JP2001061238A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable electric power supply, without influence by instantaneous voltage drop and survice interruption on the most important load, when cutting off a power system at generation of instantaneous voltage drop and survice interruption, in a power supply system where a generator is operated at all times is linked with the power system. SOLUTION: This power supply system consists of a generator 21, which is always operated and linked with a power system via a high speed breaker system 30, and an uninterruptible power supply 10 connected to the generator. As a power supply means 13 of the uninterruptible power supply 10, one among a capacitor, an electric double layer capacitor, a flywheel and superconducting power storage is used.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an uninterruptible power supply (UPS) in a power supply system in which a gas engine generator or a gas turbine generator that is constantly operated is connected to a power system. The present invention relates to an uninterruptible power supply system for reducing backup time.

[0002]

2. Description of the Related Art The configuration of a conventional power supply system having an emergency private power generator will be described with reference to FIG. The power supply system shown in FIG. 5 is provided with a circuit breaker between the power system and the emergency generator, and when a power failure is detected in the power system, disconnects an important load from the power system, and generates an emergency power generated by a diesel engine or the like. The power is supplied from the uninterruptible power supply during the time from the occurrence of a power failure to the operation of the emergency generator, in order to start the machine and supply power to the important load.

A power supply system having a private generator is
Emergency generator 21 driven by diesel engine 23
And the private generator side bus 1 connected to the emergency generator 21
A power system-side bus 7 connected to the power system 70; a circuit breaker 35 provided between the private generator-side bus 1 and the power system-side bus 7; and a power failure detection for detecting a power failure in the power system. It is configured to include a circuit 36 and the uninterruptible power supply 10 connected to the private generator side bus 1.

[0004] The output of the private generator 21 is supplied to the private generator side bus 1 via a circuit breaker 61.

Power received from the power system 70 is supplied to the power system side bus 7 via the transformer 51 and the circuit breaker 62.

The uninterruptible power supply 10 is connected to the private generator-side bus 1 via a transformer 52 and a feeder circuit breaker 63, so that the power supply is not always maintained even in the event of an instantaneous voltage drop in the power system or a power outage. Power is supplied to the most important load 41 such as a computer which must not be used.

Further, an important load 42 to which power is supplied even in the event of an instantaneous voltage drop in the power system or a power outage is connected to the private generator side bus 1 via a feeder breaker 64 and a transformer 53.

The generator 21 is started when the power failure detection circuit 36 detects a power failure in the power system, and supplies power to the private generator-side bus 1 via the circuit breaker 61.

The power system 70 is connected to the power system side bus 7 via a transformer 51 and a circuit breaker 62.

The power system side bus 7 is connected via a feeder circuit breaker 65 and a transformer 54 to a general load 43 which allows the power supply to be cut off at the time of a momentary voltage drop or power failure in the power system. .

The circuit breaker 35 has a function of separating the private generator-side bus 1 from the power supply system-side bus 7 when the voltage of the power system detected by the power failure detecting means 36 drops.

The uninterruptible power supply 10 includes a forward converter 11,
It has an inverter 12 and a storage battery 14. Storage battery 1
4 must have a capacity to supply power to the most important load 41 at least from the time when a power failure occurs in the power system to the time when the private generator 21 starts supplying power.

The operation of the above-described power supply system when a power failure occurs in the power system will be described with reference to FIG. FIG. 6A shows the state of the power system, and FIG.
6 (C) shows the operating state of the generator 21.
FIG. 6D shows the most important load 4 connected to the uninterruptible power supply.
6 (E) shows the state of power supply to the important load 42 not connected to the uninterruptible power supply.

When a power failure occurs in the power system in the normal state at time t1, the power failure detection circuit 36 detects this power failure and releases the circuit breaker 35, and at time t2, the power supply from the system side bus 7 to the private generator side The operation of separating the bus 1 ends.

As shown in FIG. 2B, from time t1 to time t
During 2, the circuit breaker is in the ON state. As shown in (C), the diesel engine 23 that has received a power failure occurrence signal (startup command) from the power failure detection circuit 36 at time t1 executes startup processing and starts operation.
Becomes the operating state. As shown in (D), the most important load 4
1, power is supplied from the power system through the uninterruptible power supply 10 until time t1, and backup power is supplied from the storage battery 14 of the uninterruptible power supply 10 from time t1 to time t3. Done. At time t3, the generator 2
From 1 to the most important load 41, private power supply is performed.

As shown in (E), the important load 42 includes:
Power is supplied from the power system until time t1, and power is not supplied between time t1 and time t3. At time t3, the generator 21 supplies private power to the important load 42.

In this way, when a power failure occurs in the power system, power is not supplied to the general load 43. Important load 4
In No. 2, power is not supplied from time t1 when a power failure occurs to time t3 when the private generator starts operating. On the other hand, the storage battery 14 of the uninterruptible power supply 10 is supplied to the most important load 41 from the time t1 when the power failure starts to the time t3 when the generator starts operating.
T3 when power is supplied from the generator and the generator starts operating
Thereafter, power is supplied from the private generator. Therefore,
Even if a power failure occurs in the power system, the most important load 41 can continue operation without a power failure.

However, in such a power supply system,
The time from the start of the power outage until the generator starts operating is
At least several tens of seconds to several minutes are required, and the storage battery 14 of the uninterruptible power supply 10 requires a large-capacity storage battery.
Therefore, the uninterruptible power supply 10 becomes an extremely large-scale device.

On the other hand, there has been proposed a power supply system in which a private generator is always operated and connected to a power system. In this system, when an instantaneous voltage drop or a power failure occurs on the power system side, the generator may be overloaded and stopped by the self-defense function. In particular, when the service generator is a turbine generator, the generator is stopped by breaking a shear pin attached to an output shaft of the turbine in order to protect the turbine as a driving source. When the shear pin is broken in this way, it may take several hours to recover, and it will not be possible to supply power to the load for a long time.

In order to cope with such inconveniences, when an instantaneous voltage drop or a power failure occurs on the power system side, the private generator is cut off from the power system to reduce the load and prevent the generator from stopping. However, for example, JP-A-6-339227 (instantaneous voltage drop compensating device: detects reactive power flowing out to a power system and shuts off a high-speed switch), JP-A-8-1
No. 26210 (disconnecting control device for a commercial power supply-connected private generator: high-speed disconnection from a power system by a directional short-circuit relay or an undervoltage relay).

Further, a method has been proposed in which the generator is quickly disconnected from the system before the self-protection function of the private generator works or before the shear pin breaks.

As a method of protecting the shear pin by disconnecting the generator from the system at high speed before the shear pin of the generator connected to the power system breaks, see Japanese Patent Application Laid-Open No. H5-2286.
No. 5 (Protector for small-capacity generator: Detects a decrease in power supply voltage and an increase in system interconnection point current, shuts off the circuit breaker at high speed, and reduces the speed of the small-capacity generator that supplies power to important loads. Unrecoverable or stopped situations are avoided), JP-A-6-3
No. 39300 (A generator torsion torque detection device using instantaneous power: A simple and instantaneous detection of the generator torsion torque to shut off the high-speed circuit breaker, and to connect an important load connected to the private generator side busbar) Protects the shear pin by supplying power only to the power supply), and JP-A-7-271401 (a shear pin protection device for a gas turbine generator: detecting the shaft torsion torque of the generator at high speed and cutting off the high-speed current limiting fuse. To shut off the load and protect the shear pin).

However, in these proposals, the main problem is to reduce or cut off the load on the private power generator, and it is important to keep supplying power to important loads when the instantaneous voltage drop of the power system occurs. It has not been.

In such a power supply device using a semiconductor switch to cut off the private generator connected to the electric power system at a high speed in the event of an instantaneous voltage drop or power failure and taking measures against the instantaneous voltage drop, Providing an uninterruptible power supply for supplying power to an important load has been proposed, for example, in Japanese Patent Laid-Open No. 6-296330.

Referring to FIG. 7, the configuration of a power supply system that takes measures against the instantaneous voltage drop will be described. The cogeneration system that takes measures against the instantaneous voltage drop includes a private power generator AG rotated by the engine ENG, a power system bus B1 connected to a 6.6 kV power company distribution line via a power receiving circuit breaker 52R, and a private power generator. A bus bar circuit breaker 52B1 such as a vacuum circuit breaker for connecting the bus B2 to the private power generation side connected to the generator AG via the circuit breaker 52G and the bus B1 to the bus B2.
And the instantaneous voltage drop countermeasure device 1 connected in series to the bus connection circuit breaker 52B1.

Transformers T3 to T5 are connected to the private power generating bus B2 via feeder breakers 52L3 to 52L5, and power is supplied to loads L3 to L5. The load L3 is the most important load fed from the transformer T3 via the CVCF device. A storage battery is connected to the CVCF device,
When the instantaneous voltage drop or power failure causes the instantaneous voltage drop countermeasure device 1 to operate, when the voltage of the private power generation side bus B2 drops, normal power is supplied to the most important load L3 via the CVCF device.

The instantaneous voltage drop countermeasure device 1 includes a semiconductor switch with a power fuse connected in series with the bus connection circuit breaker 52B1 and having a cutoff time within one cycle, a bypass circuit of the semiconductor switch, and a semiconductor switch. The bypass circuit is selected and connected to a circuit breaker connected in series to the bus connection circuit breaker 52B1.

Normally, the instantaneous voltage drop countermeasure device 1 is a series circuit with the bus connection circuit breaker 52B1 using a semiconductor switch.
The system is operated by connecting the power system side and the private power generation system side.

If a power failure occurs in the power system during this interconnection operation, the voltage of the private generator AG drops, and the semiconductor switch 1 of the instantaneous voltage drop countermeasure device 1 instantaneously reduces the voltage from the voltage waveform or the like. Detected and shut off within one cycle.

As described above, the power system side bus B1 is separated from the private power generation side bus B2 within one cycle from the instantaneous voltage drop by the semiconductor switch, so that the generator voltage is 73% (voltage effect 27%). , Which is improved to 16% as compared with the bus connection circuit breaker 52B1 (interruption time: 0.3 seconds).

However, in this system,
Since it usually takes about 20 milliseconds (msec) from the detection of a power failure or an instantaneous voltage drop to the disconnection of the generator from the system, the voltage of the most important load is reduced by the same amount. Become. Some information devices such as computers may cause problems even if the voltage drops by about 10% in 3 msec. For the most important load, the CVCF device can be used even with the high-speed cutoff system as described above. It is necessary to provide the uninterruptible power supply (UPS) used.

In the above-described system, since the private generator AG is constantly operating, the time during which the voltage of the most important load is reduced is limited to about 20 msec to about 0.2 sec. Therefore, the backup time of the uninterruptible power supply composed of the CVCF device is also reduced from the maximum of about 20 msec to 0.2 msec.
Limited to about seconds.

However, when a storage battery is used as the power storage means of the uninterruptible power supply, it is expected that the capacity of the power storage means is greatly reduced due to the shortened power supply time for the reasons described later. Have difficulty. That is, since power storage means such as a lead storage battery has a large internal resistance and is not suitable for large-current short-time discharge, it is necessary to connect a large number of storage batteries in parallel to supply a large current in a short time. Required.

Specifically, as shown in FIG.
When a lead storage battery is used as the power storage means of the uninterruptible power supply when backing up for one minute, the storage battery is 680 ×
It has a volume of 100 × 195 cm ³ and a weight of 12950 kg. The installation area of the uninterruptible power supply using this storage battery requires 25.44 m ² .

On the other hand, when backing up for 0.2 seconds, the storage battery can be reduced to about 75%, so that the volume of 510 × 100 × 195 cm ³ and 9700
kg. The installation area of the uninterruptible power supply using this storage battery requires 21.36 m ² and the capacity required for the power storage means is reduced to 0.07%, while the installation area is reduced by 16%. It just does.

[0036]

SUMMARY OF THE INVENTION The present invention relates to a power supply system in which a constantly operating generator is connected to a power system as described above. When the uninterruptible power supply to be supplied is provided, the installation area of the power storage means of the uninterruptible power supply is reduced, space advantages are improved, installation costs are reduced, maintenance costs are reduced, and environmentally harmful substances are not used. And the like.

[0037]

According to the present invention, there is provided a power generator connected to a power system via a high-speed cutoff system, which is always operated, and an uninterruptible power supply connected to the power generator.
In a power supply system for supplying power to a load via the uninterruptible power supply, a power storage unit having a high output density is used as a power storage unit of the uninterruptible power supply.

Further, according to the present invention, in the above power supply system, any one of a capacitor, an electric double layer capacitor, a flywheel, and a superconducting power storage is used as the power storage means of the uninterruptible power supply.

According to the present invention, in the power supply system, the high-speed cutoff system is configured as a high-speed cutoff system that detects instantaneous power and performs a shutoff operation when the instantaneous power exceeds a set value.

According to the present invention, in the above-mentioned power supply system, the uninterruptible power supply is an always-inverter-type uninterruptible power supply, an always-commercial-type uninterruptible power supply, or an SPS-type uninterruptible power supply. , A series-compensated uninterruptible power supply, or a triport uninterruptible power supply, or a parallel processing uninterruptible power supply, or a series-parallel compensated uninterruptible power supply .

[0041]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The configuration of a power supply system linked to a power system using an uninterruptible power supply according to the present invention will be described.
This will be described with reference to FIG. The power supply system shown in FIG. 1 uses a high-speed cutoff system as a circuit breaker provided between a power system and a private generator constantly connected to the power system, and has a large output density, for example, a maximum of 0. It is characterized by using an electric double layer capacitor, a flywheel, a capacitor and a superconducting power storage having a capacity of about 2 seconds.

The power supply system according to the present invention includes a private generator 21 driven by a gas turbine engine or a gas engine 22 which is constantly operating, and a private generator 21.
, The power system-side bus 7 connected to the power system 70, and the private generator-side bus 1
And a high-speed cut-off system 30 provided between the power system-side bus 7 and the uninterruptible power supply 10 connected to the private generator-side bus 1.

The uninterruptible power supply 10 is connected to the private generator side bus 1 via the feeder circuit breaker 63 and the transformer 52, so that the power supply is always maintained even at the moment of an instantaneous voltage drop of the power system 70 or a power outage. Power is supplied to the most important load 41 such as a computer that must be provided.

Further, an important load 42 to which power is supplied even at the time of an instantaneous voltage drop of the power system 70 or a power outage is connected to the private generator side bus 1 via a feeder breaker 64 and a transformer 53. I have.

The generator 21 is always operated, and supplies power to the private generator side bus 1 via the circuit breaker 61.

The power system 70 is connected to the power system side bus 7 via the power receiving transformer 51 and the circuit breaker 62.

When a power failure or an instantaneous voltage drop occurs in the power system 70, the high-speed cut-off system 30 rapidly moves from the system-side bus 7 to the private generator-side bus before the self-protection function of the generator works or before the shear pin is broken. Separate 1.

The uninterruptible power supply 10 of the present invention has a forward converter 11, power storage means 13, and an inverse converter 12. The power storage means 13 uses a capacitor, an electric double layer capacitor, a flywheel, and a superconducting power storage, which are power storage means having a large output density, instead of the storage battery. The power storage means 13 only needs to have a capacity capable of supplying power to the most important load 41 for a maximum of about 0.2 seconds.

Here, the output density of the power storage means will be described. When the uninterruptible power supply is used for a load with a large current output in a short time, the power storage means is required to have a high output density. The power density of the power storage means can be defined as the electric power per unit weight or unit volume.
The power storage means having a small internal impedance can supply a larger current, and the output represented by current × voltage can be a large output. A power storage means with a high power density means that more energy can be supplied in a short time, and is one measure of the superiority of a power storage means in a short time.

Here, a comparison of the output densities of the respective power storage means is as shown in FIG. FIG. 2A is a table showing output densities (watt / liter) of various power storage means, and FIG. 2B is a table comparing characteristics of a secondary battery, an electric double layer capacitor, and a capacitor. is there. FIG. 2 (B)
As is clear from the above, the electric double layer capacitor can output a large amount of power in a short time as compared with the secondary battery. Further, as shown in FIG. 2A, the electric double layer capacitor, the flywheel, the capacitor, and the superconducting power storage have a large output density and are suitable for extracting a large current in a short time as compared with the secondary battery. .

The configuration of the high-speed cutoff system 30 will be described.
The high-speed cut-off system 30 includes a means for sampling and detecting the instantaneous power, a means for outputting a cutoff signal when the instantaneous power exceeds the set value for three consecutive samples, and a cutoff circuit when the cutoff signal is output. It is configured to have operating means for performing the operation.

According to such a high-speed shut-off system, a shut-off signal is output in about 7.5 milliseconds, and it takes about 60 msec from the output of the shut-off signal to the shut-off of the breaker, so that the shut-off is completed in about 70 msec in total. I do.

As described above, according to the present invention, it is possible to quickly disconnect the private generator side bus from the power system side bus at the time of power failure of the power system.

Regardless of the description of the high-speed shut-off system described above, any high-speed shut-off system can be used as long as it is a high-speed shut-off system that can shut off at high speed and continuously operate the generator.

The operation of the above-described power supply system when a power failure or instantaneous voltage drop occurs in the power system 70 will be described with reference to FIG. FIG. 3A shows the state of the power system 70, and FIG. 3B shows the operation state of the high-speed cutoff system.
FIG. 3C shows the operation state of the generator 21 and FIG. 3D shows the power supply state to the most important load supplied from the uninterruptible power supply.

At the time t
When a power failure or an instantaneous voltage drop occurs in step 1, the high-speed power failure detection means of the high-speed cutoff system 30 detects this power failure or instantaneous voltage drop, shuts off the circuit breaker, and at time t2, switches from the system-side bus 7 to the private generator-side bus. The operation of separating 1 ends.

As shown in (B), from time t1 to time t
During the period 2, the circuit breaker of the high-speed cutoff system 30 is in the ON state. As a result, as shown in (C), the generator 21 begins to load the loads 41 and 42 connected to the private generator side bus 1 and the loads 43 connected to the system side bus 7 from time t1.
Then, power is supplied to the power system side, and the voltage starts to decrease rapidly. As shown in (D), interconnection power is supplied to the most important load 41 via the uninterruptible power supply 10 until time t1, and the generator 21 is connected between time t1 and time t2.
Backup power supply in which the power is supplied from the power storage means 13 to compensate for the decrease in the output. Therefore, the most important load 41 is not affected by an instantaneous voltage drop.

At time t2, when the circuit breaker of the high-speed cutoff system 30 performs the cutoff operation to separate the private generator-side bus 1 from the power system-side bus 7, the breaker is connected to the power outage power system 70 and the power system-side bus 7 The generator 21 disconnected from the disconnected general load 73 recovers the voltage and performs an independent operation. The most important load 41 and the most important load 42 connected to the in-house generator-side bus 1 are supplied with an independence power supply from the generator 21 which has started the independence operation.

At time t3, when the power failure or the instantaneous voltage drop of the power system 70 is restored, the high-speed cutoff system 30 that detects the restoration of the power system 70 synchronizes the power system-side bus 7 with the private generator-side bus 1. After confirmation, at time t4, the circuit breaker is turned on again, and the state automatically shifts to the interconnection state. As a result, the generator 21 performs the interconnection operation, and the most important load 41, the important load 42, and the general load 43 are supplied with interconnection. The power storage means 13 of the uninterruptible power supply 10 is charged with the power consumed during the backup power supply.

Referring to FIG. 4, the effect when an electric double layer capacitor (EDLC) or a flywheel is used as the power storage means used in the present invention will be described. When an electric double layer capacitor or a flywheel is used instead of the storage battery as the power storage means of the uninterruptible power supply, the size, weight, and installation area of the uninterruptible power supply 10 can be reduced. 4A shows a case where an electric double layer capacitor is used, FIG. 4B shows a case where a flywheel is used, and FIG. 4C shows a case where an uninterruptible power supply device 10 uses a storage battery. Shows the area required for installation. For the purpose of this comparison, 60 mils beside the power converter and power storage means for installation and maintenance work.
The installation area was calculated assuming that a space of 20 cm was required on the back, 20 cm on the back, and 120 cm on the front.

In any case, assuming that the power supply capacity is 500 kVA, the power converter has a size of 260 ×
The size is 100 × 195 cm and the weight is 4000 kg.

As shown in FIG. 4A, when the electric double layer capacitor has a power supply capacity of 500 kVA and a backup time of 0.2 second, the size is 91 × 100 ×
It is 195 cm and weighs 2000 kg. The total weight of an uninterruptible power supply using an electric double layer capacitor is 6000
kg. The installation area in this case is 4.7 × 2.4m
(11.28 m ² ).

As shown in FIG. 4B, when the flywheel is used as the power storage means, the power supply capacity is 5
Assuming that the backup time is 0.2 seconds, the size is 142 × 100 × 227 cm, and the weight is 60 kVA.
It becomes 00 kg. When a flywheel is used, a converter is additionally required, and its size is 55 × 13
It is 2 × 227 cm and weighs 1200 kg. The total weight of an uninterruptible power supply using a flywheel is 11200
kg. The installation area in this case is 5.77 × 2.7
2 m (15.0 m ² ).

As shown in FIG. 4C, in the conventional technique using a storage battery as the power storage means, the power converter is the same as described above, the power supply capacity is compensated for 500 kVA, and the backup time is set to 0.2. In seconds, the battery is 5
It is 10 × 100 × 195 cm and weighs 9700 kg. The total weight of an uninterruptible power supply using a storage battery is 137
It becomes 00 kg. The installation area in this case is 8.9 × 2.
4 m (21.36 m ² ).

In FIG. 4C, a broken line indicates an uninterruptible power supply when the emergency generator shown in FIG. 5 is used.
Power storage as power storage means 680 × 100 × 195c
m, weight becomes 12950 kg. The total weight of the uninterruptible power supply using the storage battery is 16950 kg. The installation area in this case is 10.6 × 2.4 m (25.44
m ² ).

Comparing the three, when the electric double layer capacitor is used, the installation area is 5 times that when the storage battery is used.
It was 2.8%, which enabled a significant space saving and reduced the total weight of the uninterruptible power supply to 66.1%. In addition, when the flywheel is used, the installation area is 7 compared with the case where the storage battery is used.
The weight was reduced to 0.2%, so that it was possible to significantly save space and reduce the total weight to 57.2%. Further, the weight of the power storage means is 20.6% in the case of the electric double layer capacitor as compared with the case of the storage battery.
Therefore, it is extremely lightweight, and the amount of work for installation and replacement can be greatly reduced.

In a system in which interconnected operation is enabled by using a high-speed cutoff system, a storage battery having a large internal resistance and a small output density can be used as an uninterruptible power supply as compared with a case using an emergency generator. When using an electric double layer capacitor having a large output density, the installation area is reduced to 84.0% and the total weight is reduced to 80.8%. 0.3%, total weight 35.
4%, and when using a flywheel, the installation area is reduced to 59.0% and the total weight is reduced to 66.1%.
The effect is extremely excellent as compared with the storage battery.

As the circuit system of the uninterruptible power supply system, a continuous inverter system, a continuous commercial system, an SPS (Standby
A power supply system, a series compensation system, a triport system, a parallel processing system, a series-parallel compensation system, and the like are already known, and these circuit systems can be used in the above-described power supply system. The present invention
It goes without saying that any circuit system other than these circuit systems can be used as long as it is a circuit system that compensates for a sag or power failure.

[Continuous Inverter System] As shown in FIG. 8, the continuous inverter uninterruptible power supply 10 includes a power storage unit 13 and an inverter 1 on the DC side of a converter 11.
2 are connected in parallel and inserted between a commercial power supply input and an important load, and a semiconductor switch 15 is inserted in parallel with these connecting bodies. In the continuous inverter type uninterruptible power supply, the converter 11 converts the input AC voltage into DC in a steady state, a part of the converted DC power charges the power storage unit 13, and most of the converted DC power is used in the inverter 1
The power is converted into an alternating current by the power supply 2 to supply power to an important load such as a computer. Inverter 12 is operated in synchronization with the input voltage. When a power failure or momentary voltage drop occurs on the commercial power supply side, the power stored in the power storage means 13 is converted into AC by the inverter 12 without power interruption, and power is supplied to the important load. In the case of an overload exceeding the capacity of the inverter 12 or the power storage means 13, the semiconductor switch 15 is turned on to supply the input voltage to the important load. At this time, the inverter 12
Is synchronized with the input voltage, so there is no instantaneous interruption.

[Continuous Commercial System] As shown in FIG. 9, an uninterruptible power supply 10 of a regular commercial system has a power storage means 13 and an inverter 12 connected in parallel to a DC side of a converter 11 and an AC output side of the inverter. Semiconductor switch 16
Is connected between a commercial power supply input and an important load, and a power supply input is configured via a semiconductor changeover switch 16 in parallel with these connectors. The continuous commercial uninterruptible power supply 10 supplies power to an important load from an input via a semiconductor changeover switch 16 in a steady state. The charging of the power storage means 13 is performed by the converter 11.
It is done by. When a power failure or a momentary voltage drop occurs on the commercial power supply side, it is detected and the semiconductor changeover switch 16 is switched to the inverter 12 side. After the switching operation, the power of the power storage means 13 charged in the normal state is
In step 2, the power is converted into AC and power is supplied to the important load.

[SPS (Standby Power Supply) method]
As shown in FIG. 10, the SPS uninterruptible power supply 10
Is a semiconductor switch 1 between the commercial power input and the critical load.
5, and a power storage unit 13 is connected to the important load side of the semiconductor switch 15 via a bidirectional converter 111. The SPS uninterruptible power supply 10 has a semiconductor switch 15
Are conducting, and power is supplied to the important load from the commercial power supply input. The charging of the power storage means 13 is performed by the bidirectional converter 111. When a power failure or an instantaneous sag occurs on the commercial power supply side, it is detected and the semiconductor switch 1 is detected.
5, the bidirectional converter 111 is switched from the current control mode to the voltage control mode, and a rated voltage is supplied to the important load. After the switching operation, the important load is converted into AC by the bidirectional converter 111 switched to the voltage control mode, and the power is supplied to the important load.

[Series Compensation System] As shown in FIG. 11, the uninterruptible power supply 10 of the series compensation system includes one of a series transformer (injection transformer) 171 between a commercial power supply input and an important load.
A secondary winding is inserted in series, and a converter 11 is inserted in parallel with a commercial power supply input. A power storage means 13 and an inverter 12 are connected in parallel to the DC side of the converter 11. The side is connected to the secondary winding of the series transformer 171, and the semiconductor switch 15 is inserted in parallel with the primary winding of the series transformer 171. Series-compensated uninterruptible power supply
In this method, the energy for the voltage compensation is stored in the power storage means 13 and the shortage voltage is compensated for in series with the power supply line via the inverter 12 at the momentary voltage drop. Normally, a semiconductor switch (thyristor switch) 15 supplies power from a commercial power supply to an important load, and a converter (rectifier) 1
1, energy is stored in the power storage means 13 and the inverter 12 is stopped. When a voltage sag occurs, a voltage drop is detected and the thyristor switch 15 is turned off.
The inverter 12 is started. Since the inverter 12 generates a voltage drop in series with the commercial power supply through the series transformer (injection transformer) 171, the rated voltage is applied to the load.

[Triport System] As shown in FIG. 12, the uninterruptible power supply 10 of the triport system has a power storage unit 13 and an inverter 12 on the DC side of the converter 11.
Are connected in parallel to a constant voltage transformer 18 composed of a transformer for an iron resonance circuit having a commercial power input terminal and two input terminals.
1, a semiconductor switch (thyristor switch) 15 is connected between the commercial power supply input and another input terminal of the constant voltage transformer 181 having two input terminals, and the output of the constant voltage transformer 181 is filtered. 19 and output stabilizer 19
1 are connected. In the triport type uninterruptible power supply 10, the output of the inverter 12 and the commercial power supply are operated in parallel in the constant voltage transformer 181, and the power is always supplied from the commercial power supply to the output. When the commercial power supply fails, the semiconductor switch 15 on the commercial power supply side is turned off, and power is supplied from the inverter 12. The constant voltage control of the output is performed in the ferroresonant circuit.

[Parallel Processing System] As shown in FIG. 13, the uninterruptible power supply 10 of the parallel processing system comprises a series connection of a semiconductor switch (thyristor switch) 15 and a reactor 18 between a commercial power supply input and an important load. And a filter 19, a bidirectional converter 111, and a power storage means 13 are connected in parallel between the reactor 18 and the important load. The uninterruptible power supply 10 of the parallel processing system always operates the output of the bidirectional converter 111 in parallel with the commercial power supply to perform constant voltage control of the output, or charges the power storage means 13 with the bidirectional converter 111. The battery charger is unnecessary, and multi-functionality is being achieved. The reactor 18 is inserted into the commercial power
While controlling the reactive power with and performing constant voltage control of the output,
The active power is also controlled to charge the power storage means 13, and a charger is not required. When the commercial power supply sags or loses power, the semiconductor switch 15 on the commercial power supply side is turned off to switch the bidirectional converter 111 from the current control mode to the voltage control mode. Converter 111 supplies constant power of a rated voltage.

[Serial / Parallel Compensation Method] As shown in FIG.
The uninterruptible power supply 10 of the series-parallel compensation system has a primary winding of a series transformer 171 inserted in series between a commercial power input and an important load, and a parallel connection between the commercial power input and the series transformer 171. The primary winding of the transformer 172 is inserted in parallel, and the secondary winding of the parallel transformer 172 is connected to the bidirectional converter 111.
1 is connected in parallel with the power storage means 13 and the inverter 12, the AC output side of the inverter 12 is connected to the secondary winding of the series transformer 171, and the primary winding of the series transformer 171. The semiconductor switch 15 is inserted in parallel with the line. The uninterruptible power supply 10 of the series-parallel compensation system always operates the inverter 12 in a normal state, generates an excess or deficiency of the input voltage in the inverter 12, and applies the voltage to the input voltage in series via the series transformer 171. Thus, power with a constant rated voltage is supplied to the important load. That is, when the input voltage is insufficient, the insufficient voltage is generated by the inverter 12 and the series transformer 171 is used.
Power is supplied at a constant rated voltage to the important load in addition to the input voltage in series via the. Then, the insufficient power is output from the inverter 12. This power is supplied by converting the input voltage into direct current by a bidirectional converter 111 connected in parallel to the input. Conversely, when the input voltage is excessive, the inverter 12 operates so as to reduce the excess in series via the series transformer 171. Then, excess power flows into the inverter 12. This power is regenerated by converting a DC voltage into an AC voltage to the input by a bidirectional converter 111 connected in parallel to the input. The charging of the power storage means 13 is performed by converting the input voltage into direct current by the bidirectional converter 111. When a momentary voltage drop occurs on the commercial power supply side, the shortage of voltage is
The inverter 12 operates to apply the voltage in series to the input voltage via 71. Then, the shortage power is converted to inverter 1
2 output. This electric power is supplied from the electric power storage means 13 which is charged in a steady state. At the time of overload, the semiconductor switch 15 is turned on to supply the voltage of the commercial power supply input to the important load. At this time, since the inverter 12 is synchronized with the input voltage, no instantaneous interruption occurs.

The uninterruptible power supply 10 shown in FIGS.
Can be used as the uninterruptible power supply of the power supply system shown in FIG. 1, and in any case, as in the case of FIG. Can use either wheels or superconducting power storage,
The same effect as in the case of FIG. 1 can be obtained.

[0077]

The uninterruptible power supply system according to the present invention operates the generator constantly in connection with the power system 70 and employs the high-speed cut-off system 30 to drive the engine that drives the emergency generator during a power failure. Since there is no need to start, the power storage means constituting the uninterruptible power supply only needs to have a capacity of about 0.2 seconds at the maximum, which is compared with the conventional uninterruptible power supply using a storage battery. Itself
The size and weight can be reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating an outline of a configuration of an uninterruptible power supply system according to the present invention.

FIG. 2 is a table illustrating energy density characteristics of a secondary battery, an electric double layer capacitor, and the like.

FIG. 3 is a time chart illustrating an operation when a power failure or an instantaneous voltage drop occurs in the power system in the uninterruptible power supply system according to the present invention.

FIG. 4 is a diagram for comparatively explaining the installation area of the uninterruptible power supply.

FIG. 5 is a block diagram illustrating an outline of a configuration of a conventional uninterruptible power supply system.

FIG. 6 is a time chart illustrating an operation when a power failure occurs in a power system in a conventional uninterruptible power supply system.

FIG. 7 is a block diagram illustrating an outline of a configuration of a conventional system interconnection uninterruptible power supply system.

FIG. 8 is a block diagram illustrating the configuration of a continuous inverter type uninterruptible power supply that can be used in the uninterruptible power supply according to the present invention.

FIG. 9 is a block diagram illustrating a configuration of an uninterruptible power supply of an always commercial system that can be used in the uninterruptible power supply according to the present invention.

FIG. 10 is a block diagram illustrating a configuration of an SPS uninterruptible power supply that can be used in the uninterruptible power supply according to the present invention.

FIG. 11 is a block diagram illustrating a configuration of a series-compensated uninterruptible power supply that can be used in the uninterruptible power supply according to the present invention.

FIG. 12 is a block diagram illustrating a configuration of a triport type uninterruptible power supply that can be used for the uninterruptible power supply according to the present invention.

FIG. 13 is a block diagram illustrating a configuration of a parallel processing type uninterruptible power supply that can be used in the uninterruptible power supply according to the present invention.

FIG. 14 is a block diagram illustrating a configuration of a series-parallel compensation type uninterruptible power supply that can be used in the uninterruptible power supply according to the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 private generator side bus 7 power system side bus 10 uninterruptible power supply 11 forward converter (inverter) 12 inverter (inverter) 13 power storage means 14 storage battery 15 semiconductor switch 16 semiconductor changeover switch 17 series transformer 18 reactor 19 filter DESCRIPTION OF SYMBOLS 21 Generator 22 Gas turbine engine 23 Diesel engine 30 High-speed cutoff system 35 Circuit breaker 36 Power failure detection circuit 41 Most important load 42 Important load 43 General load 51 Power receiving transformer 52-54 Transformer 61,62 Circuit breaker 63-65 Circuit breaker for feeder 70 Power System 111 Bidirectional Converter 171 Series Transformer 172 Parallel Transformer 181 Constant Voltage Transformer 191 Output Ballast

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H02J 15/00 ZAA H02J 15/00 ZAAB

Claims (4)

[Claims] 1. A generator which is connected to an electric power system via a high-speed cutoff system and which is always operated, and an uninterruptible power supply connected to the generator, and power is supplied to a load via the uninterruptible power supply. In the power supply system for supplying power, a power storage means having a high output density is used as the power storage means of the uninterruptible power supply. 2. The power storage means of an uninterruptible power supply,
The power supply system according to claim 1, wherein one of a capacitor, an electric double layer capacitor, a flywheel, and a superconducting power storage is used. 3. The high-speed cut-off system according to claim 1, wherein the high-speed cut-off system is a high-speed cut-off system that detects instantaneous power and performs a cutoff operation when the instantaneous power exceeds a set value. Power supply system. 4. An uninterruptible power supply of an always-inverter type, an uninterruptible power supply of an always-commercial type, or an uninterruptible power supply of an SPS type, or
A series compensation uninterruptible power supply, or a triport uninterruptible power supply, or a parallel processing uninterruptible power supply, or a series-parallel compensation uninterruptible power supply. The power supply system according to any one of claims 1 to 3.