JP7182361B2 - refrigeration equipment - Google Patents

Description

The present disclosure relates to refrigeration equipment.

Conventionally, an air conditioning system having an outdoor unit and a plurality of indoor units is known. For example, Patent Document 1 (Japanese Laid-Open Patent Publication No. 5-118720) discloses an air conditioning system in which one outdoor unit and a plurality of indoor units are connected via refrigerant communication pipes. In Patent Literature 1, a control valve that shuts off the flow of refrigerant when closed is arranged on the refrigerant communication pipe.

In the system as described above, the indoor units and the control valves arranged in the refrigerant communication pipes are normally supplied with separate drive power sources. However, in such a case, it is assumed that the power supply to the control valves arranged on the connecting pipe is interrupted for some reason (for example, power failure, deterioration of the power line, etc.). That is, the risk that the control valve does not operate as expected during operation of the indoor unit cannot be ignored. For example, in Patent Literature 1, when a refrigerant leak occurs in an indoor unit, the control valve plays the role of being controlled to a closed state to block the flow of refrigerant and suppress further refrigerant leakage, as expected. If the control valve does not operate immediately, safety against refrigerant leakage cannot be ensured.

A refrigerating device according to a first aspect is a refrigerating device that performs a refrigerating cycle in a refrigerant circuit, and includes an outdoor unit, a plurality of indoor units, connecting pipes, an intermediate unit, and electrical wiring. The communication pipe connects the outdoor unit and the indoor unit. The communication pipe forms a coolant channel. The intermediate unit contains control valves. A control valve is disposed on the coolant flow path. The control valve cuts off the flow of the refrigerant by being in a fully closed state. The electrical wiring is connected to a power source. A common driving power supply is supplied to the intermediate unit and each indoor unit via electrical wiring.

This reduces risk. That is, since the control valve and the indoor unit are supplied with a common driving power source, when the power supply to the control valve is cut off, the power supply to the indoor unit is also cut off. Therefore, it is possible to prevent the indoor unit from continuing to operate when the control valve does not operate as expected due to the power shutdown. Therefore, the risk of the control valve not operating as expected during operation of the indoor unit is suppressed.

A refrigerating device according to the second aspect is the refrigerating device according to the first aspect, wherein the electrical wiring includes a first electrical wiring and a second electrical wiring. The first electrical wiring electrically connects the power supply and the intermediate unit. The second electrical wiring electrically connects the intermediate unit and the indoor unit.

A refrigerating device according to the third aspect is the refrigerating device according to the second aspect, wherein the electrical wiring includes a third electrical wiring. A third electrical wiring extends between the indoor units. The third electric wiring electrically connects one indoor unit and another indoor unit.

A refrigerating device according to a fourth aspect is the refrigerating device according to any one of the first aspect to the third aspect, wherein the electric wiring also serves as a communication line for transmitting signals between the indoor unit and the intermediate unit, or between the indoor units. . A refrigeration apparatus according to a fifth aspect, in which an increase in cost is thereby suppressed, is the refrigeration apparatus according to any one of the first aspect to the fourth aspect, and further includes a control unit. The controller controls the control valves and actuators in the indoor unit. The controller cooperatively controls the control valve and the actuator in the indoor unit.

A refrigerating apparatus according to a sixth aspect is the refrigerating apparatus according to any one of the first aspect to the fifth aspect, wherein the connecting pipe includes a plurality of branched portions. A control valve is arranged in the bifurcation.

A refrigerating device according to a seventh aspect is the refrigerating device according to the sixth aspect, further comprising a branch pipe unit. The branch pipe unit is assembled in advance and connected to other pipes at the construction site. The branch pipe unit constitutes part or all of the branch portion. The branch pipe unit is configured integrally with the control valve.

1 is a schematic diagram schematically showing the overall configuration of an air conditioning system according to an embodiment of the present disclosure; FIG. A refrigerant circuit diagram of an air conditioning system. The schematic diagram which showed roughly the installation aspect of the indoor unit and intermediate unit (1st intermediate unit) in object space. FIG. 2 is a block diagram schematically showing a controller and each unit connected to the controller; FIG. 4 is a flowchart showing an example of the flow of processing by a controller; FIG. 11 is a schematic diagram schematically showing the overall configuration of an air conditioning system according to Modification 25; FIG. 11 is a schematic diagram schematically showing the overall configuration of an air conditioning system according to Modification 26; FIG. 11 is a schematic diagram schematically showing the overall configuration of an air conditioning system according to Modification 27; FIG. 21 is a refrigerant circuit diagram in an outdoor unit according to Modification 27; FIG. 11 is a refrigerant circuit diagram in an indoor unit and an intermediate unit according to Modification 27; FIG. 14 is a schematic diagram schematically showing an installation mode of an indoor unit and an intermediate unit according to Modification 27;

An air conditioning system 100 (refrigerating device) according to an embodiment of the present disclosure will be described below. It should be noted that the following embodiments are specific examples, and do not limit the technical scope, and can be modified as appropriate without departing from the scope of the invention. Further, in the present disclosure, the “closed state” is the minimum opening degree (including fully closed) that the valve can take, and the “open state” is the opening degree greater than the minimum opening degree.

(1) Air conditioning system 100
FIG. 1 is a schematic diagram schematically showing the overall configuration of an air conditioning system 100 according to an embodiment of the present disclosure. FIG. 2 is a refrigerant circuit diagram of the air conditioning system 100. As shown in FIG. The air-conditioning system 100 is a refrigeration device that performs air conditioning (cooling, heating, etc.) of a target space SP (living space, storage space, low-temperature warehouse space, transport container space, etc.) using a vapor compression refrigeration cycle. . The air conditioning system 100 mainly includes an outdoor unit 10, a plurality of indoor units 40 (40a, 40b, 40c, . , 50b), a plurality of refrigerant leakage sensors 60 (60a, 60b, . . . ), a plurality of remote controllers 65 (65a, 65b, . and a plurality of wires 90 for power supply and/or communication to the unit.

In the air conditioning system 100, the refrigerant circuit RC is configured by connecting the outdoor unit 10 and the indoor unit 40 via the liquid-side communication pipe La, the gas-side communication pipe Ga, and the intermediate unit 50. In the air conditioning system 100, a refrigeration cycle is performed in the refrigerant circuit RC in which the refrigerant is compressed, cooled or condensed, depressurized, heated or evaporated, and then compressed again. In this embodiment, the refrigerant circuit RC is filled with mildly flammable R32 as a refrigerant for performing a vapor compression refrigeration cycle.

The refrigerant circuit RC mainly includes an outdoor circuit RC1 configured in the outdoor unit 10, an indoor circuit RC2 configured in each indoor unit 40, the outdoor circuit RC1, and each indoor circuit RC2. A communication circuit RC3 (corresponding to a "refrigerant flow path") is included. Further, the communication circuit RC3 includes a liquid side communication circuit RC3a functioning as a flow path for liquid refrigerant flowing between the outdoor unit 10 and the indoor unit 40, and a gas refrigerant flowing between the outdoor unit 10 and the indoor unit 40. and a gas-side communication circuit RC3b functioning as a flow path.

(1-1) Outdoor unit 10
The outdoor unit 10 is arranged outdoors. The outdoor unit 10 is connected to a plurality of indoor units 40 via a liquid-side connecting pipe La, a gas-side connecting pipe Ga, and an intermediate unit 50, and constitutes a part of the refrigerant circuit RC (outdoor circuit RC1). there is

The outdoor unit 10, as equipment constituting the outdoor circuit RC1, mainly includes a plurality of refrigerant pipes (first pipe P1-eleventh pipe P11), a compressor 11, an accumulator 12, a flow path switching valve 13, It has an outdoor heat exchanger 14 , a supercooler 15 , a first outdoor motor-operated valve 16 , a second outdoor motor-operated valve 17 , a liquid-side closing valve 19 , and a gas-side closing valve 20 .

The first pipe P<b>1 connects the gas side shutoff valve 20 and the first port of the flow path switching valve 13 . The second pipe P<b>2 connects the second port of the flow path switching valve 13 and the inlet port of the accumulator 12 . The third pipe P3 connects the outlet port of the accumulator 12 and the suction port of the compressor 11 . A fourth pipe P<b>4 connects the discharge port of the compressor 11 and the third port of the flow path switching valve 13 . The fifth pipe P<b>5 connects the fourth port of the flow path switching valve 13 and the gas side inlet/outlet of the outdoor heat exchanger 14 .

The sixth pipe P<b>6 connects the liquid side inlet/outlet of the outdoor heat exchanger 14 and one end of the first outdoor electric valve 16 . The seventh pipe P7 connects the other end of the first outdoor motor-operated valve 16 and one end of the main flow path 151 of the supercooler 15 . The eighth pipe P8 connects the other end of the main flow path 151 of the supercooler 15 and one end of the liquid side shutoff valve 19 . The ninth pipe P<b>9 connects a portion between both ends of the sixth pipe P<b>6 and one end of the second outdoor electric valve 17 . The tenth pipe P<b>10 connects the other end of the second outdoor motor-operated valve 17 and one end of the sub-channel 152 of the supercooler 15 . The eleventh pipe P11 connects the other end of the sub-channel 152 of the supercooler 15 and the portion between both ends of the first pipe P1.

Incidentally, these refrigerant pipes (P1-P11) may actually be constituted by a single pipe, or may be constituted by connecting a plurality of pipes via joints or the like.

The compressor 11 is a device that compresses a low-pressure refrigerant in the refrigeration cycle to a high pressure. In this embodiment, the compressor 11 has a closed structure in which a positive displacement compression element such as a rotary type or a scroll type is rotationally driven by a compressor motor (not shown). Further, here, the compressor motor can control the operating frequency by means of an inverter, so that the capacity of the compressor 11 can be controlled.

The accumulator 12 is a container for suppressing excessive intake of liquid refrigerant into the compressor 11 . The accumulator 12 has a predetermined volume according to the amount of refrigerant with which the refrigerant circuit RC is filled.

The channel switching valve 13 is a four-way switching valve for switching the flow of refrigerant in the refrigerant circuit RC. The channel switching valve 13 can switch between a forward cycle state and a reverse cycle state. When the flow path switching valve 13 is in the normal cycle state, the first port (first pipe P1) and the second port (second pipe P2) are communicated, and the third port (fourth pipe P4) and the fourth port are connected. (the fifth pipe P5) (see the solid line of the flow path switching valve 13 in FIG. 2). When the flow path switching valve 13 is in the reverse cycle state, the first port (first pipe P1) and the third port (fourth pipe P4) are communicated, and the second port (second pipe P2) and the fourth port are connected. (the fifth pipe P5) (see the dashed line of the flow path switching valve 13 in FIG. 2).

The outdoor heat exchanger 14 is a heat exchanger that functions as a condenser (or radiator) or evaporator. The outdoor heat exchanger 14 functions as a refrigerant condenser during normal cycle operation (operation in which the flow path switching valve 13 is in the normal cycle state). In addition, the outdoor heat exchanger 14 functions as a refrigerant evaporator during reverse cycle operation (operation in which the flow path switching valve 13 is in the reverse cycle state). The outdoor heat exchanger 14 includes a plurality of heat transfer tubes and heat transfer fins (not shown). The outdoor heat exchanger 14 is configured such that heat is exchanged between the refrigerant in the heat transfer tubes and the air (outdoor air flow described later) passing around the heat transfer tubes or the heat transfer fins. .

The supercooler 15 is a heat exchanger that converts the inflowing refrigerant into a supercooled liquid refrigerant. The supercooler 15 is, for example, a double-tube heat exchanger, and the supercooler 15 includes a main channel 151 and sub-channels 152 . The supercooler 15 is configured such that the refrigerant flowing through the main channel 151 and the sub-channel 152 exchanges heat.

The first outdoor motor-operated valve 16 is a motor-operated valve whose degree of opening can be controlled, and reduces the pressure or adjusts the flow rate of the inflowing refrigerant according to the degree of opening. The first outdoor electric valve 16 can be switched between an open state and a closed state. The first outdoor motor-operated valve 16 is arranged between the outdoor heat exchanger 14 and the supercooler 15 (main flow path 151).

The second outdoor motor-operated valve 17 is a motor-operated valve whose degree of opening can be controlled, and reduces the pressure or adjusts the flow rate of the inflowing refrigerant according to the degree of opening. The second outdoor motor-operated valve 17 can be switched between an open state and a closed state. The outdoor second motor-operated valve 17 is arranged between the outdoor heat exchanger 14 and the supercooler 15 (sub-flow path 152).

The liquid-side closing valve 19 is a manual valve arranged at the connecting portion between the eighth pipe P8 and the liquid-side connecting pipe La. The liquid side shut-off valve 19 has one end connected to the eighth pipe P8 and the other end connected to the liquid side communication pipe La.

The gas side shutoff valve 20 is a manual valve arranged at the connecting portion between the first pipe P1 and the gas side connecting pipe Ga. The gas side shutoff valve 20 has one end connected to the first pipe P1 and the other end connected to the gas side communication pipe Ga.

The outdoor unit 10 also has an outdoor fan 25 that generates an outdoor airflow that passes through the outdoor heat exchanger 14 . The outdoor fan 25 is a blower that supplies the outdoor heat exchanger 14 with an outdoor air flow as a cooling source or a heating source for the refrigerant flowing through the outdoor heat exchanger 14 . The outdoor fan 25 includes an outdoor fan motor (not shown) as a drive source, and the start/stop and rotation speed of the outdoor fan 25 are appropriately controlled according to the situation.

The outdoor unit 10 is also provided with a plurality of outdoor sensors 26 (see FIG. 4) for detecting the state of the refrigerant (mainly pressure or temperature) in the refrigerant circuit RC. The outdoor sensor 26 is a pressure sensor, a temperature sensor such as a thermistor or a thermocouple. The outdoor sensor 26 includes, for example, a suction pressure sensor that detects a suction pressure, which is the pressure of refrigerant on the suction side of the compressor 11, and a discharge pressure sensor that detects a discharge pressure, which is the pressure of refrigerant on the discharge side of the compressor 11. , and a temperature sensor for detecting the temperature of the refrigerant in the outdoor heat exchanger 14 .

The outdoor unit 10 also has an outdoor unit control section 30 that controls the operation/state of each device included in the outdoor unit 10 . The outdoor unit control section 30 includes a microcomputer having a CPU, memory, etc., and various electrical components. The outdoor unit control section 30 is electrically connected to each device (11, 13, 16, 17, 25, etc.) included in the outdoor unit 10 and the outdoor sensor 26, and performs signal input/output with each other. In addition, the outdoor unit control section 30 individually transmits and receives control signals and the like to and from the indoor unit control section 48 (described later) of each indoor unit 40 and the intermediate unit control section 58 (described later) of the intermediate unit 50 via the wiring 90. I do.

(1-2) Indoor unit 40
Each indoor unit 40 is connected to the outdoor unit 10 via a liquid-side connecting pipe La, a gas-side connecting pipe Ga, and an intermediate unit 50 . In the refrigerant circuit RC, each indoor unit 40 is arranged in parallel with other indoor units 40 with respect to the outdoor unit 10 . Each indoor unit 40 is arranged in the target space SP and constitutes part of the refrigerant circuit RC (indoor circuit RC2). Each indoor unit 40 mainly includes a plurality of refrigerant pipes (liquid-side pipe Pa and gas-side pipe Pb), an indoor expansion valve 41, and an indoor heat exchanger 42 as devices that constitute the indoor circuit RC2. is doing.

The liquid side pipe Pa connects the liquid side communication pipe La (L2) and the liquid side refrigerant inlet/outlet of the indoor heat exchanger 42 . The gas side pipe Pb connects the gas side refrigerant inlet/outlet of the indoor heat exchanger 42 and the gas side communication pipe Ga (G2). These refrigerant pipes (Pa, Pb) may actually be configured by a single pipe, or may be configured by connecting a plurality of pipes via joints or the like.

The indoor expansion valve 41 is a motor-operated valve whose degree of opening can be controlled, and reduces the pressure or adjusts the flow rate of the inflowing refrigerant according to the degree of opening. The indoor expansion valve 41 can be switched between an open state and a closed state. The indoor expansion valve 41 is arranged on the liquid side pipe Pa and positioned between the liquid side connecting pipe La and the indoor heat exchanger 42 .

The indoor heat exchanger 42 is a heat exchanger that functions as a refrigerant evaporator or condenser (or radiator). The indoor heat exchanger 42 functions as a refrigerant evaporator during normal cycle operation. In addition, the indoor heat exchanger 42 functions as a refrigerant condenser during reverse cycle operation. The indoor heat exchanger 42 includes a plurality of heat transfer tubes and heat transfer fins (not shown). The indoor heat exchanger 42 is configured such that heat is exchanged between the refrigerant in the heat transfer tubes and the air passing around the heat transfer tubes or the heat transfer fins (indoor air flow, which will be described later). .

The indoor unit 40 also has an indoor fan 45 for sucking air in the target space SP, passing the air through the indoor heat exchanger 42 to exchange heat with the refrigerant, and then sending the air back to the target space SP. The indoor fan 45 is arranged in the target space SP. The indoor fan 45 includes an indoor fan motor (not shown) as a drive source. The indoor fan 45 generates indoor airflow as a heating source or a cooling source for the refrigerant flowing through the indoor heat exchanger 42 when driven.

Further, the indoor unit 40 is provided with an indoor sensor 46 (see FIG. 4) for detecting the state of the refrigerant (mainly pressure or temperature) in the refrigerant circuit RC and the temperature of the target space SP.

The indoor unit 40 also has an indoor unit control section 48 that controls the operation and state of each device included in the indoor unit 40 . The indoor unit control section 48 has a microcomputer including a CPU, memory, etc., and various electrical components. The indoor unit controller 48 is electrically connected to the devices (41, 45) included in the indoor unit 40 and the indoor sensor 46, and performs signal input/output with each other. The indoor unit control section 48 is connected to the outdoor unit control section 30 and an intermediate unit control section 58 (described later) of the intermediate unit 50 via wiring 90, and transmits and receives control signals and the like. Furthermore, the indoor unit control section 48 transmits and receives control signals to and from the remote controller 65 through wired communication or wireless communication.

(1-3) Liquid-side connecting pipe La, gas-side connecting pipe Ga
The liquid-side communication pipe La and the gas-side communication pipe Ga are refrigerant communication pipes that connect the outdoor unit 10 and each indoor unit 40, and are constructed on site. The liquid-side communication pipe La and the gas-side communication pipe Ga form a communication circuit RC3 (refrigerant flow path) between the outdoor unit 10 and each indoor unit 40 . The pipe lengths and pipe diameters of the liquid-side connecting pipe La and the gas-side connecting pipe Ga are appropriately selected according to the design specifications and the installation environment.

The liquid-side communication pipe La (corresponding to a “connection pipe”) constitutes a liquid-side communication circuit RC3 (liquid-side communication circuit RC3a) between the outdoor unit 10 and each indoor unit 40. This is the piping through which the refrigerant flows. The liquid-side communication pipe La is configured by connecting a plurality of pipes, joints, and the like. Specifically, the liquid-side connecting pipe La includes a first liquid-side connecting pipe L1, a plurality of second liquid-side connecting pipes L2, and a plurality of branch portions BP. In addition, the first liquid-side communication pipe L1 and the second liquid-side communication pipe L2 may actually be configured by a single pipe, or may be configured by connecting a plurality of pipes via joints or the like. may be

The liquid side first communication pipe L1 extends between the liquid side shutoff valve 19 of the outdoor unit 10 and the main pipe 52 (described later) of the intermediate unit 50 (50a). The liquid-side second communication pipe L2 extends between a branch pipe 53 (described later) of the intermediate unit 50 (50a) and the indoor expansion valve 41 of the indoor unit 40. The first liquid-side communication pipe L1 and the second liquid-side communication pipe L2 are connected and communicated by an intermediate unit 50 (50a).

The gas-side communication pipe Ga (corresponding to the “connection pipe”) constitutes a gas-side communication circuit RC3 (gas-side communication circuit RC3b) between the outdoor unit 10 and each indoor unit 40, and during operation, the low-pressure refrigerant is It is a flowing pipe. The gas-side communication pipe Ga is configured by connecting a plurality of pipes, joints, and the like. The gas-side communication pipe Ga includes a first gas-side communication pipe G1, a second gas-side communication pipe G2, and a branch portion BP. The first gas-side communication pipe G1 and the second gas-side communication pipe G2 may actually be configured by a single pipe, or may be configured by connecting a plurality of pipes via joints or the like. may be

One end of the gas side first communication pipe G1 is connected to the gas side shutoff valve 20 of the outdoor unit 10, and extends between the main pipe 52 (described later) of the intermediate unit 50 (50b). The gas-side second communication pipe G2 extends between a branch pipe 53 (described later) of the intermediate unit 50 (50b) and a gas-side inlet/outlet of the indoor heat exchanger 42 of the indoor unit 40. The first gas-side communication pipe G1 and the second gas-side communication pipe G2 are connected and communicated by an intermediate unit 50 (50b).

In the following description, one or both of the liquid-side connecting pipe La and the gas-side connecting pipe Ga will be referred to as "refrigerant connecting pipe". Further, one or both of the first liquid-side communication pipe L1 and the first gas-side communication pipe G1 are referred to as "one end side communication pipe". Also, one or all of the second liquid-side communication pipe L2 and the second gas-side communication pipe G2 will be referred to as "the other end side communication pipe".

The branching portion BP is a portion for branching or joining the refrigerant flowing from the one end side connecting pipe or the other end side connecting pipe.

(1-4) Intermediate unit 50
The intermediate unit 50 is a unit for forming a branch portion BP in the connecting circuit RC3. In addition, when refrigerant leakage occurs in the refrigerant circuit RC (in particular, the indoor circuit RC2), the intermediate unit 50 allows the refrigerant to flow between the outdoor circuit RC1 and the indoor circuit RC2 (mainly, from the outdoor circuit RC1 side to the relevant refrigerant). It is also a unit for configuring a cutoff section that cuts off the refrigerant flow toward the indoor circuit RC2 side.

The air conditioning system 100 has, as intermediate units 50, a first intermediate unit 50a and a second intermediate unit 50b.

The first intermediate unit 50a constitutes a branch portion BP (liquid side branch portion BPa) located closest to the outdoor circuit RC1 in the liquid side communication circuit RC3a. The first intermediate unit 50a is arranged between the first liquid-side communication pipe L1 and each of the second liquid-side communication pipes L2 to connect them. That is, the first intermediate unit 50a connects the first liquid side connecting pipe L1 arranged on the outdoor unit 10 side and the second liquid side connecting pipe L2 arranged on the indoor unit 40 side. The first intermediate unit 50a includes the refrigerant flowing from the outdoor unit 10 side to the indoor unit 40 side via the liquid side first communication pipe L1 and the liquid side second communication pipe L2, and the liquid side second communication pipe L2 and the liquid side first communication pipe L2. A common refrigerant channel is formed for both the refrigerant flowing from the indoor unit 40 to the outdoor unit 10 via the connecting pipe L1.

The second intermediate unit 50b constitutes a specific branch portion BP (gas side branch portion BPb) in the gas side communication circuit RC3b. The second intermediate unit 50b is arranged between the first gas-side communication pipe G1 and each of the second gas-side communication pipes G2 to connect them. That is, the second intermediate unit 50b connects the first gas side communication pipe G1 arranged on the outdoor unit 10 side and the second gas side communication pipe G2 arranged on the indoor unit 40 side. The second intermediate unit 50b contains the refrigerant flowing from the outdoor unit 10 side to the indoor unit 40 side via the first gas side communication pipe G1 and the second gas side communication pipe G2, and the second gas side communication pipe G2 and the first gas side communication pipe G2. A common refrigerant channel is formed for both the refrigerant flowing from the indoor unit 40 to the outdoor unit 10 via the connecting pipe G1.

Each intermediate unit 50 has a branch pipe unit 51, a cutoff valve 55, and an intermediate unit controller 58 in a substantially rectangular parallelepiped casing.

The branch pipe unit 51 includes a plurality of pipes and constitutes a branch portion BP in the communication circuit RC3. The branch pipe unit 51 is assembled in advance and connected to another pipe (La or Ga) at the construction site. Specifically, the branch pipe unit 51 includes a main pipe 52 and a plurality of branch pipes 53 . In the branch pipe unit 51, the main pipe 52 and the plurality of branch pipes 53 are integrally constructed.

The main pipe 52 is located closer to the outdoor unit 10 than the branch pipes 53 are. One end of the main pipe 52 is connected to the one end side connecting pipe, and the other end is connected to each branch pipe 53 .

Each branch pipe 53 is located closer to the indoor unit 40 than the main pipe 52 is. Each branch pipe 53 has a one-to-one correspondence with one of the other end side connecting pipes, and is connected to the corresponding other end side connecting pipe. Each branch pipe 53 is joined to and communicates with the main pipe 52 .

The shut-off valve 55 (corresponding to a “control valve”) is a valve that permits the flow of refrigerant when it is in an open state and shuts off the flow of refrigerant when it is in a closed state. In the present embodiment, the cutoff valve 55 is a valve that can be switched between a closed state and an open state by being supplied with a predetermined driving voltage, and is a commonly used electromagnetic valve. The operation (opening/closing) of the cutoff valve 55 is directly controlled by the intermediate unit control section 58 and is centrally controlled by the controller 70 . Specifically, the shutoff valve 55 is configured integrally with the branch pipe unit 51 . A shut-off valve 55 is arranged on the mains 52 . In other words, the shutoff valve 55 is arranged on the communication circuit RC3 in the installed state (more specifically, the shutoff valve 55 is arranged on the branch portion BP located closest to the outdoor circuit RC1). . The shutoff valve 55 is installed in a state of being joined to the branch pipe unit 51 (main pipe 52).

The intermediate unit control section 58 has a microcomputer including a CPU, memory, etc., and various electrical components. The intermediate unit control section 58 is electrically connected to a device included in the intermediate unit 50 (here, the cutoff valve 55), and performs signal input/output with each other. The intermediate unit control section 58 is connected to the outdoor unit control section 30 and the indoor unit control section 48 via wiring 90, and transmits and receives control signals and the like.

(1-5) Refrigerant leakage sensor 60
The refrigerant leakage sensor 60 is a sensor for detecting refrigerant leakage in the target space SP where the indoor unit 40 is arranged (more specifically, inside the indoor unit 40). In this embodiment, the refrigerant leakage sensor 60 is a known general-purpose product according to the type of refrigerant enclosed in the refrigerant circuit RC. The coolant leakage sensor 60 is arranged within the target space SP. More specifically, the refrigerant leakage sensors 60 are associated with the indoor units 40 on a one-to-one basis, and arranged in the corresponding indoor units 40 .

The refrigerant leakage sensor 60 continuously or intermittently outputs an electric signal (refrigerant leakage sensor detection signal) corresponding to the detected value to the controller 70 . More specifically, the refrigerant leakage sensor detection signal output from the refrigerant leakage sensor 60 changes in voltage according to the concentration of the refrigerant detected by the refrigerant leakage sensor 60 . In other words, the refrigerant leakage sensor detection signal indicates the presence or absence of refrigerant leakage in the refrigerant circuit RC, as well as the concentration of the leakage refrigerant in the target space SP where the refrigerant leakage sensor 60 is installed (more specifically, the refrigerant leakage sensor 60 detects concentration of the refrigerant) is output to the controller 70 in an identifiable manner. That is, the refrigerant leakage sensor 60 serves as a "refrigerant leakage detector" that detects refrigerant leakage in the indoor circuit RC2 by directly detecting the refrigerant (more specifically, the concentration of the refrigerant) flowing out of the indoor circuit RC2. Equivalent to.

(1-6) Remote control 65
The remote control 65 is an input device for the user to input various commands for switching the operating state of the air conditioning system 100 . For example, the remote controller 65 receives a command from the user for starting/stopping the indoor unit 40, switching the set temperature, and the like.

The remote controller 65 also functions as a display device for displaying various information to the user. For example, the remote control 65 displays the operating state (set temperature, etc.) of the indoor unit 40 . Further, for example, the remote controller 65 displays information (refrigerant leakage notification information) for notifying the administrator of the fact that the refrigerant has leaked and the corresponding countermeasures, etc., when the refrigerant leaks.

The remote control 65 exchanges signals with the controller 70 (more specifically, the corresponding indoor unit control section 48) via wired communication or wireless communication. Remote control 65 transmits commands input by the user to controller 70 . Further, the remote controller 65 displays information according to the received control signal.

(1-7) Controller 70
The controller 70 (corresponding to a “control unit”) controls the state of each device (for example, each actuator in the outdoor unit 10 and each indoor unit 40, and the shutoff valve 55 in the intermediate unit 50). is a computer that controls the operation of In this embodiment, the controller 70 is configured by connecting the outdoor unit control section 30, the indoor unit control section 48 in each indoor unit 40, and the intermediate unit control section 58 via wiring 90. there is Details of the controller 70 will be described later.

(1-8) Wiring 90
The wiring 90 includes an outdoor wiring 91 for supplying power to the outdoor unit 10 and a plurality of indoor wirings 92 (corresponding to "electric wiring") for supplying power to the indoor unit 40 or the intermediate unit 50. include. The wiring 90 also includes a transmission cable cb for transmitting control signals between the outdoor unit 10 and each intermediate unit 50 .

The outdoor wiring 91 is electrically connected to the first commercial power source 200 . The first commercial power supply 200 is a single-phase or three-phase AC power supply that supplies a voltage V1 of 100 volts or 200 volts. The indoor wiring 92 is electrically connected to a second commercial power supply 300 (corresponding to "power supply"). The second commercial power supply 300 is a single-phase or three-phase AC power supply that supplies a voltage V2 of 100 volts or 200 volts. As the outdoor-side wiring 91 and the indoor-side wiring 92, widely known general-purpose products are used. In this embodiment, the indoor wiring 92 is a three-core electrical wiring covered with an insulator. The indoor wiring 92 also functions as a "communication line" for control signal transmission. That is, the indoor wiring 92 also serves as a communication line for transmitting signals between the indoor unit 40 and the intermediate unit 50 or between the indoor units 40 . That is, the indoor wiring 92 constructs a power supply path for supplying drive power and a transmission path for signal transmission.

The outdoor wiring 91 is arranged between the first commercial power source 200 and the outdoor unit 10 (outdoor unit controller 30), and electrically connects the two.

The indoor wiring 92 includes a first indoor wiring 93 , a second indoor wiring 94 , and a plurality of third indoor wirings 95 .

The indoor-side first wiring 93 (corresponding to "first electric wiring") is arranged between the second commercial power source 300 and each intermediate unit 50 (50a and 50b) to electrically connect them. The indoor-side first wiring 93 is connected to the second commercial power supply 300 and each intermediate unit 50 (intermediate unit control unit) so that the first intermediate unit 50a and the second intermediate unit 50b are arranged in parallel with the second commercial power supply 300. 58) are electrically connected.

The indoor-side second wiring 94 (corresponding to "second electric wiring") is arranged between the intermediate unit 50 and the indoor unit 40, and electrically connects them. In this embodiment, the first intermediate unit 50a (intermediate unit control section 58) and the indoor unit 40a (indoor unit control section 48) are connected by the indoor second wiring 94. As shown in FIG. That is, the indoor unit 40a is supplied with drive power via the first intermediate unit 50a.

The indoor-side third wiring 95 (corresponding to the "third electrical wiring") is arranged between one of the indoor units 40 (indoor unit control section 48) and the other indoor unit 40 (indoor unit control section 48). (that is, it extends between the indoor units 40) and electrically connects the two. In this embodiment, for example, the indoor unit 40a and the indoor unit 40b are connected by the indoor-side third wiring 95 . That is, the indoor unit 40b is supplied with drive power via the indoor unit 40a. Further, for example, the indoor unit 40b and the indoor unit 40c are connected by the indoor-side third wiring 95 . That is, the indoor unit 40c is supplied with drive power via the indoor unit 40c.

In the air conditioning system 100 , the intermediate unit 50 and each indoor unit 40 are supplied with drive power from the second commercial power supply 300 by arranging the indoor wiring 92 in this manner. That is, the intermediate unit 50 and each indoor unit 40 are supplied with a common driving power supply through the indoor wiring 92 .

The transmission cable cb extends in the wiring 90 between the outdoor unit controller 30 and the intermediate unit controller 58 of each intermediate unit 50 (50a and 50b), and transmits and receives control signals between them. Build a transmission line.

(2) Flow of Refrigerant in Refrigerant Circuit RC Hereinafter, the flow of refrigerant in the refrigerant circuit RC will be described. The air conditioning system 100 mainly performs forward cycle operation and reverse cycle operation. The low pressure in the refrigeration cycle here is the pressure of the refrigerant sucked into the compressor 11 (suction pressure), and the high pressure in the refrigeration cycle is the pressure of the refrigerant discharged from the compressor 11 (discharge pressure).

(2-1) Flow of Refrigerant During Normal Cycle Operation During normal cycle operation (cooling operation, etc.), the flow path switching valve 13 is controlled to the normal cycle state, and the refrigerant charged in the refrigerant circuit RC is mainly directed to the outdoor side. Circuit RC1 (compressor 11, outdoor heat exchanger 14, outdoor first electric valve 16, and supercooler 15), liquid side communication circuit RC3a (liquid side first communication pipe L1, first intermediate unit 50a and liquid side first 2 communication pipe L2), indoor circuit RC2 of indoor unit 40 in operation (indoor expansion valve 41 and indoor heat exchanger 42), gas side communication circuit RC3b (gas side second communication pipe G2, second intermediate unit 50b and It circulates in the order of the gas side first connecting pipe G1) and the compressor 11. During normal cycle operation, in the outdoor circuit RC1, part of the refrigerant flowing through the sixth pipe P6 branches to the ninth pipe P9 and passes through the outdoor second motor-operated valve 17 and the supercooler 15 (sub-flow path 152). After that, it is returned to the compressor 11 .

Specifically, when the normal cycle operation is started, the refrigerant is drawn into the compressor 11 in the outdoor circuit RC1, compressed, and then discharged. In the compressor 11, capacity control is performed according to the heat load required by the indoor unit 40 in operation. Specifically, the target value of the suction pressure is set according to the heat load required by the indoor unit 40, and the operating frequency of the compressor 11 is controlled so that the suction pressure becomes the target value. The gas refrigerant discharged from the compressor 11 flows into the outdoor heat exchanger 14 .

The gaseous refrigerant that has flowed into the outdoor heat exchanger 14 exchanges heat with the outdoor air flow sent by the outdoor fan 25 to radiate heat and condense. The refrigerant that has flowed out of the outdoor heat exchanger 14 branches while flowing through the sixth pipe P6.

One of the refrigerants branched in the process of flowing through the sixth pipe P6 flows into the first outdoor motor-operated valve 16, and after being decompressed or having its flow rate adjusted according to the degree of opening of the first outdoor motor-operated valve 16, the supercooler 15 It flows into the main channel 151 . The refrigerant that has flowed into the main channel 151 of the supercooler 15 exchanges heat with the refrigerant flowing through the sub-channel 152 and is further cooled to become a supercooled liquid refrigerant. The liquid refrigerant that has flowed out of the main flow path 151 of the supercooler 15 flows out of the outdoor circuit RC1 and flows into the indoor circuit RC2 of the indoor unit 40 in operation via the liquid side communication circuit RC3a.

The other refrigerant branched in the process of flowing through the sixth pipe P6 flows into the second outdoor motor-operated valve 17, and after being decompressed or having its flow rate adjusted according to the degree of opening of the second outdoor motor-operated valve 17, the supercooler 15 It flows into the sub-channel 152 . The refrigerant that has flowed into the sub-channel 152 of the supercooler 15 exchanges heat with the refrigerant flowing through the main channel 151, and then joins the refrigerant flowing through the first pipe P1 via the 11th pipe P11.

The refrigerant that has flowed into the indoor circuit RC2 of the indoor unit 40 in operation flows into the indoor expansion valve 41, and after being decompressed to a low pressure in the refrigeration cycle according to the degree of opening of the indoor expansion valve 41, is subjected to indoor heat exchange. It flows into vessel 42 .

The refrigerant that has flowed into the indoor heat exchanger 42 exchanges heat with the indoor air flow sent by the indoor fan 45 , evaporates, becomes gaseous refrigerant, and flows out of the indoor heat exchanger 42 . The gas refrigerant that has flowed out of the indoor heat exchanger 42 flows out of the indoor circuit RC2.

The refrigerant that has flowed out of the indoor circuit RC2 flows into the outdoor unit 10 via the gas side communication circuit RC3b. The refrigerant that has flowed into the outdoor unit 10 flows through the first pipe P<b>1 , passes through the flow path switching valve 13 and the second pipe P<b>2 , and flows into the accumulator 12 . The refrigerant that has flowed into the accumulator 12 is sucked into the compressor 11 again after being temporarily stored.

(2-2) Refrigerant Flow During Reverse Cycle Operation During reverse cycle operation (heating operation, etc.), the flow path switching valve 13 is controlled to the reverse cycle state, and the refrigerant charged in the refrigerant circuit RC is mainly supplied to the compressor. 11, gas side communication circuit RC3b (gas side first communication pipe G1, second intermediate unit 50b and gas side second communication pipe G2), indoor unit 40 in operation (indoor heat exchanger 42 and indoor expansion valve 41), Liquid side communication circuit RC3a (liquid side second communication pipe L2, first intermediate unit 50a and liquid side first communication pipe L1), supercooler 15, outdoor first electric valve 16, outdoor heat exchanger 14, compressor 11 Cycle in the order of

Specifically, when the reverse cycle operation is started, in the outdoor circuit RC1, the refrigerant is sucked into the compressor 11, compressed, and then discharged. In the compressor 11, capacity control is performed according to the heat load required by the indoor unit 40 in operation. The gas refrigerant discharged from the compressor 11 flows out of the outdoor circuit RC1 through the fourth pipe P4 and the first pipe P1, and flows into the indoor circuit RC2 of the operating indoor unit 40 through the gas side communication circuit RC3b. do.

The refrigerant that has flowed into the indoor circuit RC2 flows into the indoor heat exchanger 42, exchanges heat with the indoor air flow sent by the indoor fan 45, and is condensed. The refrigerant that has flowed out of the indoor heat exchanger 42 flows into the indoor expansion valve 41, is decompressed to a low pressure in the refrigeration cycle according to the degree of opening of the indoor expansion valve 41, and then flows out of the indoor circuit RC2.

The refrigerant that has flowed out of the indoor circuit RC2 flows into the outdoor circuit RC1 through the liquid side communication circuit RC3a. The refrigerant that has flowed into the outdoor circuit RC1 passes through the eighth pipe P8, the subcooler 15 (main flow path 151), the seventh pipe P7, the first outdoor motor-operated valve 16, and the sixth pipe P6, and reaches the outdoor heat exchanger 14. flows into the liquid side inlet and outlet of the

The refrigerant that has flowed into the outdoor heat exchanger 14 exchanges heat with the outdoor air flow sent by the outdoor fan 25 and evaporates. The refrigerant that has flowed out from the gas side inlet/outlet of the outdoor heat exchanger 14 flows into the accumulator 12 via the fifth pipe P5, the flow path switching valve 13 and the second pipe P2. The refrigerant that has flowed into the accumulator 12 is sucked into the compressor 11 again after being temporarily stored.

(3) Installation mode of the indoor unit 40 and the intermediate unit 50 FIG. 3 is a schematic diagram showing the installation mode of the indoor unit 40 (40a and 40b) and the intermediate unit 50 (first intermediate unit 50a) in the target space SP. It is a diagram. In FIG. 3, up, down, left, and right directions are shown, but the left and right directions are included in the horizontal direction, and the up and down directions are included in the vertical direction.

In FIG. 3 , the first intermediate unit 50a extends from the outdoor unit 10 in the space SPa above the ceiling (for example, the space formed by the ceiling plate C1 and the floor plate C2 of the roof or the upper floor). It is connected to one communication pipe L1. Also, the first intermediate unit 50a and each indoor unit 40 are connected by a second liquid-side communication pipe L2.

3, the first intermediate unit 50a is electrically connected to the indoor first wiring 93 extending from the second commercial power source 300 in the ceiling space SPa. Also, the first intermediate unit 50a is electrically connected to a transmission cable cb extending from the outdoor unit 10 (outdoor unit controller 30). Further, the indoor-side second wiring 94 extends between the first intermediate unit 50a and the indoor unit 40a, and the first intermediate unit 50a and the indoor unit 40a are electrically connected. Further, the indoor side third wiring 95 extends between the indoor unit 40a and the indoor unit 40b and between the indoor unit 40b and the other indoor unit 40, and the indoor unit 40a and the indoor unit 40b and the indoor unit 40b and the other An indoor unit 40 is electrically connected.

In this embodiment, each indoor unit 40 is arranged in series with respect to the first intermediate unit 50a in the power supply system and the communication system. In this regard, in the power supply system and the communication system, the number of indoor units 40 arranged in series with respect to the first intermediate unit 50a is determined by design specifications (for example, power supply capacity, refrigerant charging amount, or total number of indoor units 40 ability, etc.).

Although the second intermediate unit 50b and the gas side communication pipe Ga are omitted in FIG. It is connected to the pipe G1. Also, the second intermediate unit 50b and each indoor unit 40 are connected by a second gas-side communication pipe G2. Also, the second intermediate unit 50b and the outdoor unit control section 30 are electrically connected by a transmission cable cb.

(4) Details of Controller 70 In the air conditioning system 100 , the controller 70 is configured by connecting the outdoor unit controller 30 , each indoor unit controller 48 , and each intermediate unit controller 58 with wiring 90 . FIG. 4 is a block diagram schematically showing the controller 70 and each unit connected to the controller 70. As shown in FIG.

The controller 70 has a plurality of control modes, and controls the operation of each device according to the transition control mode. In this embodiment, the controller 70 has two control modes: a normal operation mode that transitions during operation (when no refrigerant leakage occurs), and a normal operation mode that transitions when refrigerant leakage occurs (more specifically, when a leaked refrigerant is detected). ) and a refrigerant leakage mode.

The controller 70 controls devices included in the air conditioning system 100 (specifically, the compressor 11 included in the outdoor unit 10, the first outdoor motor-operated valve 16, the second outdoor motor-operated valve 17, the outdoor fan 25, and the outdoor sensor 26). , the indoor expansion valve 41, the indoor fan 45 and the indoor sensor 46 included in each indoor unit 40, the cutoff valve 55 of each intermediate unit 50, each refrigerant leakage sensor 60, each remote control 65, etc.), electrically It is connected.

The controller 70 mainly includes a storage unit 71, an input control unit 72, a mode control unit 73, a coolant leakage determination unit 74, a device control unit 75, a drive signal output unit 76, and a display control unit 77. have. These functional units in the controller 70 function integrally with the CPU, memory, and various electric/electronic components included in the outdoor unit control unit 30, the indoor unit control unit 48, and/or the intermediate unit control unit 58. is realized by doing

(4-1) Storage unit 71
The storage unit 71 is composed of, for example, ROM, RAM, flash memory, etc., and includes a volatile storage area and a nonvolatile storage area. The storage unit 71 includes a program storage area M1 that stores a control program defining processing in each unit of the controller 70 .

The storage unit 71 also includes a detection value storage area M2 for storing detection values of various sensors. In the detected value storage area M2, for example, the detected values of the outdoor sensor 26 and the indoor sensor 46 (suction pressure, discharge pressure, discharge temperature, refrigerant temperature in the outdoor heat exchanger 14, or coolant temperature, etc.) are stored.

The storage unit 71 also includes a sensor signal storage area M3 for storing a coolant leak sensor detection signal (a detected value of the coolant leak sensor 60) transmitted from the coolant leak sensor 60. FIG. The sensor signal storage area M3 has storage areas corresponding to the number of refrigerant leakage sensors 60, and the received refrigerant leakage sensor detection signal is stored in an area corresponding to the refrigerant leakage sensor 60 that is the transmission source. The refrigerant leakage signal stored in the sensor signal storage area M3 is updated each time a refrigerant leakage signal output from the refrigerant leakage sensor 60 is received.

The storage unit 71 also includes a command storage area M4 for storing commands input to each remote controller 65 .

Further, the storage unit 71 is provided with a plurality of flags having a predetermined number of bits. For example, the storage unit 71 is provided with a control mode determination flag M5 capable of determining the control mode to which the controller 70 is transitioning. The control mode determination flag M5 includes the number of bits corresponding to the number of control modes, and the bits corresponding to the transition control modes are set.

Further, the storage unit 71 is provided with a refrigerant leakage detection flag M6 for determining that refrigerant leakage has been detected within the target space SP. More specifically, the refrigerant leakage detection flag M6 has a number of bits corresponding to the number of installed indoor units 40, and corresponds to the indoor unit 40 (refrigerant leakage unit) assumed to have refrigerant leakage. Bits are set. That is, the refrigerant leakage detection flag M6 is configured to be able to determine in which indoor unit 40 (indoor circuit RC2) the refrigerant leakage has occurred when refrigerant leakage occurs in the indoor circuit RC2. The refrigerant leakage detection flag M6 is switched by the refrigerant leakage determination unit 74. FIG.

(4-2) Input control section 72
The input control unit 72 is a functional unit that serves as an interface for receiving signals output from each device connected to the controller 70 . For example, the input control unit 72 receives signals output from the sensors (26, 46, 60) and the remote control 65 and stores them in corresponding storage areas of the storage unit 71 or sets a predetermined flag.

(4-3) Mode control section 73
The mode control unit 73 is a functional unit that switches control modes. The mode control unit 73 switches the control mode to the normal operation mode during normal operation (when the refrigerant leakage detection flag M6 is not set). The mode control unit 73 switches the control mode to the refrigerant leakage mode when the refrigerant leakage detection flag M6 is set. The mode control unit 73 sets a control mode determination flag M5 according to the control mode to which it is transitioning.

(4-4) Refrigerant leakage determination unit 74
The refrigerant leakage determination unit 74 is a functional unit that determines whether or not refrigerant leakage occurs in the refrigerant circuit RC (indoor circuit RC2). Specifically, when a predetermined refrigerant leakage detection condition is satisfied, the refrigerant leakage determination unit 74 determines that refrigerant leakage is occurring in the refrigerant circuit RC (indoor circuit RC2), and sets the refrigerant leakage detection flag M6. .

In this embodiment, whether or not the refrigerant leakage detection condition is satisfied is determined based on the refrigerant leakage sensor detection signal in the sensor signal storage area M3. Specifically, the refrigerant leakage detection condition is that the voltage value (detection value of the refrigerant leakage sensor 60) related to any refrigerant leakage sensor detection signal continues for a predetermined first reference value or more for a predetermined time t1 or longer. filled by The first reference value is a value (refrigerant concentration) at which refrigerant leakage is assumed in the indoor circuit RC2. The predetermined time t1 is set to a time during which it can be determined that the refrigerant leakage sensor detection signal is not instantaneous. The refrigerant leakage determination unit 74 identifies the refrigerant leakage unit (the indoor unit 40 assumed to have refrigerant leakage) based on the refrigerant leakage sensor 60 that is the transmission source of the refrigerant leakage sensor detection signal that satisfies the refrigerant leakage detection condition. , the bit corresponding to the refrigerant leakage unit is set in the refrigerant leakage detection flag M6. In other words, the refrigerant leakage determination unit 74, together with each refrigerant leakage sensor 60, corresponds to a "refrigerant leakage detection unit" that individually detects refrigerant leakage from each of the indoor circuits RC2.

The predetermined time t1 is appropriately set according to the type of refrigerant enclosed in the refrigerant circuit RC, the specifications of each device, the installation environment, and the like, and is defined in the control program. The coolant leakage determination unit 74 is configured to be able to measure the predetermined time t1.

Also, the first reference value is appropriately set according to the type of refrigerant enclosed in the refrigerant circuit RC, design specifications, installation environment, and the like, and is defined in the control program.

(4-5) Device control section 75
The device control unit 75 controls the operation of each device (for example, 11, 13, 16, 17, 25, 41, 45, 55, etc.) included in the air conditioning system 100 according to the situation according to the control program. The device control unit 75 refers to the control mode determination flag M5 to determine the transition control mode, and controls the operation of each device based on the determined control mode.

For example, in the normal operation mode, the device control unit 75 controls the operating capacity of the compressor 11, the outdoor fan 25 and the indoor fan 25 so that the normal cycle operation or the reverse cycle operation is performed according to the set temperature, the detection value of each sensor, etc. The rotational speed of the fan 45, the degree of opening of the first outdoor electric valve 16, the degree of opening of the indoor expansion valve 41, and the like are controlled in real time.

During normal cycle operation, the device control unit 75 controls the flow path switching valve 13 to the normal cycle state, causes the outdoor heat exchanger 14 to function as a refrigerant condenser (or radiator), and controls the operation of the indoor unit 40 during operation. The indoor heat exchanger 42 is made to function as a refrigerant evaporator. In addition, during reverse cycle operation, the device control unit 75 controls the flow path switching valve 13 to the reverse cycle state, causes the outdoor heat exchanger 14 to function as a refrigerant evaporator, and performs indoor heat exchange of the indoor unit 40 during operation. The device 42 functions as a refrigerant condenser (or radiator).

In addition, the device control section 75 executes various controls as described below depending on the situation. Note that the device control unit 75 is configured to be able to measure time.

<Refrigerant leakage first control>
When it is assumed that refrigerant leakage has occurred in the target space SP (specifically, when the refrigerant leakage detection flag M6 is set), the device control unit 75 executes refrigerant leakage first control. In the refrigerant leakage first control, the device control section 75 controls the indoor expansion valve 41 of the refrigerant leakage unit (indoor unit 40 in which refrigerant leakage has occurred) to be closed. As a result, the inflow of refrigerant into the refrigerant leakage unit is suppressed, and further refrigerant leakage is suppressed. That is, the refrigerant leakage first control is control for suppressing refrigerant leakage in the indoor circuit RC2 when refrigerant leakage occurs, and the indoor expansion valve 41 is closed when refrigerant leakage occurs. Refrigerant flowing into the indoor unit 40 is blocked.

<Refrigerant leakage second control>
The device control unit 75 executes the second refrigerant leakage control when it is assumed that refrigerant leakage has occurred in the target space SP. In the second refrigerant leakage control, the equipment control section 75 operates the indoor fan 45 of each indoor unit 40 at the rotational speed (air volume) for the second refrigerant leakage control. The refrigerant leakage second control is a control to operate the indoor fan 45 at a predetermined number of revolutions in order to prevent local occurrence of a region where the leaked refrigerant concentration is high within the target space SP.

Note that the number of rotations of the indoor fan 45 in the second refrigerant leakage control is not particularly limited, but is set to the maximum number of rotations (that is, the maximum air volume) in the present embodiment. With this refrigerant leakage second control, even if refrigerant leakage occurs in the target space SP, the leaked refrigerant is stirred in the target space SP by the user-side airflow generated by the indoor fan 45, and the leaked refrigerant is stirred in the target space SP. It is possible to suppress the occurrence of a region in which the concentration of the leaked refrigerant has a dangerous value.

<Refrigerant leakage third control>
The device control unit 75 executes the third refrigerant leakage control when it is assumed that refrigerant leakage has occurred in the target space SP. In the refrigerant leakage third control, the device control unit 75 controls the cutoff valves 55 of the respective branch portions BP to the closed state in order to disconnect the outdoor circuit RC1 and the indoor circuits RC2. That is, the third refrigerant leakage control is a control that, when refrigerant leakage occurs, cuts off the refrigerant flowing from the outdoor circuit RC1 to the indoor circuit RC2 of the leaking unit by the liquid side communication circuit RC3a and the gas side communication circuit RC3b. be.

Specifically, in the refrigerant leakage third control, the device control unit 75 closes the shutoff valve 55 of the liquid side branch portion BPa to close the liquid side communication circuit RC3a. In addition, in the refrigerant leakage third control, the device control unit 75 closes the shutoff valve 55 of the gas side branch portion BPb to close the gas side communication circuit RC3b. As a result, the flow of refrigerant from the outdoor circuit RC1 to the indoor circuit RC2 is blocked by the communication circuit RC3, and the amount of refrigerant leakage in the indoor circuit RC2 is reliably suppressed.

The third refrigerant leakage control can also be interpreted as a control that complements the first refrigerant leakage control. That is, the refrigerant leakage first control controls the indoor expansion valve 41 of the refrigerant leakage unit to the closed state, suppresses the inflow of refrigerant into the refrigerant leakage unit, and realizes the effect of suppressing further refrigerant leakage. However, the third refrigerant leakage control controls the shutoff valves 55 to the closed state to close the communication circuit RC3, thereby further ensuring the effect. Thus, in the refrigerant leakage mode, the first refrigerant leakage control and the third refrigerant leakage control are related, and the indoor expansion valve 41 and the cutoff valve 55 are controlled in cooperation. In other words, the indoor expansion valve 41 and the cutoff valve 55 are cooperatively controlled in the refrigerant leakage mode.

(4-6) Drive signal output section 76
The drive signal output unit 76 outputs a corresponding drive signal (drive voltage) to each device (11, 13, 16, 17, 25, 41, 45, 55, etc.) according to the control contents of the device control unit 75. Output. The drive signal output unit 76 includes a plurality of inverters (not shown), and a specific device (for example, the compressor 11, the outdoor fan 25, or each indoor fan 45, etc.) is driven from the corresponding inverter. Output a signal.

(4-7) Display control unit 77
The display control unit 77 is a functional unit that controls the operation of the remote controller 65 as a display device. The display control unit 77 causes the remote controller 65 to output predetermined information in order to display information relating to the operating state and situation to the user. For example, the display control unit 77 causes the remote controller 65 to display various information such as the set temperature during operation in the normal mode.

Further, the display control unit 77 causes the remote controller 65 to display refrigerant leakage notification information when the refrigerant leakage detection flag M6 is set. As a result, the administrator can grasp the fact that refrigerant leakage has occurred, and can take prescribed measures.

(5) Processing Flow of Controller 70 An example of the processing flow of the controller 70 will be described below with reference to FIG. FIG. 5 is a flowchart showing an example of the processing flow of the controller 70. As shown in FIG. When the power is turned on, the controller 70 performs processing according to the flow shown in steps S101 to S110 in FIG. Note that the flow of processing shown in FIG. 5 is an example and can be changed as appropriate. For example, the order of the steps may be changed within a consistent range, some steps may be executed in parallel with other steps, and other steps may be newly added.

In step S101, when the controller 70 assumes that refrigerant leakage has occurred in the indoor circuit RC2 (that is, in the case of YES), the process proceeds to step S105. When the controller 70 assumes that there is no refrigerant leakage in the indoor circuit RC2 (that is, in the case of NO), the process proceeds to step S102.

In step S102, the controller 70 returns to step S101 when the operation start command has not been input (that is, in the case of NO). On the other hand, if the operation start command has been input (that is, if YES), the controller 70 proceeds to step S103.

In step S103, the controller 70 transitions to the normal operation mode (or maintains the normal operation mode). After that, the controller 70 proceeds to step S104.

In step S104, the controller 70 causes normal cycle operation to be performed by controlling the state of each device in real time according to the input command, set temperature, detection value of each sensor (26, 46), etc. . Although not shown, the controller 70 causes the remote control 65 to display various information such as the set temperature. After that, the controller 70 returns to step S101.

In step S105, the controller 70 transitions to refrigerant leakage mode. After that, the controller 70 proceeds to step S106.

In step S106, the controller 70 causes the remote controller 65 to output refrigerant leakage notification information. As a result, the administrator can grasp that refrigerant leakage has occurred. After that, the controller 70 proceeds to step S107.

In step S107, the controller 70 executes refrigerant leakage first control. Specifically, the controller 70 closes the indoor expansion valve 41 of the refrigerant leaking unit. As a result, the flow of refrigerant to the indoor circuit RC2 of the refrigerant leaking unit is blocked, and further refrigerant leakage is suppressed. After that, the controller 70 proceeds to step S108.

In step S108, the controller 70 executes refrigerant leakage second control. Specifically, the controller 70 drives the indoor fan 45 at a predetermined rotational speed (for example, maximum rotational speed). As a result, the leaked refrigerant is agitated in the target space SP and is prevented from becoming locally dangerous in concentration. After that, the controller 70 proceeds to step S109.

In step S109, the controller 70 executes the refrigerant leakage third control. Specifically, the controller 70 closes the liquid side communication circuit RC3a by controlling the cutoff valve 55 of the liquid side branch portion BPa to the closed state. Further, in the refrigerant leakage third control, the device control unit 75 closes the shutoff valve 55 of the gas side branch portion BPb to close the gas side communication circuit RC3b. As a result, the refrigerant is suppressed from flowing from the outdoor circuit RC1 to the indoor circuit RC2 of the leaking unit, and the leaked refrigerant amount is suppressed. After that, the controller 70 proceeds to step S110.

In step S<b>110 , the controller 70 stops the compressor 11 . The controller 70 then waits until released by the administrator.

(6) Features (6-1)
Conventionally, an air conditioning system having an outdoor unit and a plurality of indoor units (for example, one outdoor unit and a plurality of indoor units are connected via a refrigerant communication pipe, and the refrigerant flow is cut off by being closed) Air-conditioning systems are known in which a control valve for controlling the temperature is arranged on a refrigerant communication pipe. In such a system, the indoor units and the control valves arranged in the refrigerant communication pipes are normally supplied with separate drive power sources. However, in such a case, it is assumed that the power supply to the control valves arranged on the connecting pipe is cut off due to some cause (power supply abnormality, deterioration of the power line, etc.). That is, the risk that the control valve does not operate as expected during operation of the indoor unit cannot be ignored. For example, in Patent Literature 1, when a refrigerant leak occurs in an indoor unit, the control valve plays the role of being controlled to a closed state to block the flow of refrigerant and suppress further refrigerant leakage, as expected. If the control valve does not operate immediately, safety against refrigerant leakage cannot be ensured.

In the air conditioning system 100 according to the above-described embodiment, the indoor wiring 92 is connected to the second commercial power supply 300 (power supply), and the intermediate unit 50 and each indoor unit 40 are supplied with common drive power through the indoor wiring 92. be done.

This reduces risk. That is, since the cutoff valve 55 and the indoor unit 40 are supplied with a common driving power source, when the power supply to the cutoff valve 55 is cut off, the power supply to the indoor unit 40 is also cut off. It's becoming Therefore, the indoor unit 40 is prevented from continuing to operate when the cutoff valve 55 does not operate as expected due to the power shutdown. Therefore, the risk that the shutoff valve 55 does not operate as expected during operation of the indoor unit 40 is suppressed.

Conventionally, each indoor unit and intermediate unit are supplied with drive power from separate power sources, and at the construction site, electrical wiring for supplying drive power from the power source is connected to the power supply, each indoor unit, and the intermediate unit. It is normal to place each separately between In this regard, in the air conditioning system 100, the intermediate unit 50 and each indoor unit 40 are supplied with common drive power through the indoor wiring 92, and the indoor unit 40 is supplied with drive power through the intermediate unit 50. It's like As a result, at the construction site, it is possible to share electrical wiring for supplying drive power from the power supply to each indoor unit 40 and the intermediate unit 50 (that is, the electrical wiring is connected to the power supply and each indoor unit). 40 and the intermediate unit 50), the labor required for construction is reduced and the workability is improved.

(6-2)
In the air conditioning system 100 according to the above embodiment, the indoor wiring 92 includes the indoor first wiring 93 (first electrical wiring) and the indoor second wiring 94 (second electrical wiring). The indoor-side first wiring 93 electrically connects the power source and the intermediate unit 50 . The indoor-side second wiring 94 electrically connects the intermediate unit 50 and the indoor unit 40 . This makes it possible to easily supply a common drive power source to the shutoff valve 55 and the indoor unit 40 .

(6-3)
In the air conditioning system 100 according to the above embodiment, the indoor wiring 92 includes the indoor third wiring 95 (third electrical wiring). The indoor-side third wiring 95 extends between the indoor units 40 . The indoor-side third wiring 95 electrically connects one indoor unit 40 and another indoor unit 40 . This makes it possible to easily supply a common drive power source to the shutoff valve 55 and each indoor unit 40 .

(6-4)
In the air conditioning system 100 according to the above embodiment, the indoor wiring 92 also serves as a “communication line” for transmitting signals between the indoor unit 40 and the intermediate unit 50 or between the indoor units 40 . This eliminates the need to arrange a “communication line” between the indoor unit 40 and the intermediate unit 50 or between the indoor units 40 separately from the indoor wiring 92 . In relation to this, the increase in cost is suppressed, and construction is simplified and workability is improved.

(6-5)
In the air conditioning system 100 according to the above embodiment, the controller 70 cooperatively controls the shutoff valve 55 and the indoor expansion valve 41 in the indoor unit 40 (for example, in the refrigerant leakage mode). That is, in the air conditioning system 100, the drive power source is shared for the indoor expansion valve 41 and the cutoff valve 55 that are cooperatively controlled, and associated risks are suppressed.

(6-6)
In the air conditioning system 100 according to the above embodiment, the cutoff valve 55 is arranged at the branch portion BP (liquid side branch portion BPa) of the liquid side connecting pipe (La). This simplifies construction at the construction site and improves workability.

(6-7)
In the air conditioning system 100 according to the above embodiment, the branch pipe unit 51 of the intermediate unit 50 is assembled in advance and connected to other pipes (L1, L2) at the construction site. The branch pipe unit 51 constitutes the entire branch portion BP (liquid side branch portion BPa). The branch pipe unit 51 is configured integrally with the cutoff valve 55 . This simplifies construction at the construction site and improves workability.

(7) Modifications The above embodiment can be appropriately modified as shown in the following modifications. Each modified example may be applied in combination with other modified examples as long as there is no contradiction.

(7-1) Modification 1
In the above embodiment, the case where the indoor units 40 are electrically connected to each other by the indoor-side third wiring 95 has been described. However, the air conditioning system 100 may be configured without the indoor-side third wiring 95 . That is, the intermediate unit 50 and each indoor unit 40 may be electrically connected individually by a plurality of indoor-side second wirings 94 . In such a case, each indoor unit 40 is arranged in parallel with the intermediate unit 50 in the power supply system and/or the communication system.

(7-2) Modification 2
In the above embodiment, the case where the first intermediate unit 50a and the indoor unit 40a are connected by the indoor second wiring 94 has been described. However, the configuration is not necessarily limited to this, and the second intermediate unit 50b and the indoor unit 40a may be connected by the indoor-side second wiring 94 .

(7-3) Modification 3
In the above embodiment, the first intermediate unit 50a, etc. (specifically, the first intermediate unit 50a, the second intermediate unit 50b, and the indoor units 40) supply the voltage V2 of 100 volts or 200 volts, either single-phase or three-phase. A case has been described where the drive power is supplied by being electrically connected to the second commercial power supply 300, which is a phase AC power supply. In this regard, the first intermediate unit 50a and the like may be supplied with drive power from another power source.

For example, the first intermediate unit 50a and the like may be supplied with drive power from a DC power supply. Further, for example, the first intermediate unit 50a and the like may be supplied with drive power via another device (for example, the outdoor unit 10 and the like). Further, for example, the first intermediate unit 50a and the like do not necessarily need to be supplied with drive power from a commercial power supply, and may be supplied with drive power from another power supply (eg, a storage battery).

(7-4) Modification 4
In the above embodiment, the case where the first intermediate unit 50a and the second intermediate unit 50b are supplied with drive power from a common power supply (second commercial power supply 300) has been described. However, the first intermediate unit 50a and the second intermediate unit 50b may be supplied with driving power from different power sources. For example, the second intermediate unit 50 b may be supplied with drive power from a power source other than the second commercial power source 300 .

(7-5) Modification 5
The installation mode of the wiring 90 and each unit (indoor unit, intermediate unit 50, etc.) in the power supply system and communication system in the above-described embodiment can be appropriately changed according to the design specifications and installation environment.

For example, in the above embodiment, the first intermediate unit 50a and the indoor unit 40a were electrically connected via the second indoor wiring 94, but the first intermediate unit 50a is connected to another indoor unit 40 (for example, 40 b or 40 c ) may be electrically connected via the indoor second wiring 94 . That is, the indoor unit 40 to which the drive power is supplied via the first intermediate unit 50a can be appropriately selected.

Further, for example, the second intermediate unit 50b and any one of the indoor units 40 may be electrically connected via the second indoor wiring 94 . That is, the indoor unit 40 may be supplied with drive power via the second intermediate unit 50b.

Further, for example, in the above-described embodiment, the indoor unit 40a and the indoor unit 40b are electrically connected via the indoor-side third wiring 95, and the indoor unit 40b and the indoor unit 40c are electrically connected via the indoor-side third wiring 95. However, the indoor unit 40 a and the indoor unit 40 c may be electrically connected via the indoor-side third wiring 95 . That is, the combination of the indoor units 40 connected by the indoor-side third wiring 95 is not particularly limited.

Further, for example, in the above embodiment, the first intermediate unit 50a and the second intermediate unit 50b are arranged in parallel with respect to the second commercial power source 300 . However, the first intermediate unit 50 a and the second intermediate unit 50 b may be arranged in series with respect to the second commercial power supply 300 .

Further, for example, in the above embodiment, the first intermediate unit 50a and the second intermediate unit 50b are arranged independently. However, the first intermediate unit 50a and the second intermediate unit 50b may be configured integrally. In this case, the branch pipe unit 51, the shutoff valve 55 and the intermediate unit controller 58 in the first intermediate unit 50a and the branch pipe unit 51, the shutoff valve 55 and the intermediate unit controller 58 in the second intermediate unit 50b are They may be housed within a common casing.

(7-6) Modification 6
In the above-described embodiment, the case where the indoor wiring 92 is a three-core electric wiring covered with an insulator has been described. However, the indoor wiring 92 is not necessarily limited to this, and other wiring may be used.

(7-7) Modification 7
In the above-described embodiment, a case has been described in which the indoor wiring 92 for supplying drive power also serves as a "communication line" for transmitting signals. It is preferable to install the indoor wiring 92 in such a manner from the viewpoint of suppressing an increase in cost and improving workability. However, the indoor wiring 92 does not necessarily have to serve as a "communication line". That is, a communication line for transmitting control signals between the intermediate unit 50 and the indoor unit 40 or between the indoor units 40 may be installed separately from the indoor wiring 92 .

(7-8) Modification 8
In the above embodiment, the case where the shutoff valve 55 and the actuator (indoor expansion valve 41) in the indoor unit 40 are cooperatively controlled by the controller 70 in the refrigerant leakage mode has been described. The content, execution timing, and execution period of the cooperative control can be changed as appropriate as long as the shutoff valve 55 and the actuator in the indoor unit 40 are controlled in cooperation with each other. For example, the shut-off valve 55 and actuators within the indoor unit 40 may be cooperatively controlled in the normal operating mode. Further, for example, the cutoff valve 55 and the actuator in the indoor unit 40 may be cooperatively controlled based on the state (temperature and pressure) of the refrigerant in the refrigerant circuit RC. Also, the actuator in the indoor unit 40 that is cooperatively controlled with the shutoff valve 55 is not necessarily limited to the indoor expansion valve 41, and may be another device (for example, the indoor fan 45, etc.).

Also, the shutoff valve 55 and the actuator in the indoor unit 40 do not necessarily have to be controlled in a coordinated manner.

(7-9) Modification 9
In the above-described embodiment, the cutoff valve 55 (intermediate unit 50) is arranged in each of the liquid side branch portion BPa and the gas side branch portion BPb. In this respect, in order to reduce the amount of leaked refrigerant by more reliably shutting off the refrigerant flowing from the outdoor circuit RC1 to the indoor circuit RC2 in the event of refrigerant leakage, the liquid side branch portion BPa and the gas side branch portion BPb It is preferable that shut-off valves 55 are arranged on both sides. However, the shutoff valve 55 does not necessarily have to be arranged in both the liquid side branch portion BPa and the gas side branch portion BPb, and may be arranged in only one.

(7-10) Modification 10
In the above embodiment, the case where the cutoff valve 55 is an electrically operated valve whose degree of opening can be adjusted has been described. However, the shutoff valve 55 is not necessarily limited to an electrically operated valve, and may be another control valve. For example, the shutoff valve 55 may be an electromagnetic valve that can switch between open and closed states. In such a case, the arrangement of the shutoff valves 55 in the branch pipe unit 51 may be the same as in the above embodiment, or may be changed as appropriate.

(7-11) Modification 11
In the above embodiment, the case where the branch pipe unit 51 constitutes the liquid side branch portion BPa and the gas side branch portion BPb has been described. In this respect, in the air conditioning system 100, the branch pipe unit 51 may constitute other branch portions BP in place of/in addition to the liquid side branch portion BPa and the gas side branch portion BPb.

(7-12) Modification 12
In the above-described embodiment, the case where all (entirely) the liquid side branch portion BPa and the gas side branch portion BPb are configured by the branch pipe unit 51 has been described. In this respect, only part of the liquid side branch portion BPa and gas side branch portion BPb may be configured by the branch pipe unit 51 . That is, the liquid-side branching portion BPa and the gas-side branching portion BPb may be configured by the branch pipe unit 51 and other equipment (such as piping).

Also, the branching portion BP does not necessarily have to be composed of the branching pipe unit 51, and the branching pipe unit 51 can be omitted as appropriate. That is, the branch portion BP may be configured by connecting pipes and valves (the main pipe 52, the branch pipe 53, and the cutoff valve 55) that are independently carried to the construction site to each other at the construction site.

(7-13) Modification 13
In the embodiment described above, the case where the refrigerant flow path is branched into two at the branch portion BP has been described. However, the number of branches in the branch portion BP is not particularly limited, and can be changed as appropriate. For example, the coolant channel may be branched into three or more at the branch portion BP. In such a case, branch pipes 53 corresponding to the number of branches may be arranged at the branch portion BP. That is, the branch pipe unit 51 may have three or more branch pipes 53 .

(7-14) Modification 14
In the refrigerant circuit RC, the position (branch portion BP) where the cutoff valve 55 is arranged can be changed as appropriate. For example, the shut-off valve 55 may be arranged only in a portion that needs to be shut off in order to ensure safety, based on the amount of refrigerant leakage assumed when refrigerant leakage occurs. For example, regarding the position (branch portion BP) where the shutoff valve 55 is arranged, the total number, total capacity (total capacity ), the total capacity of the connecting pipes on the other end, or the capacity of the power source. Alternatively, the shutoff valve 55 may be arranged for each device containing a refrigerant charging amount corresponding to these.

For example, the shutoff valve 55 may be connected to any/all of the main pipes 52 of (a), (b) and (c) below.
(a): The main pipe 52 arranged between the plurality of indoor units 40 whose total capacity is equal to or less than the first threshold value ΔTh1 and the outdoor unit 10
(b): The main pipe 52 arranged between the plurality of indoor units 40 whose total number is equal to or less than the second threshold value ΔTh2 and the outdoor unit 10
(c): The main pipe 52 in which the total capacity of the communicating pipes on the other end side is equal to or less than the third threshold value ΔTh3

In this case, the first threshold value ΔTh1, the second threshold value ΔTh2, and/or the third threshold value ΔTh3 are set for any target space SP (for example, the narrowest target space SP) in which the indoor unit 40 is installed and air conditioning is performed. Based on the size, considering the possibility that the concentration of the leaked refrigerant in the target space SP when the refrigerant leak occurs becomes a dangerous value (lower combustion limit concentration or oxygen deficiency limit concentration), if set good.

For example, the first threshold ΔTh1, the second threshold ΔTh2, and/or the third threshold ΔTh3 are the refrigerant amount m (kg), the refrigerant lower limit concentration G (kg/m ³ ), the floor area A (m ² ), the leakage height hr (m) may be set so that the shut-off valve 55 is arranged within the range where the following condition 1 is satisfied. Here, the amount of refrigerant m is the amount of refrigerant that can be charged to the equipment that is shut off from the outdoor unit 10 by the shutoff valve 55 in order to ensure safety in the target space SP when the refrigerant leaks. Also, the leakage height hr is the height position of the portion where the leakage refrigerant is expected to flow out in the target space SP.
ｍ≦G/4・A・hr (Condition 1)

By determining the arrangement position of the shutoff valve 55 in such a manner, safety in the event of refrigerant leakage (for example, lower combustion limit concentration, acid It is possible to properly dispose the shutoff valve 55 in a portion where it is necessary to shut off the refrigerant in view of the essential concentration limit, etc.). Therefore, while suppressing an increase in the number of shutoff valves 55, security against refrigerant leakage is further promoted.

(7-15) Modification 15
In the above-described embodiment, the cutoff valve 55 is arranged at the branch portion BP. However, the shut-off valve 55 does not necessarily have to be arranged in the branch portion BP.

(7-16) Modification 16
In the above embodiment, the case where the main pipe 52 and each branch pipe 53 are joined in the branch pipe unit 51 has been described. In this regard, the main pipe 52 and any/all of the branch pipes 53 may be integrally molded.

(7-17) Modification 17
In the above embodiment, the branch pipe unit 51 and the shutoff valve 55 may be installed without being housed in a casing or the like. From the viewpoint of promoting compactness, it is preferable to install in such a manner.

(7-18) Modification 18
In the above-described embodiment, in the intermediate unit 50, the main pipe 52, the plurality of branch pipes 53, and the cutoff valve 55 are integrated. However, the intermediate unit 50 does not necessarily have to be configured in such a manner, and any element may be configured as a separate body and configured to be connected to other elements on site.

For example, the branch pipe 53 may be configured to be independently brought into the construction site and connected to other pipes.

Further, for example, the shutoff valve 55 does not necessarily have to be configured integrally with the branch pipe unit 51 . That is, the shut-off valve 55 may be configured to be independently brought into the construction site and connected to other pipes.

(7-19) Modification 19
The configuration mode of the refrigerant circuit RC in the above embodiment is not necessarily limited to the mode shown in FIG. 2, and can be changed as appropriate according to design specifications and installation environment. For example, the first outdoor electric valve 16 is not necessarily required and can be omitted as appropriate. Also, for example, the supercooler 15 and the second outdoor motor-operated valve 17 are not necessarily required, and may be omitted as appropriate. Further, for example, the channel switching valve 13 is not necessarily required, and may be omitted as appropriate (in this case, only the normal cycle operation is performed in the air conditioning system 100). Further, equipment not shown in FIG. 2 may be newly added to the refrigerant circuit RC.

(7-20) Modification 20
In the above embodiment, the idea according to the present disclosure is applied to the air conditioning system 100 in which a plurality of indoor units 40 are connected in parallel to one outdoor unit 10 by connecting pipes (Ga, La). explained. However, in the air conditioning system 100, the number of the outdoor units 10 and/or the indoor units 40 and their connection mode can be changed as appropriate according to the installation environment and design specifications. In particular, when there are a large number of indoor units 40, by sharing the drive power supply of the intermediate unit 50 and each indoor unit 40, the effect of risk reduction can be expected, and the work time and labor required for construction can be particularly reduced. be done.

(7-21) Modification 21
In the above embodiment, the controller that controls the operation of the air conditioning system 100 by connecting the outdoor unit controller 30, each indoor unit controller 48, and each intermediate unit controller 58 via wiring 90 (92, cb). 70 were constructed. However, the configuration mode of the controller 70 is not necessarily limited to this, and can be changed as appropriate according to the design specifications and installation environment. That is, the configuration of the controller 70 is not particularly limited, and some or all of the elements included in the controller 70 do not necessarily need to be arranged in either the outdoor unit 10 or the indoor unit 40, and other devices may be arranged in the , or may be arranged independently.

For example, the controller 70 may be configured by any or all of the outdoor unit control section 30, each indoor unit control section 48, and each intermediate unit control section 58 together with/instead of other devices such as a remote controller 65 and a centralized control device. may In such a case, the other device may be located at a remote location connected to the outdoor unit 10 or the indoor unit 40 via a communication network.

Further, for example, the controller 70 may be configured by only one of the outdoor unit control section 30 , each indoor unit control section 48 , or each intermediate unit control section 58 .

(7-22) Modification 22
In the above embodiment, R32 was used as the refrigerant circulating in the refrigerant circuit RC. However, the refrigerant used in the refrigerant circuit RC is not particularly limited, and other refrigerants may be used. For example, in the refrigerant circuit RC, an HFC-based refrigerant such as R407C or R410A, _CO2 , ammonia, or the like may be used.

(7-23) Modification 23
The idea according to the present disclosure has been applied to the air conditioning system 100 in the above embodiment. However, it is not limited to this, and the idea according to the present disclosure can also be applied to other refrigerating apparatuses (for example, water heaters, heat pump chillers, etc.) having a refrigerant circuit.

(7-24) Modification 24
In the above embodiment, the case where the "intermediate unit" is configured as the intermediate unit 50 having the branch pipe unit 51 and the cutoff valve 55 has been described. However, the "intermediate unit" may have other configurations as long as it is a unit arranged between the outdoor unit 10 and the indoor unit 40, and its arrangement position can be selected as appropriate.

(7-25) Modification 25
In the air conditioning system 100 according to the above embodiment, the indoor unit 40 is configured to be supplied with drive power via the intermediate unit 50 . However, the air conditioning system 100 does not necessarily have to be configured in such a manner, and may be configured like an air conditioning system 100' shown in FIG.

In the air-conditioning system 100 ′, a fourth indoor wiring 96 is arranged in place of the second indoor wiring 94 . The fourth indoor wiring 96 branches from the first indoor wiring 93 and is connected to one of the indoor units 40 (here, the indoor unit 40a) to supply drive power. That is, in the air conditioning system 100 ′, the indoor unit 40 is arranged in parallel with the intermediate unit 50 with respect to the second commercial power source 300 and is supplied with drive power without passing through the intermediate unit 50 . Other parts of the air conditioning system 100 ′ are substantially the same as the air conditioning system 100 . In addition, in the air conditioning system 100 ′, the indoor unit 40 other than the indoor unit 40 a may be connected to the indoor-side fourth wiring 96 .

In the air conditioning system 100′ as well, since the cutoff valve 55 and the indoor unit 40 are supplied with a common drive power supply, when the power supply to the cutoff valve 55 is cut off, the power supply to the indoor unit 40 is stopped. is also blocked. Therefore, the indoor unit 40 is prevented from continuing to operate when the cutoff valve 55 does not operate as expected due to the power shutdown. Therefore, the risk that the shutoff valve 55 does not operate as expected during operation of the indoor unit 40 is suppressed.

(7-26) Modification 26
Moreover, the air conditioning system 100 may be configured like an air conditioning system 100'' shown in FIG.

In the air conditioning system 100 ″, an indoor fifth wiring 97 is arranged instead of the indoor second wiring 94 . The indoor-side fifth wiring 97 extends between the second commercial power source 300 and one of the indoor units 40 (here, the indoor unit 40a) to electrically connect the two. That is, in the air conditioning system 100 ″, the indoor unit 40 is supplied with drive power without going through the intermediate unit 50 . In addition, in the air conditioning system 100 ″, the indoor units 40 other than the indoor unit 40 a may be connected to the indoor-side fifth wiring 97 .

Further, in the air conditioning system 100 ″, an indoor sixth wiring 98 is arranged in place of the indoor first wiring 93 . The indoor-side sixth wiring 98 extends between one of the indoor units 40 (here, the indoor unit 40a) and one of the intermediate units 50 (here, the first intermediate unit 50a), and electrically connects the two. there is In the air conditioning system 100 ″, the sixth indoor wiring 98 may extend between the intermediate unit 50 and the indoor unit 40 other than the indoor unit 40 a. Also, the indoor-side sixth wiring 98 may extend between the indoor unit 40 and an intermediate unit 50 other than the first intermediate unit 50a (here, the second intermediate unit 50b).

Further, in the air-conditioning system 100″, an indoor-side seventh wiring 99 is arranged. The seventh indoor wiring 99 extends between the intermediate units 50 and electrically connects the first intermediate unit 50a and the second intermediate unit 50b. The indoor-side seventh wiring 99 may extend between any of the indoor units 40 and the intermediate unit 50 (here, the second intermediate unit 50b). Further, the indoor-side seventh wiring 99 may branch from the indoor-side sixth wiring 98 and extend.

In the air conditioning system 100 ″, the intermediate unit 50 is supplied with driving power via the indoor unit 40 . Other parts of the air conditioning system 100 ″ are substantially the same as the air conditioning system 100 .

In the air conditioning system 100 ″ as well, since the cutoff valve 55 and the indoor unit 40 are supplied with a common drive power supply, when the power supply to the cutoff valve 55 is cut off, the power supply to the indoor unit 40 The supply is also cut off. Therefore, the indoor unit 40 is prevented from continuing to operate when the cutoff valve 55 does not operate as expected due to the power shutdown. Therefore, the risk that the shutoff valve 55 does not operate as expected during operation of the indoor unit 40 is suppressed.

(7-27) Modification 27
The configuration of the air conditioning system 100 in the above embodiment can be changed as appropriate according to design specifications and installation environment. For example, the air conditioning system 100 may be configured like an air conditioning system 100a shown in FIG. Hereinafter, regarding the air conditioning system 100a, mainly different parts from the air conditioning system 100 will be described. In the following description, common or similar ideas to those of the air conditioning systems 100, 100', 100'' can be applied to portions that are not particularly described.

FIG. 8 is a schematic diagram schematically showing the overall configuration of the air conditioning system 100a. The air conditioning system 100 a has an outdoor unit 10 ′ instead of the outdoor unit 10 . Further, the air conditioning system 100a has a plurality of indoor units 40' in place of the plurality of indoor units 40. As shown in FIG. In addition, the air conditioning system 100a has a plurality of intermediate units 50' instead of the plurality of intermediate units 50 (here, the same number as the indoor units 40'). Further, the air conditioning system 100a has a liquid-side communication pipe La' (corresponding to a "connection pipe") instead of the liquid-side communication pipe La. Further, the air conditioning system 100a has a gas side communication pipe Ga' (corresponding to a "connection pipe") instead of the gas side communication pipe Ga.

The air conditioning system 100a is a so-called cooling/heating free type in which cooling operation and heating operation can be individually selected for each indoor unit 40'. In this regard, the air conditioning system 100a comprises a plurality of intermediate units 50' for switching the refrigerant flow between the outdoor unit 10' and the corresponding indoor unit 40'.

Further, in the air conditioning system 100a, a communication circuit RC3' (corresponding to a "refrigerant channel") is configured between the outdoor unit 10' and each indoor unit 40'. In the air conditioning system 100a, a first liquid side communication pipe L1′ and a plurality of gas side communication pipes Ga′ (intake gas communication pipe G1a, high and low pressure gas communication pipe G1b) are provided between the outdoor unit 10′ and the intermediate unit 50′. extended. Further, in the air conditioning system 100a, each intermediate unit 50' and the corresponding indoor unit 40' are connected via a second liquid-side communication pipe L2' and a second gas-side communication pipe G2'.

<Outdoor unit 10'>
FIG. 9 is a refrigerant circuit diagram inside the outdoor unit 10'. The outdoor unit 10' has a plurality of refrigerant pipes (12th pipe P12-26th pipe P26) instead of the first pipe P1-11th pipe P11. In addition, the outdoor unit 10' has a plurality of flow path switching valves 13 (specifically, a first flow path switching valve 131, a second flow path switching valve 132 and a third flow path switching valve 133). . The outdoor unit 10' also has a plurality of gas side shutoff valves 20 (specifically, a first gas side shutoff valve 20a and a second gas side shutoff valve 20b). In the outdoor unit 10', the outdoor heat exchanger 14 is divided into a plurality of heat exchangers (specifically, the first outdoor heat exchanger 141 and the second outdoor heat exchanger 142). The outdoor unit 10 ′ also has a plurality of outdoor first electric valves 16 .

An outdoor circuit RC1' is configured in the outdoor unit 10'. In the outdoor unit 10 ′, the twelfth pipe P<b>12 connects one end of the gas side first shutoff valve 20 a and the inlet port of the accumulator 12 . The thirteenth pipe P13 connects the outlet port of the accumulator 12 and the suction port of the compressor 11 . One end of the fourteenth pipe P<b>14 is connected to the discharge port of the compressor 11 . The fourteenth pipe P14 is branched into three at the other end, and each branch destination is connected to the first port of the flow path switching valve 13 (131, 132, 133).

The fifteenth pipe P15 connects the second port of the second flow path switching valve 132 and the gas side inlet/outlet of the second outdoor heat exchanger 142 . The sixteenth pipe P<b>16 connects the liquid side inlet/outlet of the second outdoor heat exchanger 142 and one end of the first outdoor electric valve 16 . The seventeenth pipe P<b>17 connects the second port of the first flow path switching valve 131 and the gas side inlet and outlet of the first outdoor heat exchanger 141 . The eighteenth pipe P18 connects the liquid side inlet/outlet of the first outdoor heat exchanger 141 and one end of the first outdoor electric valve 16 on the other side.

One end of the nineteenth pipe P<b>19 branches into two, and is connected to the other ends of the first outdoor electric valves 16 . The nineteenth pipe P<b>19 has the other end connected to one end of the main flow path 151 of the supercooler 15 . The twentieth pipe P20 connects the other end of the main flow path 151 of the subcooler 15 and one end of the liquid side stop valve 19 .

The 21st pipe P21 connects a portion between both ends of the 19th pipe P19 and one end of the second outdoor electric valve 17 . The 22nd pipe P22 connects the other end of the second outdoor motor-operated valve 17 and one end of the sub-channel 152 of the supercooler 15 . The 23rd pipe P23 connects the other end of the sub-channel 152 of the supercooler 15 and the portion between both ends of the 24th pipe P24.

One end of the twenty-fourth pipe P24 is branched into two and connected to the third ports of the first flow path switching valve 131 and the second flow path switching valve 132, respectively. The 24th pipe P24 has the other end connected to a portion between both ends of the 12th pipe P12.

The 25th pipe P25 connects the second port of the third flow path switching valve 133 and the second gas side shutoff valve 20b. The 26th pipe P26 connects the 3rd port of the 3rd flow-path switching valve 133, and the part between both ends of the 12th pipe P12 with the other end.

Incidentally, these refrigerant pipes (P12-P26) may actually be constituted by a single pipe, or may be constituted by connecting a plurality of pipes via joints or the like.

In the outdoor unit 10', the fourth ports of the first flow switching valve 131, the second flow switching valve 132 and the third flow switching valve 133 are closed and function as three-way valves. The first flow path switching valve 131, the second flow path switching valve 132, and the third flow path switching valve 133 are in a first state in which the first port and the second port communicate and the third port and the fourth port communicate. (the state indicated by the solid line in FIG. 9) and the second state (the state indicated by the dashed line in FIG. 9) in which the first port and the fourth port are in communication and the second port and the third port are in communication. can take The states of the first flow path switching valve 131 , the second flow path switching valve 132 and the third flow path switching valve 133 are controlled by the controller 70 .

In the outdoor unit 10', the other end of the liquid side shut-off valve 19 is connected to one end of the liquid side first communication pipe L1'. The other end of the gas side first shutoff valve 20a is connected to one end of the intake gas communication pipe G1a. The other end of the second gas side shutoff valve 20b is connected to one end of the high and low pressure gas communication pipe G1b.

<Indoor unit 40'>
FIG. 10 is a refrigerant circuit diagram in the indoor unit 40' and the intermediate unit 50'. An indoor circuit RC2' is configured in the indoor unit 40'. The indoor unit 40' and the intermediate unit 50' are in one-to-one correspondence. The indoor unit 40' is connected to the corresponding intermediate unit 50' through a liquid side second communication pipe L2' and a gas side second communication pipe G2'.

<Intermediate unit 50'>
Each intermediate unit 50' is arranged between the corresponding indoor unit 40' (hereinafter referred to as "corresponding indoor unit") and the outdoor unit 10', and constitutes a part of the refrigerant circuit RC'. . The intermediate unit 50' switches the flow of refrigerant flowing into the corresponding indoor unit and the outdoor unit 10'. As shown in FIG. 10, the intermediate unit 50' has a plurality of switching valves 56 (corresponding to "control valves") and a plurality of refrigerant pipes (27th pipe P27 to 32nd pipe P32). .

The switching valve 56 switches opening and closing of the refrigerant flow path formed between the corresponding indoor unit and the outdoor unit 10' depending on the situation. The switching valve 56 is, for example, an electrically operated valve whose degree of opening can be adjusted, and switches the flow of the refrigerant by passing or blocking the refrigerant according to the degree of opening. In the intermediate unit 50', as the switching valves 56, a first switching valve 56a, a second switching valve 56b, and a third switching valve 56c are arranged. The operation (opening degree) of each switching valve 56 is controlled by an intermediate unit control section 58 (controller 70).

The twenty-seventh pipe P27 has one end connected to the liquid-side first communication pipe L1′ and the other end connected to one end of the third switching valve 56c. One end of the twenty-eighth pipe P28 is connected to the other end of the third switching valve 56c, and the other end is connected to the liquid-side second communication pipe L2'. The twenty-ninth pipe P29 has one end connected to the gas side second communication pipe G2' and the other end connected to one end of the first switching valve 56a. The thirtieth pipe P30 has one end connected to the other end of the first switching valve 56a and the other end connected to the intake gas communication pipe G1a. The 31st pipe P31 has one end connected to a portion between both ends of the 29th pipe P29, and the other end connected to one end of the second switching valve 56b. The 32nd pipe P32 has one end connected to the other end of the second switching valve 56b and the other end connected to the high/low pressure gas communication pipe G1b. Incidentally, these refrigerant pipes (P27-P32) may actually be constituted by a single pipe, or may be constituted by connecting a plurality of pipes via joints or the like.

<Liquid side connecting pipe La', gas side connecting pipe Ga'>
In the air-conditioning system 100a, one end of the liquid-side first communication pipe L1' is connected to the liquid-side shutoff valve 19, and the other end is branched into a plurality of branches and individually connected to the 27th pipe P27 of each intermediate unit 50'. ing. One end of the intake gas communication pipe G1a is connected to the gas side first shutoff valve 20a, and the other end is branched into a plurality of branches and individually connected to the 30th pipes P30 of the intermediate units 50'. One end of the high and low pressure gas communication pipe G1b is connected to the gas side second closing valve 20b, and the other end is branched into a plurality of branches and individually connected to the 32nd pipe P32 of each intermediate unit 50'.

<Refrigerant flow during operation of the air conditioning system 100a>
The refrigerant flow during operation of the air conditioning system 100a will be described for each situation. In the following description, the indoor unit 40' in the operating state is referred to as the "operating indoor unit", and the indoor unit 40' in the stopped state is referred to as the "stopped indoor unit". The indoor expansion valve 41 of the stopped indoor unit is controlled to the closed state, and the first switching valve 56a, the second switching valve 56b and the third switching valve 56c in the intermediate unit 50' corresponding to the stopped indoor unit are controlled to the closed state. shall be Various controls of the controller 70 are arranged so that the following operation is realized.

<When each indoor unit performs cooling>
In the intermediate unit 50' corresponding to the operating indoor unit, the first switching valve 56a and the second switching valve 56b are controlled to the maximum degree of opening, and the third switching valve 56c controls the subcooling degree of the refrigerant flowing into the corresponding operating indoor unit. The degree of opening is appropriately adjusted according to, for example. Further, the opening degree of the indoor expansion valve 41 of the operating indoor unit is appropriately adjusted. The first flow path switching valve 131 and the second flow path switching valve 132 are controlled to the first state, and the third flow path switching valve 133 is controlled to the second state.

When the compressor 11 is driven in such a state, the refrigerant is sucked into the compressor 11 through the suction pipe (the thirteenth pipe P13) and compressed. The compressed high-pressure gas refrigerant passes through the first flow path switching valve 131 and the second flow path switching valve 132, etc., flows into each of the outdoor heat exchangers 14 (141, 142), and is condensed. The refrigerant that has passed through the outdoor heat exchanger 14 passes through the main flow path 151 and the like of the subcooler 15 and flows into the first liquid-side communication pipe L1'. The refrigerant that has passed through the liquid-side first communication pipe L1' flows into the 27th pipe P27 of the intermediate unit 50' corresponding to the indoor unit.

The refrigerant that has flowed into the twenty-seventh pipe P27 flows into the third switching valve 56c and is decompressed according to the degree of opening of the third switching valve 56c. The refrigerant that has passed through the third switching valve 56c flows into the indoor unit via the liquid-side second communication pipe L2'.

The refrigerant that has flowed into the operating indoor unit is appropriately decompressed in accordance with the degree of opening of the indoor expansion valve 41 . The refrigerant that has passed through the indoor expansion valve 41 flows into the indoor heat exchanger 42 and evaporates. The refrigerant that has passed through the indoor heat exchanger 42 flows into the 29th pipe P29 of the corresponding intermediate unit 50 via the gas side second communication pipe G2'.

The refrigerant that has flowed into the 29th pipe P29 passes through the first switching valve 56a or the second switching valve 56b, etc., and flows into the intake gas communication pipe G1a or the high/low pressure gas communication pipe G1b. After passing through the intake gas communication pipe G1a and the high/low pressure gas communication pipe G1b, the refrigerant flows into the outdoor unit 10' and is sucked into the compressor 11 again.

<When each indoor unit performs heating>
In the intermediate unit 50' corresponding to the indoor unit, the second switching valve 56b and the third switching valve 56c are controlled to be open, and the first switching valve 56a is controlled to be closed. Further, the opening degree of the indoor expansion valve 41 of the operating indoor unit is appropriately adjusted. The first flow path switching valve 131 and the second flow path switching valve 132 are controlled to the second state, and the third flow path switching valve 133 is controlled to the first state.

When the compressor 11 is driven in such a state, the refrigerant is sucked into the compressor 11 through the suction pipe (the thirteenth pipe P13) and compressed. The compressed high-pressure gas refrigerant flows through the third flow switching valve 133 and the like into the high-low pressure gas communication pipe G1b. The refrigerant that has passed through the high and low pressure gas communication pipe G1b flows into the 32nd pipe P32 of the intermediate unit 50' corresponding to the indoor unit. The refrigerant that has flowed into the 32nd pipe P32 passes through the second switching valve 56b and the like, and flows into the gas side second communication pipe G2'. The refrigerant that has passed through the second gas-side communication pipe G2' flows into the indoor unit.

The refrigerant that has flowed into the operating indoor unit flows into the indoor heat exchanger 42 and is condensed. The refrigerant that has passed through the indoor heat exchanger 42 is appropriately decompressed according to the degree of opening of the indoor expansion valve 41 . The refrigerant that has passed through the indoor expansion valve 41 flows through the liquid-side second communication pipe L2' into the 28th pipe P28 of the intermediate unit 50' corresponding to the indoor operating unit. The refrigerant that has passed through the twenty-eighth pipe P28 passes through the third switching valve 56c and the like, and flows into the outdoor unit 10' through the liquid-side first communication pipe L1'.

The refrigerant that has flowed into the outdoor unit 10' passes through each of the first outdoor motor-operated valves 16, and is decompressed according to the degree of opening. The depressurized refrigerant flows into each outdoor heat exchanger 14 and evaporates. The refrigerant that has passed through the outdoor heat exchanger 14 is sucked into the compressor 11 again through the first flow path switching valve 131, the second flow path switching valve 132, or the like.

<When one of the operating indoor units performs cooling operation and the other performs heating operation>
In the intermediate unit 50' (hereinafter referred to as "cooling intermediate unit") corresponding to the operating indoor unit (hereinafter referred to as "cooling indoor unit") that is performing cooling operation among the intermediate units 50', the first switching The valve 56a and the third switching valve 56c are fully opened, and the second switching valve 56b is closed. Further, the opening degree of the indoor expansion valve 41 of the cooling indoor unit is appropriately adjusted. Further, in the intermediate unit 50' (hereinafter referred to as "heating intermediate unit") corresponding to the operating indoor unit (hereinafter referred to as "heating indoor unit") that performs heating operation among the intermediate units 50', The second switching valve 56b and the third switching valve 56c are opened, and the first switching valve 56a is closed. Further, the opening degree of the indoor expansion valve 41 of the heating indoor unit is appropriately adjusted. In addition, the degree of opening of the first outdoor electric valve 16 is appropriately adjusted.

When the compressor 11 is driven in such a state, the refrigerant is sucked into the compressor 11 through the suction pipe (the thirteenth pipe P13) and compressed. The compressed high-pressure gas refrigerant flows through the third flow switching valve 133 and the like into the high-low pressure gas communication pipe G1b. The refrigerant that has passed through the high and low pressure gas communication pipe G1b flows into the 32nd pipe P32 of the heating intermediate unit. The refrigerant that has flowed into the 32nd pipe P32 passes through the second switching valve 56b and the like, and flows into the gas side second communication pipe G2'. The refrigerant that has passed through the second gas-side communication pipe G2' flows into the heating indoor unit.

The refrigerant that has flowed into the heating indoor unit flows into the indoor heat exchanger 42 and is condensed. The refrigerant that has passed through the indoor heat exchanger 42 is appropriately decompressed according to the degree of opening of the indoor expansion valve 41 . The refrigerant that has passed through the indoor expansion valve 41 flows through the liquid-side second communication pipe L2' into the corresponding 28th pipe P28 of the heating intermediate unit. After passing through the twenty-eighth pipe P28, the refrigerant passes through the third switching valve 56c and the like, and flows through the liquid-side first communication pipe L1' into the twenty-seventh pipe P27 of the cooling intermediate unit.

The refrigerant that has flowed into the 27th pipe P27 of the cooling intermediate unit passes through the third switching valve 56c and the like, and flows into the cooling indoor unit via the liquid-side second communication pipe L2'.

The refrigerant that has flowed into the cooling indoor unit is appropriately decompressed according to the opening degree of the indoor expansion valve 41 . The refrigerant that has passed through the indoor expansion valve 41 flows into the indoor heat exchanger 42 and evaporates. The refrigerant that has passed through the indoor heat exchanger 42 flows through the second gas-side communication pipe G2' into the 29th pipe P29 of the corresponding cooling intermediate unit.

The refrigerant that has flowed into the 29th pipe P29 passes through the first switching valve 56a and the like, and flows into the intake gas communication pipe G1a. The refrigerant that has passed through the intake gas communication pipe G1a flows into the outdoor unit 10' and is sucked into the compressor 11 again.

<Installation Mode of Indoor Unit 40' and Intermediate Unit 50'>
FIG. 11 is a schematic diagram schematically showing how the indoor unit 40' and the intermediate unit 50' are installed in the target space SP. In FIG. 11, in the ceiling space SPa, the intermediate unit 50' is connected to the liquid side first communication pipe L1' extending from the outdoor unit 10', the intake gas communication pipe G1a, and the high/low pressure gas communication pipe G1b. Further, the intermediate unit 50' is electrically connected to a transmission cable cb extending from the outdoor unit 10' (outdoor unit control section 30). Also, the intermediate unit 50 ′ is electrically connected to the indoor-side first wiring 93 extending from the second commercial power source 300 .

Further, the intermediate unit 50' and the indoor unit 40' are connected by a second liquid-side communication pipe L2' and a second gas-side communication pipe G2'. Further, the second indoor wiring 94 extends between the intermediate unit 50' and the indoor unit 40', and the intermediate unit 50' and the indoor unit 40' are electrically connected.

<Characteristics of Air Conditioning System 100a>
In the air conditioning system 100a, as in the air conditioning system 100, the indoor wiring 92 is connected to the second commercial power supply 300 (power supply), and the intermediate unit 50' and each indoor unit 40' are commonly driven via the indoor wiring 92. Power is supplied, and the indoor unit 40' is supplied with driving power via the intermediate unit 50'.

This reduces risk. That is, since the switching valves 56 (56a, 56b, 56c) and the indoor unit 40' are supplied with a common driving power supply, when the power supply to each switching valve 56 is interrupted, the indoor unit 40 The power supply to ' is also cut off. Therefore, the indoor unit 40' is prevented from continuing to operate in a state where the switching valves 56 do not operate as expected due to the power shutdown. Therefore, the risk that each switching valve 56 does not operate as expected during operation of the indoor unit 40' is suppressed.

Conventionally, each indoor unit and intermediate unit are supplied with drive power from separate power sources, and at the construction site, electrical wiring for supplying drive power from the power source is connected to the power supply, each indoor unit, and the intermediate unit. It is normal to place each separately between In this regard, in the air conditioning system 100a, the intermediate unit 50' and each indoor unit 40' are supplied with common drive power through the indoor wiring 92, and the indoor unit 40' is supplied with the drive power through the intermediate unit 50'. supplied. As a result, at the construction site, it is possible to share electrical wiring for supplying drive power from the power supply to each indoor unit 40' and the intermediate unit 50' (that is, the electrical wiring is used as the power supply). (There is no need to dispose them individually between each indoor unit 40' and the intermediate unit 50').

In the air conditioning system 100a, the indoor wiring 92 includes a first indoor wiring 93 (first electrical wiring) and a second indoor wiring 94 (second electrical wiring). The indoor-side first wiring 93 electrically connects the power supply and the intermediate unit 50'. The indoor-side second wiring 94 electrically connects the intermediate unit 50' and the indoor unit 40'. This makes it possible to easily supply a common drive power source to each switching valve 56 and the indoor unit 40'.

In the air conditioning system 100a, the indoor wiring 92 also serves as a "communication line" for transmitting signals between the indoor unit 40' and the intermediate unit 50', or between the indoor units 40'. Thereby, it is not necessary to arrange a "communication line" separately from the indoor wiring 92 between the indoor unit 40' and the intermediate unit 50' or between the indoor units 40'. In relation to this, the increase in cost is suppressed, and construction is simplified and workability is improved.

Further, in the air conditioning system 100a, each switching valve 56 of the intermediate unit 50' and the indoor expansion valve 41 in the corresponding indoor unit are controlled in cooperation. In other words, the controller 70 cooperatively controls each switching valve 56 and the indoor expansion valve 41 (actuator) in the indoor unit 40' during operation. That is, in the air conditioning system 100a, the indoor expansion valve 41 and the switching valves 56 that are cooperatively controlled share a common drive power supply, and associated risks are suppressed.

In the air conditioning system 100a, when refrigerant leakage occurs in any of the indoor units 40', the indoor expansion valve 41 and each switching valve 56 are controlled to be closed, thereby suppressing refrigerant leakage in the target space SP. is possible.

In addition, in the air conditioning system 100a, a plurality of intermediate units 50' are individually arranged. However, the present invention is not limited to this, and a plurality of intermediate units 50' (for example, 4, 8, or 16 units) may be collected and arranged as a collective unit accommodated in one casing.

Further, in the air conditioning system 100a, the indoor unit 40' is associated with the intermediate unit 50' one-to-one. However, the indoor unit 40' may correspond to the intermediate unit 50' in many-to-one correspondence. That is, a plurality of indoor units 40' may be arranged in series or in parallel with respect to one intermediate unit 50'. In such a case, by arranging an indoor third wiring 95 (third electrical wiring) as the indoor wiring 92 electrically connecting the indoor units 40', each switching valve 56 and each indoor unit 40' It is possible to easily supply a common driving power supply.

Also, any/all of the switching valves 56 in the intermediate unit 50' may be solenoid valves instead of electric valves.

(8)
Although the embodiments have been described above, it will be appreciated that various changes in form and detail may be made without departing from the spirit and scope of the claims.

INDUSTRIAL APPLICABILITY The present disclosure is applicable to refrigerators.

10, 10': outdoor unit 11: compressor 12: accumulator 13: flow path switching valve 14: outdoor heat exchanger 15: supercooler 16: first outdoor motor-operated valve 17: second outdoor motor-operated valve 19: liquid side closed Valve 20: Gas side shut-off valve 20a: Gas side first shut-off valve 20b: Gas side second shut-off valve 25: Outdoor fan 30: Outdoor unit control section 40, 40': Indoor unit 41: Indoor expansion valve (actuator)
42: Indoor heat exchanger 45: Indoor fan 48: Indoor unit controller 50, 50': Intermediate unit 50a: First intermediate unit 50b: Second intermediate unit 51: Branch pipe unit 52: Main pipe 53: Branch pipe 55: Cutoff valve (control valve)
56: Switching valve (control valve)
56a: first switching valve (control valve)
56b: Second switching valve (control valve)
56c: third switching valve (control valve)
58: Intermediate unit control section 60: Refrigerant leak sensor 65: Remote controller 70: Controller (control section)
90: Wiring 91: Outdoor wiring 92: Indoor wiring (electrical wiring)
93: Indoor-side first wiring (first electrical wiring)
94: Second indoor wiring (second electrical wiring)
95: Indoor third wiring (third electrical wiring)
96: Indoor-side fourth wiring 100, 100', 100'', 100a: Air conditioning system (refrigerating device)
131: first flow switching valve 132: second flow switching valve 133: third flow switching valve 141: first outdoor heat exchanger 142: second outdoor heat exchanger 200: first commercial power supply 300: second Commercial power supply (power supply)
BP: Branching portion BPa: Liquid side branching portion BPb: Gas side branching portion G1: Gas side first communication pipe G1a: Suction gas communication pipe G1b: High and low pressure gas communication pipes G2, G2': Gas side second communication pipe Ga, Ga': gas side connecting pipe (connecting pipe)
L1, L1': liquid side first connecting pipes L2, L2': liquid side second connecting pipes La, La': liquid side connecting pipes (connecting pipes)
P1-P32: 1st pipe - 32nd pipe RC, RC': Refrigerant circuits RC1, RC1': Outdoor circuits RC2, RC2': Indoor circuits RC3, RC3': Connection circuits (refrigerant flow paths)
RC3a: Liquid-side communication circuit RC3b: Gas-side communication circuit SP: Target space SPa: Ceiling space cb: Transmission cable

JP-A-5-118720

Claims (7)

A refrigeration system (100 ) that performs a refrigeration cycle in a refrigerant circuit (RC ) ,
an outdoor unit (10);
a plurality of indoor units (40 ) ;
connecting pipes (La , Ga ) connecting the outdoor unit and the indoor unit and forming a refrigerant flow path (RC3 ) ;
an intermediate unit (50 ) including control valves (55, 56) arranged on the refrigerant flow path and shutting off the flow of the refrigerant by being in a fully closed state;
a refrigerant leakage sensor (60) for detecting refrigerant leakage in the indoor unit;
a control unit (70) for controlling the control valve to be closed when the refrigerant leakage sensor detects refrigerant leakage;
electrical wiring (92) connected to a power source (300);
with
The intermediate unit and each indoor unit are connected to the power supply via the electric wiring, and are supplied with a common driving power supply,
When power supply from the power supply to the control valve is cut off due to an abnormality in the power supply or deterioration of the electrical wiring , power supply from the power supply to each of the indoor units is cut off.
Refrigeration equipment (100, 100', 100' ') . The electrical wiring is
a first electrical wiring (93) electrically connecting the power source and the intermediate unit;
a second electrical wiring (94) electrically connecting the intermediate unit and the indoor unit;
including,
A refrigeration system (100 ) according to claim 1. the electrical wiring includes a third electrical wiring (95) extending between the indoor units;
The third electrical wiring electrically connects one of the indoor units and another of the indoor units,
A refrigeration system (100 ) according to claim 2. The electric wiring also serves as a communication line for transmitting signals between the indoor unit and the intermediate unit, or between the indoor units.
A refrigeration system (100, 100', 100' ') according to any one of claims 1 to 3. The control unit cooperatively controls the control valve and an actuator (41) in the indoor unit.
A refrigeration system (100, 100', 100' ') according to any one of claims 1 to 4. the connecting pipe includes a plurality of branching portions (BP);
The control valve (55) is arranged at the branch portion,
A refrigeration device (100, 100', 100'') according to any one of claims 1 to 5. The intermediate unit (50) further includes a branch pipe unit (51) pre-assembled and connected to other pipes (La, Ga) at the construction site,
The branch pipe unit constitutes part or all of the branch portion, and is configured integrally with the control valve,
A refrigeration device (100, 100', 100'') according to claim 6.

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