JP2015075317A - Air conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning system capable of easily starting up a plurality of outdoor units at the time of power failure.SOLUTION: The air conditioning system comprises: a plurality of outdoor units 2A to 2D which have compressors 12 run by gas engines 10; and a plurality of indoor units 13a to 13d which have indoor heat exchangers 21a to 21d. The outdoor units 2A to 2D respectively have generators 11 run by the gas engines 10 and grid connection inverters 33 to output generated power of the generators 11 to a commercial power supply system 36. One of the outdoor units 2A is operated as a master machine which has a battery 49 to store power for starting up the gas engine 10 and the remaining outdoor units 2B to 2D are operated as slave machines. The air conditioning system also has a self-control section 39a which, at the time of power failure in the commercial power supply system, allows: the outdoor unit 2A to be started up using the power of the battery 49; and the outdoor units 2B to 2D to be started up using the power generated by the generator 11 of the outdoor unit 2A.

Description

  The present invention relates to an air conditioning system including a compressor driven by an engine, an outdoor heat exchanger, a generator, and a plurality of outdoor units having a grid-connected inverter that outputs power generated by the generator to a commercial system. In particular, the present invention relates to a start-up control technology for a generator of an outdoor unit during a power failure.

  An air conditioning system is known that can be driven even during a power failure when power supply from a commercial power supply is stopped (see, for example, Patent Document 1). In the engine-driven heat pump device with a power generation function described in Patent Document 1, the generated power of the generator and the power from the commercial power source are each converted to DC power, and converted into AC current by an inverter in a combined state. The AC current can be supplied to the outdoor fan, indoor fan, and other power loads, and the storage unit for storing the generated power is provided in the outdoor unit. The engine is started by the power from the storage unit even during a power failure. The air-conditioning operation is performed.

JP 2009-236417 A

By the way, in large buildings and schools, etc., there are a plurality of outdoor units having compressors driven by engines, outdoor heat exchangers, generators, and grid-connected inverters that output the generated power of the generators to a commercial system. Air conditioning system is adopted. When performing such large-scale air conditioning, it is also possible to provide power storage means in each outdoor unit and to activate each outdoor unit independently during a power failure.
However, in the above-described configuration, the storage unit is provided in each outdoor unit, and the control of starting the own machine with the electric power of the storage unit is performed. Therefore, the configuration of the air conditioning system becomes excessive, for example, the cost of the air conditioning system There is a problem of rising.

  This invention is made | formed in view of the situation mentioned above, and it aims at providing the air conditioning system which can start the several outdoor unit at the time of a power failure easily.

  In order to solve the above-described problem, the present invention includes a plurality of outdoor units having a compressor driven by an engine and an outdoor heat exchanger, and a plurality of indoor units having an indoor heat exchanger. Each of the outdoor units includes a generator driven by the engine and a grid-connected inverter that outputs the generated power of the generator to a commercial system. At least one of the outdoor units is a parent device including a battery that stores electric power for starting the engine, and the remaining outdoor units are child devices. At the time of a power failure of the commercial power supplied to the commercial system, the master unit is activated using the power of the battery, and the slave unit is activated using the generated power generated by the generator of the master unit. An activation control unit is provided.

In this configuration, the activation control unit may sequentially activate a plurality of the slave units using the generated power generated by the generator of the master unit.
Further, the activation control unit uses the generated power generated by the generator of the parent device to activate a part of the plurality of child devices, and then each of the parent device and the activated child device. You may start the said subunit | mobile_unit as many as the number of the said subunit | mobile_unit started with this parent | base_unit using the electric power generated by the generator.

The activation control unit may supply the generated power to a load including the indoor unit after all of the parent device and the child device are activated.
Further, a power supply switching board for switching between the commercial system and the generated power system may be provided, and the master unit and the slave unit may be connected to the power supply switching board, respectively.

  According to the present invention, at the time of a commercial power outage, the battery power is used to start the parent device, and the start control unit is used to start the child device using the generated power generated by the parent device generator. Therefore, it is not necessary to provide a battery for each outdoor unit, and the outdoor unit can be activated with a simple configuration.

It is a figure showing typically the electric power system of the air harmony system concerning this embodiment. It is a circuit diagram which shows the outdoor unit and indoor unit group which operate | move as a main | base station. It is a figure which shows the air conditioning system at the time of normal operation (normal operation mode). It is a flowchart which shows the procedure of starting control of the independent operation at the time of a power failure of a commercial system. It is a figure which shows the state which the main | base station and the 1st subunit | mobile_unit started during the self-supporting operation. It is a figure which shows the state which the main | base station and all the subunit | mobile_units started at the time of independent operation. It is a figure which shows the state by which the electric power generated at the time of a self-sustained operation was supplied to the load.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram schematically showing a power system of an air conditioning system according to an embodiment of the present invention.
The air conditioning system 1 is a system installed in a facility such as a large building or school, and includes a plurality of outdoor units 2A to 2D (four in this embodiment) installed outdoors. In this configuration, in the start-up control at the time of a power failure of the commercial grid power, the air conditioning system 1 operates as a master unit with one predetermined outdoor unit 2A, and the remaining three under the control of the outdoor unit 2A. The outdoor units 2B to 2D of the base operate as slave units.
Each of the outdoor units 2A to 2D is connected to an indoor unit group 3A to 3D installed in a predetermined area indoors to form an independent refrigeration cycle circuit, and air conditioning operation is performed in each refrigeration cycle. Each of the indoor unit groups 3 </ b> A to 3 </ b> D includes a plurality of indoor units 13 a to 13 d (four in each embodiment). The number of these indoor units can be appropriately changed depending on the size of the air-conditioning target area and the capacity of the outdoor unit.

In addition, the air conditioning system 1 includes a single power supply switching board 50 that switches between a commercial power source and a system of generated power generated by the generator 11 included in each of the outdoor units 2A to 2D. The units 2A to 2D and the indoor unit groups 3A to 3D are connected to each other. Furthermore, the power supply switching panel 50 is connected to lighting devices 38 provided in areas where the indoor units 13a to 13d of each indoor unit group are installed.
The power supply switching board 50 includes power supply changeover switches 52, 152, 252 and 352 for switching between the commercial system 36 and the systems of generated power generated by the generators 11 of the outdoor units 2A to 2D, and connection relays 153 and 253. And a self-supporting load relay 353. These power supply selector switch and each relay will be described later.

Next, the outdoor unit and the indoor unit group will be described.
FIG. 2 is a circuit diagram showing the outdoor unit 2A and the indoor unit group 3A that operate as a base unit.
The outdoor unit 2A and the indoor unit group 3A are connected by an inter-unit pipe 4 including a liquid pipe 4a and a gas pipe 4b, thereby constituting a refrigeration cycle circuit for performing an air conditioning operation.
The outdoor unit 2A includes a gas engine 10 (engine) that functions as a driving source, a generator 11 that generates power using the driving force of the gas engine 10, and a compressor 12 that compresses refrigerant using the driving force of the gas engine 10. Is housed. The gas engine 10 generates a driving force by burning an air-fuel mixture of a fuel such as a gas supplied via the fuel adjustment valve 7 and air supplied via the throttle valve 8.

  The indoor unit group 3A is configured to include a plurality of (four in this embodiment) indoor units 13a to 13d that are distributed and installed in each location of the same facility. Each of these indoor units 13a to 13d is provided with a remote controller 5 for operating the indoor units 13a to 13d. When power is supplied to each of the indoor units 13a to 13d, the remote unit 5 is operated according to a remote control operation by the user. Individual operations such as operation / operation stop are possible. In FIG. 2, a line to which power is supplied is indicated by a bold line.

The compressor 12 includes large and small compressors 12a and 12b having different capacities, and two units are connected to the gas engine 10 in parallel via electromagnetic clutches 14a and 14b, respectively. By switching the connection between the compressors 12a and 12b and the gas engine 10 by the electromagnetic clutches 14a and 14b, the driving of the compressors 12a and 12b is controlled according to the load of the air conditioning. A plate heat exchanger 31, a four-way valve 15, and an outdoor heat exchanger 17 are sequentially connected to the discharge pipes 12c of the compressors 12a and 12b. The outdoor heat exchanger 17 is connected to expansion valves 19a to 19d (also referred to as decompression devices) and indoor heat exchangers 21a to 21d of the indoor units 13a to 13d via the liquid pipe 4a. A four-way valve 15 is connected to the indoor heat exchangers 21a to 21d via a gas pipe 4b, and compressors 12a and 12b are connected to the four-way valve 15. The indoor heat exchangers 21a to 21d are respectively provided with blowers 6a to 6d (also referred to as indoor blowers) driven by a DC motor.
Further, the discharge pipe 12c and the suction pipe 12d of the compressors 12a and 12b are connected by a bypass pipe 18, and an unloading bypass valve 20 is connected to the bypass pipe 18. In this configuration, the refrigerant circuit is formed by including the above-described devices.

When the compressors 12a and 12b are driven, if the switching state of the four-way valve 15 is heating switching, the compressors 12a and 12b (either one of the compressors 12a and 12b are indicated as indicated by solid arrows in FIG. 2). The refrigerant circulates in the order of the four-way valve 15, the indoor heat exchangers 21a to 21d, the expansion valves 19a to 19d, and the outdoor heat exchanger 17, and indoors due to the heat of refrigerant condensation in the indoor heat exchangers 21a to 21d. Is heated. On the other hand, if the four-way valve 15 is switched to cooling, the compressors 12a, 12b, the four-way valve 15, the outdoor heat exchanger 17, the expansion valves 19a to 19d, The refrigerant circulates in the order of the heat exchangers 21a to 21d, and the room is cooled by the refrigerant evaporation heat in the indoor heat exchangers 21a to 21d.
Since the indoor units 13a to 13d are connected in parallel, the refrigerant can be individually supplied to the indoor units 13a to 13d, and the indoor units 13a to 13d can be operated independently.

Next, a cooling device for the gas engine 10 will be described.
The gas engine 10 is water-cooled, and the cooling water circulated through the water jacket of the gas engine 10 is supplied to the radiator 25 through the first three-way valve 22, the reverse power flow heater 23, and the second three-way valve 24. The The radiator 25 is provided together with the outdoor heat exchanger 17, which are air-cooled by air sent by the same blower 26, and the cooling water that has passed through the radiator 25 is supplied to the cooling water pump 27 and the exhaust gas heat exchanger 29. It flows in order and is returned to the water jacket of the gas engine 10.
Exhaust gas from the gas engine 10 is passed through the exhaust gas heat exchanger 29, and the exhaust gas is discharged out of the outdoor unit 2 </ b> A through the exhaust top 30.

The first three-way valve 22 described above is automatically switched according to the cooling water temperature. That is, when the cooling water temperature is lower than the predetermined temperature, the cooling water from the water jacket of the gas engine 10 is bypassed by the radiator 25 and directly led to the cooling water pump 27 and the exhaust gas heat exchanger 29, so that the water jacket Return to.
The second three-way valve 24 is switched, for example, during heating operation, and the cooling water is bypassed from the radiator 25 and flows through the plate heat exchanger 31 through the cooling water pump 27 and the exhaust gas heat exchanger 29 in this order. Return to.

Next, the power system will be described.
As shown in FIG. 1, in the air conditioning system 1 of the present embodiment, the generators 11 of the outdoor units 2A to 2D are connected to a commercial system 36 (also referred to as a commercial power source) that is a power system of an electric power company. doing. Thereby, the generated power of each generator 11 can be supplied to the outdoor units 2A to 2D, the indoor units 13a to 13d, and the lighting device (other power load) 38 together with the power of the commercial system 36.
In this case, the outdoor units 2A to 2D and the indoor units 13a to 13d correspond to the power load of self-consumption (self-power consumption) of the air conditioning system 1, and supply power to the lighting device 38 and the outlet (not shown). Corresponds to another power load (non-air conditioner) not related to air conditioning.

  The power switching board 50 includes power switching switches 52, 152, 252 and 352 provided in parallel to the upstream power supply line 51a which is a commercial power line (also referred to as a lamp line). In the present embodiment, the most upstream power supply changeover switch 52 is connected to the outdoor unit 2A that is the parent device and the outdoor unit 2B that is the first child device. Similarly, the outdoor unit 2C, which is the second slave unit, is connected to the power source switch 152, and the outdoor unit 2D, which is the third slave unit, is connected to the power source switch 252. The indoor units 13a to 13d and the lighting devices 38 are connected to the most downstream power supply changeover switch 352 via the downstream power supply line 51b.

The first power supply selector switch 52 is connected to a first terminal 52a (normal operation terminal) to which the upstream power supply line 51a is connected and a power supply line 34b to which the power generated by the generator 11 of the outdoor unit 2A is supplied. The second terminal 52b (self-sustained operation terminal) and the third terminal 52c (power feeding terminal) to which the grid connection power line 34a is connected are provided, and the third terminal 52c is connected to the first terminal 52a. And a switch circuit that switches to either one of the second terminal 52b.
The power line 34a includes a power branch line 34a1 that branches between the third terminal 52c and the grid interconnection inverter 33 of the outdoor unit 2A. The power supply branch line 34a1 is further branched into two, one connected to the grid interconnection inverter 33 of the outdoor unit 2B, and the other connected to the first and second connection relays 153 and 253 and the independent load relay 353. Are connected to the power supply selector switch 352 on the most downstream side.
For this reason, by connecting the third terminal 52c and the first terminal 52a, commercial power (200V AC power in the present embodiment) from the commercial system 36 is connected to each system-connected inverter of the outdoor unit 2A and the outdoor unit 2B. 33 can be supplied. Furthermore, by connecting the third terminal 52c and the second terminal 52b, the generated power of the generator 11 of the outdoor unit 2A can be supplied to the power branch line 34a1.

  The second power supply switch 152 is connected to the first terminal 152a (normal operation terminal) to which the upstream power supply line 51a is connected and the power supply branch line 34a1 to which the power generated by the generator 11 of the outdoor unit 2A is supplied. A second terminal 152b (terminal for autonomous operation) and a third terminal 152c (power feeding terminal) to which the power line 134 for grid connection is connected, and the connection destination of the third terminal 152c is connected to the first terminal It functions as a switch circuit that switches to either the 152a or the second terminal 152b. In addition, a first connection relay 153 is provided on the power branch line 34a1 between the branch point 35 to the outdoor unit 2B and the second terminal 152b of the second power switch 152. The first connection relay 153 functions as a switch that opens and closes in order to supply the power generated by the generator 11 of the outdoor unit 2 </ b> A to the downstream side of the first power supply switch 52. By controlling the opening and closing of the first connection relay 153, the generated power of the outdoor unit 2A is prevented from being supplied simultaneously to the other outdoor units 2B to 2D, the indoor units 13a to 13d, and the lighting device 38 (load). To do.

  The third power supply switch 252 has the same configuration as the second power supply switch 152. That is, the third power supply selector switch 252 includes a first terminal 252a (normal operation terminal) to which the upstream power supply line 51a is connected and a power supply branch line 34a1 to which the generated power of the generator 11 of the outdoor unit 2A is supplied. The second terminal 252b (terminal for independent operation) to be connected and the third terminal 252c (power feeding terminal) to which the power supply line 234 for grid connection is connected, and the connection destination of the third terminal 152c is It functions as a switch circuit that switches to one of the first terminal 152a and the second terminal 152b. The power supply branch line 34a1 is provided with a second connection relay 253 between the second terminal 152b of the second power supply changeover switch 152 and the second terminal 252b of the third power supply changeover switch 252.

The most downstream fourth power supply switch 352 includes a first terminal 352a (normal operation terminal) to which the upstream power supply line 51a is connected, and a power supply branch line 34a1 to which the generated power of the generator 11 of the outdoor unit 2A is supplied. Is connected to the second terminal 352b (terminal for independent operation) and the downstream power supply line 51b to which the indoor units 13a to 13d, the lighting device 38 (load), and the like are connected, is connected to the third terminal 352c (power supply terminal). ) And functions as a switch circuit that switches the connection destination of the third terminal 352c to one of the first terminal 352a and the second terminal 352b. The power supply branch line 34a1 is provided with a self-supporting load relay 353 between the second terminal 252b of the third power supply changeover switch 252 and the second terminal 352b of the fourth power supply changeover switch 352.
This self-supporting load relay 353 has the same configuration as the first and second connection relays 153 and 253. Whether or not the power generated by the outdoor unit 2A is supplied to the indoor units 13a to 13d and the lighting device 38 (load) can be controlled by opening and closing the self-supporting load relay 353.

As described above, the power supply switching panel 50 includes the power supply changeover switches 52 to 352, the connection relays 153 and 253, and the self-sustained load relay 353, and the power source to the downstream power supply line 51b is connected to the commercial system 36 and the generated power. Function as a switching means for switching between the two systems (also referred to as a power generation system).
Therefore, in the air conditioning system 1, the outdoor units 2 </ b> A to 2 </ b> D, the indoor units 13 a to 13 d, and the lighting device 38 are driven using the power supplied from the commercial system 36 and the generators 11 of the outdoor units 2 </ b> A to 2 </ b> D. A normal operation and a self-sustained operation in which the outdoor units 2A to 2D, the indoor units 13a to 13d, and the lighting device 38 are driven by the generated power of the generators 11 of the outdoor units 2A to 2D separately from the commercial system 36 are selectively performed. Can be done.

Next, the system of generated power will be described.
As shown in FIG. 2, the outdoor unit 2A that functions as a master unit includes a grid-connected inverter 33 that converts the generated power of the generator 11 and a battery 49 that stores a part of the generated power.
The power generated by the generator 11 is output to the grid interconnection inverter 33 via the power line 32. The grid interconnection inverter 33 converts the three-phase AC power that is generated by the generator 11 into DC power via an AC / DC converter, and then converts it back into 200 V AC power to convert the power line 34 ( Output to the power output line).
The power supply line 34 branches into the power supply line 34 a for grid connection and the power supply line 34 b for independent operation. These power supply lines 34 a and 34 b are connected to the first terminal 52 a of the first power supply changeover switch 52. Are respectively connected to the second terminals 52b. The grid connection power line 34 a is connected to the outdoor controller 39 via the power line 41, and can supply power to the outdoor unit 2 A including the outdoor controller 39.
A part of the generated power is supplied to the battery 49 via the power line 47 b shown in FIG. 1, and the generated power is stored in the battery 49.

The power supply line 34 b for independent operation is connected to the second terminal 52 b of the first power supply switch 52 described above. Therefore, as described above, by connecting the second terminal 52b and the third terminal 52c of the first power supply switch 52, the generated power is directly supplied to the power branch line 34a1 via the first power switch 52. can do.
Here, the power supply line 34b for independent operation is provided with a self-supporting relay 34c that is turned on when the generated power is supplied to the power supply line 34b. The power supply line 34a for grid connection also includes the power supply line 34b. An interconnection relay 34d that is turned on when the generated power is supplied to the power line 34a is provided.

The grid interconnection inverter 33 is communicably connected to the outdoor controller 39 of the outdoor unit 2A via the communication line 40, and appropriately supplies power to the reverse flow heater 23 described above so that the reverse flow does not flow. Supply.
The outdoor controller 39 can obtain operating power from the commercial system 36 via the power line 41 in addition to the configuration capable of supplying the generated power via the grid connection power line 34a, and via the communication line 42. Are connected to the indoor controller of each indoor unit group 3A in a communicable manner.
The outdoor controller 39 includes an independent control unit (startup control unit) 39a to which power of the battery 49 is directly supplied via the power line 54, and a storage unit 39b that stores various data such as a control program. .

In addition, the outdoor controller 39 includes a normal operation mode for performing a normal operation for driving the outdoor unit 2A, the indoor unit group 3A, and the lighting device 38 with electric power supplied from the commercial system 36 and the generator 11 of the outdoor unit 2A, and a power failure. Control for switching the operation mode to any one of a self-sustained operation mode in which a self-sustained operation in which the outdoor unit 2A, the indoor unit group 3A, and the lighting device 38 are driven by the power generated by the generator 11 after being disconnected from the commercial system 36, etc. Do.
The self-sustained control unit 39a is connected to a self-sustaining operation switching switch 56 (self-sustaining operation switch) which is a manual switch manually operated by a user or the like. Start switching to operation mode.

A cell motor (not shown) of the gas engine 10 is connected to a power supply line 54 to which power of the battery 49 is supplied via a power supply line 48 (FIG. 2), and the battery 49 is controlled under the control of the outdoor controller 39. The cell motor can be driven with the electric power to start the gas engine 10.
As described above, the outdoor controller 39 centrally controls the operation of each device of the outdoor unit 2A (for example, the gas engine 10, the electromagnetic clutches 14a and 14b, the blower 26, the battery 49, the power switch board 50, and the like). Functions as a control unit. Further, since the outdoor unit 2A functions as a master unit, the outdoor controller 39 of the outdoor unit 2A serves as a main controller for starting control of the outdoor units 2A to 2D at the time of a power failure. The outdoor side controller 39 of the outdoor unit 2A is connected to each of the outdoor side controllers 39 of the outdoor units 2B to 2D serving as slave units via a communication line 53.

  A grid interconnection board 45 is connected to the grid interconnection inverter 33 via a communication line 44, and this grid interconnection board 45 is installed between the commercial system 36 and the breaker 37 via a communication line 46. The detected power detector 43 is connected. The power detector 43 acquires the power value supplied to the commercial grid 36 in real time, and the acquired power value data is input to the grid interconnection inverter 33 via the grid interconnection board 45, and the communication line 40. To the outdoor controller 39. Although not shown in the figure, the grid interconnection board 45 includes OVGR / RPR (ground fault overvoltage relay / reverse power relay), UPR (underpower relay), W / TD (watt transducer), etc., and received power detection A signal from the OVGR / RPR, UPR, and W / TD is transmitted to the grid interconnection inverter 33 together with the signal from the device 43. For this reason, the grid interconnection inverter 33 can obtain information on the commercial system 36.

The outdoor units 2B to 2D that operate as slave units have the same configuration as the outdoor unit 2A that operates as a master unit. As shown in FIG. 1, from the battery 49, the independent operation changeover switch 56, and the grid interconnection inverter 33, The difference is that the output power supply line 34b for independent operation is not provided.
That is, the outdoor unit 2A as a master unit can operate the own unit (outdoor unit 2A) by the stored power of its own battery 49 at the time of a power failure, whereas the outdoor units 2B to 2D as slave units Independently, it is not possible to operate the aircraft independently during a power failure.
For this reason, if it is going to start the whole air conditioning system at the time of a power failure, it was necessary to set it as the structure which can be equipped with the battery etc. in all the outdoor units, and the structure of the air conditioning system became complicated.
Therefore, in this configuration, the outdoor controller 39 of the outdoor unit 2A includes a self-supporting control unit (starting control unit) 39a that performs control to start the outdoor unit 2A and the outdoor units 2B to 2D as slave units. It has the characteristics.

Next, the basic operation of the air conditioning system 1 will be described.
FIG. 3 shows the air conditioning system 1 during normal operation (normal operation mode). In FIG. 3, a line through which electric power flows is indicated by a bold line.
The normal operation mode is an operation mode when electric power is supplied from the commercial system 36. In this mode, as shown in FIG. 3, the power supply switching panel 50 controls the autonomous operation of the outdoor controller 39 of the outdoor unit 2A. Under the control of the unit 39a, each of the power supply selector switches 52, 152, 252 and 352 is switched to the first terminals 52a, 152a, 252a and 352a side. Further, the connection relays 153 and 253 and the self-supporting load relay 353 are all controlled to be turned off (opened).
For this reason, the electric power supplied from the commercial system 36 is supplied via the upstream power supply line 51a, the power supply changeover switches 52, 152, 252 and the power supply lines (for system interconnection) 34a, 34a1, 134, 234, etc. , And supplied to each part of each of the outdoor units 2A to 2D. Furthermore, it is supplied to each indoor unit 13a-13d and the illuminating device 38 via the 4th power supply switch 352 and the downstream electric power feeding line 51b.
Further, during this normal operation, the generator 11 of each of the outdoor units 2A to 2D outputs generated power that covers all of the drive power for driving the outdoor units 2A to 2D. The surplus power generated is supplied to the indoor units 13a to 13d and the lighting device 38 via the grid interconnection inverter 33, power lines (for grid interconnection) 34a, 34a1, 134, 234, and the downstream power supply line 51b. To be supplied.

Next, start-up control of the independent operation at the time of power failure will be described.
FIG. 4 is a flowchart showing a start-up control procedure for the independent operation when the power supply to the commercial system 36 is stopped (at the time of a power failure). In this procedure, the outdoor unit 2A, which is the master unit, operates as a control subject.
When power supply from the commercial system 36 is cut off due to a power failure or the like, the outdoor units 2A to 2D, the indoor units 13a to 13d, the lighting device 38, and the like are stopped because power is not supplied.
In this power failure state, when the independent operation changeover switch 56 provided in the outdoor unit 2A is operated to “ON” by the user's manual operation (step S1), the electric power from the battery 49 is turned on when the switch 56 is turned on. Is supplied to the outdoor controller 39 (independent control unit 39a (see FIG. 2)), and under the control of the outdoor controller 39, the power of the battery 49 is set to DC 200V through a DC / DC converter (not shown). Is supplied as a power source.

  Subsequently, the outdoor side controller 39 of the outdoor unit 2A starts an operation of switching from the normal operation mode to the self-sustained operation mode. In this case, the outdoor controller 39 drives the cell motor with the electric power of the battery 49 and starts the gas engine 10 (step S2). Thereby, when the gas engine 10 is started, power generation by the generator 11 is started. Also. In the present embodiment, even when the gas engine 10 is started, the outdoor controller 39 keeps the electromagnetic clutches 14a and 14b disconnected and postpones the start of operation of the compressor 12. This is because, in the event of a power failure, the air conditioning operation is started after all outdoor units 2A to 2D (generators) are activated with priority on power generation.

Subsequently, the outdoor side controller 39 of the outdoor unit 2A determines whether or not the power for self-sustained operation is output from the generator 11 of the own unit (step S3). Since the electric power output from the generator 11 is input to the grid interconnection inverter 33, the determination is made based on whether or not power is input to the grid interconnection inverter 33.
In this determination, when power for independent operation is not output from the generator 11 (step S3; No), an error alarm is output (step S4) and the process is terminated.
In addition, when power for autonomous operation is output from the generator 11 (step S <b>3; Yes), the outdoor controller 39 outputs power for autonomous operation to the power switching board 50 through the grid interconnection inverter 33. (Step S5). As a result, as shown in FIG. 5, the power supply selector switches 52, 152, 252, 352 of the power selector board 50 are automatically set to the second terminals 52 b, 152 b, 252 b, 352 b, which are independent operation terminals, respectively. Switching (step S6). Then, the outdoor units 2A to 2D including the grid interconnection inverter 33 are disconnected from the commercial system 36, and the outdoor units 2A to 2D, the indoor units 13a to 13d, and the lighting device 38 are connected to form a closed independent operation circuit. Independent operation is started.

When the gas engine 10 of the outdoor unit 2A is activated and the power generation by the generator 11 is started, the generated power is supplied from the power line 34b (for self-sustained operation) and the first power switch 52 as shown in FIG. The power is supplied to the outdoor unit 2B through the power lines 34a and 34a1.
In this case, the outdoor controller 39 of the outdoor unit 2A maintains the first connection relay 153, the second connection relay 153, and the self-supporting load relay 353 in an off (open) state. When these relays are turned on (closed), the generated power 11 of the outdoor unit 2A is supplied to a plurality of outdoor units at the same time, so that the power supplied to each outdoor unit is reduced. For this reason, in the present embodiment, the generated power is supplied only to the same number of outdoor units 2B as the number of outdoor units 2A actually activated (one unit), thereby reliably starting the gas engine 10 of this outdoor unit 2B. It is possible.

Subsequently, the outdoor controller 39 of the outdoor unit 2A uses the generated power generated by the outdoor unit 2A to drive the cell motor of the gas engine 10 of the outdoor unit 2B (first slave unit). Is activated (step S7). When the gas engine 10 is activated, power generation by the generator 11 of the outdoor unit 2B is started.
The outdoor side controller 39 of the outdoor unit 2A determines whether or not generated power for independent operation is output from the generator 11 of the outdoor unit 2B (step S8). Since the generated power output from the generator 11 is input to the grid interconnection inverter 33, it is determined by the presence / absence of power input to the grid interconnection inverter 33 via the outdoor controller 39 of the outdoor unit 2B. Is done.
In this determination, when the generated power is not output from the generator 11 (step S8; No), an error alarm is output (step S4) and the process is terminated.
When the generated power is output from the generator 11 (step S8; Yes), the outdoor controller 39 of the outdoor unit 2A generates power that is output through the grid interconnection inverter 33 through the grid interconnection inverter 33. The power is adjusted so as to be superimposed on the generated power output from the outdoor unit 2A (step S9). Thereby, the generated electric power output from the outdoor unit 2A (master unit) and the outdoor unit 2B (first slave unit) is supplied to the downstream side in a state where the wavelengths and the like are matched.

  Subsequently, the outdoor controller 39 of the outdoor unit 2A performs on (close) control of the first and second connection relays 153 and 253 (step S10). As a result, as shown in FIG. 6, the generated power output from the outdoor unit 2A and the outdoor unit 2B passes through the power supply branch line 34a1, the first connection relay 153, the second power supply changeover switch 152, and the power supply line 134. , Supplied to the outdoor unit 2C (second slave unit). Further, the generated power is supplied to the outdoor unit 2D (third slave unit) through the power branch line 34a1, the second connection relay 253, the third power switch 252 and the power line 234.

In the present embodiment, the generated power is supplied to the outdoor units 2C and 2D having the same number as the number of outdoor units 2A (master unit), the outdoor unit 2B (first slave unit), and the number of units (two units) actually started. One outdoor unit (gas engine) can be started by the generated electric power of one outdoor unit, and the outdoor unit can be started stably.
Here, when the other outdoor units 2B to 2D are activated using the generated power of the outdoor unit 2A (master unit), the outdoor units 2B to 2D may be sequentially activated. However, in this configuration, in order to activate, for example, four outdoor units, it is necessary to repeat a total of four activation operations. On the other hand, in this configuration, after the outdoor unit 2B (first slave unit) is activated using the generated power generated by the generator 11 of the outdoor unit 2A (master unit), the outdoor unit 2A and the outdoor unit 2A are activated. Using the generated power generated by each generator 11 of the outdoor unit 2B, two outdoor units 2C and 2D (second slave unit and third slave unit) that are the same number as the number of the outdoor units 2A and the outdoor units 2B are used. It was set as the structure to start. For this reason, the start-up operation of each outdoor unit is only three times, and the start-up at the time of power failure can be performed in a short time. The effect of this control becomes more prominent as the number of outdoor units increases.

Subsequently, the outdoor controller 39 of the outdoor unit 2A drives the cell motors of the gas engines 10 of the outdoor units 2C and 2D using the generated power output from the outdoor unit 2A and the outdoor unit 2B, respectively. 10 is activated (step S11). In this case, the gas engines 10 of the outdoor units 2C and 2D are not activated at the same time, but are activated at a slight time difference (for example, 10 seconds). Thereby, it is prevented that the electric power supplied at the time of starting is used simultaneously, and starting of the gas engine 10 can be performed more reliably.
Further, when the gas engine 10 is activated, power generation by the generators 11 of the outdoor units 2C and 2D is started.

Subsequently, the outdoor controller 39 of the outdoor unit 2A determines whether or not generated power is output from each of the generators 11 of the outdoor units 2C and 2D (step S12). In this determination, when the generated power is not output from the generator 11 (step S12; No), an error alarm is output (step S4) and the process is terminated.
When the generated power is output from the generator 11 (step S12; Yes), the outdoor controller 39 of the outdoor unit 2A generates power output through the grid interconnection inverter 33 through the grid interconnection inverter 33. The electric power is adjusted so as to be superimposed on the generated electric power output from the outdoor unit 2A and the outdoor unit 2B (step S13). Thereby, the generated electric power output from the outdoor unit 2A (master unit) and the outdoor units 2B to 2D (first to third slave units) is supplied to the downstream side in a state where the wavelengths and the like are matched.

Subsequently, the outdoor controller 39 of the outdoor unit 2A performs control to turn on (close) the self-sustained load relay 353 (step S14). As a result, as shown in FIG. 7, the generated power output from the outdoor units 2 </ b> A to 2 </ b> D flows to the downstream power supply line 51 b via the self-supporting load relay 353 and the fourth power supply switch 352. For this reason, electric power can be supplied to the indoor units 13a to 13d and the lighting device 38, and the air conditioning operation by the indoor units 13a to 13d and the operation of the lighting device 38 can be performed.
In this configuration, after the generators 11 of all the outdoor units 2A to 2D are driven, the self-sustained load relay 353 is closed and power is supplied to the indoor units 13a to 13d and the lighting device 38. It is possible to prevent the outdoor units 2 </ b> A to 2 </ b> D from starting up abnormally when a large amount of power is used, and to supply stable power to the load after the outdoor unit is started up.

When operating any of the indoor units 13a to 13d, the remote controller 5 is operated. Thereby, the electromagnetic clutches 14a and 14b in the corresponding outdoor unit are connected, the compressors 12a and 12b are driven, and the refrigerant circulates in the refrigerant circuit, thereby realizing the air conditioning operation.
Further, during the self-sustaining operation, the upstream power supply line 51 a is disconnected from the outdoor units 2 </ b> A to 2 </ b> D by the power supply switching panel 50, so that the power of each generator 11 is supplied to the commercial system 36 upstream from the power switching panel 50. Not supplied. For this reason, it is possible to prevent a reverse power flow from being generated toward the commercial system 36 during the independent operation with a simple configuration, and it is possible to operate the desired indoor units 13a to 13d and the lighting device 38.
Therefore, even if it is a case where electric power is supplied with the generator 11 with which electric power generation capability is limited, the apparatus which wants to drive | operate at the time of a power failure can be operated.
Moreover, even if it is in the confused state at the time of a power failure, the equipment currently selected and arrange | positioned in the self-supporting operation circuit can be operated quickly, without selecting the equipment which wants to drive on the spot.

  When it is not necessary to operate the indoor units 13a to 13d at the time of a power failure, the electromagnetic clutches 14a and 14b are disconnected and the compressors 12a and 12b are stopped. For this reason, when it is desired to supply power only to the illumination device 38, it is not necessary to operate the compressors 12a and 12b, and power can be supplied efficiently.

  As described above, the air conditioning system 1 includes the plurality of outdoor units 2A to 2D including the compressor 12 driven by the gas engine 10 and the outdoor heat exchanger 17, and the indoor heat exchangers 21a to 21d. A plurality of indoor units 13a to 13d, and the outdoor units 2A to 2D each include a generator 11 driven by the gas engine 10 and a grid interconnection inverter 33 that outputs the generated power of the generator 11 to the commercial system 36; A single outdoor unit 2A is a master unit including a battery 49 that stores electric power for starting the gas engine 10, and the remaining outdoor units 2B to 2D are slave units. In the event of a power failure, the power of the battery 49 is used to activate the outdoor unit 2A as the master unit and the outdoor unit. Generator 11 2A is equipped with a self-supporting control unit 39a for activating the outdoor unit 2B~2D as handset using the generated power generated. For this reason, it is not necessary to provide the batteries 49 in the outdoor units 2A to 2D, respectively, and the outdoor units 2A to 2D can be activated with a simple configuration.

Further, according to the present embodiment, the outdoor controller 39 (self-supporting control unit 39a) of the outdoor unit 2A uses the generated power generated by the generator 11 of the outdoor unit 2A (master unit) to use the outdoor unit 2B (first unit). 2 outdoor units 2A and 2 outdoor units 2B, which are the same as the number of outdoor units 2A and 2B, using the generated power generated by each of the generators 11 of the outdoor unit 2A and the activated outdoor unit 2B. Since the units 2C and 2D (second child device and third child device) are activated, each outdoor unit is activated three times in total, and can be activated in a short time during a power failure.
Furthermore, according to the present embodiment, the generated power generated by the generator 11 of the outdoor unit 2A (master unit) is prevented from being supplied to the three outdoor units 2B to 2D at the same time. 2B to 2D can be activated stably.

  According to this embodiment, the outdoor side controller 39 (self-supporting control unit 39a) of the outdoor unit 2A closes the self-supporting load relay 353 after the generators 11 of all the outdoor units 2A to 2D are activated, Since power is supplied to the units 13a to 13d and the lighting device 38, it is prevented that a great amount of power is used during start-up and the start-up of the outdoor units 2A to 2D is prevented, and stable after the start-up of the outdoor unit. Electric power can be supplied to the load.

  According to the present embodiment, the power supply switching board 50 for switching between the commercial system 36 and the generated power system is provided, and the outdoor units 2A to 2D and the indoor units 13a to 13d are connected to the power supply switching board 50, respectively. 50 is a single configuration, and the arrangement of the power system in the air conditioning system 1 can be simplified.

In addition, the said embodiment shows the one aspect | mode which applied this invention, Comprising: This invention is not limited to the said embodiment.
For example, the outdoor controller 39 (self-supporting control unit 39a) of the outdoor unit 2A sequentially activates the other outdoor units 2B to 2D using the generated power generated by the generator 11 of the outdoor unit 2A (master unit). Of course, it is good. In this configuration, the outdoor units as slave units can be reliably started one by one.

1 Air conditioning system 2A Outdoor unit (base unit)
2B Outdoor unit (first slave unit)
2C outdoor unit (second slave unit)
2D outdoor unit (third slave unit)
3A-3D Indoor unit group 10 Gas engine (engine)
11 generator 12 compressor 13a-13d indoor unit (load)
17 Outdoor heat exchangers 21a to 21d Indoor heat exchangers 33 Grid-connected inverter 36 Commercial system 38 Illumination device (load)
39 Outdoor controller 39a Independent control unit (startup control unit)
DESCRIPTION OF SYMBOLS 50 Power supply switching board 51a Upstream side feeding line 51b Downstream side feeding line 52 1st power supply switching switch 152 2nd power supply switching switch 153 1st connection relay 252 3rd power supply switching switch 253 2nd connection relay 352 4th power supply switching switch 353 Relay for self-supporting load

Claims (5)

A generator including a plurality of outdoor units having compressors and outdoor heat exchangers driven by an engine, and a plurality of indoor units having indoor heat exchangers, each of the outdoor units being driven by the engine And a grid interconnection inverter that outputs the generated power of the generator to a commercial system,
At least one of the outdoor units is a master unit including a battery that stores power for starting the engine, and the remaining outdoor unit is a slave unit. In the event of a power failure of commercial power supplied to the commercial system, the battery An air conditioning system, comprising: an activation control unit that activates the master unit using the power of the master unit and activates the slave unit using the generated power generated by the generator of the master unit.   2. The air conditioning system according to claim 1, wherein the activation control unit sequentially activates a plurality of the slave units using the generated power generated by the generator of the master unit.   The start control unit uses the generated power generated by the generator of the master unit to start a part of the plurality of slave units, and then each generator of the master unit and the started slave unit 3. The air conditioning system according to claim 1, wherein the same number of slave units as the number of the slave units that have been activated are activated using the generated power generated by the air conditioner.   The air conditioning according to any one of claims 1 to 3, wherein the activation control unit supplies the generated power to a load including the indoor unit after all of the parent device and the child device are activated. system.   The power supply switching board which switches the said commercial system and the system of the generated electric power is provided, The said main | base station and the said subunit | mobile_unit were each connected to this power supply switching board, The Claim 1 thru | or 4 characterized by the above-mentioned. Air conditioning system.

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