defrost operation controls, for example, to close the electric valve of the indoor unit and end the defrost operation when it detects that the heat storage of the connecting pipe and the heat exchanger of the indoor unit is exhausted. In this case, depending on the configuration of the refrigerant cycle device, the time required for the defrost operation may become long.

The heat capacity estimation system of the first aspect estimates the heat capacity of a predetermined portion of the refrigerant cycle device. The refrigerant cycle device is a device in which an outdoor unit having a compressor and a heat source side heat exchanger and an indoor unit having a user side heat exchanger are connected via a connecting pipe. The heat capacity estimation system includes a calculation unit and a first estimation unit. From the start of defrost operation, the calculation unit is at the time when the temperature of the gas connecting pipe or the degree of overheating of the refrigerant in the gas connecting pipe drops to a predetermined value, or the temperature of the gas connecting pipe, or in the gas connecting pipe. The amount of heat possessed by the heat exchanger on the user side and the gas connecting pipe is calculated up to the point when the absolute value of the amount of decrease in the degree of overheating of the refrigerant in the predetermined time exceeds the predetermined value. The defrost operation is an operation in which the refrigerant discharged from the compressor is supplied to the heat source side heat exchanger to defrost the heat source side heat exchanger. The gas connecting pipe is a connecting pipe that connects the compressor and the heat exchanger on the user side. The first estimation unit estimates the heat capacity of a predetermined portion based on the amount of heat possessed by the user-side heat exchanger and the gas connecting pipe calculated by the calculation unit. The predetermined part includes the gas connecting pipe.

The heat capacity estimation system of the first aspect can estimate the amount of surplus refrigerant in the refrigerant cycle device by estimating the heat capacity of a predetermined portion of the refrigerant cycle device, and can shorten the time required for the defrost operation.

The heat capacity estimation system of the second viewpoint is the heat capacity estimation system of the first viewpoint, and further includes an acquisition unit and a second estimation unit. The acquisition unit acquires the heat capacity of the heat exchanger on the user side. The second estimation unit estimates the amount of heat possessed by the user side heat exchanger based on the heat capacity of the user side heat exchanger acquired by the acquisition unit. The first estimation unit is based on the heat capacity of the user-side heat exchanger and the gas communication pipe calculated by the calculation unit and the heat capacity of the user-side heat exchanger estimated by the second estimation unit. Estimate the heat capacity of.

The heat capacity estimation system of the second aspect can estimate the amount of surplus refrigerant in the refrigerant cycle device by estimating the heat capacity of the gas connecting pipe of the refrigerant cycle device, and can shorten the time required for the defrost operation.

The heat capacity estimation system of the third viewpoint is the heat capacity estimation system of the second viewpoint, and further includes a third estimation unit. The third estimation unit estimates the amount of excess refrigerant in the refrigerant cycle device based on the heat capacity of the gas connecting pipe estimated by the first estimation unit.

The heat capacity estimation system of the third aspect can shorten the time required for the defrost operation by estimating the amount of surplus refrigerant in the refrigerant cycle device.

The heat capacity estimation system of the fourth aspect is the heat capacity estimation system of the second aspect, and further includes a first determination unit. The first determination unit determines at least one of the opening degree of the solenoid valve during the defrost operation and the time for maintaining the opening degree based on the heat capacity of the gas connecting pipe estimated by the first estimation unit. .. The indoor unit further has an indoor motorized valve for adjusting the amount of refrigerant supplied to the utilization side heat exchanger during defrost operation.

The heat capacity estimation system of the fourth aspect can control the opening degree of the indoor solenoid valve during the defrost operation by estimating the heat capacity of the gas connecting pipe of the refrigerant cycle device, and can shorten the time required for the defrost operation. ..

The heat capacity estimation system of the fifth aspect is the heat capacity estimation system of the third aspect, and further includes a first determination unit. The first determination unit determines at least one of the opening degree of the solenoid valve during the defrost operation and the time for maintaining the opening degree based on the excess refrigerant amount estimated by the third estimation unit. The indoor unit further has an indoor motorized valve for adjusting the amount of refrigerant supplied to the utilization side heat exchanger during defrost operation.

The heat capacity estimation system of the fifth aspect can control the opening degree of the indoor solenoid valve during the defrost operation by estimating the amount of surplus refrigerant in the refrigerant cycle device, and can shorten the time required for the defrost operation.

The heat capacity estimation system of the sixth aspect is the heat capacity estimation system of the second aspect or the fifth aspect, and the refrigerant cycle apparatus has a plurality of outdoor units and further includes a second determination unit. The second determination unit determines the method of defrost operation based on the heat capacity of the gas connecting pipe estimated by the first estimation unit. The defrost operation method is the first method that uses the heat amount of the heat exchanger on the user side and the gas communication pipe, or the heat exchanger of each outdoor unit is alternately used as a radiator or a heat absorber among multiple outdoor units. This is the second method used as the above.

The heat capacity estimation system of the sixth aspect can determine an appropriate defrost operation method by estimating the heat capacity of the gas connecting pipe of the refrigerant cycle device, and can shorten the time required for the defrost operation.

The refrigerant cycle device according to the seventh aspect is a device in which an outdoor unit having a compressor and a heat source side heat exchanger and an indoor unit having a user side heat exchanger are connected via a connecting pipe. The refrigerant cycle device includes a calculation unit and a first estimation unit. From the start of defrost operation, the calculation unit is at the time when the temperature of the gas connecting pipe or the degree of overheating of the refrigerant in the gas connecting pipe drops to a predetermined value, or the temperature of the gas connecting pipe, or in the gas connecting pipe. The amount of heat possessed by the heat exchanger on the user side and the gas connecting pipe is calculated up to the point when the absolute value of the amount of decrease in the degree of overheating of the refrigerant in the predetermined time exceeds the predetermined value. The defrost operation is an operation in which the refrigerant discharged from the compressor is supplied to the heat source side heat exchanger to defrost the heat source side heat exchanger. The gas connecting pipe is a connecting pipe that connects the compressor and the heat exchanger on the user side. The first estimation unit estimates the heat capacity of a predetermined portion based on the amount of heat possessed by the user-side heat exchanger and the gas connecting pipe calculated by the calculation unit. The predetermined part includes the gas connecting pipe.

The refrigerant cycle device according to the seventh aspect can estimate the amount of surplus refrigerant by estimating the heat capacity of a predetermined portion of the refrigerant cycle device, and can shorten the time required for the defrost operation.

The heat capacity estimation method of the eighth aspect is a method of estimating the heat capacity of a predetermined portion of the refrigerant cycle device. The refrigerant cycle device is a device in which an outdoor unit having a compressor and a heat source side heat exchanger and an indoor unit having a user side heat exchanger are connected via a connecting pipe. The heat capacity estimation method includes a calculation step and an estimation step. In the calculation step, from the start of the defrost operation, when the temperature of the gas connecting pipe or the degree of overheating of the refrigerant in the gas connecting pipe drops to a predetermined value, or the temperature of the gas connecting pipe, or in the gas connecting pipe. The amount of heat possessed by the heat exchanger on the user side and the gas connecting pipe is calculated up to the point when the absolute value of the amount of decrease in the degree of overheating of the refrigerant in the predetermined time exceeds the predetermined value. The defrost operation is an operation in which the refrigerant discharged from the compressor is supplied to the heat source side heat exchanger to defrost the heat source side heat exchanger. The gas connecting pipe is a connecting pipe that connects the compressor and the heat exchanger on the user side. In the estimation step, the heat capacity of a predetermined portion is estimated based on the amount of heat possessed by the user-side heat exchanger and the gas connecting pipe calculated in the calculation step. The predetermined part includes the gas connecting pipe.

The heat capacity estimation method of the eighth aspect can estimate the amount of surplus refrigerant in the refrigerant cycle device by estimating the heat capacity of a predetermined portion of the refrigerant cycle device, and can shorten the time required for the defrost operation.

It is a schematic block diagram of a heat capacity estimation system 200. It is a time chart at the time of execution of defrost operation. It is a pressure-enthalpy diagram before the start of defrost operation. It is a pressure-enthalpy diagram at the time of performing defrost operation. It is a block diagram of a control unit 60. It is a flowchart of opening degree change control of an indoor electric valve 32. It is a block diagram of the control unit 60 in the modification A. It is a schematic block diagram of the heat capacity estimation system 200 in the modification H.

The heat capacity estimation system 200 according to the embodiment of the present disclosure will be described with reference to the drawings.

(1) Configuration of heat capacity estimation system 200 The heat capacity estimation system 200 realizes air conditioning such as cooling and heating in a target space included in a building such as a house, a building, a factory or a public facility by using a refrigerant cycle device 100. It is configured to do. The heat capacity estimation system 200 includes a refrigerant cycle device 100.

The refrigerant cycle device 100 includes a refrigerant circuit RC in which a refrigerant circulates. The refrigerant cycle device 100 cools or heats the target space by circulating the refrigerant in the refrigerant circuit RC and performing a steam compression type refrigeration cycle. A refrigerant such as R410A, R32 or ammonia is sealed in the refrigerant circuit RC.

The refrigerant cycle device 100 mainly includes one outdoor unit 10 as a heat source unit, a plurality of indoor units 30 (30a, 30b, 30c) as utilization units (three in FIG. 1), and a plurality of units (FIG. 1). It is equipped with a remote controller 50 (three in 1) and a control unit 60. The refrigerant circuit RC of the refrigerant cycle device 100 is configured by connecting the outdoor unit 10 and each indoor unit 30 by a gas communication pipe GP and a liquid communication pipe LP. In other words, the refrigerant cycle device 100 is a multi-type (multi-tenant) air conditioner in which a plurality of indoor units 30 are connected to the same refrigerant system.

(1-1) Outdoor unit 10
The outdoor unit 10 is an outdoor unit arranged outdoors (outside the target space). The outdoor unit 10 mainly includes a plurality of refrigerant pipes (first pipe P1 to fifth pipe P5), a compressor 11, a four-way switching valve 12, a heat source side heat exchanger 13, an outdoor fan 15, and an outdoor unit. It has a unit control unit 17, an accumulator 19, and a temperature sensor 40.

The first pipe P1 is a refrigerant pipe that connects the gas connecting pipe GP and the four-way switching valve 12. The second pipe P2 is a suction pipe that connects the four-way switching valve 12 and the suction port (not shown) of the compressor 11. The third pipe P3 is a discharge pipe that connects the discharge port (not shown) of the compressor 11 and the four-way switching valve 12. The fourth pipe P4 is a refrigerant pipe that connects the four-way switching valve 12 and the gas side of the heat source side heat exchanger 13. The fifth pipe P5 is a refrigerant pipe that connects the liquid side of the heat source side heat exchanger 13 and the liquid communication pipe LP.

The compressor 11 is a mechanism that sucks in the low-pressure gas refrigerant and discharges the high-pressure gas refrigerant. The compressor 11 has a closed structure in which the compressor motor 11a is built. In the compressor 11, a rotary type or scroll type compression element (not shown) housed in the compressor casing (not shown) is driven by the compressor motor 11a as a drive source. The compressor motor 11a is controlled by an inverter during operation, and the rotation speed is adjusted according to the situation. At the time of driving, the compressor 11 sucks the refrigerant from the suction port, compresses it, and discharges it from the discharge port.

The four-way switching valve 12 is a valve for switching the flow direction of the refrigerant in the refrigerant circuit RC. The four-way switching valve 12 is individually connected to the first pipe P1, the second pipe P2, the third pipe P3, and the fourth pipe P4. The four-way switching valve 12 switches the flow path so that the first pipe P1 and the second pipe P2 are connected and the third pipe P3 and the fourth pipe P4 are connected during the cooling operation (FIG. 1 Refer to the solid line of the four-way switching valve 12.). The four-way switching valve 12 switches the flow path so that the first pipe P1 and the third pipe P3 are connected and the second pipe P2 and the fourth pipe P4 are connected during the heating operation (FIG. Refer to the broken line of the four-way switching valve 12 in 1).

The heat source side heat exchanger 13 is a heat exchanger that functions as a refrigerant condenser or radiator during cooling operation and as a refrigerant evaporator or endothermic during heating operation. The heat source side heat exchanger 13 includes a heat transfer tube through which the refrigerant flows (not shown) and heat transfer fins (not shown) for increasing the heat transfer area. The heat source side heat exchanger 13 is arranged so that the refrigerant in the heat transfer tube and the air flow generated by the outdoor fan 15 can exchange heat during operation.

The outdoor fan 15 is, for example, a propeller fan. The outdoor fan 15 is connected to the output shaft of the outdoor fan motor 15a and is driven in conjunction with the outdoor fan motor 15a. When the outdoor fan 15 is driven, it generates an air flow that flows into the outdoor unit 10 from the outside, passes through the heat source side heat exchanger 13, and then flows out to the outside of the outdoor unit 10.

The outdoor unit control unit 17 is a microcomputer composed of a CPU, a memory, and the like. The outdoor unit control unit 17 controls the operation of each actuator of the outdoor unit 10. The outdoor unit control unit 17 is connected to the indoor unit control unit 34 of each indoor unit 30 via a communication line (not shown), and transmits and receives signals to and from each other.

The accumulator 19 is attached to the second pipe P2. The accumulator 19 separates the gas-liquid mixed refrigerant flowing through the refrigerant circuit RC into a gas refrigerant and a liquid refrigerant, and sends only the gas refrigerant to the suction port of the compressor 11. The liquid refrigerant separated from the gas refrigerant is stored in the accumulator 19. When the liquid refrigerant exceeding a predetermined allowable amount is stored in the accumulator 19, a part of the liquid refrigerant overflows from the accumulator 19 and is discharged to the second pipe P2. As a result, the liquid refrigerant is sent to the suction port of the compressor 11, and there is a possibility that liquid back, which is a phenomenon in which the compressor 11 sucks the liquid refrigerant, occurs.

The temperature sensor 40 is attached to the second pipe P2. The temperature sensor 40 is attached between the accumulator 19 and the four-way switching valve 12 in the vicinity of the accumulator 19. The temperature sensor 40 is arranged to measure the temperature of the refrigerant flowing into the accumulator 19.

(1-2) Indoor unit 30
The indoor unit 30 (30a, 30b, 30c) is an indoor unit arranged in the target space. The indoor unit 30 and the outdoor unit 10 form a refrigerant circuit RC. The indoor unit 30 mainly has a user-side heat exchanger 31, an indoor motorized valve 32 (32a, 32b, 32c), an indoor fan 33, and an indoor unit control unit 34.

The user-side heat exchanger 31 is a heat exchanger that functions as a refrigerant evaporator or a heat absorber during a cooling operation and as a refrigerant condenser or a radiator during a heating operation. The user side heat exchanger 31 is, for example, a cross fin tube heat exchanger. The liquid side of the user-side heat exchanger 31 is connected to the indoor motorized valves 32 (32a, 32b, 32c) via a refrigerant pipe. The gas side of the user-side heat exchanger 31 is connected to the gas connecting pipe GP via a refrigerant pipe. One end of the gas connecting pipe GP is connected to the first pipe P1 of the outdoor unit 10. The other end of the gas communication pipe GP is branched according to the number of indoor units 30, and is individually connected to the user-side heat exchanger 31 of each indoor unit 30 via the refrigerant pipe of each indoor unit 30. .. The user-side heat exchanger 31 has a heat transfer tube through which the refrigerant flows. The user-side heat exchanger 31 is arranged so that the refrigerant in the heat transfer tube (not shown) and the air flow generated by the indoor fan 33 can exchange heat during operation.

The indoor motorized valve 32 (32a, 32b, 32c) is an electronic expansion valve whose opening degree can be adjusted. The opening degree of the indoor motorized valve 32 is appropriately adjusted according to the situation during operation, and the refrigerant is depressurized according to the opening degree. Each indoor unit 30 has one indoor electric valve 32. Specifically, the indoor unit 30a has an indoor motorized valve 32a, the indoor unit 30b has an indoor motorized valve 32b, and the indoor unit 30c has an indoor motorized valve 32c. The opening degrees of the indoor motorized valves 32a, 32b, 32c are appropriately adjusted according to the operating conditions of the corresponding indoor units 30a, 30b, 30c, respectively.

The indoor electric valve 32 is connected to the liquid side of the user side heat exchanger 31 via a refrigerant pipe, and is connected to the liquid communication pipe LP via a refrigerant pipe. One end of the liquid communication pipe LP is connected to the fifth pipe P5 of the outdoor unit 10. The other end of the liquid communication pipe LP is branched according to the number of the indoor units 30, and is individually connected to the indoor electric valve 32 of each indoor unit 30 via the refrigerant pipe of each indoor unit 30.

The indoor fan 33 is, for example, a blower such as a turbo fan, a sirocco fan, a cross flow fan, or a propeller fan. The indoor fan 33 is connected to the output shaft of the indoor fan motor 33a. The indoor fan 33 is driven in conjunction with the indoor fan motor 33a. When the indoor fan 33 is driven, it generates an air flow that is sucked into the indoor unit 30, passes through the user-side heat exchanger 31, and then blown out to the target space.

The indoor unit control unit 34 is a microcomputer composed of a CPU, a memory, and the like. The indoor unit control unit 34 controls the operation of each actuator of the indoor unit 30. Each indoor unit control unit 34 is connected to the outdoor unit control unit 17 via a communication line, and transmits and receives signals to and from each other. The indoor unit control unit 34 wirelessly communicates with the remote controller 50.

The indoor unit control unit 34 of the indoor unit 30 is connected to the indoor motorized valve 32 of the indoor unit 30 via a communication line (not shown), and the opening degree of the indoor motorized valve 32 can be adjusted.

(1-3) Remote control 50
The remote controller 50 includes a remote controller control unit (not shown) including a microcomputer composed of a CPU, a memory, and the like, and a remote controller input unit (not shown) including input keys for inputting various commands to the refrigerant cycle device 100. It is a device to have.

The refrigerant cycle device 100 has the same number of remote controllers 50 as the indoor unit 30. The remote controller 50 is associated with any of the indoor units 30 on a one-to-one basis. The remote controller 50 performs wireless communication with the indoor unit control unit 34 of the corresponding indoor unit 30 by using infrared rays, radio waves, and the like. When a command is input to the remote controller input unit by a user, an administrator, or the like, the remote controller 50 transmits a predetermined signal to the indoor unit control unit 34 in response to the input command.

(1-4) Control unit 60
In the refrigerant cycle device 100, the outdoor unit control unit 17 of the outdoor unit 10 and the indoor unit control unit 34 of each indoor unit 30 (30a, 30b, 30c) are connected via a communication line to connect the control unit 60. Is configured. The control unit 60 controls the operation of the refrigerant cycle device 100. The control unit 60 is connected to each component of the refrigerant cycle device 100 to be controlled by wire or wirelessly.

(2) Operation of Refrigerant Cycle Device 100 When an operation start command is input to any remote controller 50 and control related to cooling operation or heating operation is executed by the control unit 60, the four-way switching valve 12 is in a predetermined state. It is switched and the compressor 11 and the outdoor fan 15 are activated. After that, the indoor unit 30 corresponding to the remote controller 50 to which the operation start command is input is put into the operating state (the state in which the indoor fan 33 is operating). The refrigerant cycle device 100 can perform a cooling operation, a heating operation, and a defrost operation.

(2-1) Cooling operation During the cooling operation, the four-way switching valve 12 is switched to the cooling cycle state (the state shown by the solid line of the four-way switching valve 12 in FIG. 1). When each actuator of the refrigerant cycle device 100 is activated in this state, the refrigerant is sucked into the compressor 11 via the second pipe P2 and compressed. The refrigerant discharged from the compressor 11 passes through the third pipe P3, the four-way switching valve 12, and the fourth pipe P4, and flows into the heat source side heat exchanger 13.

The refrigerant flowing into the heat source side heat exchanger 13 exchanges heat with the air flow generated by the outdoor fan 15 and dissipates (condenses). The refrigerant flowing out of the heat source side heat exchanger 13 passes through the fifth pipe P5 and the liquid communication pipe LP and flows into each indoor unit 30.

The refrigerant that has flowed into the indoor unit 30 flows into the indoor motorized valve 32. The refrigerant flowing into the indoor motor-operated valve 32 is depressurized according to the opening degree of the indoor motor-operated valve 32. The refrigerant flowing out of the indoor motorized valve 32 flows into the user-side heat exchanger 31 and exchanges heat with the air flow generated by the indoor fan 33 to absorb (evaporate) heat. The refrigerant flowing out of the user-side heat exchanger 31 passes through the gas connecting pipe GP and flows into the outdoor unit 10.

The refrigerant flowing into the outdoor unit 10 passes through the first pipe P1, the four-way switching valve 12, and the second pipe P2, and is sucked into the compressor 11 again and compressed.

(2-2) Heating operation During the heating operation, the four-way switching valve 12 is switched to the heating cycle state (the state shown by the broken line of the four-way switching valve 12 in FIG. 1). When each actuator of the refrigerant cycle device 100 is activated in this state, the refrigerant is sucked into the compressor 11 via the second pipe P2 and compressed. The refrigerant discharged from the compressor 11 passes through the third pipe P3, the four-way switching valve 12, the first pipe P1 and the gas communication pipe GP, and flows into each indoor unit 30.

The refrigerant that has flowed into the indoor unit 30 flows into the user-side heat exchanger 31 and exchanges heat with the air flow generated by the indoor fan 33 to dissipate heat (condensation). The refrigerant flowing out of the user-side heat exchanger 31 flows into the indoor motorized valve 32 and is depressurized according to the opening degree of the indoor motorized valve 32. The refrigerant flowing out of the indoor motorized valve 32 passes through the liquid communication pipe LP and flows into the outdoor unit 10.

The refrigerant that has flowed into the outdoor unit 10 passes through the fifth pipe P5 and flows into the heat source side heat exchanger 13. The refrigerant flowing into the heat source side heat exchanger 13 exchanges heat with the air flow generated by the outdoor fan 15 and absorbs (evaporates) heat. The refrigerant flowing out of the heat source side heat exchanger 13 passes through the fourth pipe P4, the four-way switching valve 12, and the second pipe P2, and is sucked into the compressor 11 again and compressed.

(2-3) Defrost operation The defrost operation is an operation for removing frost generated in the heat source side heat exchanger 13 during the heating operation. During the heating operation, the air flow generated by the outdoor fan 15 is cooled as it passes through the heat source side heat exchanger 13. Therefore, when the humidity of the outside air is high during the heating operation, frost generated from the water vapor contained in the outside air tends to adhere to the heat exchange portion (heat transfer tube and heat transfer fin) of the heat source side heat exchanger 13. be. If the surface of the heat exchange portion of the heat source side heat exchanger 13 is covered with frost, the heat exchange capacity of the heat source side heat exchanger 13 may decrease, and the operating capacity of the refrigerant cycle device 100 may decrease. Therefore, the defrost operation is performed as necessary in order to suppress a decrease in the operating capacity of the refrigerant cycle device 100. The defrost operation is executed by inputting a defrost operation start command to any of the remote controllers 50. The defrost operation may be automatically executed when the continuous execution time of the heating operation exceeds a predetermined value. Next, the control of the defrost operation by the control unit 60 will be described with reference to FIG. 2. FIG. 3 is a pressure-enthalpy diagram during the heating operation before the start of the defrost operation. FIG. 4 is a pressure-enthalpy diagram when the outlet of the gas connecting pipe GP becomes damp when the defrost operation is executed.

The control unit 60 switches the four-way switching valve 12 from the heating cycle state to the cooling cycle state, and starts the defrost operation of the heat source side heat exchanger 13 (time t1 in FIG. 2). The opening degree of the indoor motorized valve 32 at the start of the defrost operation is the first opening degree. The first opening degree may be set according to the risk level. The risk level is, for example, the possibility of liquid refrigerant flowing into the suction pipe (first pipe P1) of the outdoor unit 10 and water leakage due to the generation of drain water in the heat exchanger 31 on the user side of the indoor unit 30. May occur. The control unit 60 may be set to have a smaller first opening degree as the risk level is higher.

In the defrost operation, the frost adhering to the heat source side heat exchanger 13 is removed by utilizing the heat accumulated in the user side heat exchanger 31 and the gas connecting pipe GP during the heating operation before the start of the defrost operation. .. When the four-way switching valve 12 is switched at time t1 (FIG. 2) to start the defrost operation, the refrigerant in the user side heat exchanger 31 and the gas connecting pipe GP uses the first pipe P1 and the four-way switching valve 12. It passes through and flows into the accumulator 19 attached to the second pipe P2. Therefore, as shown in FIG. 2, after the start of the defrost operation, the accumulator inlet temperature measured by the temperature sensor 40 rises due to the heat storage of the user side heat exchanger 31 and the gas connecting pipe GP (time t2 in FIG. 2). ). During the execution of the defrost operation, the heat source side heat exchanger 13 functions as a refrigerant condenser or radiator, and the user side heat exchanger 31 functions as a refrigerant evaporator or heat absorber.

In the defrost operation, the refrigerant in the user-side heat exchanger 31 and the gas connecting pipe GP is sucked into the compressor 11, and the refrigerant discharged from the compressor 11 is supplied to the heat source-side heat exchanger 13. As a result, the frost adhering to the heat source side heat exchanger 13 from the start time of the defrost operation to a predetermined time point is melted and removed by the heat storage of the user side heat exchanger 31 and the gas connecting pipe GP. As shown in FIG. 2, the heat storage of the user-side heat exchanger 31 is used, so that the temperature of the user-side heat exchanger 31 is lowered. By supplying the heat storage of the user side heat exchanger 31 and the gas connecting pipe GP to the heat source side heat exchanger 13, the temperature of the heat source side heat exchanger 13 rises.

After the start of the defrost operation, when the heat storage of the heat exchanger 31 on the user side and the gas connecting pipe GP disappears, the accumulator inlet temperature drops (time t3 in FIG. 2). At this time, the outlet of the gas connecting pipe GP becomes damp. In FIGS. 3 and 4, the state of the refrigerant at the outlet of the gas connecting pipe GP (the connection portion between the gas connecting pipe GP and the first pipe P1) is indicated by the point Q. When the outlet of the gas connecting pipe GP becomes damp, as shown in FIG. 4, a refrigerant in a gas-liquid two-phase state flows at the outlet of the gas connecting pipe GP. In this case, since liquid backing may occur, the opening degree of the indoor motorized valve 32 is reduced from the first opening degree to a predetermined second opening degree at time t3.

After that, when the frost adhering to the heat source side heat exchanger 13 is removed, the accumulator inlet temperature also begins to rise. As a result, the defrost operation ends (time t4 in FIG. 2). During the period during which the defrost operation is being executed (periods t1 to t4 in FIG. 2), and during the period after the heat storage of the heat exchanger 31 on the user side and the gas connecting pipe GP is exhausted (periods t3 to t4 in FIG. 2). The opening degree of the indoor electric valve 32 is maintained at the second opening degree. The control unit 60 determines the second opening degree and the time during which the second opening degree is maintained by the method described later.

After the defrost operation is completed, the control unit 60 switches the four-way switching valve 12 from the cooling cycle state to the heating cycle state. As a result, the heating operation of the refrigerant cycle device 100 is restarted.

(3) The operating heat capacity estimation system 200 of the control unit 60 estimates the heat capacity of a predetermined portion of the refrigerant cycle device 100. The predetermined portion includes the gas connecting pipe GP. In the present embodiment, the predetermined portion is composed of the gas connecting pipe GP. The control unit 60 performs opening degree change control for changing the opening degree of the indoor motorized valve 32 of each indoor unit 30 during the defrost operation. Next, the estimation of the heat capacity of the predetermined portion by the control unit 60 and the opening degree change control of the indoor motorized valve 32 will be described.

As shown in FIG. 5, the control unit 60 mainly includes a calculation unit 61, an acquisition unit 62, a first estimation unit 71, a second estimation unit 72, a third estimation unit 73, and a first determination unit. Has 81 and. These elements execute each function of the control unit 60 by realizing the calculation of specific information by means and methods in which the hardware (CPU, memory, etc.) of the control unit 60 and the software cooperate with each other. Each function of the control unit 60 is realized by at least one of the outdoor unit control unit 17 and the indoor unit control unit 34. The control unit 60 executes these controls according to the flowchart of FIG.

The calculation unit 61 is the user side heat exchanger 31 and the gas from the start time of the defrost operation (time t1 in FIG. 2) to the time when the temperature of the gas connecting pipe GP drops to a predetermined value (time t3 in FIG. 2). The amount of heat held in the portion composed of the connecting pipe GP (the amount of heat held by the heat exchanger 31 on the user side and the gas connecting pipe GP) is calculated (step S1 in FIG. 6). The calculation unit 61 uses the accumulator inlet temperature measured by the temperature sensor 40 as the temperature of the gas connecting pipe GP. The predetermined value is the temperature at which the outlet of the gas connecting pipe GP becomes damp after the start of the defrost operation. The predetermined value corresponds to the temperature when the heat storage of the heat exchanger 31 on the user side and the gas connecting pipe GP is exhausted. The predetermined value may be preset from the pressure-enthalpy diagram as shown in FIGS. 3 and 4. The calculation unit 61 calculates the amount of heat possessed by the user-side heat exchanger 31 and the gas connecting pipe GP by integrating the amount of heat used from the start of the defrost operation to the time when the outlet of the gas connecting pipe GP becomes damp. do. The amount of heat used is the amount of heat used for evaporation (endothermic) of the refrigerant by the user side heat exchanger 31 and the gas connecting pipe GP at a predetermined time. The amount of heat used corresponds to the value obtained by multiplying the enthalpy difference H1 shown in FIG. 3 or the enthalpy difference H2 shown in FIG. 4 by the amount of refrigerant circulation. The enthalpy differences H1 and H2 correspond to the difference between the enthalpy near the inlet of the user-side heat exchanger 31 and the enthalpy near the outlet of the user-side heat exchanger 31. The refrigerant circulation amount is the flow rate of the refrigerant passing through the utilization side heat exchanger 31 within a predetermined period. The retained heat amount calculated by the calculation unit 61 is a portion consisting of the user side heat exchanger 31 and the gas connecting pipe GP from the time t1 when the defrost operation starts to the time t3 when the temperature of the gas connecting pipe GP drops to a predetermined value. Corresponds to the integrated value of the decrease in the amount of heat. The calculation unit 61 calculates the amount of heat possessed by integrating the amount of heat used at each time from the time t1 when the defrost operation starts to the time t3 when the temperature of the gas connecting pipe GP drops to a predetermined value.

The acquisition unit 62 acquires the heat capacity of the user-side heat exchanger 31 (step S2 in FIG. 6). The acquisition unit 62 acquires the heat capacity of each user-side heat exchanger 31 from the database stored in the storage device (memory, hard disk drive, solid state drive, etc.) of the control unit 60.

The second estimation unit 72 estimates the amount of heat possessed by the user side heat exchanger 31 based on the heat capacity of the user side heat exchanger 31 acquired by the acquisition unit 62 (step S3 in FIG. 6). Specifically, the second estimation unit 72 is the user side heat exchanger at the time t3 when the temperature of the gas connecting pipe GP drops to a predetermined value from the temperature of the user side heat exchanger 31 at the time t1 when the defrost operation starts. The first temperature decrease value obtained by subtracting the temperature of 31 is calculated. Next, the second estimation unit 72 estimates a value obtained by multiplying the calculated first temperature decrease value by the heat capacity of the user-side heat exchanger 31 as the amount of heat possessed by the user-side heat exchanger 31.

The first estimation unit 71 determines the amount of heat possessed by the user-side heat exchanger 31 and the gas connecting pipe GP calculated by the calculation unit 61, and the amount of heat possessed by the user-side heat exchanger 31 estimated by the second estimation unit 72. Based on this, the heat capacity of the gas connecting pipe GP is estimated (step S4 in FIG. 6). Specifically, the first estimation unit 71 calculates the amount of heat possessed by the gas connecting pipe GP by subtracting the amount of heat possessed by the user side heat exchanger 31 from the amount of heat possessed by the user side heat exchanger 31 and the gas connecting pipe GP. do. Next, the first estimation unit 71 subtracts the temperature of the gas connecting pipe GP at the time t3 when the temperature of the gas connecting pipe GP drops to a predetermined value from the temperature of the gas connecting pipe GP at the time t1 when the defrost operation starts. The second temperature drop value is calculated. Next, the first estimation unit 71 estimates the value obtained by dividing the amount of heat possessed by the gas connecting pipe GP by the calculated second temperature decrease value as the heat capacity of the gas connecting pipe GP.

The third estimation unit 73 estimates the amount of surplus refrigerant in the refrigerant cycle device 100 based on the heat capacity of the gas connecting pipe GP estimated by the first estimation unit 71. The surplus refrigerant amount is a parameter indicating whether the amount of the refrigerant filled in the refrigerant cycle device 100 (filled refrigerant amount) is large or small with respect to the capacity of the accumulator 19.

First, the third estimation unit 73 transfers the heat capacity (J / K) of the gas connecting pipe GP estimated by the first estimation unit 71 to the specific heat (J / (kg · K)) of the material of the gas connecting pipe GP. Divide to calculate the total weight (kg) of the gas connecting pipe GP (step S5 in FIG. 6). The specific heat of the material (for example, copper) of the gas connecting pipe GP is stored in advance in the storage device of the control unit 60.

Next, the third estimation unit 73 estimates the dimensions of the gas connecting pipe GP based on the calculated value of the total weight of the gas connecting pipe GP and the installation conditions of the gas connecting pipe GP (step S6 in FIG. 6). .. The dimensions of the gas connecting pipe GP are the length and diameter of the gas connecting pipe GP. Specifically, the third estimation unit 73 is based on the layout of the gas connecting pipe GP so that the amount of the additional filled refrigerant, which is the amount of the additionally filled refrigerant at the time of the installation work of the refrigerant cycle device 100, is the largest. , Estimate the dimensions of the gas connecting pipe GP. The third estimation unit 73 may estimate the dimensions of the gas connecting pipe GP based only on the calculated value of the total weight of the gas connecting pipe GP.

Next, the third estimation unit 73 calculates the amount of the additional filled refrigerant of the refrigerant cycle device 100 based on the estimated value of the dimensions of the gas connecting pipe GP (step S7 in FIG. 6). For example, the third estimation unit 73 calculates the volume of the gas connecting pipe GP based on the dimensions of the gas connecting pipe GP, and calculates a predetermined ratio of the calculated value of the volume of the gas connecting pipe GP as the additional filling refrigerant amount. May be good.

Next, the third estimation unit 73 estimates the amount of surplus refrigerant in the refrigerant cycle device 100 based on the calculated value of the amount of additional filled refrigerant (step S8 in FIG. 6). For example, the third estimation unit 73 may calculate the excess refrigerant amount by adding at least a part of the allowable overfilling amount of the refrigerant of the refrigerant cycle device 100 to the calculated value of the additional filled refrigerant amount.

Based on the amount of surplus refrigerant estimated by the third estimation unit 73, the first determination unit 81 determines the opening degree of the indoor solenoid valve 32 during the defrost operation and the time for maintaining the opening degree (period t3 in FIG. 2). At least one of (t4) is determined (step S9 in FIG. 6). The opening degree of the indoor motorized valve 32 is the above-mentioned "second opening degree" maintained during the execution of the defrost operation. In the present embodiment, the first determination unit 81 determines both the second opening degree and the time during which the second opening degree is maintained.

In this way, the third estimation unit 73 estimates the amount of surplus refrigerant based on the heat capacity of the gas connecting pipe GP. Therefore, the first determination unit 81 has an opening degree of the indoor motorized valve 32 during the defrost operation and a time for maintaining the opening degree based on at least the heat capacity of the gas connecting pipe GP estimated by the first estimation unit 71. Determine at least one of.

(4) Effect The heat capacity estimation system 200 of the present embodiment estimates the heat capacity of the gas connecting pipe GP of the refrigerant cycle device 100, and estimates the amount of surplus refrigerant in the refrigerant cycle device 100. The heat capacity estimation system 200 determines at least one of the opening degree of the indoor motorized valve 32 during the defrost operation and the time for maintaining the opening degree based on the estimated value of the excess refrigerant amount.

As a result, the heat capacity estimation system 200 can appropriately control the opening degree change of the indoor motorized valve 32 during the defrost operation according to the length of the gas connecting pipe GP of the refrigerant cycle device 100. The longer the gas connecting pipe GP, the larger the amount of additional refrigerant filled in the refrigerant when the refrigerant cycle device 100 is arranged, and the larger the amount of surplus refrigerant. Therefore, when the gas connecting pipe GP is long and the gas connecting pipe GP becomes damp during the defrost operation, a part of the liquid refrigerant overflows from the accumulator 19 and is easily sent to the suction port of the compressor 11. In this case, in order to suppress the occurrence of liquid back, it is necessary to advance the time (time t3 in FIG. 2) for reducing the opening degree of the indoor solenoid valve 32 from the first opening degree to the second opening degree during the defrost operation. There is. On the other hand, when the gas connecting pipe GP is short, the amount of surplus refrigerant is also small, so even if the time for reducing the opening degree of the indoor motorized valve 32 from the first opening degree to the second opening degree (time t3 in FIG. 2) is delayed. good. Similarly, the larger the diameter of the gas connecting pipe GP, the larger the amount of surplus refrigerant. Therefore, the time for reducing the opening degree of the indoor motorized valve 32 from the first opening degree to the second opening degree (time t3 in FIG. There is a need to.

The heat capacity estimation system 200 estimates the dimensions (length and diameter) of the gas connecting pipe GP from the estimated value of the heat capacity of the gas connecting pipe GP of the refrigerant cycle device 100, and estimates the amount of surplus refrigerant in the refrigerant cycle device 100. be able to. As a result, the heat capacity estimation system 200 reduces the opening degree of the indoor motorized valve 32 from the first opening to the second opening during the defrost operation according to the dimensions (length and diameter) of the gas connecting pipe GP. Can be determined appropriately. Therefore, the heat capacity estimation system 200 can execute an efficient defrost operation and can shorten the time required for the defrost operation.

(5) Modification example A modification of the embodiment is shown below. Part or all of the content of each variant may be combined with the content of other variants to the extent that they do not contradict each other.

(5-1) Modification A
When the refrigerant cycle device 100 has a plurality of outdoor units 10, the control unit 60 may further include a second determination unit 82 together with a first determination unit 81, as shown in FIG. 7. Alternatively, the control unit 60 may include a second determination unit 82 instead of the first determination unit 81. The second determination unit 82 determines the defrost operation method based on the heat capacity of the gas connecting pipe GP estimated by the first estimation unit 71. The defrost operation method is, for example, a reverse cycle defrost operation and an alternate defrost operation.

The reverse cycle defrost operation is a defrost operation executed by the refrigerant cycle device 100 of the embodiment. In the reverse cycle defrost operation, the defrost operation is performed using the heat possessed by the heat exchanger 31 on the user side and the gas connecting pipe GP accumulated during the heating operation. In the alternate defrost operation, the heat exchanger 13 on the heat source side of each outdoor unit 10 is alternately used as a radiator or a heat absorber among the plurality of outdoor units 10 to perform the defrost operation.

The refrigerant cycle device 100 executes the more dominant defrost operation of the reverse cycle defrost operation and the alternate defrost operation. The advantages of the defrost operation are, for example, the time required for the defrost operation, the amount of frost adhering to the heat source side heat exchanger 13 at the end of the defrost operation, the time required to start up when the heating operation is restarted after the end of the defrost operation, and , It is determined by the temperature of the heat exchanger 31 on the user side when the heating operation is restarted. The time required for the start-up is the time required for the temperature of the user-side heat exchanger 31 to reach a predetermined value after the heating operation is restarted.

When the refrigerant cycle device 100 has a plurality of outdoor units 10, which of the reverse cycle defrost operation and the alternate defrost operation is superior may be determined by the configuration of the refrigerant cycle device 100. For example, the larger the number of indoor units 30 or the larger the dimensions (length and diameter) of the gas connecting pipe GP, the higher the heat capacity of the gas connecting pipe GP. Therefore, the heat exchanger 31 on the user side and the gas connecting pipe The amount of heat possessed by the GP increases. When the heat exchanger 31 on the user side and the gas connecting pipe GP have a large amount of heat, the reverse cycle defrost operation tends to be more efficient than the alternate defrost operation.

Therefore, in the refrigerant cycle device 100 having a large number of indoor units 30 and a long gas connecting pipe GP, it is highly possible that the reverse cycle defrost operation is more efficient than the alternate defrost operation. On the other hand, in the refrigerant cycle device 100 in which the number of indoor units 30 is small and the gas connecting pipe GP is short, it is highly possible that the alternate defrost operation is more efficient than the reverse cycle defrost operation.

In this modification, the second determination unit 82 estimates the dimensions (length and diameter) of the gas connecting pipe GP from the estimated value of the heat capacity of the gas connecting pipe GP, thereby performing the reverse cycle defrost operation and the alternate defrost operation. Of these, the more efficient defrost operation can be determined and executed. For example, the second determination unit 82 may decide to execute the reverse cycle defrost operation when the estimated value of the length of the gas connecting pipe GP exceeds 500 m, and to execute the alternate defrost operation when the estimated value is 500 m or less. good. Further, the second determination unit 82 further bases on the estimated value of the length of the gas connecting pipe GP and the parameters affecting the amount of heat possessed by the user side heat exchanger 31 and the gas connecting pipe GP after the heating operation. , The defrost operation method may be determined. Such parameters are, for example, the type of refrigerant, the material of the gas connecting pipe GP, the number of outdoor units 10, and at least one of the models of the outdoor units 10.

In the heat capacity estimation system 200 of this modification, an appropriate defrost operation method can be selected from the viewpoint of the amount of heat possessed by the user side heat exchanger 31 and the gas connecting pipe GP.

(5-2) Modification B
In the embodiment, the calculation unit 61 of the control unit 60 is from the start time of the defrost operation (time t1 in FIG. 2) to the time when the temperature of the gas connecting pipe GP drops to a predetermined value (time t3 in FIG. 2). The amount of heat possessed by the user-side heat exchanger 31 and the gas connecting pipe GP is calculated. The time when the temperature of the gas connecting pipe GP drops to a predetermined value corresponds to the time when the heat storage of the user side heat exchanger 31 and the gas connecting pipe GP disappears after the start of the defrost operation. However, the calculation unit 61 may use the time point when the degree of superheat of the refrigerant in the gas connecting pipe GP drops to a predetermined value instead of the time point when the temperature of the gas connecting pipe GP drops to a predetermined value. Further, in the calculation unit 61, instead of the time when the temperature of the gas connecting pipe GP drops to a predetermined value, the calculation unit 61 performs a time when the absolute value of the amount of decrease in the temperature of the gas connecting pipe GP within a predetermined time exceeds a predetermined value, or the gas. A time point may be used when the absolute value of the amount of decrease in the degree of superheat of the refrigerant in the connecting pipe GP within a predetermined time exceeds a predetermined value. Further, the calculation unit 61 indicates that the temperature of the gas connecting pipe GP or the degree of superheat of the refrigerant in the gas connecting pipe GP is within a predetermined time when the heat storage of the user side heat exchanger 31 and the gas connecting pipe GP is exhausted. It may be determined based on the rate of decline.

(5-3) Modification C
The calculation unit 61 of the control unit 60 calculates the flow rate of the refrigerant flowing through the heat exchanger 31 on the user side based on at least one of the rotation speed of the compressor 11 and the density of the refrigerant sucked into the compressor 11. You may. For example, the calculation unit 61 calculates the product of the volume of the compressor 11, the number of revolutions of the compressor 11, the density of the refrigerant sucked into the compressor 11, and the volumetric efficiency of the compressor 11 within a predetermined period. It may be calculated as the flow rate (refrigerant circulation amount) of the refrigerant flowing through the user-side heat exchanger 31.

(5-4) Modification D
The calculation unit 61 of the control unit 60 calculates the enthalpy difference in the user-side heat exchanger 31 based on the temperature and pressure of the refrigerant flowing through the gas connecting pipe GP and the temperature and pressure of the refrigerant flowing through the liquid connecting pipe LP. May be.

(5-5) Modification E
The calculation unit 61 of the control unit 60 determines the amount of heat possessed by the user side heat exchanger 31 and the gas communication pipe GP based on the ambient temperature of the user side heat exchanger 31 and the pressure in the user side heat exchanger 31. It may be calculated. The ambient temperature of the user-side heat exchanger 31 may be the temperature of the space in which the indoor unit 30 is arranged.

(5-6) Modification F
The first determination unit 81 of the control unit 60 determines the opening degree (second opening degree) of the indoor motorized valve 32 during the defrost operation and its opening degree (second opening degree) based on both the heat capacity of the gas connecting pipe GP and the amount of excess refrigerant. At least one of the times for maintaining the opening may be determined.

(5-7) Modification G
The temperature sensor 40 is used to detect that the heat storage of the user side heat exchanger 31 and the gas connecting pipe GP has disappeared during the execution of the defrost operation. In the embodiment, the temperature sensor 40 is attached to the second pipe P2 and measures the accumulator inlet temperature.

The temperature sensor 40 may be attached to the first pipe P1 or the gas connecting pipe GP. When the temperature sensor 40 is attached to the gas connecting pipe GP, it is preferable that the temperature sensor 40 is attached in the vicinity of the connection portion between the gas connecting pipe GP and the first pipe P1.

The temperature sensor 40 may be attached to the second pipe P2 between the accumulator 19 and the compressor 11. In this case, the temperature sensor 40 may be attached in the vicinity of the suction port of the compressor 11.

(5-8) Modification H
In the embodiment, the temperature sensor 40 is used to detect that the heat storage of the user side heat exchanger 31 and the gas connecting pipe GP has disappeared during the execution of the defrost operation. However, in order to detect that the heat storage is exhausted, a device other than the temperature sensor 40 may be used, or the temperature sensor 40 and another device may be used in combination. For example, instead of the temperature sensor 40, or together with the temperature sensor 40, a sensor that measures at least one temperature of the first pipe P1, the second pipe P2, and the gas connecting pipe GP in a non-contact manner may be used. By combining a plurality of sensors, it is possible to detect with high accuracy that the heat storage of the user-side heat exchanger 31 and the gas connecting pipe GP has disappeared during the execution of the defrost operation.

(5-9) Modification I
In the embodiment, the first estimation unit 71 estimates the heat capacity of a predetermined portion based on the amount of heat possessed by the user-side heat exchanger 31 and the gas connecting pipe GP calculated by the calculation unit 61 (step S3 in FIG. 6). .. The predetermined portion is composed of a gas connecting pipe GP. However, the predetermined portion may further include other portions included in the refrigerant circuit RC in addition to the gas connecting pipe GP.

Specifically, the predetermined portion may further include a portion where heat may be accumulated during the heating operation. For example, in addition to the gas connecting pipe GP, the predetermined portion further includes a user-side heat exchanger 31, a pipe connecting the user-side heat exchanger 31 and the gas connecting pipe GP, and at least one of the first pipe P1. It may be included.

In this modification, the first estimation unit 71 estimates the heat capacity of the predetermined portion and estimates the heat capacity of the gas connecting pipe GP, as in the embodiment. Specifically, the first estimation unit 71 calculates the heat capacity of the gas connecting pipe GP by subtracting the heat capacity of the portion other than the gas connecting pipe GP from the heat capacity of the predetermined portion. The heat capacity of the part other than the gas connecting pipe GP is, for example, the heat capacity of the user side heat exchanger 31, the heat capacity of the pipe connecting the user side heat exchanger 31 and the gas connecting pipe GP, and the heat capacity of the first pipe P1. be. These heat capacities are stored in the storage device of the control unit 60 and acquired by the acquisition unit 62.

(5-10) Modification J
In the embodiment, the first determination unit 81 has at least the opening degree (second opening degree) of the indoor motorized valve 32 during the defrost operation and the time for maintaining the opening degree based on the heat capacity of the gas connecting pipe GP. Decide on one. The first determination unit 81 may individually determine the opening degree of the indoor motorized valve 32 and at least one of the times for maintaining the opening degree for each of the plurality of indoor units 30. In this case, the first determination unit 81 sets a plurality of these parameters based on, for example, the capacity of the user-side heat exchanger 31 of each indoor unit 30, the dimensions of the refrigerant pipes in each indoor unit 30, and the like. It may be determined for each of the indoor units 30.

(5-11) Modification K
In the embodiment, the first estimation unit 71 includes the heat holding amount of the utilization side heat exchanger 31 and the gas connecting pipe GP calculated by the calculation unit 61, and the utilization side heat exchanger 31 estimated by the second estimation unit 72. The heat capacity of the gas connecting pipe GP is estimated based on the amount of heat possessed by the gas connecting pipe GP. However, the amount of heat possessed by the user-side heat exchanger 31 may be estimated from, for example, the measured value of the temperature sensor attached to the user-side heat exchanger 31, or may be stored in advance in the storage device of the control unit 60. good.

(5-12) Modification L
In the heat capacity estimation system 200, the outdoor unit 10 may further have other components not shown in FIG. As shown in FIG. 8, the outdoor unit 10 may further include an oil separator 14, an outdoor motorized valve 16, and a receiver 18.

The oil separator 14 is attached to the third pipe P3. The oil separator 14 removes the lubricating oil mixed in the refrigerant from the high-pressure gas refrigerant discharged from the compressor 11.

The outdoor motorized valve 16 is attached to the fifth pipe P5. The outdoor electric valve 16 is an electronic expansion valve whose opening degree can be adjusted. The opening degree of the outdoor electric valve 16 is appropriately adjusted according to the situation during the operation of the refrigerant cycle device 100, and the refrigerant is depressurized according to the opening degree.

The receiver 18 is attached to the fifth pipe P5. The receiver 18 is attached between the outdoor motorized valve 16 and the liquid communication pipe LP. The receiver 18 temporarily stores the refrigerant in order to absorb the change in the amount of the refrigerant in the heat source side heat exchanger 13 and the utilization side heat exchanger 31 according to the operating condition of the refrigerant cycle device 100. The receiver 18 may have a mechanism for removing water and foreign matter contained in the refrigerant circulating in the refrigerant circuit RC.

The contents described in the embodiments and the modifications A to G are also applicable to the refrigerant cycle device 100 shown in FIG.

―Conclusion―
Although the embodiments of the present disclosure have been described above, it will be understood that various modifications of the embodiments and details are possible without departing from the spirit and scope of the present disclosure described in the claims. ..

10: Outdoor unit 11: Compressor 13: Heat source side heat exchanger 19: Accumulator 30: Indoor unit 31: User side heat exchanger 32: Indoor electric valve 60: Control unit 61: Calculation unit 62: Acquisition unit 71: First Estimating part 72: 2nd estimation part 73: 3rd estimation part 81: 1st decision part 82: 2nd decision part GP: Gas communication pipe (communication pipe)
LP: Liquid communication pipe (connection pipe)
100: Refrigerant cycle device 200: Heat capacity estimation system

Japanese Patent Application Laid-Open No. 2003-302131

Claims (8)

An outdoor unit (10) having a compressor (11) and a heat source side heat exchanger (13) and an indoor unit (30) having a user side heat exchanger (31) are connected via a connecting pipe (GP, LP). A heat capacity estimation system that estimates the heat capacity of a predetermined portion of the connected refrigerant cycle device (100).
The compressor and the user-side heat exchanger are connected from the start of the defrost operation in which the refrigerant discharged from the compressor is supplied to the heat source-side heat exchanger to defrost the heat-source-side heat exchanger. When the temperature of the gas connecting pipe (GP), which is the connecting pipe, or the degree of overheating of the refrigerant in the gas connecting pipe drops to a predetermined value, or the amount of the decrease in the temperature or the degree of superheating within a predetermined time. A calculation unit (61) for calculating the amount of heat held by the heat exchanger on the user side and the gas connecting pipe until the absolute value exceeds a predetermined value.
A first estimation unit (71) that estimates the heat capacity of the predetermined portion based on the amount of heat possessed by the user-side heat exchanger and the gas connecting pipe calculated by the calculation unit.
Equipped with
The predetermined portion includes the gas connecting pipe.
Heat capacity estimation system (200). The acquisition unit (62) that acquires the heat capacity of the user-side heat exchanger,
A second estimation unit (72) that estimates the amount of heat possessed by the user side heat exchanger based on the heat capacity of the user side heat exchanger acquired by the acquisition unit.
Further prepare
The first estimation unit determines the amount of heat possessed by the user-side heat exchanger and the gas connecting pipe calculated by the calculation unit, and the amount of heat possessed by the user-side heat exchanger estimated by the second estimation unit. Based on this, the heat capacity of the gas connecting pipe is estimated.
The heat capacity estimation system according to claim 1. A third estimation unit (73) for estimating the amount of surplus refrigerant in the refrigerant cycle device based on the heat capacity of the gas connecting pipe estimated by the first estimation unit is further provided.
The heat capacity estimation system according to claim 2. The indoor unit further includes an indoor motorized valve (32) for adjusting the amount of refrigerant supplied to the utilization side heat exchanger during defrost operation.
A first determination to determine at least one of the opening degree of the solenoid valve during defrost operation and the time for maintaining the opening degree based on the heat capacity of the gas connecting pipe estimated by the first estimation unit. Further equipped with a section (81),
The heat capacity estimation system according to claim 2. The indoor unit further includes an indoor motorized valve (32) for adjusting the amount of refrigerant supplied to the utilization side heat exchanger during defrost operation.
Based on the excess refrigerant amount estimated by the third estimation unit, the first determination unit (1st determination unit) that determines at least one of the opening degree of the indoor solenoid valve during the defrost operation and the time for maintaining the opening degree. 81) is further provided,
The heat capacity estimation system according to claim 3. The refrigerant cycle device has a plurality of the outdoor units.
A second determination unit (82) for determining the defrost operation method based on the heat capacity of the gas connecting pipe estimated by the first estimation unit is further provided.
The defrost operation method is
The first method using the heat amount of the user side heat exchanger and the gas connecting pipe, or
A second method in which the heat exchangers of the outdoor units are alternately used as radiators or heat absorbers among the plurality of outdoor units.
The heat capacity estimation system according to any one of claims 2 to 5. An outdoor unit (10) having a compressor (11) and a heat source side heat exchanger (13) and an indoor unit (30) having a user side heat exchanger (31) are connected via a connecting pipe (GP, LP). The refrigerant cycle device (100) to be connected.
The compressor and the user-side heat exchanger are connected from the start of the defrost operation in which the refrigerant discharged from the compressor is supplied to the heat source-side heat exchanger to defrost the heat-source-side heat exchanger. When the temperature of the gas connecting pipe (GP), which is the connecting pipe, or the degree of overheating of the refrigerant in the gas connecting pipe drops to a predetermined value, or the amount of the decrease in the temperature or the degree of superheating within a predetermined time. A calculation unit (61) for calculating the amount of heat held by the heat exchanger on the user side and the gas connecting pipe until the absolute value exceeds a predetermined value.
A first estimation unit (71) that estimates the heat capacity of a predetermined portion based on the amount of heat possessed by the user-side heat exchanger and the gas connecting pipe calculated by the calculation unit.
Equipped with
The predetermined portion includes the gas connecting pipe.
Refrigerant cycle device. An outdoor unit (10) having a compressor (11) and a heat source side heat exchanger (13) and an indoor unit (30) having a user side heat exchanger (31) are connected via a connecting pipe (GP, LP). A heat capacity estimation method for estimating the heat capacity of a predetermined portion of the connected refrigerant cycle device (100).
The compressor and the user-side heat exchanger are connected from the start of the defrost operation in which the refrigerant discharged from the compressor is supplied to the heat source-side heat exchanger to defrost the heat-source-side heat exchanger. When the temperature of the gas connecting pipe (GP), which is the connecting pipe, or the degree of overheating of the refrigerant in the gas connecting pipe drops to a predetermined value, or the amount of the decrease in the temperature or the degree of superheating within a predetermined time. A step of calculating the amount of heat possessed by the heat exchanger on the user side and the gas connecting pipe until the absolute value exceeds a predetermined value, and
A step of estimating the heat capacity of the predetermined portion based on the calculated amount of heat possessed by the user-side heat exchanger and the gas connecting pipe, and
Equipped with
The predetermined portion includes the gas connecting pipe.
Heat capacity estimation method.

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