JP3923738B2 - Control power supply mechanism for inverter inspection - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an inverter inspection control power supply mechanism to a power generator for power supply in which a generator for supplying power via an inverter is arranged.
[0002]
[Prior art]
Conventionally, a configuration in which electric power generated by a generator is supplied to a load via an inverter is known. And what supplies all the power supplies including the control power supply of an inverter from a generator is known. Or what equips a power generator with a battery is also known. For example, as shown in Japanese Patent Application Laid-Open No. 9-163635, when a power failure occurs, the power failure detection sensor detects a power failure, starts a 20-minute downcount, supplies power with a battery, and then starts the engine. More power is supplied. And the power supply is always supplied from the battery to the control circuit of the power generator.
[0003]
[Problems to be solved by the invention]
Since the control power supply of the inverter cannot be secured when the generator is stopped, the failure information held by the inverter cannot be read. In addition, various settings using the operation display section of the inverter cannot be made. In a state where fuel is not supplied to the generator, electric power cannot be supplied to the inverter control unit. The same applies to the case where power is not supplied from the battery.
[0004]
In general, the fuel of the generator is a combustible material, and transportation is not performed in a state where the fuel is put into the generator. This is to maintain safety during transportation, and is also a measure necessary to ensure traffic safety. And since a battery liquid is a dangerous substance also in a battery, a charging liquid is inject | poured into a battery and it is not conveyed with electric power fully stored in this battery. However, in the installation of the power generation device, when the precision equipment such as the inverter is inspected after the generator is installed, the fuel is supplied to the engine, the battery liquid is injected into the battery, and the battery is charged to some extent . And an engine is started and an inverter control part can be checked by the electric power supply of a generator. In other words, even if the wiring is connected after the installation of the power generation apparatus, the inspection of the control unit of the inverter is performed after all the settings have been made, which requires time and labor.
[0005]
[Means for Solving the Problems]
In order to solve the above problems, the present invention uses the following means.
[0006]
According to claim 1, in the inverter inspection control power supply mechanism of the power generator for the power source in which the generator (7) for supplying power via the inverter (8) is arranged, the smoothing capacitor inrush current suppression resistor (19) Inverter output is allowed to exceed the minimum voltage required for control of the inverter (8) via the switch (20) and the switch (18) that cannot supply commercial power when the generator (7) generates power. The electric power below the generated voltage is input from the commercial power supply (4) to the input side of the inverter (8) .
[0007]
According to a second aspect of the present invention, in the control power supply mechanism for inspecting the inverter according to the first aspect, the power supplied from the commercial power source (4) to the input side of the inverter (8) is converted into a direct current and input to the inverter (8). This is input downstream of the rectifier circuit (16) on the side .
[0008]
According to a third aspect of the present invention, in the control power supply mechanism for inverter inspection according to the first aspect, the switching device (20) that cannot supply the commercial power source (4) at the time of power generation is provided with the transformer (24) and the transformer (24). The electric power supplied from the commercial power supply (4) to the input side of the inverter (8) is converted into direct current after transformation, and the rectifier on the input side of the inverter (8) is replaced with a rectifier (25) connected to the output side of 24 It is input downstream of the circuit (16) .
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings. 1 is a diagram showing the overall configuration of a power supply system using a power generator, FIG. 2 is a diagram showing the configuration of a power generator, FIG. 3 is a block diagram showing the configuration of an inverter, and FIG. 4 is a control power supply configuration. FIG. 5 is a diagram showing a second embodiment of the control power supply configuration, FIG. 6 is a diagram showing a third embodiment of the control power supply configuration, and FIG. 7 is a fourth diagram of the control power supply configuration. It is a figure which shows an Example.
[0010]
The overall configuration of a power supply system using a power generator will be described with reference to FIG. The power generation system includes a power generation device 2, a commercial power source 4, and a load 5. The output of the power generator 2 is connected to the commercial power source 4. The commercial power 4 is connected to loads 5, 5, 5,. The power output side of the power generator 2, the load 5, and the commercial power supply 4 are connected to each other. Thereby, when starting the electric power generating apparatus 2 and generating electric power with this electric power generating apparatus 2, electric power is supplied to load 5,5 .... When the load amount of the loads 5, 5, and so on exceeds the output of the power generation device 2, the insufficient power is supplied from the commercial power source 4. As a result, power can be stably supplied to the loads 5, 5,.
[0011]
Further, a co-generator can be used as the power generation device 2. The co-generator has an internal combustion engine for generating heat, and a generator is driven by the internal combustion engine to produce electric power simultaneously with the heat. Cooling water is introduced into the internal combustion engine, and heat generated from the internal combustion engine by the cooling water is extracted outside. The amount of heat taken out is stored in a hot water storage tank or the like as hot water or the like. When the power generator 2 is a co-generator, power supply to the load 5 is mainly performed by the power generator 2, and the amount of power required by the load 5 exceeds the output power amount of the power generator 2. Only in this case, electric power is supplied from the commercial power supply 4 to the loads 5, 5,. As a result, hot water for hot water supply can be stored while stably generating heat, and stable power supply can be performed to the loads 5, 5,.
[0012]
It is also possible to use the power generation device 2 as an emergency power source. In this case, the loads 5, 5,... Are normally supplied with power by the commercial power source 4. And when the electric power supply of the commercial power source 4 stops, the electric power generating apparatus 2 is started and electric power is supplied to the loads 5, 5,. Thereby, it is possible to guarantee the power supply to the loads 5.
[0013]
Next, the configuration of the power generation device 2 will be described with reference to FIG. The power generation device 2 includes an engine 6, a generator 7, and an inverter 8. The engine 6 is connected to a generator 7, and the generator 7 is driven by the engine 6. In addition, it is possible to introduce cooling water into the engine 6 and extract the amount of heat generated in the engine 6 by the cooling water to the outside. An inverter 8 is connected to the generator 7, and the power output from the generator 7 is introduced into the inverter 8, and the AC output generated by the generator 7 is converted into DC power, and then the frequency is changed. Is output as controlled AC power. The inverter 8 is provided with a controller, and the controller controls the frequency of the AC power. It is also possible to connect a plurality of inverters 8 to the generator 7 and output power by the individual inverters 8.
[0014]
Next, the configuration of the inverter 8 will be described with reference to FIG. In the inverter 8, an output unit 81, a control circuit 82, a display unit 83, an operation unit 84, and a communication unit 85 are configured. Electric power that is voltage-controlled and frequency-controlled in the control circuit 82 is output from the output 81. Is. In the control circuit 82, information such as the operation status of the inverter 8, failure information, and accumulated operation time is accumulated, and the information accumulated in the control circuit 82 can be recognized by the display unit 83. The setting of the control circuit 82 is performed by the operation unit 84.
[0015]
Further, when a plurality of inverters 8 are linked, the communication units 85 are connected to each other and the plurality of inverters are linked and operated. Further, even when the inverter 8 is remotely operated, information of the control circuit 82 is transmitted / received via the communication unit 85 and a control signal of the inverter 8 is transmitted / received. Thereby, the inverter 8 can be remotely operated and the power generator 2 can be controlled in a remote place.
[0016]
Next, a first embodiment of the control power supply configuration will be described. As shown in FIG. 4, a rectifier 16 is connected to the generator 7 via a circuit breaker 15. An inverter 8 is connected to the rectifier 16. The AC power from the generator 7 is converted into a DC current by the rectifier 16 and is converted into an AC current by the inverter 8 connected to the rectifier 16. The electric power output from the inverter 8 is supplied to the electric wire of the commercial power supply 4 through the circuit breaker 17. Thereby, electric power is supplied to the load 5 through the electric wire of the commercial power source 4.
[0017]
And the connection terminal on the coil side of the relay switch 20 is connected to the wiring between the generator 7 and the circuit breaker 15. One of the switch side terminals of the relay switch 20 is connected to the wiring between the circuit breaker 15 and the rectifier 16, and the other is connected to the wiring between the inverter 8 and the circuit breaker 17. One end of a switch 18 is connected to the wiring between the inverter 8 and the circuit breaker 17, and the other end of the switch 18 is connected to the wiring between the circuit breaker 15 and the rectifier 16 through a resistor 19. is there.
[0018]
That is, the rectifying unit 16 in the power generation output unit or the inverter is connected via the resistor 19 that is a smoothing capacitor inrush current suppression resistor, the relay 20 that is a switching device that cannot supply commercial power supply during generator power generation, and the switch 18. The commercial power supply 4 is input to the previous stage.
[0019]
In such a configuration, when the switch 18 is turned on while the generator 7 is not driven, a current is supplied from the commercial power source 4 to the wiring between the circuit breaker 15 and the rectifier 16. Note that the switch side of the relay switch 20 is in the on state. The electric power supplied from the commercial power source 4 is converted into a direct current by the rectifier 16 and supplied to the inverter 8. The inverter 8 is configured not to output an alternating current when there is no specified power supply. The electric power supplied to the inverter 8 through the resistor 19 activates the control circuit in the inverter 8 to check the inverter 8.
[0020]
That is, when inspecting the power generation device 2, it is possible to supply power to the inverter 8 without driving the generator 7 by contacting the switch 18 and to inspect the inverter 8. is there. When the generator 7 is driven, a current flows to the coil side of the relay switch 20, and the connection on the switch side of the relay switch 20 is disconnected. Thereby, in the state where the generator 7 is driven, power is not supplied from the commercial power source 4 to the inverter 8, and the inverter 8 can be inspected by the power supplied from the generator 7. Is possible.
[0021]
By making the switch 18 an automatic return switch such as a push switch, power is supplied to the inverter 8 only when the switch 18 is being pressed, and forgetting to turn off the switch 18 can be avoided. Further, the switch 18 can be a timer switch. Once the switch 18 is connected, power is supplied to the inverter 8 only during inspection by using a timer switch that is kept connected for a certain period of time.
[0022]
For example, when a timer switch that maintains a connection for 5 minutes is used as the switch 18, the operator opens the cover of the power generation device 2, turns on the switch 18, and displays information about the inverter on the display unit of the inverter 8. Let it be confirmed. And after checking a confirmation matter, the cover of the electric power generating apparatus 2 is closed and an inspection is complete | finished. Since the switch 18 is a timer switch, the connection is automatically cut off. Therefore, the operation of turning off the switch 18 can be omitted, and forgetting to turn off the switch 18 can be avoided.
[0023]
Next, a second embodiment of the control power supply configuration will be described. As shown in FIG. 5, the generator 7 is connected to the electric wire of the commercial power supply 4 through the circuit breaker 15, the rectifier 16, the inverter 8, and the circuit breaker 17. A connection terminal on the coil side of the relay switch 20 is connected to the wiring between the generator 7 and the circuit breaker 15. One of the switch side terminals of the relay switch 20 is connected to the wiring between the rectifier 16 and the inverter 8 via a diode 22. The other of the switch side terminals of the relay switch 20 is connected to one end of the AC / DC converter 21 on the DC output side via a resistor 19. The other end on the direct current output side of the AC / DC converter 21 is connected to the wiring between the rectifier 16 and the inverter 8. The AC input side of the AC / DC converter 21 is connected between the inverter 8 and the circuit breaker 17, and one end of the AC / DC converter 21 on the AC input side is connected via a switch 18.
[0024]
That is, the DC power supply is connected to the power generation output unit or the inverter through the resistor 19 which is a smoothing capacitor inrush current suppression resistor, the relay 20 which is a switching device which cannot supply commercial power when generating power, and the switch 18. This is input to a subsequent stage of the rectifying unit. In the configuration shown in FIG. 5, the switch 18 may be arranged in front of the AC / DC converter 21 so that power does not flow into the AC / DC converter 21 when not used.
[0025]
In such a configuration, when the switch 18 is turned on while the generator 7 is not driven, current is supplied from the commercial power source 4 to the AC / DC converter 21. The electric power via the AC / DC converter 21 is supplied to the wiring connecting the rectifier 16 and the inverter 8 as DC power. Note that the switch side of the relay switch 20 is turned on, and the diode 22 prevents a reverse flow of electric power input to the inverter 8. The inverter 8 can inspect the inverter 8 by operating the control circuit in the inverter 8 with the electric power supplied from the AC / DC converter 21.
[0026]
That is, when inspecting the power generation device 2, it is possible to supply power to the inverter 8 without driving the generator 7 by contacting the switch 18 and to inspect the inverter 8. is there. Further, as described above, an automatic return switch such as a push switch can be used as the switch 18.
[0027]
Next, a third embodiment of the control power supply configuration will be described. As shown in FIG. 6, the generator 7 is connected to the electric wire of the commercial power supply 4 through the circuit breaker 15, the rectifier 16, the inverter 8, and the circuit breaker 17. And the connection terminal on the coil side of the relay switch 20 is connected to the wiring between the generator 7 and the circuit breaker 15. One of the switch side terminals of the relay switch 20 is connected to the control circuit of the inverter 8 via a diode 22. The other of the switch side terminals of the relay switch 20 is connected to the battery 23 via the switch 18. Further, the control circuit of the inverter 8 is connected to the battery 23 terminal.
[0028]
A power supply circuit in the inverter circuit is connected via a diode 22 that is a reverse charge prevention diode, a relay 20 that is a switching device that cannot supply commercial power during generator power generation, and a switch 18 or a timer that is a battery power supply switch. The power source of the battery 23 is input.
[0029]
In such a configuration, when the switch 18 is turned on while the generator 7 is not driven, current is supplied from the battery 23 to the control circuit of the inverter 8. Note that the switch side of the relay switch 20 is turned on, and the diode 22 prevents the reverse flow of power input to the control circuit of the inverter 8. The inverter 8 can inspect the inverter 8 by operating the control circuit in the inverter 8 with the electric power supplied from the battery 23. Further, as described above, an automatic return switch such as a push switch can be used as the switch 18.
[0030]
Next, a fourth embodiment of the control power supply configuration will be described. As shown in FIG. 7, the generator 7 is connected to the electric wire of the commercial power supply 4 through the circuit breaker 15, the rectifier 16, the inverter 8, and the circuit breaker 17. The wiring between the inverter 8 and the circuit breaker 17 is connected to the input side of the transformer 24 via the switch 18. A rectifier 25 is connected to the output side of the transformer 24, and the rectifier 25 is connected to a wiring between the rectifier 16 and the inverter 8 via a resistor 19. The power supplied to the transformer 24 is set to be equal to or higher than the minimum control voltage of the inverter and equal to or lower than the output permission voltage of the inverter. As the transformer 24, a transformer that is connected to the commercial power source 4 and becomes a power source that is equal to or higher than the inverter control minimum voltage and lower than the inverter output permission voltage is used for the inverter 8 side. As a result, electric power for operating the inverter 8 is supplied to the preceding stage of the inverter 8 via the transformer 24.
[0031]
In such a configuration, when the switch 18 is turned on while the generator 7 is not driven, current is supplied from the commercial power source 4 to the transformer 24. The electric power transformed by the transformer 24 is supplied to the inverter 8 as DC power by the rectifier 25. The inverter 8 can inspect the inverter 8 by operating the control circuit in the inverter 8 with electric power supplied via the transformer 24. That is, when inspecting the power generation device 2, it is possible to perform the inspection without driving the generator 7 by bringing the switch 18 into contact therewith. Further, as described above, an automatic return switch such as a push switch can be used as the switch 18. Further, when the generator is generating power, the switch 18 can be always turned on by adopting a configuration in which the output voltage on the generator side becomes larger.
[0032]
【The invention's effect】
According to the first aspect of the present invention, there is provided a smoothing capacitor inrush current suppression resistor (in a control power supply mechanism for inverter inspection) of a power generator for a power source in which a generator (7) for supplying power via an inverter (8) is arranged. 19), a switching device (20) that cannot supply commercial power when the generator (7) generates power, and a switch (18) through which the inverter output exceeds the minimum voltage necessary for controlling the inverter (8). Is input from the commercial power supply (4) to the input side of the inverter (8). Therefore, when the generator is stopped, the inverter holds by securing the control power supply of the inverter. Fault information can be read and various settings using the operation display section of the inverter can be made.
Since a commercial power source is used, there is no need to perform power source maintenance, and the reliability of the power source is improved.
[0033]
As described in claim 2, the power supplied from the commercial power source (4) to the input side of the inverter (8) is converted into direct current and input to the downstream side of the rectifier circuit (16) on the input side of the inverter (8) . When the generator is stopped, by securing the control power supply of the inverter, the failure information held by the inverter is read, and various settings using the operation display unit of the inverter are made possible.
[0035]
As described in claim 3, the switch (20) that cannot supply the commercial power source (4) during power generation to the generator (7) is connected to the transformer (24) and the rectifier (25) connected to the output side of the transformer 24. Since the power supplied from the commercial power supply (4) to the input side of the inverter (8) is converted into direct current after transformation and input to the downstream side of the rectifier circuit (16) on the input side of the inverter (8). By securing the control power supply of the inverter when the machine is stopped, the failure information held by the inverter is read, and various settings using the operation display unit of the inverter are made possible. With a simple configuration, power can be supplied to the inverter circuit, and the reliability of the power supply circuit can be improved.
[Brief description of the drawings]
FIG. 1 is a diagram showing an overall configuration of a power supply system using a power generator.
FIG. 2 is a diagram illustrating a configuration of a power generation device.
FIG. 3 is a block diagram showing a configuration of an inverter.
FIG. 4 is a diagram showing a first embodiment of a control power supply configuration.
FIG. 5 is a diagram showing a second embodiment of the control power supply configuration.
FIG. 6 is a diagram showing a third embodiment of the control power supply configuration.
FIG. 7 is a diagram showing a fourth embodiment of the control power supply configuration.
[Explanation of symbols]
2 Power Generator 3 Communication Line 4 Commercial Power Supply 5 Load 6 Engine 7 Generator 8 Inverter 15 Circuit Breaker 16 Rectifier Circuit 17 Circuit Breaker 18 Switch 19 Resistance 20 Relay Switch

Claims (3)

In an inverter inspection control power supply mechanism of a power generator with a power generator that supplies power via an inverter, a smoothing capacitor inrush current suppression resistor and an open / close that disables supply of commercial power when the generator generates power A power that is equal to or higher than a minimum voltage necessary for controlling the inverter and equal to or lower than a voltage that allows inverter output is input from a commercial power source to an input side of the inverter via a device and a switch. Control power supply mechanism for inverter inspection. The inverter inspection control power supply mechanism according to claim 1, wherein the power supplied from the commercial power source to the input side of the inverter is converted into direct current and input downstream of the rectifier circuit on the input side of the inverter. Control power supply mechanism. 2. The inverter inspection control power supply mechanism according to claim 1, wherein the switchgear that disables the supply of commercial power during power generation by the generator is replaced with a transformer and a rectifier connected to the output side of the transformer, and the inverter is input from the commercial power. The inverter inspection control power supply mechanism is characterized in that the power supplied to the inverter is converted into direct current after transformation and is input downstream of the rectifier circuit on the input side of the inverter.

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