JP5434334B2 - Power generation system - Google Patents

Description

  The present invention includes a generator that generates DC power, such as a fuel cell or a gas engine, an orthogonal converter that converts the DC power of the generator into AC power, and a surplus power heater that consumes surplus power of the generator. The power generation system.

A fuel cell system, which is one of the power generation systems, includes, for example, a hydrogen generator that produces hydrogen from fuel gas, a fuel cell stack (generator) that converts the generated hydrogen into DC power, and the generated power for household use. It consists of an inverter (orthogonal transformer) for converting to AC power energy. Inverter over the DC power produced in the fuel cell once converted into DC power of a voltage higher than the voltage of the system power source by a DC-DC converter (DC voltage converter), so that interconnection in synchronism with the system power supply of AC Although it is converted, it may not be possible to maintain the interconnection due to various abnormalities (power failure, surge, etc.) on the system side, so it has a disconnection relay (disconnector) to disconnect from the system power supply in a short time .

  Further, in the conventional technology, when the disconnection relay is turned off, or when the power consumption of the power load suddenly changes and the power consumption of the power load becomes smaller than the power generation amount of the fuel cell, the power of the fuel cell is reduced. It had a surplus power heater that was temporarily consumed to heat the water in the hot water tank (see, for example, Patent Document 1).

  Similarly, in a power generator using a gas engine, when surplus power is generated, a power generation system having a surplus power heater that heats cooling water for cooling the power generator or heats hot water stored in a hot water storage tank. Has been proposed (see, for example, Patent Document 2).

JP 2007-267508 A (page 1-10, FIG. 1) JP 2008-228543 A

  The power generation system equipped with the surplus power heater as exemplified in the fuel cell system of Patent Document 1 and the gas engine power generation system described in Patent Document 2 is provided with surplus power when the surplus power heater is mounted in the manufacturing stage. If the electrical wiring connected to the heater terminal interferes with other parts and is damaged or bite, there is a possibility that the insulating property is lowered. Further, the surplus power heater itself usually has an insulating structure, but this insulating structure may be destroyed by damage during mounting.

  On the other hand, when conducting a withstand voltage test on a power generation system, it is normal to apply a high voltage from a power supply inlet provided in the power generation system to confirm that insulation is ensured. Until the power generation operation starts, the disconnection relay is opened, and the communication of the electrical circuit between the system power supply and the inverter is cut off, so the surplus power heater provided in the electrical circuit upstream from the disconnection relay No voltage is applied. Therefore, it was difficult to confirm that no deterioration in insulation occurred in parts related to the surplus power heater (such as electrical wiring connected to the surplus power heater) even when the above test was performed.

  The present invention solves the above-described conventional problems, and when an insulation withstand voltage test is performed on a power generation system in which a surplus power heater is mounted, a decrease in insulation occurs in parts related to the surplus power heater. An object is to provide a power generation system capable of confirming that the power generation has not occurred.

In order to solve the above problems, a power generation system of the present invention includes a generator, an orthogonal transformer that converts DC power output from the generator into AC power, an output side of the orthogonal converter, and a connection point. A disconnector for disconnecting the connection between the orthogonal transformer and the system power supply, and an excess power heater connected to an electrical circuit upstream from the disconnector and consuming surplus power of the generator The disconnector is configured to be disconnected when the connection with the system power supply is interrupted during power generation by the generator, and is in a non-power generation of the generator and the system When the energization from the power source to the disconnector is off, it is configured to be closed.

  According to such a configuration, the disconnector is turned on while the power supply from the system power supply to the power generation system is off, that is, the circuit between the system power supply and the surplus power is in communication, so The test makes it possible to confirm whether or not insulation failure has occurred due to damage to the electrical wiring connected to the terminals of the surplus power heater, damage to the insulation structure of the surplus power heater, or the like.

  In the power generation system of the present invention, the orthogonal transformer includes a power circuit that controls the power generation output of the generator, a controller that controls the power circuit and performs pulse output, and a pulse output of the controller. An abnormality detection circuit for detecting an abnormality, and a drive circuit for energizing the disconnector to disconnect the disconnector, wherein the drive circuit receives (i) a disconnection signal from the controller And (ii) When the abnormality detection circuit detects an abnormality in the pulse output from the controller, at least one of the disconnection devices is energized.

  According to this configuration, when the microcomputer of the quadrature converter runs out of control, the disconnector turns off and is disconnected from the system power supply due to the stop of the pulse signal. It is possible to configure a system that is supplied to the power load of the power source and does not lead to an extended accident that destroys the external power load and that is safer than before.

According to the power generation system of the present invention, the disconnecting relay is turned on when the generator is not generating power and the energization from the system power supply to the disconnector is turned off. Insulation withstand voltage test is performed in the ON state, and it is checked whether insulation failure has occurred due to damage due to breakdown of surplus power heater or biting of electric wiring connected to the terminal of surplus power heater It becomes possible.

Block diagram of the power generation system in Embodiment 1 of the present invention Block diagram of a power generation system according to Embodiment 2 of the present invention

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a block diagram of a power generation system according to Embodiment 1 of the present invention. As shown in FIG. 1, a power generation system according to the present embodiment includes a generator 1 that generates DC power and a DC-DC converter 2 that is a first DC voltage converter that boosts DC power of the generator 1. And an inverter 3, which is an orthogonal converter that converts DC power output from the DC-DC converter 2 into AC power, and an electric circuit upstream from the connection point 16 with the system power supply 5. A disconnecting relay 4 serving as a disconnecting device for interrupting an electric circuit between the power source 5 and a second DC voltage converter that takes out power from the downstream of the DC-DC converter 2 and supplies power to the surplus power heater 8. The DC-DC converter 6, the electrical wiring 7 that electrically connects the output side of the DC-DC converter 6 and the terminal of the surplus power heater 8, the surplus power heater 8 that is connected to the electrical wiring 7, and the DC -DC The controller 10 that controls the inverter 2, inverter 3, disconnecting relay 4, and DC-DC converter 6, the AC detection circuit 13 that detects the voltage of the system power supply 5, and the equipment that constitutes the power generation system are housed inside. And a housing 17 to be provided. The generator 1 may be any generator that generates DC power, such as a fuel cell,
Examples include gas engine generators.

  Here, the inverter body 9 includes the DC-DC converter 2, the inverter 3, the disconnecting relay 4, the DC-DC converter 6, the controller 10, and the AC detection circuit 13. Further, the controller 10 controls the DC-DC converter 2 to boost the DC power from the fuel cell 1 to a peak voltage or higher of the system power supply, and further, the DC power boosted by the DC-DC converter 2 is increased to AC. DC-AC conversion is performed so that the voltage of the system power supply detected by the detection circuit 13 is synchronized by PWM control. Then, the AC power converted by the inverter 3 is supplied to the power load 15 outside the power generation system.

  Further, when the controller 10 detects an abnormality in the power generation system, the controller 10 controls to disconnect the disconnect relay 4 and disconnect the connection between the inverter 3 and the system power supply 5. Specifically, in the power generation system of this embodiment, the disconnecting relay 4 has a normal on terminal, a normal off terminal, a common terminal, and a coil terminal (not shown), and the normal on terminal is turned off by energizing the coil terminal. Normally, the OFF terminal is configured to be switched on. However, if the system power supply 5 becomes abnormal, such as a power failure, and the inverter 3 and the system power supply 5 need to be disconnected, the controller 10 An energization signal is output to the coil terminal of the column relay 4 to turn off the normally-on terminal and turn on the normally-off terminal. The disconnecting relay 4 is provided for each of the two poles. When the inverter 3 and the system power supply 5 are connected, both relays are turned on, and the connection between the inverter 3 and the system power supply 5 is cut off. In this case, both relays are configured to be in an off state (a so-called double cut state).

  In the manufacturing stage of the power generation system having the above-described configuration, after the surplus power heater 8 is mounted and the constituent devices of the power generation system are housed in the casing 17, a dielectric strength test is usually performed. Here, since the electric power from the system power supply is not introduced into the inside through the power supply inlet (not shown) of the power generation system before the dielectric strength test, the controller 10 supplies the coil terminal to the coil terminal. Energization is not performed, and the disconnection relay is always on. Specifically, the common terminal and the normally-on terminal are in a relay connection state. In this state, the withstand voltage test is performed by grounding the casing 17 and applying a test voltage (for example, 1500 V) higher than the voltage of the system power supply to the power supply inlet. At this time, since a high voltage is applied to the surplus power converter 6 and the power wiring 7 via the disconnection relay 4, the electrical wiring 7 connected to the terminal of the surplus power heater 8 is sandwiched when the surplus heater 8 is mounted. It is possible to confirm whether or not there is an insulation failure due to damage such as coating breakage caused by the damage or damage to the insulation structure of the surplus power heater 8.

(Embodiment 2)
FIG. 2 is a block diagram of a power generation system according to Embodiment 2 of the present invention. In FIG. 2, the same reference numerals are given to the configurations as in the power generation system of the first embodiment. Power generation system of the first embodiment, the inverter-3, the controller (microcomputer) 10, a power circuit for converting DC power inputted from the DC-DC converter 2 under the control of the controller 10 to the AC by PWM switching 12, an FV conversion circuit 11 that is an abnormality detection circuit that detects an abnormality of a pulse signal input from the controller 10, an AC detection circuit 13 that detects a voltage from the system power supply 5, and an input signal from the controller 10 And an OR circuit 14 for outputting a signal based on an inverted signal of the input signal from the FV conversion circuit 11.

In the power generation system having the above configuration, the controller 10 controls the power circuit 12 to synchronize with the AC voltage of the system power supply 5 based on the voltage of the system power supply detected by the AC detection circuit 13, and the DC-DC converter 2. The DC power input to the power circuit 12 is converted into AC power. Further, the controller 10 outputs a disconnection signal (Hi signal) to the OR circuit 14 when a system abnormality such as a power failure occurs. On the other hand, the controller 10 converts the pulse signal into the FV conversion circuit 1.
Output to 1. The FV conversion circuit 11 transmits the Hi signal to the OR circuit 14 when the frequency of the pulse signal is equal to or higher than a predetermined threshold, and the OR circuit 14 is input via an inverting circuit.

Therefore, the OR circuit 14 receives the disconnection signal (Hi signal) from the microcomputer 10 or turns off the disconnection relay 4 when the pulse signal of the controller 10 falls below a predetermined threshold. Here, the case where the pulse signal output from the controller 10 is less than a predetermined threshold is defined as the case where the pulse signal output from the controller 10 is abnormal. For example, when the controller 10 runs out of control. An abnormality appears as a decrease in the frequency of the pulse signal. Further, when the controller 10 runs away, the power circuit 12 is abnormally controlled, for example, a very high voltage power is supplied to the power load 15 outside the power generation system connected to the system power supply 5, and the power load 15 In the power generation system configured as described above, an abnormality (for example, runaway) of the controller 10 is detected by the FV conversion circuit 11, and the disconnect relay 4 is turned off. because it is configured, it is possible to protect the power system outside the power load from the abnormality of the controller 10 in the inverter-3.

  The power generation system of the present invention confirms whether insulation failure has occurred due to dielectric breakdown of the surplus power heater or damage due to biting of the electric wiring connected to the terminal of the surplus power heater, etc., by a dielectric strength test. Therefore, it is useful as a power generation system for business use and home use.

1 generator 2 DC-DC converter 3 inverter over <br/> 4 parallel off relay 5 system power supply 6 DC-DC converter 7 electric wiring 8 surplus power heater 9 inverter main body 10 controller 11 FV converting circuit 12 power circuit 13 AC detection Circuit 14 OR circuit 15 Power load 16 Connection point 17 Case

Claims (2)

A generator, a quadrature converter for converting the DC power output from the generator into AC power, provided path between the output side and the connecting point of the orthogonal transformer, said orthogonal transformer and the system A disconnector that cuts off the connection with the power source, and a surplus power heater that is connected to an electrical circuit upstream from the disconnector and consumes surplus power of the generator,
The disconnector is configured to be disconnected when the connection with the system power supply is interrupted during power generation by the generator, and the disconnector is in the non-power generation of the generator and from the system power supply. A power generation system configured to be closed when the power to the row is off . The orthogonal transformer includes a power circuit that controls the power generation output of the generator, a controller that controls the power circuit and performs pulse output, and an abnormality detection circuit that detects an abnormality in the pulse output of the controller, A drive circuit for energizing the disconnector to disconnect the disconnector;
The drive circuit is
(I) When a disconnection signal is received from the controller, and (ii) When an abnormality in pulse output from the controller is detected by the abnormality detection circuit,
Power generation system of the at least one, for energizing the disconnection device, according to claim 1, wherein.

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