JP7278330B2 - Refrigeration cycle device, refrigeration cycle control system, and refrigeration cycle control method - Google Patents

Description

The present invention relates to a refrigerating cycle device, a refrigerating cycle control system, and a refrigerating cycle control method.

In recent years, the number of nuclear families and double-income households is increasing, and people often turn off air conditioners in their homes during the day when they go out. Therefore, when the family comes home, it will be a humid room in the summer and a cold room in the winter, and they will return home to an uncomfortable house. For this reason, there is an increasing demand to operate the air conditioner from outside before returning home. Furthermore, there are cases where it is desired to operate an air conditioner from outside for health management of a person receiving home nursing care or a person such as a pet who cannot manage electrical equipment. In addition, there are cases where it is desired to operate an air conditioner from outside in order to prevent deterioration of a house that is normally vacant, such as a villa.

Patent Literature 1 discloses a technique for operating an air conditioner from outside with an information terminal device such as a mobile phone, a smart phone, or a tablet computer using Wi-Fi (registered trademark) wireless.

JP 2015-010769 A

Air conditioners using a refrigerating cycle do not use fire, so they are safer than other air conditioners such as combustion heaters. However, accidents have occurred even in air conditioners using a refrigeration cycle due to factors such as defective installation such as poor contact of power supply wiring, defective power supply lines for various reasons, and aging of equipment.
It is known that an air conditioner using a refrigerating cycle uses a large proportion of electric power used in a home. In particular, when an air conditioner using an inverter-driven refrigeration cycle starts operating, the capacity required to warm or cool the room, that is, the air conditioning load is large. For this reason, the cooling capacity or heating capacity will be high, and the electric power used will be large. As described above, when an air conditioner using a refrigerating cycle starts operating, there is a high possibility that an accident will occur if some kind of trouble occurs in the electric line system.

As disclosed in Patent Document 1, when an air conditioner is operated from outside, there is a high possibility that there is no one to manage the air conditioner, and the risk of an accident occurring at the start of operation increases. There is

SUMMARY OF THE INVENTION An object of the present invention is to suppress the occurrence of an accident at the start of operation even when operating a refrigeration cycle device such as an air conditioner from outside.

A refrigerating cycle device according to the present invention includes a plurality of refrigerating cycle devices each having a refrigerating cycle for compressing and circulating a refrigerant with a compressor, absorbing heat from a low-temperature heat source with a heat exchanger, and exhausting heat to a high-temperature heat source; A refrigeration cycle device comprising a control device for controlling the operation of the refrigeration cycle equipment of
The control device is
an acquisition unit that acquires an operation request for controlling the plurality of refrigeration cycle devices installed indoors to a target state;
a memory that stores the number of refrigeration cycle devices that start operating at the same time as a limit number;
When the operating request transmitted from outdoors is acquired, the plurality of refrigerating cycle devices are brought to the target state at an operating capability lower than the operating capability of the plurality of refrigerating cycle devices when the operating request is transmitted from indoors. and an operation control unit that controls to
The operation control unit is
When the operating request transmitted from the outdoors is acquired, the operating operation of the limited number of refrigerating cycle devices among the plurality of refrigerating cycle devices is started.

In the refrigerating cycle apparatus according to the present invention, when the refrigerating cycle devices are operated from the outside, the number of refrigerating cycle devices that start operation at the same time can be limited, so that the occurrence of accidents during operation can be suppressed. can.

1 is an overall configuration diagram including a refrigeration cycle apparatus according to Embodiment 1. FIG. A refrigerant circuit during cooling operation when the refrigeration cycle device is an air conditioner. A refrigerant circuit during heating operation when the refrigerating cycle device is an air conditioner. 1 is a configuration diagram of a control device according to Embodiment 1; FIG. 4 is a flow chart showing the operation of the control device according to the first embodiment; FIG. FIG. 2 is a configuration diagram of a control device according to a modification of Embodiment 1; The block diagram of the refrigerating-cycle control system which concerns on Embodiment 2. FIG. FIG. 2 is a configuration diagram of a control device according to Embodiment 2; FIG. 11 is a diagram showing an example of a lifestyle log according to Embodiment 2; FIG. FIG. 10 is a flowchart showing the operation of the control device according to the second embodiment; FIG.

The present embodiment will be described below with reference to the drawings. In each figure, the same reference numerals are given to the same or corresponding parts. In the description of the embodiments, the description of the same or corresponding parts will be omitted or simplified as appropriate. It should be noted that the present embodiment is not limited to the embodiments described below, and various modifications can be made as necessary. Specifically, among the embodiments described below, two or more embodiments may be combined for implementation. Alternatively, one embodiment or a combination of two or more of the embodiments described below may be partially implemented.

Embodiment 1.
This embodiment will be described with reference to FIGS. 1 to 6. FIG.

*** Configuration description ***
FIG. 1 is an overall configuration diagram including a refrigeration cycle apparatus 100 according to this embodiment.
The refrigeration cycle device 100 is installed indoors 90 . The indoor 90 is a building such as a house, a building, or a factory in which the refrigerating cycle device 110 is installed.
Refrigerating cycle device 100 includes refrigerating cycle equipment 110 and controller 120 .
The refrigerating cycle device 110 is a device having a refrigerating cycle that compresses and circulates a refrigerant with a compressor, absorbs heat from a low-temperature heat source with a heat exchanger, and exhausts heat to a high-temperature heat source. Specifically, the refrigerating cycle equipment 110 includes equipment such as an air conditioner, a floor heating system, or a water heater.
Control device 120 controls the operation of refrigeration cycle equipment 110 . When there are multiple refrigeration cycle devices 110 , the controller 120 controls the operation of the multiple refrigeration cycle devices 110 .
In FIG. 1, the refrigerating cycle equipment is composed of a plurality of refrigerating cycle equipments 110, but the present embodiment can be applied even if there is only one refrigerating cycle equipment.

The controller 120 is specifically a microcomputer. The control device 120 controls the refrigeration cycle equipment 110 according to the operation request 63 transmitted from the first operation equipment 40 . Also, the control device 120 controls the refrigeration cycle device 110 according to the operation request 63 transmitted from the second operation device 50 .
The operation request 63 is a command requesting that the refrigeration cycle equipment 110 installed indoors 90 be controlled to a target state. The target state is the state of refrigeration cycle equipment 110 desired by user 80 . Specifically, in the case of an air conditioner, the status includes temperature, air volume, wind direction, and air conditioning type. In the case of floor heating, the status includes temperature, heating area, and heating type. In the case of a water heater, the status is the temperature and the amount of hot water.

The first operation device 40 transmits a driving operation request 63 to the control device 120 using short-range wireless communication 13 such as infrared communication or Bluetooth (registered trademark). The first operation device 40 is specifically a remote controller. Alternatively, the first operation device 40 may be an operation device such as a switch provided on the control device 120 .
The first operating device 40 is used by a user 80 indoors 90 . That is, the driving operation request 63 from the first operating device 40 is transmitted from indoors 90 .

The second operation device 50 communicates with the control device 120 using the wireless LAN 12 such as Wi-Fi (registered trademark). The second operation device 50 is specifically a personal computer, smart phone, mobile phone, or tablet computer. The second manipulation device 50 is a communication terminal with higher functionality than the first manipulation device 40 . The second operation device 50 uses the wireless LAN 12 to transmit a driving operation request 63 to the control device 120 .
The second operating device 50 is used by the user 80 indoors 90 and outdoors 91 . That is, the driving operation request 63 from the second operation device 50 may be transmitted from the indoors 90 or outdoors 91 . When the driving operation request 63 is transmitted from the second manipulation device 50 outdoors 91, the second manipulation device 50 connects to the wireless LAN 12 indoors 90 via the network 11 such as the Internet. That is, the second operation device 50 outdoors 91 transmits the driving operation request 63 to the control device 120 via the network 11 and the wireless LAN 12 .

A configuration of a refrigeration cycle apparatus 100 according to the present embodiment will be described with reference to FIGS. 2 and 3. FIG.
FIG. 2 shows the refrigerant circuit 31 during cooling operation when the refrigeration cycle device 110 is an air conditioner. FIG. 3 shows the refrigerant circuit 31 during heating operation when the refrigeration cycle device 110 is an air conditioner.

The refrigeration cycle device 110 includes a refrigerant circuit 31 through which refrigerant circulates. The refrigerating cycle device 110 includes a compressor 32, a four-way valve 33, a first heat exchanger 34 that is an outdoor heat exchanger, an expansion mechanism 35 that is an expansion valve, and a second heat exchanger that is an indoor heat exchanger. 36. Compressor 32 , four-way valve 33 , first heat exchanger 34 , expansion mechanism 35 and second heat exchanger 36 are connected to refrigerant circuit 31 .

Compressor 32 compresses the refrigerant. The four-way valve 33 switches the direction of refrigerant flow between cooling operation and heating operation. The first heat exchanger 34 operates as a condenser during cooling operation, and radiates heat from the refrigerant compressed by the compressor 32 . That is, the first heat exchanger 34 performs heat exchange using the refrigerant compressed by the compressor 32 . The first heat exchanger 34 operates as an evaporator during heating operation, and heats the refrigerant by exchanging heat between the outdoor air and the refrigerant expanded by the expansion mechanism 35 . The expansion mechanism 35 expands the refrigerant radiated by the condenser. The second heat exchanger 36 operates as a condenser during heating operation, and releases the refrigerant compressed by the compressor 32 . That is, the second heat exchanger 36 performs heat exchange using the refrigerant compressed by the compressor 32 . The second heat exchanger 36 operates as an evaporator during cooling operation, and heats the refrigerant by exchanging heat between the indoor air and the refrigerant expanded by the expansion mechanism 35 .

Here, the refrigerant used in the refrigeration cycle device 110 is a mildly flammable refrigerant or a combustible refrigerant. Most of refrigerants mainly used in air conditioners are R410A, which is a nonflammable refrigerant. However, in order to achieve a low GWP (Global Warming Potential), it is preferable to use HFO-based refrigerants such as R32 and HFO1234ze, which are mildly flammable refrigerants. Alternatively, a combustible refrigerant such as R290 refrigerant may be used for the purpose of lowering GWP.

The compressor 32 is of a variable speed type driven by an inverter.
The compressor motor specifically uses a DC brushless motor (DC motor) and is driven by an inverter drive device. The heat exchanger has a fan and a fan motor, at least one of which uses a DC motor.

The refrigerating cycle device 100 further includes a control device 120 that controls the refrigerating cycle of the refrigerating cycle device 110 .

Although FIG. 2 and FIG. 3 only show the connection between the control device 120 and the compressor 32, the control device 120 connects not only the compressor 32 but also the components other than the compressor 32 connected to the refrigerant circuit 31. may be connected. Control device 120 monitors and controls the state of each component connected to control device 120 .

FIG. 4 is a diagram showing the configuration of control device 120 according to the present embodiment.
Controller 120 is a computer. The controller 120 comprises a processor 910 as well as memory 921 and other hardware such as a communication device 950 . The processor 910 is connected to other hardware via signal lines and controls these other hardware. Also, although not shown, the control device 120 may include an input interface, an output interface, and an auxiliary storage device as other hardware.

The control device 120 includes an acquisition unit 121 and an operation control unit 122 as functional elements. Also, the memory 921 stores a limit number 123 .
The functions of the acquisition unit 121 and the operation control unit 122 are realized by software.

Processor 910 is a device that executes a refrigeration cycle control program. The refrigeration cycle control program is a program that implements the functions of the acquisition unit 121 and the operation control unit 122 .
The processor 910 is an IC (Integrated Circuit) that performs arithmetic processing. Specific examples of the processor 910 are a CPU (Central Processing Unit), a DSP (Digital Signal Processor), and a GPU (Graphics Processing Unit).

The memory 921 is a storage device that temporarily stores data. A specific example of the memory 921 is SRAM (Static Random Access Memory) or DRAM (Dynamic Random Access Memory).
Auxiliary storage is a storage device that stores data. A specific example of the auxiliary storage device is the HDD. Also, the auxiliary storage device may be a storage medium such as an SD (registered trademark) memory card, CF, NAND flash, flexible disk, optical disk, compact disk, Blu-ray (registered trademark) disk, or DVD. Note that HDD is an abbreviation for Hard Disk Drive. SD® is an abbreviation for Secure Digital. CF is an abbreviation for CompactFlash®. DVD is an abbreviation for Digital Versatile Disk.

An input interface is a port connected to an input device such as a mouse, keyboard, or touch panel. The input interface is specifically a USB (Universal Serial Bus) terminal. The input interface may be a port connected to a LAN (Local Area Network).
An output interface is a port to which a cable of an output device such as a display is connected. The output interface is specifically a USB terminal or an HDMI (registered trademark) (High Definition Multimedia Interface) terminal. The display is specifically an LCD (Liquid Crystal Display).

A communication device has a receiver and a transmitter. A communication device is connected to a communication network such as a LAN, the Internet, or a telephone line. The communication device is specifically a communication chip or NIC (Network Interface Card).

A refrigeration cycle control program is executed in the control device 120 . The refrigeration cycle control program is read into processor 910 and executed by processor 910 . The memory 921 stores not only the refrigeration cycle control program but also an OS (Operating System). Processor 910 executes the refrigeration cycle control program while executing the OS. The refrigeration cycle control program and OS may be stored in an auxiliary storage device. The refrigeration cycle control program and OS stored in the auxiliary storage device are loaded into memory 921 and executed by processor 910 . Note that part or all of the refrigeration cycle control program may be incorporated in the OS.

Controller 120 may include multiple processors that replace processor 910 . These multiple processors share the execution of the refrigeration cycle control program. Each processor, like the processor 910, is a device that executes a refrigeration cycle control program.

Data, information, signal values, and variable values used, processed, or output by the refrigeration cycle control program are stored in memory 921, auxiliary storage, or registers or cache memory within processor 910. FIG.

The “part” of each part of the control device 120 may be read as “processing”, “procedure” or “process”. In addition, "processing" obtained by replacing the "part" of each part of the control device 120 with "program", "program product", "computer-readable storage medium recording the program", or "computer-readable storage medium recording the program" You may read it as "recording medium".
The refrigerating cycle control program causes the computer to execute each processing, each procedure, or each process, where the above "part" is read as "processing", "procedure", or "step". Moreover, the refrigerating cycle control method is a method performed by the controller 120 executing a refrigerating cycle control program.
The refrigeration cycle control program may be provided by being stored in a computer-readable recording medium. Also, the refrigeration cycle control program may be provided as a program product.

***Description of operation***
FIG. 5 is a flowchart showing the operation of control device 120 according to the present embodiment.

<Acquisition Processing: Step S101>
In step S101, the acquisition unit 121 acquires the operation request 63 for controlling the refrigeration cycle equipment 110 installed indoors 90 to the target state. When there are a plurality of refrigeration cycle devices 110, the acquisition unit 121 acquires the operation request 63 for controlling the plurality of refrigeration cycle devices 110 to the target state. When there are a plurality of refrigerating cycle devices 110, the operation request 63 may specify a target state individually for each of the plurality of refrigerating cycle devices 110, or may specify a target state for the plurality of refrigerating cycle devices 110 as a whole. You may specify one target state.

<Operation control processing: Step S102, Step S103, Step S104>
When the operation control unit 122 acquires the operation request 63 transmitted from the outdoors 91, the operation control unit 122 operates the refrigeration cycle equipment with a lower operation capability than the operation capability of the refrigeration cycle equipment 110 when the operation request 63 is transmitted from the indoors 90. 110 to the target state.
Specifically, it is as follows.

In step S<b>102 , the driving control unit 122 determines whether the transmission source of the driving operation request 63 is indoors 90 or outdoors 91 . Specifically, when the driving control unit 122 receives the driving operation request 63 via short-range wireless communication 13 such as infrared communication or Bluetooth (registered trademark), the transmission source of the driving operation request 63 is determined to be indoors 90. do. Further, when the driving control unit 122 receives the driving operation request 63 via the wireless LAN 12 such as Wi-Fi (registered trademark), it determines whether the driving operation request 63 is via the external network 11. . The driving control unit 122 uses information such as the MAC (Media Access Control) address and IP (Internet Protocol address) of the destination and the MAC address and IP address of the transmission source included in the driving operation request 63 to issue the driving operation request. 63 is via the external network 11 or not.

The driving control unit 122 determines that the transmission source of the driving operation request 63 is indoors 90 when the driving operation request 63 is not transmitted through the network 11 . The driving control unit 122 determines that the transmission source of the driving operation request 63 is the outdoors 91 when the driving operation request 63 is transmitted through the network 11 .
If the transmission source of the driving operation request 63 is indoors 90, the process proceeds to step S103. If the transmission source of the driving operation request 63 is the outdoors 91, the process proceeds to step S104. The method of determining the source of the driving operation request 63 described above is an example, and another method may be used to determine whether the source of the driving operation request 63 is indoors 90 or outdoors 91 .

In step S<b>103 , the operation control unit 122 controls the refrigeration cycle equipment 110 to the target state based on the operation request 63 . Specifically, the operation control unit 122 generates the operation control instruction 64 so that the refrigeration cycle equipment 110 quickly reaches the target state, and transmits the operation control instruction 64 to the refrigeration cycle equipment 110 .

In step S<b>104 , the operation control unit 122 controls the refrigeration cycle equipment 110 to the target state with an operation capability lower than the operation capability of the refrigeration cycle equipment 110 when the operation request 63 is transmitted from indoors 90 . The operation control unit 122 generates an operation control instruction 64 so that the refrigeration cycle equipment 110 is in a target state with an operation capability lower than the operation capability of the refrigeration cycle equipment 110 when the operation request 63 is transmitted from the indoor 90. and transmitted to the refrigeration cycle device 110 .

Specifically, as described below, the operation control unit 122 controls the operation capability of the refrigeration cycle equipment 110 to be lower than when the operation request 63 is transmitted from indoors 90 .

When the operation control unit 122 acquires the operation request 63 transmitted from the outdoors 91, the operation control unit 122 operates the refrigeration cycle so that the time required to reach the target state is longer than when the operation request 63 is transmitted from indoors. Control ability low. When the operating request 63 is given to the refrigerating cycle device 100 from the outdoors 91, the operation control unit 122 makes the refrigerating cycle device 100 operate at the same set temperature compared to when the operating request is given indoors 90. , the equipment is operated with reduced operability. In this way, the operation control unit 122 operates so that the time required to reach the set temperature becomes longer.

Further, when the operation control unit 122 acquires the operation request 63 transmitted from the outdoors 91, the operation control unit 122 may control the operability of the refrigeration cycle to be low by suppressing the maximum power consumption of the refrigeration cycle to the rated power consumption or less. .
In addition, the control device 120 can acquire information on the power that can be used in the house where the refrigeration cycle device 110 is installed as the power information that can be used. In addition, the control device 120 can acquire information on electric power of electric equipment used in a house, including the refrigeration cycle equipment 110, as electric equipment electric power information. When the driving control unit 122 acquires the driving operation request 63 transmitted from the outdoors 91, the total electric power of the electric equipment exceeds the electric power usable in the house based on the usable electric power information and the electric equipment electric power information. Determine whether or not Then, the operation control unit 122 may start the operation of the refrigeration cycle equipment when the total power of the electrical equipment does not exceed the power that can be used in the house.

Also, if there are a plurality of refrigeration cycle devices 110, the operation control unit 122 controls the operability of the refrigeration cycle devices 110 to be lower than when the operation request 63 is transmitted from indoors 90, as described below.

When the operation control unit 122 acquires the operation request 63 transmitted from the outdoors 91, the operation control unit 122 controls the operation capacity of each of the plurality of refrigeration cycle devices 110 to be lower than when operating a single refrigeration cycle device.
Further, when the operation control unit 122 acquires the operation request 63 transmitted from the outdoors 91 , the operation control unit 122 may shift the operation start time points of at least some of the plurality of refrigeration cycle devices 110 . That is, when an operation is performed to start operation of a plurality of refrigeration cycle devices 110 from the outdoors 91, the operation control unit 122 delays the operation start time without starting the operation of the plurality of refrigeration cycle devices 110 at the same time. I do.

The control device 120 includes a memory 921 that stores the number of refrigeration cycle devices 110 that start operating at the same time as the limit number 123 when the operating request 63 transmitted from the outdoors 91 is acquired. When the operation control unit 122 acquires the operation request 63 transmitted from the outdoors 91 , the operation control unit 122 starts operating the limited number 123 of the refrigeration cycle devices 110 among the plurality of refrigeration cycle devices 110 . Thus, when operating a plurality of refrigerating cycle devices 110 from the outdoors 91, the number of refrigerating cycle devices 110 that can be operated may be limited in advance.

Next, the lower limit value of the required capacity when the maximum capacity is lowered when operating from the outdoors 91 will be described using an air conditioner as an example.
As a feature of inverter-driven air conditioners, reducing the ability to operate generally improves energy consumption efficiency COP (Coefficient Of Performance). However, if the capacity is lowered too much, the COP will worsen. For this reason, the COP is the highest near the intermediate capacity, which corresponds approximately to half the rated capacity. Therefore, when energy saving is emphasized, operation with the highest energy saving can be achieved by operating the air conditioner so that the maximum capacity of the air conditioner is close to the intermediate capacity at the start of operation.

Next, it will be considered whether or not there will be a problem with the air conditioning capacity when the capacity at the start of operation is reduced to about half of the rated capacity.
In recent years, airtightness has been increasing due to energy saving in houses. Specifically, in the energy conservation standards of the 1980s, the heat loss coefficient Q value of houses in the Tokyo area was 5.2 W/m ² · K, while the heat loss coefficient Q value in the new energy conservation standards of 1999 was 2 .7 W/m ² ·K. In this way, the heat loss coefficient of the entire house is about half, and in recent years, energy saving has progressed further. The heat loss coefficient Q value means the amount of heat required to change the temperature by 1 degree ^{per square} meter of the floor area of a house.
In order to consider the stock of houses and consider the average house, the air conditioning load of the house is calculated from the heat loss coefficient of the house in the 1980s. Specifically, in order to raise the room temperature of an eight-tatami-mat wooden house (floor area of 13 m ² ) to 20 degrees indoors when the outside temperature is 0 degrees, heat of 1350 W should be added. On the other hand, in the case of air-conditioning an 8-tatami room in a wooden house, we select equipment with a rated heating capacity of about 3,600 W, which is more than double that.

This means that the heat loss coefficient of a house is the heat loss of the entire house, so the air conditioning capacity obtained from this is different from the capacity required when the air conditioner is actually operated. are doing. A major factor for this is, specifically, the amount of heat required to warm the cold wall surface in winter or the amount of heat required to cool the warm wall surface in summer. This amount of heat is called the heat storage load of the house. In addition, there is heat loss to the adjacent room, heat amount for ventilation, and latent heat amount for removing indoor humidity in summer. For this reason, there are people in the room when air conditioning is started, so the air conditioning capacity is sufficient so that problems do not occur even if there is an air conditioning load such as a heat storage load in the house in order to quickly approach the set temperature. It is necessary to drive with high ability with sufficient margin.
However, when the air conditioner is operated from the outside, it is not necessary to quickly reach the set temperature after starting the operation of the air conditioner. approaching the capacity of air conditioning obtained from Therefore, even if the maximum capacity is reduced to about half of the rated capacity, in many cases the temperature approaches the set temperature. Of course, depending on environmental factors such as outside air temperature or set temperature conditions, there are cases where the set temperature is not reached, but it is possible to satisfy the purpose of reducing discomfort when returning home.

Next, an example of a simple control method for reducing the rated capacity to about 1/2 will be described.
In general air conditioners, the equipment itself often does not detect the air conditioning capacity during operation. Therefore, since it is difficult to control the air conditioning capacity, it becomes easier to control by detecting and controlling the rotational speed of the compressor to be driven, the power consumption, or the operating current.
In other words, in the case of simple control, it is easy to control by setting the power consumption to about 1/2 of the rated power consumption and controlling to ensure the minimum capacity when the air conditioner is operated from outside. can. Alternatively, when controlling with the operating current, the current is half the operating current when the rated power consumption is exhibited, and the air conditioner is controlled to ensure the minimum capacity when operating the air conditioner from outside. Then you can easily control it. Alternatively, it is easy to control by setting the rotation speed of the compressor to about 1/2 when the air conditioner is operating at the rated capacity, and controlling it to ensure the minimum capacity when operating the air conditioner from outside. can.

As described above, when the operation of the air conditioner is operated from the outside and the capacity is lowered, it is preferable to control the maximum capacity from approximately the rated capacity to about 1/2 of the rated capacity. In other words, for simple control, it is preferable to control the maximum power consumption of the air conditioner so that the upper limit is approximately between the rated power consumption and 1/2 of the rated power consumption. Alternatively, when controlling the compressor rotation speed, it is preferable to control the rotation speed of the air conditioner from the rotation speed of the compressor at the rated capacity to 1/2 of the rotation speed at the rated capacity as an upper limit.

***Other Configurations***
<Modification 1>
In this embodiment, the functions of the acquisition unit 121 and the operation control unit 122 are realized by software. As a modification, the functions of the acquisition unit 121 and the operation control unit 122 may be realized by hardware.

FIG. 6 is a configuration diagram of control device 120 according to a modification of the present embodiment.
Controller 120 comprises electronic circuitry 909 , memory 921 and communication device 950 .

The electronic circuit 909 is a dedicated electronic circuit that implements the functions of the acquisition unit 121 and the operation control unit 122 .
Electronic circuit 909 is specifically a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, a logic IC, GA, ASIC, or FPGA. GA is an abbreviation for Gate Array. ASIC is an abbreviation for Application Specific Integrated Circuit. FPGA is an abbreviation for Field-Programmable Gate Array.

The functions of the acquisition unit 121 and the operation control unit 122 may be implemented by one electronic circuit, or may be implemented by being distributed among a plurality of electronic circuits.
As another modification, part of the functions of the acquisition unit 121 and the operation control unit 122 may be implemented by electronic circuits, and the remaining functions may be implemented by software.
As another modification, part or all of the functions of the acquisition unit 121 and the operation control unit 122 may be realized by firmware.

Each of the processor and electronic circuitry is also called processing circuitry. That is, in the control device 120, the functions of the acquisition unit 121 and the operation control unit 122 are realized by processing circuitry.

***Description of the effect of the embodiment***
Here, taking an air conditioner as an example of a refrigeration cycle device, the difference between operating the air conditioner from the outdoors and operating the air conditioner indoors, which is generally used, will be described.
When an air conditioner is operated indoors, it is usually used in the presence of people in the room. For this reason, when operating the equipment, the user must check whether there are any objects in the surrounding area that may interfere with the operation of the equipment, or whether there are any unsafe objects in the vicinity of the equipment before operation. It is normal to do Furthermore, if an abnormality occurs in the electric wire system or equipment, the user will notice the abnormality from the odor or smoke that precedes the occurrence of a fire, and take safety measures such as stopping the equipment. Fire extinguishing measures will be implemented so that even if a fire breaks out, it will not become an extended disaster. For this reason, it was difficult to become a big accident, and it was hard to become a big disaster such as a fatal accident.
On the other hand, when operating an air conditioner from outside, it is necessary to check the safety before operating the equipment or in the event of an abnormality, such as when there is no one at home indoors, or there is a bedridden elderly person who needs nursing care. Avoidance measures cannot be taken in the event of an abnormality, increasing the risk of a major accident.

Furthermore, when an air conditioner is operated indoors, it is common to use it to air-condition only the room in which there are occupants. However, when operating the air conditioner from the outside, there is a case where all rooms in which the user may live after returning home are air-conditioned. In such a case, since the air conditioners in a plurality of rooms are started at the same time, an extremely large amount of electric power is used compared to air conditioning in a normal life where the air conditioners are operated indoors. This further increases the risk of accidents occurring.
In addition to the problem of abnormalities in air conditioners, even if the power consumption is within the contracted power with the electric power company in normal life, multiple air conditioners and other devices can be operated at the same time when operating outdoors. By operating, the power may exceed the contracted power. As a result, there is a risk that the current breaker in the home will be cut off, making it impossible to use all the electricity in the home, and of course, the subsequent Wi-Fi (registered trademark) operation will also become impossible. In particular, when elderly caregivers use medical equipment that uses electricity, there is a risk of causing a serious accident involving human life.

Next, the risks in air conditioners in recent years will be explained.
Refrigerants used in air conditioners using a refrigeration cycle have mainly used nonflammable Freon refrigerants such as R22 or R410A. However, in recent years, due to the suppression of global warming and the promotion of energy saving, flammable refrigerants such as R32 fluorocarbon refrigerants have come to be mainly used.
Furthermore, in the future, more flammable refrigerants will be used, such as the use of flammable HFO refrigerants such as HFO1234ze, which is said to be more effective in curbing global warming than R32 refrigerants, or the use of natural refrigerants such as R290, which is highly flammable. is becoming practical. In other words, when these flammable refrigerants are used, an accident is likely to lead to a larger accident.
Therefore, it will be essential to further reduce the risk of accidents in the future. Therefore, it is becoming more and more important to further reduce the risk that the use of the operation of the air conditioner from the outside will lead to an accident.

In the above explanation, an air conditioner using a refrigerating cycle was explained as an example, but even if it is a floor heating or water heater using a refrigerating cycle, it is a device that uses the Carnot cycle, and the principle is the same as that of an air conditioner. In addition, it can be said that there is a similar problem because it is a device that requires a large amount of power like an air conditioner.

Below, the effect of the refrigerating cycle apparatus according to the present embodiment will be described.
In the refrigerating cycle apparatus according to the present embodiment, when the refrigerating cycle equipment is operated from the outside, the refrigerating cycle equipment is controlled to the target state with low operating ability, so that the occurrence of accidents during operation can be suppressed.

In the following, the effect of the embodiment will be described by taking an air conditioner as an example in equipment using a refrigeration cycle.
In the case of an air conditioner that uses a refrigeration cycle driven by an inverter, the upper limit of the cooling or heating capacity that the air conditioner can exhibit is the applicable number of tatami mats of the air conditioner, that is, the rated capacity used when determining the applicable floor area. , is generally large. The upper limit of the cooling or heating capacity that the air conditioner can exhibit is called the maximum capacity. Also, the power consumption at this time is referred to as maximum power consumption.
This maximum capacity is provided to quickly bring the room temperature closer to the set temperature when starting the air conditioner, and can be said to be a major feature of inverter drive. However, the power consumption at maximum capacity is greater than the power consumption at normal rated capacity.
This quick adjustment of the temperature of the room to the set temperature is very comfortable in normal usage such as operating the air conditioner when returning home. However, when operating the air conditioner from the outside, there is no need to quickly approach the set temperature.

Furthermore, the energy efficiency of an air conditioner is generally indicated by the energy consumption efficiency COP (Coefficient of performance) calculated from the ratio of the air conditioning capacity (W) and the power consumption (W) at that time. The larger the value of this COP, the more efficient the operation.
An air conditioner currently on the market is shown as an example. Specifically, taking a home-use wall-mounted air conditioner with a rated capacity of 2.8 kW as an example, the COP of heating when the rated capacity is exhibited is 4.0, whereas the maximum capacity is exhibited. Some equipment has a heating COP of 3.2 when it is on. Thus, in inverter-driven air conditioners, the COP when operating at maximum capacity is generally worse than the COP when operating at rated capacity. In other words, when operating from outside, since the user is not already in the room, there is no need to quickly bring the room closer to the set temperature. For this reason, the energy efficiency is higher and energy-saving operation is possible by lowering the operating capacity.

Taking advantage of the above features, air conditioners that can be operated from outdoors using Wi-Fi (registered trademark) radio can be operated at maximum when giving operation commands to the refrigeration cycle equipment from outdoors. There is no need to demonstrate the limited ability and quickly approach the set temperature. Therefore, even if the operating operation is at the same set temperature, compared to the case where the operation command of the refrigeration cycle equipment is given indoors, by performing the operation with the operating ability of the equipment lowered, the power consumption to be used will decrease, resulting in an accident. can reduce the risk of Furthermore, since it becomes possible to operate with high energy consumption efficiency, it contributes to energy saving.

Similarly, when an operation is performed to start operation of multiple refrigeration cycle equipment from outdoors, there is a risk that a large amount of power will be used rapidly, exceeding the domestic contract power and tripping the switchboard breaker. increases. In addition, the sharp increase in power consumption increases the amount of heat generated in power lines in the home, increasing the risk of accidents.
In order to reduce such risks, when a plurality of refrigeration cycle devices are operated at the same time, operation is automatically performed at a lower capacity than when a single refrigeration cycle device is given an operation command. . As a result, it is possible to suppress the power consumption to be used, stop the switchboard breaker, or reduce the risk of an accident. It also enables operation with high energy consumption efficiency, contributing to energy conservation.

Next, another method for reducing risks when an operation is performed to start operation of a plurality of refrigeration cycle devices from outdoors will be described.
When operating a plurality of refrigerating cycle devices from the outdoors, a user presets the order of starting operation of the refrigerating cycle devices. As a result, when a plurality of refrigerating cycle devices are operated from the outside, the operation of each refrigerating cycle device is started at regular intervals according to the order of starting operation. . If the refrigerating cycle device is an air conditioner, a plurality of air conditioners will not be driven at the same time, so it is possible to suppress large power consumption that occurs at the start of operation. Therefore, it is possible to suppress the risk of an accident or the breaker stoppage of the switchboard.

Next, when the refrigerating cycle equipment is operated from the outside, a guideline for lowering the performance of the equipment will be described. Generally, in the case of air conditioners, the residential floor area that can be installed is set according to the rated capacity.
Specifically, according to JISC9612, a residential air conditioner requires a rated capacity of 275 W/m ² for heating a wooden structure, facing south, and a one-story house. Since the floor area of an 8 tatami room is about 13 m ² , an air conditioner with a rated heating capacity of 3575 W (about 3600 W) will be selected. When the equipment is set in this way, even if the outside air temperature is 0 degrees, it is possible to warm the room up to about 20 degrees.

In the case of an inverter-driven air conditioner, the maximum capacity beyond this rated capacity can be exhibited, which is the capacity required to quickly reach the set temperature in the room. In other words, the higher the maximum capacity, the faster the room will reach the set temperature. However, when the air conditioner is operated from the outside, it is not necessary to quickly reach the set temperature, so it is preferable to lower the maximum capacity to below the rated capacity when the air conditioner is operated. By doing so, the power consumption at the start of operation of the air conditioner can be reduced to near the rated power consumption, and the risk of an accident or the risk of the switchboard breaker stopping can be reduced. Furthermore, the energy efficiency of the air conditioner is increased, and energy saving is also improved.

Embodiment 2.
In this embodiment, differences from the first embodiment are mainly described. In addition, the same code|symbol may be attached|subjected to the structure similar to Embodiment 1, and the description may be abbreviate|omitted.

*** Configuration description ***
FIG. 7 is a diagram showing the configuration of a refrigeration cycle control system 500 according to this embodiment.
A refrigerating cycle control system 500 of FIG. 7 includes a file server 20 that communicates with the refrigerating cycle apparatus 100 via a network 11 in addition to the configuration of FIG.

A refrigerating cycle control system 500 has a file server 20 and a refrigerating cycle device 100 having refrigerating cycle equipment 110 and a control device 120 .
File server 20 can communicate with control device 120 via network 11 . The file server 20 is specifically a cloud server provided in a cloud system.
The file server 20 stores a lifestyle log 21 representing the lifestyle of the user 80 of the refrigeration cycle equipment 110 .

FIG. 8 is a diagram showing the configuration of control device 120 according to the present embodiment.
In the present embodiment, operation control unit 122 acquires lifestyle log 21 via communication device 950 .

Acquisition unit 121 acquires operation request 63 requesting control of refrigeration cycle equipment 110 installed indoors 90 to a target state.
When the operation control unit 122 acquires the operation request 63 transmitted from the outdoors 91, the operation control unit 122 determines, based on the lifestyle log 21, the operation capability of the refrigeration cycle equipment 110 when the operation request 63 is transmitted from the indoors 90. The refrigeration cycle equipment 110 is controlled to the target state with low operating capability.

FIG. 9 is a diagram showing an example of lifestyle log 21 according to the present embodiment.
Lifestyle log 21 represents the lifestyle of user 80 . A lifestyle 521 representing the lifestyle of the user 80 is set in the lifestyle log 21 . Also, information such as living range 522 representing the range in which the user lives may be set.
Information for specifying the lifestyle of the user 80 is set in the lifestyle log 21 . In this embodiment, as an example, information such as season, weather, date attribute, and life scene is set. In addition, it is desirable to set various information for specifying a lifestyle. Specifically, it is desirable that information such as user 80's sex, age, family composition, job type, behavior pattern, preference, or house information is included. It is also desirable to include vital data such as blood pressure, heart rate, and respiration of the human body. From these lifestyles 521, the lifestyle itself is recognized as a user attribute. As a specific example, if user 80 is a two-person household of a man in his 30s and a woman in her 30s, it is desirable to recognize whether or not the household is a dual-income household with no children. It is desirable that behavioral patterns such as what time to get up, go out, go home, take a bath, and go to bed are also recognized as attributes. Preferences such as sensitivity to heat or sensitivity to cold may also be recognized as attributes. Also, information on the house where the refrigeration cycle device 110 is arranged may be recognized.

***Description of operation***
FIG. 10 is a flowchart showing the operation of control device 120 according to the present embodiment.
Steps S101 and S102 are the same as in the first embodiment.

In steps S103a and S104a, the operation control unit 122 controls the operation of the refrigeration cycle equipment 110 based on the lifestyle log 21 in addition to the functions similar to those of the first embodiment.

In step S<b>103 a , the operation control unit 122 controls the refrigeration cycle equipment 110 to the target state based on the lifestyle log 21 and the operation request 63 . Specifically, the operation control unit 122 generates the operation control instruction 64 in consideration of the lifestyle log 21 so that the refrigeration cycle equipment 110 quickly reaches the target state, and transmits the operation control instruction 64 to the refrigeration cycle equipment 110 . .

In step S<b>104 a , based on the lifestyle log 21 and the driving operation request 63 , the driving control unit 122 sets the driving ability lower than the driving ability of the refrigeration cycle equipment 110 when the driving operation request 63 is transmitted from the indoor 90 . , to control the refrigeration cycle equipment 110 to the target state. The operation control unit 122 controls the refrigeration cycle equipment 110 to be in the target state with an operation capability lower than the operation capability of the refrigeration cycle equipment 110 when the operation request 63 is transmitted from the indoor 90, and the lifestyle log 21 to generate an operation control instruction 64 and transmit it to the refrigeration cycle equipment 110 .
In other words, operation control unit 122 adjusts the target state of refrigeration cycle equipment 110 according to user's 80 preference, in addition to the same function as in the first embodiment, according to user's 80 lifestyle. Specifically, when the user 80 operates the refrigeration cycle equipment 110 from outside, the operation control unit 122 determines an appropriate target state based on the lifestyle log 21 even if the target state is not specified. May be set.

***Description of the effects of the present embodiment***
According to the refrigeration cycle control system according to the present embodiment, when the refrigeration cycle equipment is operated from the outside, it is possible to suppress the occurrence of accidents during operation, realize energy saving, and perform operation control that is just the right fit for the user. can be realized.

In the above first and second embodiments, each part of the control device has been described as an independent functional block. However, the configuration of the control device may be different from that of the above-described embodiment. The functional blocks of the control device may have any configuration as long as they can implement the functions described in the above embodiments. Also, the control device may be a system composed of a plurality of devices instead of a single device.
Also, a plurality of portions of the first and second embodiments may be combined for implementation. Alternatively, one portion of these embodiments may be implemented. In addition, these embodiments may be implemented in any combination as a whole or in part.
That is, in Embodiments 1 and 2, it is possible to freely combine each embodiment, modify any component of each embodiment, or omit any component from each embodiment.

The above-described embodiments are essentially preferable examples, and are not intended to limit the scope of the invention, the scope of applications of the invention, or the scope of applications of the invention. Various modifications can be made to the above-described embodiments as required.

11 network, 12 wireless LAN, 13 short-range wireless communication, 20 file server, 21 lifestyle log, 31 refrigerant circuit, 32 compressor, 33 four-way valve, 34 first heat exchanger, 35 expansion mechanism, 36 second heat exchange device, 40 first operation device, 50 second operation device, 63 operation request, 64 operation control instruction, 80 user, 90 indoors, 91 outdoors, 100 refrigerating cycle device, 110 refrigerating cycle device, 120 control device, 121 Acquisition unit, 122 operation control unit, 123 number limit, 500 refrigeration cycle control system, 521 lifestyle, 522 living area, 909 electronic circuit, 910 processor, 921 memory, 950 communication device.

Claims (9)

A plurality of refrigerating cycle devices each having a refrigerating cycle for compressing and circulating a refrigerant with a compressor, absorbing heat from a low-temperature heat source and exhausting heat to a high-temperature heat source with a heat exchanger, and controlling the operation of the plurality of refrigerating cycle devices. In a refrigeration cycle device comprising a control device,
The control device is
an acquisition unit that acquires an operation request for controlling the plurality of refrigeration cycle devices installed indoors to a target state;
a memory that stores the number of refrigeration cycle devices that start operating at the same time as a limit number;
It is determined whether the driving operation request is transmitted from outdoors or indoors based on the type of communication when the driving operation request is received. an operation control unit that controls the plurality of refrigerating cycle devices to a target state with an operating capability lower than the operating capability of the plurality of refrigerating cycle devices when an operation request is transmitted from indoors,
The operation control unit is
A refrigeration cycle apparatus for starting the operation of the limited number of refrigeration cycle devices among the plurality of refrigeration cycle devices when it is determined that the operation request is transmitted from outdoors. The operation control unit is
2. The refrigeration cycle apparatus according to claim 1, wherein when the operation request transmitted from outdoors is acquired, the operability of each of the plurality of refrigeration cycle devices is controlled to be lower than when operating a single refrigeration cycle device. The operation control unit is
3. The refrigeration cycle apparatus according to claim 1, wherein when the operation request transmitted from the outdoors is acquired, the operation start time of at least some of the plurality of refrigeration cycle devices is shifted. The operation control unit is
When the driving operation request transmitted from outdoors is obtained, the operability of the refrigeration cycle is controlled to be low so that the time required to reach the target state is longer than when the driving operation request is transmitted from indoors. The refrigeration cycle apparatus according to any one of claims 1 to 3. The operation control unit is
5. The operating capability of the refrigeration cycle is controlled to be low by suppressing the maximum power consumption of the refrigeration cycle to a rated power consumption or less when the operation request transmitted from outdoors is acquired. The refrigeration cycle device according to Item 1. The operation control unit is
When the operation request transmitted from the outdoors is acquired, information on the electric power that can be used in the house in which the plurality of refrigeration cycle devices are installed, and the electric devices used in the home that are the plurality of refrigeration cycle devices are obtained. Based on the information on the electric power of the electric equipment including the power information of the electric equipment, it is determined whether the total electric power of the electric equipment exceeds the electric power that can be used in the home, and if it does not exceed, the operation of the plurality of refrigeration cycle equipment 6. The refrigeration cycle apparatus according to any one of claims 1 to 5, starting from . The refrigeration cycle apparatus according to any one of claims 1 to 6, wherein the refrigerant used in the plurality of refrigeration cycle devices is a mildly flammable refrigerant or a combustible refrigerant. a file server;
A plurality of refrigerating cycle devices each having a refrigerating cycle that compresses and circulates a refrigerant with a compressor, absorbs heat from a low-temperature heat source and exhausts heat to a high-temperature heat source with a heat exchanger, and controls the operation of the plurality of refrigerating cycle devices. In a refrigeration cycle control system having a refrigeration cycle device comprising:
The file server is
comprising a lifestyle log representing the lifestyle of the user of the plurality of refrigeration cycle devices;
The control device is
an acquisition unit that acquires an operation request for controlling the plurality of refrigeration cycle devices installed indoors to a target state;
a memory that stores the number of refrigeration cycle devices that start operating at the same time as a limit number;
It is determined whether the driving operation request is transmitted from outdoors or indoors based on the type of communication when the driving operation request is received, and if it is determined that the driving operation request has been transmitted from outdoors, An operation control unit that controls the plurality of refrigerating cycle devices to a target state based on the lifestyle log with an operating capability lower than the operating capability of the plurality of refrigerating cycle devices when the operation request is transmitted from indoors. and
The operation control unit is
A refrigeration cycle control system for starting the operation of the limited number of refrigeration cycle devices among the plurality of refrigeration cycle devices when it is determined that the operation request is transmitted from outdoors. A plurality of refrigerating cycle devices each having a refrigerating cycle for compressing and circulating a refrigerant with a compressor, absorbing heat from a low-temperature heat source and exhausting heat to a high-temperature heat source with a heat exchanger, and controlling the operation of the plurality of refrigerating cycle devices. A refrigeration cycle control method for a refrigeration cycle device comprising a control device,
the computer acquires a driving operation request for controlling the plurality of refrigeration cycle devices installed indoors to a target state;
The computer has a memory that stores the number of refrigeration cycle devices that start operating at the same time as a limit number,
The computer determines whether the driving operation request is transmitted from outdoors or indoors based on the type of communication when the driving operation request is received, and determines that the driving operation request has been transmitted from outdoors. and controlling the plurality of refrigerating cycle devices to a target state with an operating capability lower than the operating capability of the plurality of refrigerating cycle devices when the operation request is transmitted from indoors,
The refrigeration cycle control method, wherein the computer starts the operation of the limited number of refrigeration cycle devices out of the plurality of refrigeration cycle devices when it is determined that the operation request is transmitted from outdoors.

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