JP2014185819A - Refrigeration cycle system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a refrigeration cycle system capable of automatically reducing a load on a fault heat source machine without degrading convenience if a failure occurs to a compressor in the heat source machine in a certain refrigerant circuit system.SOLUTION: This refrigeration cycle system comprises: heat source machines 2A to 2D; a plurality of refrigerant circuit systems each including a load-side device and a refrigerant pipe; and a centralized monitoring device 1 controlling these constituent elements. The centralized monitoring device 1 includes: a machine-type-information acquisition unit 101; a failure-information acquisition unit 104; an operation-capability-ratio acquisition unit 108; a storage device unit 102; a heat-source ranking unit 103; a similar-heat-source selection unit 107; an operation-capability-ratio calculation unit 105; and a control-command transmission unit 106.

Description

  This invention reduces the load on a failed heat source unit by automatically increasing the operating capacity of any of the heat source units that are in air conditioning in the same air-conditioned room. The present invention relates to a refrigeration cycle system that performs load distribution control during failure.

Conventionally, in a heat source apparatus having a plurality of compressors with variable rotation speeds in the same refrigerant circuit system, each compressor automatically performs operation capacity control in accordance with the operation status of the load side device. However, a compressor with a variable rotation speed has a drawback that it has a higher probability of failure than a compressor with a constant rotation speed. In addition, a heat source apparatus having a plurality of compressors is known that operates only with a normal compressor in the same refrigerant circuit system when there is a malfunctioning compressor (for example, Patent Documents). 1).

JP 7-19624 A

In the prior art described in Patent Document 1, when there is a malfunctioning compressor, an attempt is made to maintain the performance by increasing the operating capacity ratio of a normal compressor in the same refrigerant circuit system. If an attempt is made to maintain the performance of the machine, the remaining normal compressor may be in a high-load operation state, which may affect the operating life. The same applies to a multi heat source machine having a plurality of compressors in the same refrigerant circuit system. That is, when a certain compressor fails, it tries to maintain the internal temperature by increasing the operating capacity of a normal compressor in the same refrigerant circuit system. However, in order to maintain the performance with a small number of compressors, the burden on each compressor is increased.

The present invention has been made to solve the above-described conventional problems. When a failure occurs in a heat source machine, the load on the failed heat source machine can be automatically reduced without impairing convenience. The purpose is to obtain a refrigeration cycle system.

In order to achieve the above object, a refrigeration cycle system according to the present invention has a variable capacity compressor, a heat source unit disposed outside the air-conditioned room, and a use-side heat exchanger in the air-conditioned room. A plurality of refrigerant circuit systems each composed of a load-side device disposed, and a refrigerant pipe connecting between the heat source device and the load-side device to circulate the refrigerant, and the plurality of refrigerant circuit systems A centralized monitoring device that is connected to the individual heat source devices via a communication line to control the operation of the plurality of refrigerant circuit systems, and the centralized monitoring device is connected to the internal network. A model information acquisition unit that acquires information about the model of the heat source unit from the machine, a failure information acquisition unit that acquires fault information from each of the heat source units, and an operation capability that acquires the operating capability ratio set for each of the heat source units A ratio acquisition unit; The information on the model of the heat source machine acquired by the model information acquisition unit, the failure information acquired by the failure information acquisition unit, and the operation capability ratio of each heat source unit acquired by the operation capability acquisition unit are stored. Stored in the storage device unit, the heat source unit ranking unit for setting the rank of the operation capacity for each heat source unit based on the information on the model stored in the storage unit, and the previous storage unit Based on the failure information and the order set by the heat source unit ranking unit, a similar heat source unit selecting unit that selects a heat source unit having a similar operation capability to the failed heat source unit from among normal heat source units, and the heat source unit An operation capability ratio calculation unit that calculates an operation capability ratio that represents the current operation state with respect to the maximum operation of, and a ratio with the operation capability of the heat source unit selected by the similar heat source unit selection unit, and On the basis of the ratio of the serial failed heat source machine runnability, to determine the operating capacity of the failed heat source apparatus is characterized in that to operate on the failed heat source apparatus.

  The refrigeration cycle system according to the present invention performs load distribution control at the time of failure, and the ratio of the operation capability of the heat source unit selected by the similar heat source unit selection unit to the operation capability of all the heat source units, and the failed heat source Based on the ratio to the operating capacity of the machine, the operating capacity of the failed heat source machine is determined so that the failed heat source machine can be operated. It has the effect of automatically compensating for the load of the heat source machine. That is, when a heat source unit of a certain refrigerant circuit system breaks down, by increasing the operating capability of the heat source units of a plurality of normal refrigerant circuit systems and maintaining the room temperature of the air-conditioned room at the set target temperature, The burden on the compressor of the refrigerant circuit system can be automatically reduced. Further, since it can follow user operations, it can be realized without impairing the user's ease of use.

It is a block block diagram which shows the schematic structure of the whole refrigerating-cycle system in Embodiment 1 of this invention. It is a block block diagram which shows schematic structure of the centralized monitoring apparatus of the said refrigeration cycle system. It is a figure which shows the table of ranking of the heat source machine by the said centralized monitoring apparatus. It is a figure which shows the flow of the sequence control at the time of the failure generation by the said centralized monitoring apparatus. It is a figure which shows the flow of the sequence control at the time of the environmental load change in Embodiment 1 of this invention by the said centralized monitoring apparatus. It is a figure which shows the flow of the sequence control at the time of the preset temperature change by the said centralized monitoring apparatus. It is a figure which shows the flow of the sequence control at the time of the failure recovery by the said centralized monitoring apparatus. It is a block block diagram which shows the schematic structure of the whole refrigeration cycle system in Embodiment 2 of this invention.

Embodiment 1 FIG.
FIG. 1 shows an overall schematic configuration of a refrigeration cycle system according to Embodiment 1 of the present invention.
1, the refrigeration cycle system according to Embodiment 1 includes four refrigerant circuit systems 8A to 8D in which load-side devices 3A to 3D are arranged in the same air-conditioned room 7. In each refrigerant circuit system 8A to 8D, a compressor 9, a throttle valve 10, a use-side heat exchanger 11, and an accumulator (not shown) are connected in an annular manner via refrigerant pipes 6A to 6D in that order, respectively, and refrigerant circulation is performed. It is configured to be possible. The throttle valve 10 and the use side heat exchanger 11 are provided in, for example, the load side devices 3A to 3D, and the compressor 9 and the accumulator are provided in, for example, the heat source devices 2A to 2D. The plurality of refrigerant circuit systems 8A to 8D are communicably connected to a remote controller 4A having a common load side device 3A to 3D via a communication line 5F. The heat source devices 2A to 2D of all the refrigerant circuit systems 8A to 8D are connected to the centralized monitoring device 1 through the communication line 5A so as to be communicable and are controlled for operation. Reference numerals 5B to 5E denote communication lines that connect the load side devices 3A to 3D and the heat source devices 2A to 2D, respectively, so that they can communicate with each other. In this embodiment, the air-conditioned room 7 is exemplified as a “refrigerated warehouse”, the heat source devices 2A to 2D are exemplified as “refrigerators”, and the load side devices 3A to 3D are exemplified as “unit coolers”, for example. The use side heat exchanger 11 is exemplified as an “evaporator”. However, the present invention is not limited to them.

  FIG. 2 is a functional block diagram illustrating a configuration example of the centralized monitoring device 1 according to the first embodiment. The centralized monitoring apparatus 1 is mainly composed of a general-purpose central processing unit (CPU), a memory, a data bus, input / output devices, and external communication devices. The CPU of the centralized monitoring apparatus 1 includes a model information acquisition unit 101, a heat source unit ranking unit 103, a failure information acquisition unit 104, an operation capability ratio calculation unit 105, a control command transmission unit 106, a similar heat source unit selection unit 107, and Each function of the driving ability ratio acquisition unit 108 is provided. These functions are preset in the CPU as program data. Further, the storage device unit 102 is embodied by the memory described above.

And as shown in the table of FIG. 3, the heat source unit ranking unit 103 ranks the heat source units 2A to 2D in order of the operation capability within the group G1 for each target heat source unit, Is stored in the storage unit 102.
Further, when a failure occurs in each of the heat source units 2A to 2D, the centralized monitoring device 1 is notified of the occurrence of the failure via the communication line 5A. Then, as will be described later, the “threshold value” relating to the difference between the operating capacity ratio of the failed heat source apparatus 2A and the operating capacity ratio of the selected heat source apparatus 2B is set and input from the outside in advance and stored in the centralized monitoring device 1 It is stored in the device unit 102.

Next, operations performed in the centralized monitoring device 1 of the refrigeration cycle system according to Embodiment 1 will be described with reference to FIGS.
FIG. 4 shows the content of the communication sequence at the time of “failure occurrence”.
“Collecting heat source machine model information”: First, when the centralized monitoring apparatus 1 becomes capable of communicating with the heat source machines 2A to 2D, the model information acquisition unit 101 relates to each model from the heat source machines 2A to 2D. Information data is acquired by monitoring and stored in the storage device 102 (S1).
“Notification of occurrence of failure”: When a failure occurs in itself, the heat source devices 2A to 2D notify the central monitoring device 1 of the occurrence of the failure via the communication line 5A (S2).
“Operation capability ratio fixed command”: When the failure information acquisition unit 104 of the centralized monitoring apparatus 1 detects a failure of the compressor, the operation capability ratio calculation unit 105 sends the compressor to the corresponding heat source device (for example, 2A). The operation capacity ratio of 9 is fixed to the current value and the operation capacity ratio is fixed to the current value, and a command is output to the heat source unit 2A via the control command transmission unit 106 (S3).
“Fixed operation capability ratio of the failed heat source unit”: When the failure heat source unit 2A receives the operation capability ratio fixation command from the centralized monitoring device 1, the operation continues at the operation capability ratio set at that time ( S4).

“Normal Autonomous Operation of Heat Source Unit”: The normal heat source units 2B to 2D autonomously change their respective operating capacity ratios with respect to environmental changes in the air-conditioned room 7 due to the failure of the heat source unit 2A. (S5). Note that “the operation capacity ratio autonomously changes” means that the operation capacity ratio of the heat source apparatus 2B selected by the similar heat source apparatus selection unit 107 to the operation capacity of all the heat source apparatuses 2A to 2D, And, based on the operation capability ratio with the operation capability of the failed heat source unit 2A, the operation capability of the failed heat source unit 2A is determined, and when the failed heat source unit 2A is operated with the operation capability, That is, the operation capability ratio of the remaining normal heat source devices that are operated independently changes with respect to the operation capability of the heat source devices 2A to 2D.

“Selection from normal heat source devices”: The similar heat source device selection unit 107 of the centralized monitoring device 1 searches the rank data in the storage device unit 102, and in the normal heat source devices 2B to 2D, in step S1 The heat source machine (for example, 2B) having the highest set order is selected (S6).
“Periodic monitoring of operating capacity ratio”: The operating capacity ratio acquisition unit 108 of the centralized monitoring device 1 periodically monitors the operating capacity ratio, that is, acquires the data of the operating capacity ratio from the selected heat source unit 2B (S7). .
“Change in operating capacity ratio”: The operating capacity ratio calculation unit 105 of the centralized monitoring apparatus 1 determines that the operating capacity ratio of the selected heat source apparatus 2B is stable, and further determines the operating capacity ratio of the failed heat source apparatus 2A. When it is determined that the difference from the operation capacity ratio of the selected heat source device 2B is equal to or greater than the above-described threshold value, the control command transmission unit 106 selects the selected heat source device 2B with respect to the failed heat source device 2A. Outputs a command requesting the setting of the same driving capacity ratio. When the operation capability of the failed heat source unit 2A is different from the operation capability of the selected heat source unit 2B, the setting command is output after weighting each. When the difference between the operating capacity ratio of the failed heat source apparatus 2A and the operating capacity ratio of the selected heat source apparatus 2B is less than the above-described threshold value, the operating capacity ratio setting change command is not output (S8).

“Change in operating capacity ratio of failed heat source machine”: Thus, the failed heat source machine 2A operates based on the operating capacity ratio transmitted from the centralized monitoring device 1 (S9).
“Autonomous operation of normal heat source unit”: The normal heat source units 2B to 2D autonomously change their operating capability ratios in response to environmental changes caused by changes in the operating capability ratio of the heat source unit 2A (S10). ).
“Periodic monitoring of operating capacity ratio”: The centralized monitoring device 1 periodically monitors the operating capacity ratio of the selected heat source unit 2B, similarly to step S7 (S11).
Subsequently, the centralized monitoring device 1 repeats the processing from step S8 to S11 (S12).

FIG. 5 shows the contents of the communication sequence “when the environmental load changes”.
“Periodic monitoring of operating capacity ratio”: Following the sequence process (S12) of FIG. 4, the operating capacity ratio acquisition unit 108 of the centralized monitoring apparatus 1 periodically monitors the operating capacity ratio of the selected heat source unit 2B. (S13).
“Environmental load change”: The normal heat source units 2B to 2D autonomously change their respective operating capacity ratios in response to changes in the environmental load (for example, changes in the internal temperature of the air-conditioned room 7). (S14).
“Change in operating capacity ratio”: Thus, the operating capacity ratio calculation unit 105 of the centralized monitoring device 1 determines that the operating capacity ratio of the selected heat source apparatus 2B is stable, and further, the faulty heat source apparatus 2A When it is determined that the difference between the operating capacity ratio and the operating capacity ratio of the selected heat source unit 2B is equal to or greater than the above-described threshold, the control command transmission unit 106 is selected for the failed heat source unit 2A. The command output which requests the setting of the same operating capacity ratio as the heat source machine 2B is made. When the operation capability of the failed heat source unit 2A is different from the operation capability of the selected heat source unit 2B, the setting command is output after weighting each. When the difference between the operating capacity ratio of the failed heat source apparatus 2A and the operating capacity ratio of the selected heat source apparatus 2B is less than the above-described threshold, the setting command output of the operating capacity ratio is not performed (S15).

“Change in operating capacity ratio of failed heat source machine”: The failed heat source machine 2A operates based on the operating capacity ratio transmitted from the centralized monitoring device 1 (S16).
“Autonomous operation of a normal heat source unit”: The normal heat source units 2B to 2D have their respective operation capability ratios against the environmental change in the air-conditioned room 7 due to the change of the operation capability ratio of the heat source unit 2A. It changes autonomously (S17).
“Periodic monitoring of operating capacity ratio”: The centralized monitoring device 1 periodically monitors the operating capacity ratio of the selected heat source unit 2B, similarly to step S13 (S18).
Subsequently, the centralized monitoring device 1 repeats the processing from step S15 to S18 (S19).

Next, FIG. 6 shows the contents of the communication sequence “when the set temperature is changed”.
“Periodic monitoring of operating capacity ratio”: Following the sequence process (S12) of FIG. 4, the operating capacity ratio acquisition unit 108 of the centralized monitoring apparatus 1 periodically monitors the operating capacity ratio of the selected heat source unit 2B. (S20).
“Set temperature change”: When a set temperature operation from the user, such as a change in the set temperature inside the cabinet, is input from the centralized monitoring device 1, the normal heat source units 2B to 2D have autonomous operation capacity ratios relative to the overall capacity. Change (S21).
“Change in operating capacity ratio”: The operating capacity ratio calculation unit 105 of the centralized monitoring apparatus 1 determines that the operating capacity ratio of the selected heat source apparatus 2B is stable, and further determines the operating capacity ratio of the failed heat source apparatus 2A. When it is determined that the difference from the operation capacity ratio of the selected heat source device 2B is equal to or greater than the above-described threshold value, the control command transmission unit 106 selects the selected heat source device 2B with respect to the failed heat source device 2A. A command to set the same driving capacity ratio as is output. When the operation capability of the failed heat source unit 2A is different from the operation capability of the selected heat source unit 2B, the setting command is output after weighting each. When the difference between the operating capacity ratio of the failed heat source apparatus 2A and the operating capacity ratio of the selected heat source apparatus 2B is less than the above-described threshold, the setting command output of the operating capacity ratio is not performed (S22).

“Change in operating capacity ratio of failed heat source machine”: The failed heat source machine 2A operates based on the operating capacity ratio transmitted from the centralized monitoring device 1 (S23).
“Autonomous operation of a normal heat source unit”: The normal heat source units 2B to 2D have their respective operation capability ratios against the environmental change in the air-conditioned room 7 due to the change of the operation capability ratio of the heat source unit 2A. It changes autonomously (S24).
“Periodic monitoring of operating capacity ratio”: The centralized monitoring device 1 periodically monitors the operating capacity ratio of the selected heat source machine 2B, similarly to step S20 (S25).
Subsequently, the centralized monitoring device 1 repeats the processing from steps S22 to S25 (S26).

On the other hand, FIG. 7 shows the contents of the communication sequence “at the time of failure recovery”.
“Periodic monitoring of operating capacity ratio”: Continuously from the sequence process (S12) of FIG. 4, the operating capacity ratio acquisition unit 108 of the centralized monitoring apparatus 1 periodically monitors the operating capacity ratio of the selected normal heat source unit 2B. (S27).
“Notification of Failure Recovery”: Then, when the failure is recovered, the heat source unit 2A that has failed notifies the central monitoring device 1 of the failure recovery (S28).
“Instruction of autonomous control operation”: When the failure information acquisition unit 104 of the centralized monitoring device 1 detects the failure recovery of the compressor, the control command transmission unit 106 outputs an autonomous control operation command to the corresponding heat source unit 2A. (S29).
“Operation recovery of failed heat source unit”: When the failed heat source unit 2A receives the command signal of autonomous control operation from the centralized monitoring device 1, the operation capability ratio changes autonomously with respect to the environmental load (S30). .

As described above, according to the centralized monitoring device 1 of the refrigeration cycle system according to the first embodiment, the operation capability ratio of the heat source unit 2B selected by the similar heat source unit selection unit 107 and the operation capability of the failed heat source unit 2A. Based on the difference from the ratio, the operation capability of the failed heat source unit 2A is determined and operated, so that the load of the failed heat source unit 2A is maintained while keeping the room temperature of the air-conditioned room 7 at the set target temperature. Can be reduced automatically. Further, since it can follow user operations, it can be realized without impairing the user's ease of use. This refrigeration cycle system is exemplified as a “refrigerated warehouse” in which the cargo is taken in and out during the day as the air-conditioned room 7, so it is automatically adapted to changes in the environmental load, such as the temperature inside the compartment easily changing during the day. Can follow. In addition, the air-conditioned room 7 as a refrigerated warehouse can automatically cope with a change in setting of the set target internal temperature at night that is set higher than during the day, and the purpose of energy saving can be achieved.

Embodiment 2. FIG.
In the first embodiment, one group G1 including four refrigerant circuit systems 8A to 8D in which load side devices 3A to 3D installed in the same air-conditioned room 7 are connected to one remote controller 4A is illustrated. However, the second embodiment in which the central monitoring device 1 controls both the group G1 including the four refrigerant circuit systems 8A to 8D and the group G2 including the four refrigerant circuit systems 8E to 8H will be described.
FIG. 8 shows an overall schematic configuration of a refrigeration cycle system according to Embodiment 2 of the present invention. 8, the same components as those in FIGS. 1 and 2 are denoted by the same reference numerals, and the description thereof is omitted.

The refrigeration cycle system in the second embodiment has the same configuration as that of FIG. 1, but includes eight refrigerant circuit systems 8A to 8H in which load-side devices 3A to 3H are arranged in the same air-conditioned room 7. Yes. The plurality of refrigerant circuit systems 8A to 8H include a group G1 in which the load side devices 3A to 3D are communicably connected to a common remote controller 4A via a communication line 5F, and a load side device 3E to 3H having a common remote. It is grouped into a group G2 that is communicably connected to the controller 4B via the communication line 5K. The refrigerant circuit systems 8E to 8H of the group G2 also exhibit the same operation as the refrigerant circuit systems 8A to 8D of G1 described above.

And heat source machine 2A-2H of all the refrigerant circuit systems 8A-8H is comprised so that communication can be connected to the centralized monitoring apparatus 1 via communication line 5A, 5L, and it is controlled. In addition, the centralized monitoring device 1 executes the ranking of the heat source devices 2A to 2H across the two groups G1 and G2. Reference numerals 5G to 5J denote communication lines that connect the load side devices 3E to 3H and the heat source devices 2E to 2H, respectively, so that they can communicate with each other. 6E to 6H are refrigerant pipes that connect the load side devices 3E to 3H and the heat source units 2E to 2H so that the refrigerant can flow. In addition, although many illustrations are abbreviate | omitted, the throttle valve 10 and the utilization side heat exchanger 11 are arrange | positioned at the load side apparatus 3A-3H, for example, and the compressor 9 and the accumulator are arranged at the heat source apparatus 2A-2H, for example. Yes.
Furthermore, in the centralized monitoring apparatus 1, the model information acquisition unit 101 is configured to acquire information on the groups G1 and G2 to which the heat source devices 2A to 2H belong from the heat source devices 2A to 2H. Further, the heat source unit ranking unit 103 is based on the information on the models of the heat source units 2A to 2H stored in the storage unit 102, and the heat source units belonging to the groups G1 and G2 arranged in the same air-conditioned room 7 It is the structure which sets the order | rank of each driving capability over 2A-2H.

As in the first embodiment, the centralized monitoring device 1 monitors information on each model from the model information acquisition unit 101 to the heat source units 2A to 2H when communication with the heat source units 2A to 2H becomes possible. And stored in the storage unit 102. Further, by registering that the load side devices 3A to 3H of the plurality of groups G1 and G2 are installed in the same air-conditioned room 7, the heat source unit ranking unit 103 of the centralized monitoring device 1 can For each of the machines 2A to 2H, the heat source machines 2A to 2H are ranked in descending order of the operation capability within each group G1 or group G2 in the same air-conditioned room 7. Since the subsequent operation is the same as that shown in the first embodiment, the description thereof is omitted here.

As described above, according to the centralized monitoring device 1 according to Embodiment 2, it is registered that the load-side devices 3A to 3H of the two groups G1 and G2 are installed in the same air-conditioned room 7. Therefore, the ranking of the heat source devices 2A to 2H having similar operation capabilities can be performed across the plurality of groups G1 and G2, and more accurate operation can be performed.

In each of the above embodiments, the refrigeration room is described as an example of the air-conditioned room, but the refrigeration cycle system of the present invention is not limited thereto. For example, the present invention can be applied to a freezing room or a living room as an air-conditioned room.
Further, in the above, an example in which the centralized monitoring device is applied to a control method of a heat source device typified by a refrigerator or the like has been described, but the present invention is not limited thereto, and is used in a refrigeration cycle system, for example, Needless to say, it can be realized as a program to be executed by another computer.

DESCRIPTION OF SYMBOLS 1 Centralized monitoring apparatus 2A-2H Heat source machine 3A-3H Load side apparatus 4A, 4B Remote controller 5A-5L Communication line 6A-6H Refrigerant piping 7 Air-conditioned room 8A-8H Refrigerant circuit system 9 Compressor 10 Throttle valve 11 Use side heat Exchanger 101 Model information acquisition unit 102 Storage unit 103 Heat source unit ranking unit 104 Failure information acquisition unit 105 Operating capability ratio calculation unit 106 Control command transmission unit 107 Similar heat source unit selection unit 108 Operating capability ratio acquisition unit G1, G2 Group S1 ~ S30 step

Claims (2)

A heat source device having a variable capacity compressor and disposed outside the air-conditioned room, a load-side device having a use-side heat exchanger and disposed in the air-conditioned room, and the heat source for circulating the refrigerant A plurality of refrigerant circuit systems each composed of a refrigerant pipe connecting between the machine and the load side device,
A centralized monitoring device that is connected to each heat source unit of the plurality of refrigerant circuit systems via a communication line and controls operation of the plurality of refrigerant circuit systems;
The centralized monitoring device is
A model information acquisition unit for acquiring information on the model of the heat source machine from each of the heat source machines;
A failure information acquisition unit for acquiring failure information from each of the heat source units;
An operation capability ratio acquisition unit for acquiring an operation capability ratio set in each heat source unit;
Stores information on the model of the heat source unit acquired by the model information acquisition unit, failure information acquired by the failure information acquisition unit, and the operation capability ratio of each heat source unit acquired by the operation capability acquisition unit Storage device section
A heat source unit ranking unit for setting the rank of the operation capability for each heat source unit based on information on the model of the heat source unit stored in the storage unit;
Based on the failure information stored in the previous storage unit and the order set by the heat source unit ranking unit, a similar heat source unit is selected from normal heat source units that have a similar operating capability to the failed heat source unit A heat source machine selection department,
An operation capability ratio calculation unit for calculating an operation capability ratio representing a current operation state with respect to the maximum operation of the heat source unit,
Based on the ratio with the operating capability of the heat source unit selected by the similar heat source unit selection unit and the operating capability of the failed heat source unit, the operating capability of the failed heat source unit is determined and the failure A refrigeration cycle system characterized in that the heat source machine is operated. Each load-side device includes a plurality of refrigerant circuit systems arranged in the same air-conditioned room, and the plurality of refrigerant circuit systems include a plurality of load-side devices connected to a common remote controller so as to communicate with each other. It is grouped into groups, and the heat source devices of all refrigerant circuit systems are connected to the centralized monitoring device so as to be communicably controlled, and the model information acquisition unit of the centralized monitoring device provides information on the group to which each heat source device belongs. The heat source unit ranking unit of the centralized monitoring device is arranged in the same air-conditioned room based on information on the model of the heat source unit stored in the storage unit. 2. The refrigeration cycle system according to claim 1, wherein a ranking of the operation capacity of the heat source device is set across the plurality of groups.

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