JP2020153567A - Refrigerant cycle system - Google Patents

Abstract

To solve the problem that in a refrigerant cycle device comprising a switching unit for switching the flow of refrigerant to be supplied to a utilization unit, when supply from a main power source to the switching unit is cut off, it is impossible to operate the switching unit.SOLUTION: A refrigeration cycle device 1 comprises a heat source unit 10, a plurality of first utilization units 20, a first switching unit 40, and a first power supply unit 51. The first utilization unit 20 performs heating and cooling with a refrigerant supplied from the heat source unit 10. The first switching unit 40 is connected to the heat source unit 10, and switches the flow of the refrigerant supplied to at least one first utilization unit of the plurality of first utilization units 20. The first power supply unit 51 supplies auxiliary power to the first switching unit when supply from a main power source to the first switching unit is cut off.SELECTED DRAWING: Figure 4

Description

The present invention relates to a refrigeration cycle device including a heat source unit, a utilization unit, and a switching unit for switching the flow of the refrigerant supplied to the utilization unit.

Conventionally, there is a refrigeration cycle device including a plurality of utilization units and a power supply unit for one heat source unit. As shown in Non-Patent Document 1 (“Mitsubishi Electric Building Air Conditioning Multi Air Conditioning System Design / Construction Manual” Mitsubishi Electric Corporation, created in July 2013, p146, see figure), the heat source unit, utilization unit, and power supply unit are It is connected via a communication line.

The power supply unit of Non-Patent Document 1 opens and closes a valve to a utilization unit whose main power supply is cut off when another utilization unit or a heat source unit is operating even when the main power supply of one utilization unit is cut off. A power supply unit was prepared to perform such operations. However, in Non-Patent Document 1, the switching unit that switches the flow of the refrigerant supplied to the utilization unit cannot be supplied with power when the main power supply is cut off.

Even if the main power supply to the switching unit is cut off, it may happen that some components of the switching unit are desired to be driven. If only the main power supply supplies power to the switching unit, the switching unit cannot be driven when the main power supply is cut off.

The refrigeration cycle device of the first aspect includes a heat source unit, a plurality of first utilization units, a first switching unit, and a first power supply unit. The first utilization unit performs heating and cooling with the refrigerant supplied from the heat source unit. The first switching unit is connected to the heat source unit and switches the flow of the refrigerant supplied to at least one first utilization unit of the plurality of first utilization units. The first power supply unit supplies auxiliary power to the first switching unit when the supply of the main power to the first switching unit is cut off.

Since the refrigeration cycle device of the first aspect supplies the auxiliary power to the first switching unit when the supply of the main power to the first switching unit is cut off, the first is even if the supply of the main power is cut off. The switching unit can be operated.

The refrigeration cycle device of the second aspect is the device of the first aspect, and further includes a second power supply unit. The second power supply unit supplies the auxiliary power supply to the first utilization unit when the supply of the main power supply to the first utilization unit is cut off.

Since the refrigeration cycle device of the second aspect includes the second power supply unit, the first utilization unit can be operated even if the supply of the main power supply to the first utilization unit is cut off.

The refrigeration cycle device of the third aspect is the device of the second aspect, and the first power supply unit and the second power supply unit are independent.

The refrigeration cycle device of the fourth aspect is the device of the second aspect, and the first power supply unit and the second power supply unit are also used.

In the refrigeration cycle device of the fourth aspect, since the first power supply unit and the second power supply unit are shared, the number of power supply units can be reduced.

The refrigeration cycle device of the fifth aspect is the device of the first aspect or the second aspect, and further includes the second utilization unit, the second switching unit, and the third power supply unit. The second utilization unit is a plurality of utilization units that perform heating and cooling with the refrigerant supplied from the heat source unit, and is a unit different from the first utilization unit. The second switching unit is connected in parallel with the first switching unit, and switches the flow of the refrigerant supplied to at least one second utilization unit of the plurality of second utilization units. The third power supply unit supplies the auxiliary power supply to the second switching unit when the supply of the main power supply to the second switching unit is cut off.

The refrigeration cycle device of the fifth aspect supplies the auxiliary power supply to the second switching unit when the supply of the main power supply to the second switching unit is cut off, so that even if the supply of the main power supply is cut off, the second The switching unit can be operated.

The refrigeration cycle device of the sixth aspect is any of the devices of the first aspect to the fifth aspect, and the heat source unit, the first power supply unit, and the first switching unit are connected by a communication line. Auxiliary power is supplied from the first power supply unit to the first switching unit by a communication line.

In the refrigeration cycle device of the sixth aspect, since the auxiliary power supply is supplied by the communication line, it is not necessary to newly provide the wiring equipment for the auxiliary power supply.

The refrigeration cycle device of the seventh aspect is any of the devices of the first aspect to the fourth aspect, and the heat source unit, the first power supply unit, the first switching unit, the second power supply unit, and the first utilization unit communicate with each other. It is connected by a wire. The supply of the auxiliary power supply from the first power supply unit to the first switching unit and the supply of the auxiliary power supply from the second power supply unit to the first utilization unit are performed by the communication line.

In the refrigeration cycle device of the seventh aspect, auxiliary power is supplied from the first power supply unit to the first switching unit and from the second power supply unit to the first utilization unit by a communication line. Therefore, it is not necessary to newly provide wiring equipment for supplying auxiliary power.

The refrigeration cycle device of the eighth aspect is any of the devices of the first aspect to the seventh aspect, and the first switching unit has a flow rate adjusting valve.

In the refrigeration cycle device of the eighth aspect, since the first switching unit has a flow rate adjusting valve, the flow of the refrigerant can be controlled.

The refrigeration cycle device of the ninth aspect is the device of the eighth aspect, and further includes a control unit. The control unit controls the operation of the refrigeration cycle device. The flow rate regulating valve is an electronic expansion valve. The control unit supplies auxiliary power to the electronic expansion valve from the first power supply unit when the supply of the main power to the first switching unit is cut off during the oil return operation, and controls the opening degree of the electronic expansion valve. .. Here, controlling the opening degree of the electronic expansion valve includes opening and closing the electronic expansion valve.

In the refrigeration cycle device of the ninth aspect, when the supply of the main power supply to the first switching unit is cut off, the auxiliary power supply is supplied from the first power supply unit to the electronic expansion valve to control the opening degree of the electronic expansion valve. Therefore, the oil return operation can be smoothly performed.

The refrigeration cycle device of the tenth aspect is the device of the eighth aspect, and further includes a control unit. The control unit controls the operation of the refrigeration cycle device. The flow rate regulating valve is an electronic expansion valve. During the defrost operation, when the supply of the main power supply to the first switching unit is cut off, the control unit supplies the auxiliary power supply from the first power supply unit to the electronic expansion valve to control the opening degree of the electronic expansion valve. Here, controlling the opening degree of the electronic expansion valve includes opening and closing the electronic expansion valve.

In the refrigeration cycle device of the tenth aspect, when the supply of the main power supply to the first switching unit is cut off, the auxiliary power supply is supplied from the first power supply unit to the electronic expansion valve to control the opening degree of the electronic expansion valve. Therefore, the defrost operation can be smoothly performed.

The refrigeration cycle device of the eleventh aspect is the device of the ninth aspect or the tenth aspect, and the control unit is arranged in the heat source unit and the first power supply unit.

In the refrigeration cycle device of the eleventh aspect, since the control unit is also arranged in the first power supply unit, the first switching unit can be controlled from the first power supply unit.

It is a figure which shows the electrical wiring of the refrigerating cycle apparatus 1 of 1st Embodiment. It is a figure which shows the electric wiring of the conventional refrigeration cycle apparatus 1x. It is a figure which shows the electric wiring of the refrigerating cycle apparatus 1a of the modification 1A. It is a figure which shows the electrical wiring of the refrigerating cycle apparatus 1d of the modification 1B. It is a figure which shows the electric wiring of the refrigerating cycle apparatus 1b of 2nd Embodiment. It is a figure which shows the electric wiring of the refrigerating cycle apparatus 1c of the modification 2A. It is a figure which shows the electric wiring of the refrigerating cycle apparatus 1e of the modification 2B. It is a figure which shows the refrigerant circuit of a switching unit 40. It is a figure which shows the refrigerant circuit of the refrigerating cycle apparatus 1b of 2nd Embodiment.

<First Embodiment>
(1) Overall Configuration of Refrigeration Cycle Device 1 The refrigeration cycle device 1 of the present embodiment is an air conditioner. The refrigerant is circulated between the heat source unit and the utilization unit to perform air conditioning such as cooling and heating. The refrigerating cycle device 1 may be an air conditioner, a hot water supply device, a cold / hot water generator, a refrigerating device, a refrigerating device, or a combination device thereof.

As shown in FIG. 1, the refrigeration cycle device 1 of the first embodiment includes a heat source unit 10, a first power supply unit 51, a first switching unit 40, a second power supply unit 52, and a plurality of first utilization units 20a to 20h. It includes a control unit 15 and a communication line 8. In the refrigeration cycle device 1 of the present embodiment, the utilization units 20a to 20h are connected to one heat source unit 10. The number of utilization units 20a to 20h is, for example, 1 or more and 8 or less. In this embodiment, there are eight units. In the present embodiment, the heat source unit 10, the first power supply unit 51, the switching unit 40, the second power supply unit 52, and the plurality of utilization units 20a to 20h are via the breakers 71, 751, 74, 752, 72a to 72h. It is connected to each main power supply 61, 651, 64, 652, 62a to 62h. The main power supply is usually ultimately connected to the grid power supply.

The heat source unit 10, the switching unit 40, and the utilization units 20a to 20h are connected to a common refrigerant circuit.

The heat source unit 10 includes a compressor, a heat source side heat exchanger, and the like. The refrigerant compressed by the compressor is supplied to the first utilization units 20a to 20h.

The utilization units 20a to 20h harmonize the air in the room. A plurality of utilization units may be arranged in one room, or one utilization unit may be arranged in one room.

The first switching unit 40 switches the flow of the refrigerant to switch the air conditioning operation of the first utilization unit to a cooling operation or a heating operation. In the present embodiment, eight first utilization units 20a to 20h are connected to one first switching unit 40. The first switching unit 40 collectively switches the eight first utilization units 20a to 20h from cooling to heating or from heating to cooling.

As shown in FIG. 6, the switching unit 40 has a refrigerant flow path inside. The switching unit 40 has a liquid pipe P41, gas pipes P42, P43, P44, and a flow rate adjusting valve 41, 42. The flow rate adjusting valves 41 and 42 may be electronic expansion valves capable of adjusting the opening degree and opening / closing. The flow rate adjusting valves 41 and 42 may be solenoid valves whose opening degree cannot be adjusted and which can only be opened and closed. The liquid pipe P41 is connected to the heat source side liquid pipe P11 and the user side liquid pipe P31 at the connection port. One of the gas pipes P44 is connected to the user side gas pipe P32 at the connection port. The other end of the gas pipe P44 is branched and connected to the flow rate adjusting valve 41 and the flow rate adjusting valve 42. One of the gas pipes P42 is connected to the flow rate adjusting valve 41. The other side of the gas pipe P42 is connected to the heat source side gas pipe P12 at the connection port. One of the gas pipes P43 is connected to the flow rate adjusting valve 42. The other side of the gas pipe P43 is connected to the heat source side gas pipe P13 at the connection port.

In the present embodiment, the control unit 15 is arranged incidentally to the heat source unit 10. Although not shown, the control unit is also arranged in the first power supply unit 51 and the second power supply unit 52. Each control unit has a processor and a memory. Each control unit controls a unit on the downstream side of the accompanying unit. The control unit 15 and the control units of the power supply units 51 and 52 control the heat source unit 10, the switching unit 40, and the utilization units 20a to 20h. The heat source unit 10, the switching unit 40, and the utilization units 20a to 20h are connected by a communication line 8. The control command of the control unit 15 is transmitted to the switching unit 40 and the utilization units 20a to 20h by the communication line 8. On the contrary, the device information of the switching unit 40 and the utilization units 20a to 20h and the information detected by the sensor are transmitted to the control unit 15 via the communication line 8.

(2) Power Supply Configuration of Refrigeration Cycle Devices 1 and 1x (2-1) Power Supply Configuration of Refrigeration Cycle Device 1x of Comparative Example 1 The electrical wiring of the refrigeration cycle device 1x of Comparative Example 1 is shown in FIG. The refrigeration cycle device 1 of FIG. 2 includes a heat source unit 10, a switching unit 40, and utilization units 20a to 20h. Unlike the first embodiment, the refrigeration cycle device 1x does not include a power supply unit. Other configurations are the same as those in the first embodiment.

Also in the refrigerating cycle apparatus 1x of Comparative Example 1, the heat source unit 10, the switching unit 40, and the plurality of utilization units 20a to 20h are connected to the main power sources 61, 64, 62a through the breakers 71, 74, 72a to 72h. It is connected to 62h. The main power supply or disconnection to the heat source unit 10, the switching unit 40, and the plurality of utilization units 20a to 20h is performed by connecting or disconnecting the breakers.

Further, the heat source unit 10, the switching unit 40, and the plurality of utilization units 20a to 20h are connected in parallel by the communication line 8.

In the refrigeration cycle device 1x of Comparative Example 1, when the breaker 74 of the switching unit 40 is cut off and the supply of the main power supply 64 is stopped, the switching unit 40 cannot operate the flow rate adjusting valves 41, 42 and the like.

Further, in Comparative Example 1A, when one utilization unit, for example, the breaker 72b of the utilization unit 20b is cut off and the supply of the main power supply 62b is cut off, the auxiliary power supply cannot be supplied to the utilization unit.

(2-2) Power Supply Configuration of Refrigerating Cycle Device 1 of the First Embodiment The refrigerating cycle device 1 of the first embodiment includes a first power feeding unit 51. The first power supply unit 51 supplies the auxiliary power supply to the first switching unit 40 when the supply of the main power supply 64 to the first switching unit 40 is cut off. The auxiliary power supply from the first power supply unit 51 to the first switching unit 40 is supplied via the communication line 8. A voltage is always superimposed through the communication line 8 downstream of the power supply units 51 and 52. When the power supply units 51 and 52 are connected, the power is cut off there.

Therefore, in the refrigeration cycle device 1 of the first embodiment, when the breaker 74 of the switching unit 40 is cut off and the supply of the main power supply 64 is stopped, the auxiliary power supply is supplied from the first power supply unit 51 to the first switching unit 40. Then, the first switching unit 40 can operate the flow rate adjusting valves 41, 42 and the like.

Further, the refrigeration cycle device 1 of the first embodiment includes a second power supply unit 52. The second power supply unit 52 supplies the auxiliary power supply to the first utilization units 20a to 20h when the supply of the main power supplies 62a to 62h to the first utilization units 20a to 20h is cut off. The auxiliary power supply from the second power supply unit 52 to the first utilization units 20a to 20h is performed via the communication line 8.

Therefore, in the refrigeration cycle apparatus 1 of the first embodiment, when any of the breakers 72a to 72h of the first utilization units 20a to 20h is cut off and the supply of any of the main power supplies 62a to 62h is stopped, the second Auxiliary power is supplied from the power supply unit 52 to the first utilization units 20a to 20h, and the first utilization units 20a to 20h can be operated.

(3) Features (3-1)
The refrigeration cycle device 1 of the present embodiment includes a heat source unit 10, a plurality of first utilization units 20, a first switching unit 40, and a first power supply unit 51. The first switching unit 40 switches the flow of the refrigerant of the first utilization unit 20. The first power supply unit 51 supplies the auxiliary power supply to the first switching unit 40 when the supply of the main power supply 64 to the first switching unit 40 is cut off.

The refrigeration cycle device 1 of the present embodiment supplies the auxiliary power supply to the first switching unit 40 when the supply of the main power supply 64 to the first switching unit 40 is cut off, so that the supply of the main power supply 64 is cut off. However, the first switching unit 40 can be operated.

In the refrigeration cycle device 1 of the present embodiment, for example, it is assumed that a plurality of tenants having different stores and offices, such as a shopping center and a building in which a complex facility is located, use the first utilization unit. Of the plurality of tenants, for example, when the tenant using the first utilization unit 20b ends the use of the room and disconnects the breaker 74 of the switching unit 40 together with the breaker 72b of the first utilization unit 20b, the other first 1 Tenants who use the utilization units 20a and 20c to 20h have difficulty in using the utilization units. If the power supply unit 51 can be used at this time, the switching unit 40 can be operated.

(3-2)
The refrigeration cycle device 1 of the first embodiment further includes a second power supply unit 52. When the supply of any of the main power supplies 62a to 62h to the first utilization units 20a to 20h is cut off, the second power supply unit 52 supplies the auxiliary power supply to the first utilization unit whose main power supply is cut off. Do. For example, when the main power supply 62b of the first utilization unit 20b is cut off, the auxiliary power supply is supplied to the first utilization unit 20b.

Since the refrigeration cycle device 1 of the present embodiment includes the second power supply unit 52, in the above example, the first utilization unit 20b in which the supply of the main power supply 62b is cut off can be operated.

Further, the refrigeration cycle device 1 of the present embodiment supplies auxiliary power to all the first utilization units when all the supplies of the main power supplies 62a to 62h to the first utilization units 20a to 20h are cut off. .. In this case, when it is difficult to supply the electric power required to operate the plurality of first utilization units 20a to 20h at the same time, the plurality of first utilization units 20a to 20h are sequentially driven.

Further, the operation of the first utilization unit here includes, for example, adjustment of the opening degree (including opening / closing) of the expansion valve in the first utilization unit, operation of the drain pump, and the like.

(3-3)
In the refrigeration cycle device 1 of the present embodiment, the heat source unit 10 (control unit 15), the first power supply unit 51, the first switching unit 40, the second power supply unit 52, and the first utilization units 20a to 20h are communication lines. At 8, they are connected in parallel.

The auxiliary power supply from the first power supply unit 51 to the first switching unit 40 is supplied by the communication line 8.

The communication line 8 has a higher resistance and a larger limitation on the amount of power than the power supply line from the main power source. The voltage and electric energy of the auxiliary power supply are lower than those of the main power supply. Therefore, there is no problem even if a communication line is used.

In the refrigeration cycle device 1 of the present embodiment, the auxiliary power supply is supplied by the communication line 8, so that it is not necessary to newly provide the wiring equipment for the auxiliary power supply.

Further, the auxiliary power supply is supplied from the second power supply unit 52 to the first utilization units 20a to 20h via the communication line 8.

Therefore, even in this case, since the auxiliary power supply is supplied by the communication line 8 in the refrigeration cycle device 1 of the present embodiment, it is not necessary to newly provide the wiring equipment for supplying the auxiliary power supply.

(3-4)
In the refrigeration cycle device 1 of the present embodiment, the first switching unit 40 has flow rate adjusting valves 41 and 42.

In the refrigeration cycle device 1 of the present embodiment, since the first switching unit 40 has the flow rate adjusting valves 41 and 42, the flow of the refrigerant can be controlled. Further, when the supply of the main power supply 64 to the first switching unit 40 is cut off, the opening / closing of the flow rate adjusting valves 41 and 42 can be adjusted or opened / closed.

(4) Modification example (4-1) Modification example 1A
As shown in FIG. 3A, the refrigeration cycle device 1a of the modification 1A does not have a power supply unit 52 dedicated to the utilization unit 20. The power supply unit 51 of the modification 1A can supply power to both the switching unit 40 and the utilization unit 20.

The first power supply unit 51 supplies the auxiliary power supply to the first switching unit 40 when the supply of the main power supply 64 to the first switching unit 40 is cut off. The auxiliary power supply from the first power supply unit 51 to the first switching unit 40 is supplied via the communication line 8.

The first power supply unit 51 supplies the auxiliary power supply to the first utilization units 20a to 20g when the supply of the main power supply 62a to 62g to the first utilization units 20a to 20g is cut off. The auxiliary power supply from the first power supply unit 51 to the first utilization units 20a to 20g is performed via the communication line 8.

Other configurations of the modified example 1A are the same as those of the first embodiment.

The refrigeration cycle device 1a of the modification 1A can save one power supply unit as compared with the refrigeration cycle device 1 of the first embodiment. However, when considering the same power supply unit, the number of available units is small. In FIG. 1 of the first embodiment, there are 8 units, and in FIG. 3 of the modified example 1A, there are 7 units.

(4-2) Modification 1B
As shown in FIG. 3B, the refrigeration cycle device 1d of the modification 1B includes a power supply unit 52q and utilization units 20aq to 20hq in addition to the configuration of the refrigeration cycle device 1 of the first embodiment. The power supply unit 52q supplies the auxiliary power supply to the utilization units 20aq to 20hq when the supply of the main power supply 62aq to 62hq to the utilization units 20aq to 20hq is cut off. The auxiliary power supply from the power supply unit 52q to the utilization units 20aq to 20hq is performed via the communication line 8. The same components as those of the first embodiment will be omitted because they are the same as those of the first embodiment.

In the refrigerant circuit of the refrigeration cycle device 1d of the modification 1B, the switching unit 40 is arranged in parallel with the utilization units 20aq to 20hq. Therefore, the switching unit 40 cannot switch the flow of the refrigerant in the utilization units 20aq to 20hq. The flow of the refrigerant in the utilization units 20aq to 20hq is switched in the heat source unit 10.

In the refrigeration cycle device 1d of the modified example 1B, when the supply of the main power supply 64 to the first switching unit 40 is cut off, the auxiliary power supply is supplied to the first switching unit 40, so that the supply of the main power supply 64 is cut off. Even if it is done, the first switching unit 40 can be operated. In particular, when the main power supply of the first switching unit is cut off during the operation of the utilization units 20aq to 20hq, the auxiliary power supply can be supplied to the first switching unit 40 to operate the first switching unit 40.

<Second Embodiment>
(5) Refrigeration cycle device 1b of the second embodiment
(5-1) Overall Configuration of Refrigeration Cycle Device 1b of Second Embodiment In the first embodiment, as shown in FIG. 1, the refrigeration cycle device 1 has a heat source unit 10, a first power supply unit 51, and a first switch. It includes a unit 40, a second power feeding unit 52, a plurality of first utilization units 20a to 20h, a control unit 15, and a communication line 8. In the refrigeration cycle device 1b of the second embodiment, as shown in FIG. 4, in addition to the configuration of the refrigeration cycle device 1, a second switching unit 40p, a fourth power supply unit 52p, and a plurality of second utilization units It is provided with 20a to 20h. The refrigerating cycle device 1b of the second embodiment may further include another switching unit connected to the first power feeding unit and a utilization unit that switches the flow of the refrigerant by the switching unit.

Since the configuration common to the refrigerating cycle device 1 in the refrigerating cycle device 1b of the second embodiment is common to that of the first embodiment, it will be simplified by avoiding duplicate explanations.

In the refrigeration cycle device 1b of the second embodiment, the switching unit 40p, the fourth power feeding unit 52p, and the plurality of second utilization units 20ap to 20hp are connected to each main power source 64p via the breakers 74p, 752p, 72ap to 72hp. , 652p, 62ap to 62hp. The main power supply is usually ultimately connected to the grid power supply.

In the second embodiment, the heat source unit 10, the first switching unit 40, the first utilization units 20a to 20h, the second switching unit 40p, and the second utilization units 20ap to 20hp are connected to a common refrigerant circuit.

The heat source unit 10 includes a compressor, a heat source side heat exchanger, and the like. The refrigerant compressed by the compressor is supplied to the first utilization units 20a to 20h and the second utilization units 20ap to 20hp.

The second utilization units 20ap to 20hp harmonize the air in the room. A plurality of utilization units may be arranged in one room, or one utilization unit may be arranged in one room.

The second switching unit 40p switches the flow of the refrigerant to switch the air conditioning operation of the second utilization unit between cooling operation and heating operation. In the present embodiment, eight second utilization units 20ap to 20hp are connected to one second switching unit 40p. The second switching unit 40p collectively switches the eight second utilization units 20ap to 20hp from cooling to heating or from heating to cooling.

Since the internal configuration of the second switching unit 40p is exactly the same as that of the first switching unit 40, the description thereof will be omitted.

In the present embodiment, the control unit 15 is arranged incidentally to the heat source unit 10. Although not shown, the control unit is also arranged in each power supply unit 51, 52, 52p. Each control unit has a processor and a memory. Each control unit controls a unit on the downstream side of the accompanying unit. The control unit 15 and the control units of the power supply units 51, 52, 52p are the heat source unit 10, the first switching unit 40, the first utilization unit 20a to 20h, the second switching unit 40p, and the second utilization unit 20ap to 20hp. To control. The heat source unit 10, the second switching unit 40p, and the second utilization units 20ap to 20hp are connected in parallel by the communication line 8. The communication line 8 is branched between the power supply unit 51 and the switching units 40 and 40p. In other words, the first switching unit 40 and the second switching unit 40p are connected to the first power feeding unit 51 in parallel by the communication line 8. The control command of the control unit 15 is transmitted to the second switching unit 40p and the second utilization units 20ap to 20hp by the communication line 8. On the contrary, the device information of the second switching unit 40p and the utilization units 20ap to 20hp and the information detected by the sensor are transmitted to the control unit 15 via the communication line 8.

(5-2) Power supply unit of the second embodiment The refrigeration cycle device 1b of the second embodiment includes a first power supply unit 51. The first power supply unit 51 supplies the auxiliary power supply to the first switching unit 40 when the supply of the main power supply 64 to the first switching unit 40 is cut off. The first power supply unit 51 further supplies an auxiliary power supply to the second switching unit 40p when the supply of the main power supply 64p to the second switching unit 40p is cut off. The auxiliary power supply from the first power supply unit 51 to the second switching unit 40p is supplied via the communication line 8.

Therefore, in the refrigeration cycle device 1 of the second embodiment, when the breaker 74p of the second switching unit 40p is cut off and the supply of the main power supply 64p is stopped, the auxiliary power supply is supplied from the first power supply unit 51 to the second switching unit 40p. Is supplied, and the second switching unit 40p can operate the flow rate adjusting valves 41, 42 and the like.

Further, the refrigeration cycle device 1 of the second embodiment includes a fourth power supply unit 52p. The fourth power supply unit 52p supplies the auxiliary power supply to the second utilization units 20ap to 20hp when the supply of the main power supplies 62ap to 62hp to the second utilization units 20ap to 20hp is cut off. The auxiliary power supply from the fourth power supply unit 52p to the second utilization units 20ap to 20hp is performed via the communication line 8.

Therefore, in the refrigeration cycle apparatus 1b of the second embodiment, when any of the breakers 72ap to 72hp of the second utilization unit 20ap to 20hp is cut off and the supply of any of the main power supplies 62ap to 62hp is stopped, the fourth Auxiliary power is supplied from the power supply unit 52p to the second utilization units 20ap to 20hp, and the second utilization units 20ap to 20hp can be operated.

(5-3) Refrigerant Circuit of Refrigerant Cycle Device 1b of the Second Embodiment The outline of the refrigerant circuit of the refrigerating cycle device 1b of the second embodiment is shown in FIG. Note that FIG. 7 describes the refrigerant circuits of the refrigeration cycle apparatus 1b that are particularly relevant to the present disclosure, and does not show all the components of the refrigerant circuit. Further, although the refrigeration cycle device 1b has many utilization units 20, only two utilization units are described here for convenience of explanation. The other utilization units 20 are connected in parallel and the description is omitted.

The refrigeration cycle device 1b of the second embodiment includes a heat source unit 10, switching units 40 m and 40 n, and utilization units 20 m and 20 n. The utilization unit 20m is connected to the switching unit 40m by a liquid pipe P31m and a gas pipe P32m. The utilization unit 20n is connected to the switching unit 40n by a liquid pipe P31m and a gas pipe P32m. Further, the heat source unit 10 and the switching unit 40 m are connected by a liquid pipe P11 m and gas pipes P12 m and P13 m. The heat source unit 10 and the switching unit 40n are connected by a liquid pipe P11n and gas pipes P12n and P13n.

The switching unit 40m of FIG. 7 may be regarded as the first switching unit 40 of FIG. 4, and the utilization unit 20m of FIG. 7 may be regarded as the first utilization unit 20a of FIG. In the connection by the communication line of FIG. 4, the first utilization units 20a to 20h are connected in parallel. In the connection of the refrigerant pipe of FIG. 7, the first utilization units 20b to 20h are not described, but when described, they are connected in parallel with the first utilization unit 20a (utilization unit 20m). The switching unit 40n of FIG. 7 may be regarded as the second switching unit 40p of FIG. 4, and the utilization unit 20n of FIG. 7 may be regarded as the second utilization unit 20ap of FIG. In the connection by the communication line of FIG. 4, the second utilization units 20a to 20h are connected in parallel. In the connection of the refrigerant pipe of FIG. 7, the second utilization units 20bp to 20hp are not described, but when they are described, they are connected in parallel with the second utilization unit 20ap (utilization unit 20n).

As shown in FIG. 7, the heat source unit 10 includes a compressor 6, switches 2a, 2b, 2c, heat source side heat exchangers 3a, 3b, expansion valves 4a, 4b, a fan 5, and piping Pa. It has Pb and Pc. The compressor 6 compresses the refrigerant sucked into the compressor 6 from the pipe Pa and discharges it to the pipe Pb. The switches 2a, 2b, and 2c switch the direction of the refrigerant between heating and cooling. The heat source side heat exchangers 3a and 3b heat or cool the refrigerant by exchanging heat between the refrigerant and air. In the refrigeration cycle apparatus of the second embodiment, the heat exchanger 3b is designed so that the heat exchange amount is larger than that of the heat exchanger 3a. The heat exchange amounts of the heat exchanger 3a and the heat exchanger 3b may be designed to be the same. The fan 5 sends air to the heat exchangers 3a and 3b.

Since the configurations of the switching units 40m and 40n are the same as those of the switching unit 40 of the first embodiment and FIG. 6, description thereof will be omitted here.

The utilization unit 20m includes a utilization side heat exchanger 23m, an expansion valve 21m, a fan 25m, and pipes P21m, P22m, and P23m. Further, the utilization unit 20n includes a utilization side heat exchanger 23n, an expansion valve 21n, a fan 25n, and pipes P21n, P22n, and P23n.

(5-4) Flow of Refrigerant in Refrigerant Circuit of Refrigerant Cycle Device 1b of the Second Embodiment (5-4-1) Total Cooling State Explains the flow of refrigerant when all the units used for air conditioning operation perform cooling operation. To do. In FIG. 7, assuming that the utilization units 20m and 20n perform the cooling operation, the following description will be given.

In FIG. 7, the low-temperature, low-pressure refrigerant is sucked into the compressor 6 from the gas pipe Pa and compressed. The refrigerant becomes a high-temperature, high-pressure gas and is discharged to the gas pipe Pb. The refrigerant branches into two in the gas pipe Pb and flows into the switches 2a and 2b. Next, the refrigerant is cooled and liquefied in the radiators (utility side heat exchangers 3a and 3b), further decompressed in the expansion valves 4a and 4b, and is discharged from the heat source unit 10 via the liquid pipe Pc. Head to. The refrigerant leaving the heat source unit 10 goes to the switching units 40m and 40n via the liquid pipes P11m and P11n.

The refrigerant that has entered the switching unit P40m flows through the liquid pipe P41m and passes through the switching unit 40m. The refrigerant passes through the liquid pipe P31 m and heads for the utilization unit 20 m. The refrigerant that has entered the utilization unit 20 m is depressurized when it passes through the liquid pipe P21 m and passes through the expansion valve 21 m. The refrigerant passes through the liquid pipe P22 m, cools the air in the evaporator (utility side heat exchanger 23 m), and the refrigerant is heated to become a gas refrigerant. In other words, the room is cooled. The refrigerant goes to the outlet of the utilization unit 20 m via the gas pipe P23 m. The refrigerant exits the utilization unit 20 m and reaches the switching unit 40 m via the gas pipe P32 m.

The refrigerant flowing into the switching unit 40 m is divided into two by the gas pipe P44 m, and passes through the flow rate adjusting valve 41 m or the flow rate adjusting valve 42 m. The refrigerant that has passed through the flow rate adjusting valve 41 m passes through the gas pipe P42 m and heads for the outlet of the switching unit 40 m. The refrigerant leaving the switching unit 40m merges with the refrigerant flowing through the switching unit 40n and the utilization unit 20n at the piping P12n via the gas pipe P12m, and heads for the heat source unit 10. The refrigerant returned to the heat source unit 10 joins the gas pipe Pa via the switch 2c.

On the other hand, in the switching unit 40m, the refrigerant that has passed through the flow rate adjusting valve 42m passes through the gas pipe 43m and reaches the outlet of the switching unit 40m. The refrigerant exits the switching unit 40 m and flows through the gas pipe P13 m. The refrigerant flowing through the gas pipe P13m merges with the refrigerant flowing through the switching unit 40n and the utilization unit 20n at the pipe P13n in exactly the same manner, and heads for the heat source unit 10. The refrigerant returned to the heat source unit 10 merges with the refrigerant that has passed through the switch 2c in the gas pipe Pa, and heads for the compressor again.

(5-4-2) Full heating state The flow of the refrigerant when all the utilization units that perform the air conditioning operation perform the heating operation will be described. In FIG. 7, assuming that the utilization units 20m and 20n perform the heating operation, the following description will be given.

In FIG. 7, the low-temperature, low-pressure refrigerant is sucked into the compressor 6 from the gas pipe Pa and compressed. The refrigerant becomes a high-temperature, high-pressure gas and is discharged to the gas pipe Pb. The gas refrigerant flows into the switch 2c from the gas pipe Pb and goes to the outlet of the heat source unit 10.

The refrigerant leaving the heat source unit 10 goes to the switching units 40m and 40n via the gas pipes P12m and P12n. The refrigerant that has entered the switching unit P40m flows through the gas pipe P42m, the flow rate adjusting valve 41m, and the gas pipe P44m, and passes through the switching unit 40m. The refrigerant passes through the gas pipe P32 m and heads for the utilization unit 20 m. The refrigerant that has entered the utilization unit 20m passes through the gas pipe P23m and heats the air in the radiator (utilization side heat exchanger 23m), and the refrigerant is cooled to become a liquid refrigerant. In other words, it heats the room. The refrigerant is depressurized by the expansion valve 21m via the liquid pipe P22m, passes through the pipe P21m, and goes to the outlet of the utilization unit 20m. The refrigerant exits the utilization unit 20 m and reaches the switching unit 40 m via the liquid pipe P31 m. The refrigerant flowing into the switching unit 40m passes through the liquid pipe P41m and heads for the outlet of the switching unit 40m. The refrigerant leaving the switching unit 40m merges with the refrigerant flowing through the switching unit 40n and the utilization unit 20n at the piping P11n via the liquid pipe P11m, and heads for the heat source unit 10.

The refrigerant returned to the heat source unit 10 is divided into two parts via the pipe Pc, decompressed by the expansion valves 4a and 4b, passed through the evaporator (heat source side heat exchangers 3a and 3b), gasified, and overheated. It will be in a prescription state. Then, the refrigerant that has passed through the switches 2a and 2b joins the gas pipe Pa and is sucked into the compressor 6 again.

(5-4-3) Simultaneous cooling / heating operation The flow of the refrigerant when a part of the utilization unit performs a heating operation and the other part performs a cooling operation will be described. It will be described assuming that the utilization unit 20m performs the cooling operation and the utilization unit 20n performs the heating operation.

When performing such simultaneous cooling and heating operation, the heat source side heat exchanger heats the heat source side in order to stabilize the refrigeration cycle device according to the difference in heat exchange capacity between the cooling utilization unit and the heating utilization unit. Switch the exchanger to a radiator or evaporator. If the amount of heat exchange is balanced only by the utilization unit, it is not necessary to use the heat exchanger on the heat source side at all .

Here, as a whole, the case where the amount of heat of cooling by cooling is slightly larger than the amount of heat of heating by heating will be described. Therefore, the heat source side heat exchangers 3a and 3b are used as radiators.

The low-temperature and low-pressure refrigerant is sucked into the compressor 6 from the gas pipe Pa and compressed. The refrigerant becomes a high-temperature, high-pressure gas and is discharged to the gas pipe Pb. The refrigerant branches into three in the gas pipe Pb and flows into the switches 2a, 2b and 2c. First, the refrigerant directed to the switch 2c will be described.

The high-temperature, high-pressure gas refrigerant heading for the switch 2c passes through the switch 2c and heads for the outlet of the heat source unit 10. The refrigerant leaving the heat source unit 10 goes to the switching unit 40n via the gas pipe P12n. The refrigerant that has entered the switching unit P40n flows through the gas pipe P42n, passes through the flow rate adjusting valve 41n and the gas pipe P44n, and heads for the outlet of the switching unit 40n. The refrigerant leaving the switching unit 40n passes through the gas pipe P32n and heads for the utilization unit 20n. The refrigerant that has entered the utilization unit 20n passes through the gas pipe P23n and heats the air in the radiator (utilization side heat exchanger 23n), and the refrigerant is cooled to become a liquid refrigerant. In other words, it heats the room. The refrigerant is depressurized by the expansion valve 21n via the gas pipe P22n, and goes to the outlet of the utilization unit 20n via the liquid pipe P21n. The refrigerant exits the utilization unit 20n and reaches the switching unit 40n via the pipe P31n. The refrigerant that has flowed into the switching unit 40n goes to the outlet of the switching unit 40n via the liquid pipe P41n. The refrigerant leaving the switching unit 40n enters the liquid pipe P11m from the liquid pipe P11n and heads for the switching unit 40m on the cooling side.

The refrigerant that has entered the switching unit P40m flows through the liquid pipe P41m and passes through the switching unit 40m. The refrigerant passes through the liquid pipe P31 m and heads for the utilization unit 20 m. The refrigerant that has entered the utilization unit 20 m is depressurized when it passes through the liquid pipe P21 m and passes through the expansion valve 21 m. The refrigerant passes through the liquid pipe P22 m, cools the air in the evaporator (utility side heat exchanger 23 m), and the refrigerant is heated to become a gas refrigerant. In other words, the room is cooled. The refrigerant goes to the outlet of the utilization unit 20 m via the gas pipe P23 m. The refrigerant exits the utilization unit 20 m and reaches the switching unit 40 m via the gas pipe P32 m. The refrigerant that has flowed into the switching unit 40m passes through the gas pipe P44m, the flow rate adjusting valve 42m, and the gas pipe P43m, and heads for the outlet of the switching unit 40m. The refrigerant leaving the switching unit 40 m goes to the heat source unit 10 via the gas pipe P13 m. The refrigerant returned to the heat source unit 10 flows through the gas pipe Pa and heads for the compressor again.

On the other hand, of the high-pressure gas refrigerant compressed by the compressor and discharged to the gas pipe, the one flowing to the switches 2a and 2b is cooled and liquefied in the radiator (utility side heat exchangers 3a and 3b). To. The refrigerant is further depressurized at the expansion valves 4a and 4b, and goes to the outlet of the heat source unit 10 via the liquid pipe Pc. The refrigerant leaving the heat source unit 10 merges with the refrigerant flowing through the liquid pipe P11n from the switching unit 40n on the heating side, and heads for the switching unit 40m on the cooling side via the liquid pipe P11m. The flow of the refrigerant in the switching unit 40 m and the utilization unit 20 m on the cooling side is as described above.

(5-4-4) Oil return operation during simultaneous cooling and heating operation The refrigeration cycle device 1b of the second embodiment is used when the supply of main power sources 64, 64p to the switching units 40, 40p (40m, 40n) is cut off. It has a first power supply unit 51 that supplies auxiliary power to the switching unit. Therefore, even when the supply of the main power supplies 64 and 64p is cut off, the flow rate adjusting valves 41m, 41n, 42m and 42n of the switching unit can be opened and closed, and the opening degree can be adjusted. As an example of the case where this is advantageous, the oil return operation during the simultaneous cooling and heating operation will be described.

If the refrigerating machine oil is mixed with the refrigerant discharged from the compressor and remains in the refrigerant circuit other than the compressor as it is, the oil return operation for returning the refrigerating machine oil to the compressor is performed.

This section describes a case where the oil return operation is performed while maintaining the air conditioning operation during the air conditioning operation so as not to impair the comfort of the user.

In the simultaneous cooling and heating operation described in 5-4-3, the switching unit was controlled as follows.

In the switching unit 40m on the cooling side, the flow rate adjusting valve 41m was closed to prevent the refrigerant from flowing through the gas pipes P42m and P12m, and the flow rate adjusting valve 42m was opened to allow the refrigerant to flow through the gas pipes P43m and P13m. In the switching unit 40n on the heating side, the flow rate adjusting valve 42n was closed to prevent the refrigerant from flowing through the gas pipes P43n and P13n, and the flow rate adjusting valve 41n was opened to allow the refrigerant to flow through the gas pipes P42n and P12n.

One method of the oil return operation is to set the flow velocity of the refrigerant flowing through the pipe to a predetermined value or higher and return the oil staying in the pipe to the compressor. In the case of this method, the amount of refrigerant discharged from the compressor may be required to be equal to or larger than the total amount of refrigerant circulation required by the utilization unit during heating and cooling. In this case, there is a risk that the capacity will be excessive and the comfort of air conditioning will be impaired. As a countermeasure for this, there is a bypass control using the flow rate adjusting valve of the switching unit described below. This control is performed even when the utilization unit downstream of the switching unit is stopped. Therefore, even when the supply of the main power supply of the switching unit and the utilization unit downstream thereof is cut off, it is necessary to operate the flow rate adjusting valve of the switching unit.

When the refrigerant discharge amount of the compressor is increased and the refrigerant circulation amount is increased, both flow rate adjusting valves 41 and 42 are opened in the switching unit 40, and the gas pipes P42 and P12 also have the gas pipe P43. Allow the refrigerant to flow to P13 as well.

In the switching unit 40m on the cooling side, the refrigerant flowing through the gas pipes P12m and P42m merges with the refrigerant coming from the utilization unit 20m and flows to the gas pipes P43m and P13m. In the switching unit 40n on the heating side, the refrigerant flowing through the gas pipes P12n and P42n is branched into a pipe flowing to the utilization unit 20n and a refrigerant flowing to the gas pipes P13n and P43n. Although not shown in FIG. 7, in the case of the switching unit 40 in which the downstream utilization unit is stopped, the refrigerant flowing through the gas pipes P12 and P42 flows to the gas pipes P43 and P13. In either case, the refrigerant that has flowed through some or all of the gas pipes P12 and P42 flows out to the gas pipes P43 and P13 without flowing through the utilization unit (bypassing). By controlling in this way, it is possible to increase the amount of refrigerant circulating and prevent the refrigerant from being supplied to the utilization unit more than necessary.

(5-4-5) Oil return operation during defrost operation As a second example in which the first power supply unit 51 that supplies auxiliary power to the switching unit becomes effective, the oil return operation during defrost operation will be described.

When the outside air temperature is low and frost is formed on the heat source side heat exchanger placed outdoors, defrost operation is performed. Here, as the defrost operation, a case where a reverse cycle defrost operation in which the flow of the refrigerant is reversed so that the radiator and the evaporator are exchanged is examined. Therefore, the basic flow of the refrigerant is the same as the total cooling state described in 5-4-1.

In the fully cooled state, the flow rate adjusting valves 41 and 42 are open in all the switching units 40, and the refrigerant flowing through the gas pipe P32 from the utilization unit 20 enters the switching unit 40 and enters the gas pipe P44. Branches at, and flows through the gas pipes P42 and P12 or the gas pipes P43 and P13.

The reverse cycle defrost operation is preferably performed in a short time as much as possible because the cooling operation is performed during the heating operation. In order to defrost the heat source side heat exchanger as soon as possible, it is preferable to increase the amount of refrigerant discharged from the compressor. Along with such characteristics of the reverse cycle defrost operation, the oil return operation is also carried out together with the defrost operation.

As described above, when the reverse cycle operation is performed with the same flow of refrigerant as in the total cooling state, the flow rate adjusting valves 41 and 42 are open in the switching unit 40. Even if the flow rate adjusting valves 41 and 42 are fully open, there is no problem if the refrigerant flow rate is sufficient for the oil return operation, but if the refrigerant flow rate is insufficient, one of the flow rate adjusting valves may be closed. , Control such as narrowing the opening of the flow rate adjusting valve is performed.

The reverse cycle defrost operation is usually not limited to the utilization unit during the air conditioning operation, and is carried out in all utilization units. Therefore, it is also necessary to control the flow rate adjusting valves 41 and 42 of the switching unit 40 having the unused unit in the downstream.

(6) Features of the second embodiment (6-1)
In the refrigerant circuit of the refrigeration cycle device 1b of the second embodiment, as shown in FIG. 7, a plurality of switching units 40m and 40n are connected to the heat source unit 10. In the refrigerant circuit of the refrigeration cycle device 1b, three or more switching units may be connected to the heat source unit 10. Each switching unit has one or more utilization units connected to the downstream side. Each switching unit can switch the flow of the refrigerant of the utilization unit connected downstream thereof between cooling and heating.

Since the refrigeration cycle device 1b of the second embodiment has a plurality of utilization units, the air-conditioning operation of the plurality of utilization units can be switched between cooling and heating for each switching unit upstream thereof. it can.

Further, the switching units 40m and 40n in FIG. 7 correspond to, for example, the first switching unit 40 and the second switching unit 40p in the electrical wiring diagram of FIG. The first switching unit 40 and the second switching unit 40p are connected in parallel to the power feeding unit 51 by the communication line 8.

The first power supply unit 51 provides an auxiliary power supply to the first switching unit 40 or the second switching unit 40p when the supply of the main power supplies 64 and 64p to the first switching unit 40 or the second switching unit 40p is cut off. Supply.

The refrigeration cycle device of the first aspect is an auxiliary power supply to the first switching unit 40 or the second switching unit 40p when the supply of the main power supplies 64 and 64p to the first switching unit 40 or the second switching unit 40p is cut off. The first switching unit 40 or the second switching unit 40p can be operated even if the supply of the main power supplies 64 and 64p is cut off.

(6-2)
The refrigeration cycle device 1b of the second embodiment further includes a second power supply unit 52 and a fourth power supply unit 52p. When the supply of any of the main power supplies 62a to 62h to the first utilization units 20a to 20h is cut off, the second power supply unit 52 supplies the auxiliary power supply to the first utilization unit whose main power supply is cut off. Do. For example, when the main power supply 62b of the first utilization unit 20b is cut off, the auxiliary power supply is supplied to the first utilization unit 20b.

Since the refrigeration cycle device 1 of the present embodiment includes the second power supply unit 52, in the above example, the first utilization unit 20b in which the supply of the main power supply 62b is cut off can be operated.

Further, the refrigeration cycle device 1 of the present embodiment supplies auxiliary power to all the first utilization units when all the supplies of the main power supplies 62a to 62h to the first utilization units 20a to 20h are cut off. .. In this case, at the same time, if it is difficult to supply the electric power required for the operation to the plurality of first utilization units 20a to 20h, the plurality of first utilization units 20a to 20h are sequentially operated.

Further, the operation of the first utilization unit here includes, for example, adjustment of the opening degree (including opening / closing) of the expansion valve in the first utilization unit, operation of the drain pump, and the like.

Further, the fourth power supply unit 52p receives the auxiliary power supply to the second utilization unit from which the main power supply is cut off when the supply of any of the main power supplies 62ap to 62hp to the second utilization units 20ap to 20hp is cut off. Make a supply. For example, when the main power supply 62bp of the second utilization unit 20bp is cut off, the auxiliary power supply is supplied to the second utilization unit 20bp.

Since the refrigeration cycle device 1b of the present embodiment includes the fourth power supply unit 52p, in the above example, the second utilization unit 20bp in which the supply of the main power supply 62bp is cut off can be operated.

Further, the refrigeration cycle device 1c of the present embodiment supplies auxiliary power to all the second utilization units when all the supply of the main power supplies 62ap to 62hp to the second utilization units 20ap to 20hp is cut off. .. In this case, at the same time, when it is difficult to supply the electric power required for the operation to the plurality of second utilization units 20ap to 20hp, the plurality of second utilization units 20ap to 20hp are sequentially operated.

Further, the operation of the second utilization unit here includes, for example, adjustment of the opening degree (including opening / closing) of the expansion valve in the second utilization unit, operation of the drain pump, and the like.

(6-3)
It is assumed that the refrigeration cycle apparatus 1b of the second embodiment has three or more switching units and a utilization unit on the downstream side of each switching unit. It is assumed that the cooling operation is performed in the utilization unit downstream of the first switching unit, the heating operation is performed downstream of the second switching unit, and the main power supply is cut off in the third switching unit and the utilization unit downstream thereof.

In the refrigeration cycle device 1b of the second embodiment, in such a case, as shown in FIG. 6, both the flow rate adjusting valves 41 and 42 of the switching unit 40 are opened, and the gas pipe P42 passes through the pipe P44. Bypass control is performed so that the refrigerant flows through the gas pipe P43.

Such operations of the flow rate adjusting valves 41 and 42 are also performed in the third switching unit 40 in which the supply of the main power supply is cut off. In this case, the power supply unit can supply auxiliary power to the third switching unit 40 and operate the flow rate adjusting valves 41 and 42.

(6-4)
In the refrigeration cycle apparatus 1b of the second embodiment, the reverse cycle defrost operation is performed when the heat exchanger on the heat source side is frosted. Then, during this defrost operation, an oil return operation is performed to return the oil in the piping to the compressor. Since it is necessary to increase the flow velocity of the refrigerant in the oil return operation, the opening / closing or opening degree of the flow rate adjusting valves 41 and 42 of the switching unit 40 is appropriately adjusted. The adjustment of the flow rate adjusting valve is also carried out for the switching unit 40 in which the main power supply is cut off. When the supply of the main power supply is stopped, the auxiliary power supply is supplied from the first power supply unit 51 to the switching unit 40 so that the opening degree of the flow rate adjusting valve can be adjusted and opened / closed.

(7) Modification example (7-1) Modification example 2A
As shown in FIG. 5A, the refrigeration cycle device 1c of the modified example 2A further includes a power supply unit 51p that supplies power to the second switching unit 40p in addition to the refrigeration cycle device 1b of the second embodiment. The power supply unit 51p is connected to the heat source unit 10 by a communication line 8 in parallel with the power supply unit 51. Other configurations including the refrigerant circuit are the same as in the second embodiment.

The refrigeration cycle device 1c of the modified example 2A includes each power supply unit that supplies auxiliary power to each switching unit when the supply of the main power to each switching unit is cut off.

(7-2) Modification 2B
As shown in FIG. 5B, the components of the refrigeration cycle device 1e of the modification 2B are the same as the components of the refrigeration cycle device 1b of the second embodiment. In the first modification 1A, the power supply unit 51p that supplies power to the second switching unit 40p is connected to the communication line 8 branched from the immediate vicinity of the heat source unit 10, whereas in the first modification 1B, the power supply unit 51p is the first. 1 The difference is that it is connected to the communication line 8 on the downstream side of the utilization unit 20h. Other configurations are the same as in the second embodiment including the refrigerant circuit.

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

1,1a, 1b, 1c, 1d, 1e, 1x Refrigeration cycle device 10 Heat source unit 20, 20a to 20h First utilization unit 20ap to 20hp Second utilization unit 40, 40p, 40m, 40n Switching unit 41, 42, 41m, 42m, 41n, 42n Flow control valve 51 1st power supply unit 52 2nd power supply unit 64, 64p, 62a to 62h, 62ap to 62hp Main power supply 74, 74p, 72a to 72h, 72ap to 72hp Breaker 8 Communication line

"Mitsubishi Electric Building Air Conditioning Multi Air Conditioning System Design and Construction Manual" Mitsubishi Electric Corporation, created in July 2013, p146

Claims (11)

Heat source unit (10) and
A plurality of first-utilization units (20) that perform cooling and heating with the refrigerant supplied from the heat source unit, and
A first switching unit (40) connected to the heat source unit and switching the flow of the refrigerant supplied to at least one first utilization unit of the plurality of first utilization units.
When the supply of the main power supply (64) to the first switching unit is cut off, the first power supply unit (51) that supplies the auxiliary power supply to the first switching unit and
Refrigeration cycle device (1). The refrigeration cycle device further
A second power supply unit (52) that supplies an auxiliary power supply to the first utilization unit when the supply of the main power supply to the first utilization unit is cut off is provided.
The refrigeration cycle apparatus according to claim 1. The first power supply unit (51) and the second power supply unit (52) are independent.
The refrigeration cycle apparatus according to claim 2. The first power supply unit and the second power supply unit are shared.
The refrigeration cycle apparatus according to claim 2. The refrigeration cycle device further
A plurality of utilization units that perform heating and cooling with the refrigerant supplied from the heat source unit, and a second utilization unit (20p) different from the first utilization unit.
A second switching unit (40p) which is connected to the heat source unit in parallel with the first switching unit and switches the flow of the refrigerant supplied to at least one second utilization unit of the plurality of second utilization units.
When the supply of the main power supply to the second switching unit is cut off, the third power supply unit (51, 51p) that supplies the auxiliary power supply to the second switching unit and
To prepare
The refrigeration cycle apparatus according to claim 1 or 2. The heat source unit, the first power supply unit, and the first switching unit are connected by a communication line (8).
The auxiliary power supply from the first power supply unit to the first switching unit is performed by the communication line.
The refrigeration cycle apparatus according to any one of claims 1 to 5. The heat source unit, the first power supply unit, the first switching unit, the second power supply unit, and the first utilization unit are connected by a communication line.
The supply of the auxiliary power supply from the first power supply unit to the first switching unit and the supply of the auxiliary power supply from the second power supply unit to the first utilization unit are performed by the communication line.
The refrigeration cycle apparatus according to any one of claims 1 to 4. The first switching unit has a flow rate adjusting valve (41, 42).
The refrigeration cycle apparatus according to any one of claims 1 to 7. The refrigeration cycle device further
A control unit (15) for controlling the operation of the refrigeration cycle device is provided.
The flow rate adjusting valve is an electronic expansion valve (41, 42).
When the supply of the main power supply to the first switching unit is cut off during the oil return operation, the control unit supplies the auxiliary power supply from the first power supply unit to the electronic expansion valve, and the electronic expansion valve Control the opening,
The refrigeration cycle apparatus according to claim 8. The refrigeration cycle device further
A control unit for controlling the operation of the refrigeration cycle device is provided.
The flow rate adjusting valve is an electronic expansion valve and
During the defrost operation, when the supply of the main power supply to the first switching unit is cut off, the control unit supplies the auxiliary power supply from the first power supply unit to the electronic expansion valve to open the electronic expansion valve. Control the degree,
The refrigeration cycle apparatus according to claim 8. The control unit is arranged in the heat source unit and the first power supply unit.
The refrigeration cycle device according to claim 9 or 10.

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