JP2005295648A - System-interconnected system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system-interconnected system which can control the increase of the number of control ports for signal output of an inverter. <P>SOLUTION: This system-interconnected system is equipped with the inverter 13 which is connected between a DC power source 11 and an AC power system 12 so as to convert the output of the DC power source 11, a first control power source 15 which supplies its control power before the system-interconnected operation of the inverter 13, a second control power source 16 which is connected to the DC side of the inverter 13 so as to supply its control power during the system-interconnected operation of the inverter 13, and a switch 14 which is connected to the AC side of the inverter 13 and interconnects it with the AC power source 12 based on the control signal S1 from a control circuit for the inverter 13 when the phase and the amplitude of the output of the inverter accord with those of the AC power system 12. The first control power source 15 is connected with the AC power system 12 via a B contact 14b which is already installed in the switch 14 and interlocks with the control signal S1 from the control circuit for the inverter 13. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a grid interconnection system, and more particularly, to a grid interconnection system provided with means for supplying control power to an inverter connected between a DC power supply and an AC power supply system and converting the output power of the DC power supply to AC. .

  For example, the power generated by a DC power source (distributed power source) such as a solar cell, a secondary battery, or a fuel cell is transmitted to an AC power consumer such as a general household connected to an AC power system via an inverter, For example, there is a grid interconnection system linked to an AC power supply system that is a commercial power source such as a single-phase three-wire system (100 V / 200 V), a three-phase three-wire system (200 V), and a single-phase two-wire system (200 V). Is shown in FIG.

  This grid-connected system is connected between a DC power supply 1 and an AC power supply system 2, and is connected to an inverter 3 (DC / AC inverter) that converts the output power of the DC power supply 1 into an AC, and an AC power supply system 2. A control power supply 5 (AC / DC power supply) that feeds the control power before system interconnection operation of the inverter 3 is connected to the AC side of the inverter 3, and the phase and amplitude of the inverter output coincide with those of the AC power supply system 2. The power converter 10 comprised with the switch 4 (electromagnetic contactor) linked | related with the alternating current power supply system 2 is comprised. In the figure, reference numeral 9 denotes a DC circuit breaker connected between the DC power source 1 and the inverter 3.

  In the grid interconnection system of FIG. 9, the control power of the inverter 3 is supplied from the AC power supply system 2 by the control power supply 5. For example, AC 200 V is converted to DC 24 V by the control power supply 5. When the DC circuit breaker 9 is closed when the DC power supply 1 is ready to start, the output power of the DC power supply 1 is AC converted by the inverter 3, and the AC output matches the phase and amplitude of the AC power supply system 2. Thus, the inverter 3 is linked to the AC power supply system 2 by closing the switch 4, and the DC power supplied from the DC power supply 1 is supplied to an AC power consumer (not shown) such as a general household on the AC side. It is trying to transmit power to. The opening / closing operation of the switch 4 is performed based on the control signal S1 from the control circuit of the inverter 3.

  However, when the control power of the inverter 3 is supplied from the AC power supply system 2 by the control power supply 5 as described above, the AC power from the AC power supply system 2 is converted into DC by the control power supply 5 and a high voltage (for example, 200 V) to a low voltage (for example, 24 V), the power loss (power conversion loss, no-load loss) in the control power supply 5 is large. Therefore, a grid interconnection system having the configuration shown in FIG. 10 is used.

  This grid interconnection system is connected between a DC power supply 1 and an AC power supply system 2, and an inverter 3 (DC / AC inverter) for converting the output power of the DC power supply 1 to AC, and a switch 7 in the AC power supply system 2. Connected to the first control power source 5 (AC / DC power source) for supplying the control power before the grid-connected operation of the inverter 3 and the DC side of the inverter 3. A second control power supply 6 (DC / DC power supply) that feeds the control power therein, and an AC power supply system connected to the AC side of the inverter 3 and the phase and amplitude of the inverter output coincide with those of the AC power supply system 2 2 is provided with a power converter 10 composed of a switch 4 (electromagnetic contactor) linked to the switch 2.

  In the grid interconnection system of FIG. 10, before the grid interconnection operation of the inverter 3, the control power of the inverter 3 is supplied from the AC power supply system 2 by the first control power supply 5, and during the grid interconnection operation of the inverter 3. The control power of the inverter 3 is supplied from the DC power source 1 by the second control power source 6.

  That is, before the system connection operation of the inverter 3, the control power of the inverter 3 is supplied from the AC power supply system 2 by the first control power supply 5, and the DC circuit breaker 9 is closed when the DC power supply 1 is ready to start. Thus, when the output power of the DC power supply 1 is AC converted by the inverter 3 and the AC output matches the phase and amplitude of the AC power supply system 2, the switch 4 is closed to connect the inverter 3 to the AC power supply system 2. The AC power is transmitted to an AC power consumer (not shown) such as a general household.

  At this time, since the DC circuit breaker 9 is closed, the inverter control power is also supplied from the DC power supply 1 by the second control power supply 6. Since the first control power supply 5 and the second control power supply 6 are connected by a diode OR circuit, control power can be supplied from both the DC power supply side and the AC power supply system side. Here, the power supply of the inverter control power by the first control power supply 5 is cut off by opening the switch 7, and only the power supply by the second control power supply 6 is performed. The opening / closing operation of the switch 4 and the switch 7 is performed based on the control signals S1 and S2 from the control circuit of the inverter 3.

  By the way, in the grid interconnection system of FIG. 9, the control power of the inverter 3 is supplied from the AC power supply system 2 by the control power supply 5 even after being linked to the AC power supply system 2 by starting the inverter 3. In the grid interconnection system of FIG. 10, when the inverter 3 is activated and linked to the AC power supply system 2, the control power of the inverter 3 by the first control power supply 5 is cut off by opening the switch 7. Like to do. As a result, power loss due to the first control power supply 5 can be eliminated.

  However, in the grid interconnection system of FIG. 10, it is necessary to provide a switch 7 for cutting off the supply of control power of the inverter 3 by the first control power supply 5 and to output a control signal S2 for opening the switch 7 from the inverter 3. There is. As a result, a control port for signal output of the control signal S2 must be provided in the inverter 3.

  Therefore, the present invention has been proposed in view of the above-described problems, and an object of the present invention is to provide a grid interconnection system capable of suppressing an increase in the signal output control port of the inverter. .

  As technical means for achieving the above-mentioned object, the present invention provides an inverter connected between a DC power supply and an AC power supply system, and converts the output of the DC power supply into AC, and before the system interconnection operation of the inverter A first control power supply for supplying control power and a second control power supply connected to the DC side of the inverter and supplying the control power during grid-connected operation of the inverter, and connected to the AC side of the inverter A system interconnection system comprising a switch that is linked to the AC power supply system based on a control signal from the inverter control circuit when the phase and amplitude of the inverter output coincides with the AC power supply system. The control power supply is connected to the AC power supply system via a B contact which is already provided in the switch and interlocks with a control signal from the inverter control circuit.

  In the grid interconnection system configured as described above, the inverter control power is supplied from the AC power supply system by the first control power supply before the inverter grid connection operation, but separately from the AC power supply system described above. When there is an arbitrary power supply system, it is also possible to supply the control power of the inverter from the arbitrary power supply system. In this case, the first control power supply is connected to an arbitrary power supply via an existing B contact in the switch. What is necessary is just to set it as the structure connected to the system | strain.

  In the grid interconnection system configured as described above, the inverter is linked to the AC power supply system by the switch when the phase and amplitude of the inverter output coincides with the AC power supply system by starting the inverter. By opening the existing B contact, the control power supply of the inverter by the first control power supply is cut off. In addition, after opening the B contact of the switch, the control power of the inverter is supplied from the DC power source by the second control power source.

  In this way, by using the B contact already provided in the switch, a switch interposed between the AC power supply system and the first control power supply is unnecessary in the conventional system, and the number of parts can be reduced and the inverter can be reduced. In this case, since the signal output control port of the switch becomes unnecessary, the increase in the signal output control port in the inverter can be suppressed.

  In addition, the present invention is an inverter connected between a DC power supply and an AC power supply system and AC-converting the output of the DC power supply, and a first control power supply for supplying the control power before system connection operation of the inverter A second control power source connected to the DC side of the inverter and supplying the control power during the grid-connected operation of the inverter, and connected to the AC side of the inverter, and the phase and amplitude of the inverter output is the AC power source system And a switch connected to the AC power supply system based on a control signal from the inverter control circuit when the first control power supply is controlled by the inverter control circuit. It is connected to an AC power supply system through a contact that opens and closes in conjunction with the switch based on a signal.

  In the grid interconnection system configured as described above, the inverter control power is supplied from the AC power supply system by the first control power supply before the inverter grid connection operation, but separately from the AC power supply system described above. When there is an arbitrary power supply system, it is also possible to supply the control power of the inverter from the arbitrary power supply system. In this case, the first control power supply is connected to the switch based on the control signal from the inverter control circuit. What is necessary is just to set it as the structure connected to arbitrary power supply systems through the contact which opens and closes interlockingly. As the contact, either A contact or B contact can be used.

  In the grid interconnection system configured as described above, the inverter is linked to the AC power supply system by a switch when the phase and amplitude of the inverter output coincides with the AC power supply system when the inverter is started. The contact of the control power of the inverter by the first control power supply is cut off by opening and closing the contact in conjunction with the switch based on the control signal from the circuit. In addition, after opening / closing of the contact linked with the switch, the control power of the inverter is supplied from the DC power source by the second control power source.

  Thus, by opening and closing the contact in conjunction with the switch based on the control signal from the inverter control circuit, the switch signal output control port of the conventional inverter becomes unnecessary, so the signal output control port of the inverter Increase can be suppressed.

  According to the present invention, the configuration using the B contact already provided in the switch eliminates the need for a switch interposed between the conventional AC power supply system and the first control power supply, and reduces the number of parts. Since the inverter does not require a switch signal output control port, an increase in the signal output control port in the inverter can be suppressed. As a result, as a means for supplying the control power of the inverter, a high-efficiency circuit configuration that eliminates the loss of the first control power supply at a low cost is possible.

  In addition, the configuration that opens and closes the contact that is linked to the switch based on the control signal from the inverter control circuit eliminates the need for a switch signal output control port in the conventional inverter, thus increasing the signal output control port in the inverter. Can be suppressed. As a result, as a means for supplying the control power of the inverter, a high-efficiency circuit configuration that eliminates the loss of the first control power supply at a low cost is possible.

  FIG. 1 shows a first embodiment of a grid interconnection system according to the present invention. The grid interconnection system in the first embodiment is connected between a DC power supply 11 and an AC power supply system 12, an inverter 13 (DC / AC inverter) that converts the output power of the DC power supply 11 to AC, and an inverter 13. A switch 14 (electromagnetic contactor) that is connected to the AC power supply system 12 when the phase and amplitude of the inverter output coincide with that of the AC power supply system 12, and the switch 14 is connected to the AC power supply system 12. And connected to the first control power supply 15 (AC / DC power supply) for supplying the control power before the grid interconnection operation of the inverter 13 and the DC side of the inverter 13. A power converter 20 configured with a second control power supply 16 (DC / DC power supply) for supplying the control power therein is provided. In the figure, reference numeral 19 denotes a DC circuit breaker connected between the DC power supply 11 and the inverter 13.

  The aforementioned switch 14 has a normally open A contact 14a and a normally closed B contact 14b. In this embodiment, the A contact 14a is connected between the AC power supply system 12 and the AC side of the inverter 13, and the B contact 14b is connected between the aforementioned AC power supply system 12 and the first control power supply 15. .

  In the grid interconnection system in the first embodiment shown in FIG. 1, before the grid interconnection operation of the inverter 13, the inverter 13 is connected to the inverter 13 by the first control power supply 15 via the B contact 14 b of the switch 14 from the AC power supply system 12. The control power is supplied, and the control power of the inverter 13 is supplied from the DC power supply 11 by the second control power supply 16 during the grid interconnection operation of the inverter 13.

  That is, before the system connection operation of the inverter 13, the control power of the inverter 13 is supplied from the AC power supply system 12 by the first control power supply 15, and the DC circuit breaker 19 is closed when the DC power supply 11 is ready to start. Thus, when the output power of the DC power supply 11 is AC converted by the inverter 13 and the AC output coincides with the phase and amplitude of the AC power supply system 12, the control signal S1 from the control circuit of the inverter 13 causes the A of the switch 14 to When the contact 14a is closed, the AC power supply system 12 is linked to transmit the AC power to an AC power consumer (not shown) such as a general household.

  At this time, since the DC circuit breaker 19 is closed, the inverter control power is also supplied from the DC power supply 11 by the second control power supply 16. Since the first control power supply 15 and the second control power supply 16 are connected by a diode OR circuit, control power can be supplied from both the DC power supply side and the AC power supply system side. Here, the power supply of the control power of the inverter 13 by the first control power supply 15 is cut off by opening the B contact 14b interlocked with the A contact 14a of the switch 14, and the power supply of the inverter control power by the second control power supply 16 is cut off. Only.

  In this way, by using the B contact 14b already provided in the switch 14, it is not necessary to connect the first control power supply 5 to the AC power supply system 2 via the switch 7 (see FIG. 10) as in the prior art. Therefore, the switch 7 is not required and the number of parts can be reduced, and it is not necessary to provide the inverter 13 with a signal output control port for the control signal S2 (see FIG. 10) for opening the switch 7. An increase in the output control port can be suppressed.

  In the grid interconnection system in the first embodiment, the control power of the inverter 13 is supplied from the AC power supply system 12 by the first control power supply 15 before the grid interconnection operation of the inverter 13. A power supply system other than the power supply system 12 may be used. FIG. 2 shows a second embodiment, and illustrates a case where there is an arbitrary power supply system 12 ′ (DCorAC power supply system) separately from the AC power supply system 12. The same parts as those of the first embodiment shown in FIG.

  In the grid interconnection system in the second embodiment, the first control power supply 15 (DC / DC power supply or AC / DC power supply) is connected to the AC power supply system 12 via the B contact 14b already provided in the switch 14. It is configured to be connected to an arbitrary power supply system 12 ′ installed separately. In this case, before the system connection operation of the inverter 13, the control power of the inverter 13 is supplied from the arbitrary power supply system 12 ′ by the first control power supply 15 through the B contact 14 b of the switch 14, and the system of the inverter 13 is supplied. During the interconnection operation, the control power of the inverter 13 is supplied from the DC power supply 11 by the second control power supply 16.

  That is, before the system connection operation of the inverter 13, the control power of the inverter 13 is supplied from the AC power supply system 12 by the first control power supply 15, and the DC circuit breaker 19 is closed when the DC power supply 11 is ready to start. Thus, when the output power of the DC power source 11 is AC converted by the inverter 13 and the AC output of the inverter 13 coincides with the phase and amplitude of the AC power source system 12, the control signal S1 from the control circuit of the inverter 13 causes the A contact. It connects with AC power supply system 2 via 14a.

  Here, by opening the B contact 14b interlocked with the A contact 14a of the switch 14, the control power supply of the inverter 13 from the arbitrary power system 12 'by the first control power supply 15 is interrupted, and the second control Only the control power supply of the inverter 13 from the DC power supply 11 by the power supply 16 is performed.

  In this way, by using the B contact 14b already provided in the switch 14, the switch 7 (see FIG. 10) interposed between the control power supply 5 and the AC power supply system 2 is not required, and the number of parts is reduced. In addition, since it is not necessary to provide the inverter 13 with a signal output control port for the control signal S2 that opens the switch 7, an increase in the signal output control port of the inverter 13 can be suppressed.

  In the first and second embodiments described above, the case where the B contact 14b of the switch 14 is connected to the AC power supply system 12 or the arbitrary power supply system 12 ′ has been described. The configuration as shown in the third to sixth embodiments shown may be used.

  In the third embodiment shown in FIG. 3, two A contacts 14a and 14a ′ are provided, and one A contact 14a connected between the inverter 13 and the AC power supply system 12 is linked to the other A contact 14a ′. A switch 14 'that is connected to the AC power supply system 12 and the first control power supply 15, and a B contact 14b' connected to the A contact 14a 'of the switch 14'. The switch 14 ″ is used in conjunction with the switch.

  The switch 14 'closes the A contact 14a and closes the A contact 14a' linked to the A contact 14a based on the control signal S1 from the control circuit of the inverter 13, and the switch 14 '' The B contact 14b 'is opened in conjunction with the 14' A contact 14a '. FIG. 7 shows a specific circuit configuration for explaining the interlocking between the switch 14 'and the switch 14' '.

  In the grid interconnection system in the third embodiment, before the grid interconnection operation of the inverter 13, the inverter 13 is connected to the inverter 13 by the first control power supply 15 from the AC power supply system 12 through the B contact 14 b ′ of the switch 14 ″. The control power is supplied, and the control power of the inverter 13 is supplied from the DC power supply 11 by the second control power supply 16 during the grid interconnection operation of the inverter 13.

  That is, before the system connection operation of the inverter 13, the control power of the inverter 13 is supplied from the AC power supply system 12 by the first control power supply 15, and the DC circuit breaker 19 is closed when the DC power supply 11 is ready to start. Thus, the output power of the DC power supply 11 is AC converted by the inverter 13, and when the AC output of the inverter 13 matches the phase and amplitude of the AC power supply system 12, the switch 14 is controlled by the control signal S 1 from the control circuit of the inverter 13. When one A contact 14a of 'is closed, the AC power supply system 12 is connected.

  Here, the other A contact 14a ′ linked to one A contact 14a of the switch 14 ′ is closed, and further, the B contact of the switch 14 ″ linked to the other A contact 14a ′ of the switch 14 ′. By opening 14b ', the control power supply of the inverter 13 by the first control power supply 15 is cut off, and the control power supply of the inverter 13 by the second control power supply 16 is only supplied.

  Moreover, in 4th embodiment shown in FIG. 4, it has A contact 14a and B contact 14b ', and the other B contact 14b' is connected to one A contact 14a connected between the inverter 13 and the alternating current power supply system 12. And a switch 14 'that is linked to the AC power supply system 12 and the first control power supply 15. The contact A is connected to the contact B 14b' of the switch 14 '. A switch 14 ″ is used in which 14a ′ is interlocked.

  Since the B contact 14 b ′ of the switch 14 ′ is closed, the A contact 14 a ′ of the switch 14 ″ is in a closed state. Accordingly, the switch 14 'closes the A contact 14a and opens the B contact 14b' linked to the A contact 14a based on the control signal S1 from the control circuit of the inverter 13, and the switch 14 '' The A contact 14a ′ is opened in conjunction with the B contact 14b ′ of the switch 14 ′. FIG. 8 shows a specific circuit configuration for explaining the interlocking between the switch 14 'and the switch 14' '.

  In the grid interconnection system according to the fourth embodiment, since the B contact 14b ′ of the switch 14 ′ is closed, the A contact 14a ′ of the switch 14 ″ is in a closed state. Before the grid interconnection operation, the control power of the inverter 13 is supplied from the AC power supply system 12 by the first control power supply 15 through the A contact 14a ′ of the switch 14 ″, and the inverter 13 is in the grid interconnection operation. The DC power supply 11 supplies the control power of the inverter 13 from the second control power supply 16.

  That is, before the system connection operation of the inverter 13, the control power of the inverter 13 is supplied from the AC power supply system 12 by the first control power supply 15, and the DC circuit breaker 19 is closed when the DC power supply 11 is ready to start. Thus, the output power of the DC power supply 11 is AC converted by the inverter 13, and when the AC output of the inverter 13 coincides with the phase and amplitude of the AC power supply system 12, the switch 14 is switched by the control signal S 1 from the control circuit of the inverter 13. When the A contact 14a of 'is closed, the AC power supply system 12 is connected.

  Here, the B contact 14b ′ interlocked with the A contact 14a of the switch 14 ′ is opened, and further, the A contact 14a ′ of the switch 14 ″ interlocked with the B contact 14b ′ of the switch 14 ′ is opened. The control power supply of the inverter 13 by the first control power supply 15 is cut off and only the control power supply of the inverter 13 by the second control power supply 16 is supplied.

  In the grid interconnection system in the third and fourth embodiments, the control power of the inverter 13 is supplied from the AC power supply system 12 by the first control power supply 15 before the grid interconnection operation of the inverter 13. As in the second embodiment described above, a power supply system other than the AC power supply system 12 can be used. 5 and 6 show the fifth and sixth embodiments, and exemplify a case where there is an arbitrary power supply system 12 ′ (DCorAC power supply system) separately from the AC power supply system 12. The switches 14 'and 14' 'in the fifth embodiment shown in FIG. 5 are the same as those in the third embodiment shown in FIG. 3, and the switches 14' in the sixth embodiment shown in FIG. , 14 '' are the same as in the fourth embodiment shown in FIG.

  The system interconnection system in the fifth embodiment shown in FIG. 5 includes a switch 14 ″ having a B contact 14b ′ interlocked with an A contact 14a ′ of the switch 14 ′ and an arbitrary power system 12 ′. A configuration in which the control power supply 15 is connected is provided.

  In this case, before the grid interconnection operation of the inverter 13, the control power of the inverter 13 is supplied from the first control power supply 15 through the B contact 14 b ′ of the switch 14 ″ from an arbitrary power supply system 12 ′. During the 13 grid interconnection operation, the control power of the inverter 13 is supplied from the DC power supply 11 by the second control power supply 16.

  That is, before the system connection operation of the inverter 13, the control power of the inverter 13 is supplied from the AC power supply system 12 by the first control power supply 15, and the DC circuit breaker 19 is closed when the DC power supply 11 is ready to start. Thus, when the output power of the DC power supply 11 is AC converted by the inverter 13 and the AC output of the inverter 13 matches the phase and amplitude of the AC power supply system 12, the power is opened and closed based on the control signal S 1 from the control circuit of the inverter 13. When one A contact 14a of the container 14 'is closed, the AC power supply system 12 is connected.

  Here, the other A contact 14a ′ linked to one A contact 14a of the switch 14 ′ is closed, and further, the B contact of the switch 14 ″ linked to the other A contact 14a ′ of the switch 14 ′. By opening 14 b ′, the control power supply of the inverter 13 by the first control power supply 15 from any power supply system 12 ′ is cut off, and the control power supply of the inverter 13 by the second control power supply 16 from the DC power supply 11 is cut off. Only.

  Further, in the grid interconnection system in the sixth embodiment shown in FIG. 6, a switch 14 ″ having an A contact 14a ′ interlocked with a B contact 14b ′ of the switch 14 ′ is connected to an arbitrary power system 12 ′. A configuration in which a single control power supply 15 is connected is provided.

  In this case, since the B contact 14b ′ of the switch 14 ′ is closed, the A contact 14a ′ of the switch 14 ″ is in a closed state. The control power of the inverter 13 is supplied from the system 12 ′ by the first control power supply 15 through the A contact 14 a ′ of the switch 14 ″, and the DC circuit breaker 19 is connected during the system interconnection operation of the inverter 13. By closing, the control power of the inverter 13 is supplied from the DC power supply 11 by the second control power supply 16.

  That is, before the system connection operation of the inverter 13, the control power of the inverter 13 is supplied from the AC power supply system 12 by the first control power supply 15, and the DC circuit breaker 19 is closed when the DC power supply 11 is ready to start. Thus, the output power of the DC power supply 11 is AC converted by the inverter 13, and when the AC output of the inverter 13 coincides with the phase and amplitude of the AC power supply system 12, the switch 14 is switched by the control signal S 1 from the control circuit of the inverter 13. When the A contact 14a of 'is closed, the AC power supply system 12 is connected.

  Here, the B contact 14b ′ interlocked with the A contact 14a of the switch 14 ′ is opened, and further, the A contact 14a ′ of the switch 14 ″ interlocked with the B contact 14b ′ of the switch 14 ′ is opened. The control power supply of the inverter 13 by the first control power supply 15 is cut off and only the control power supply of the inverter 13 by the second control power supply 16 is supplied.

  As in the third to sixth embodiments shown in FIG. 3 to FIG. 6, the switch 14 ″ interlocked with the A contact 14 a ′ or the B contact 14 b ′ of the switch 14 ′ based on the control signal S <b> 1 from the inverter 13. By opening the B contact 14b ′ or the A contact 14a ′, it is not necessary to provide the inverter 13 with a signal output control port for the control signal S2 (see FIG. 10) for opening the switch 7 as in the prior art. An increase in the signal output control port can be suppressed.

1 is a circuit diagram showing a first embodiment of a grid interconnection system according to the present invention. It is a circuit diagram which shows 2nd embodiment of the grid connection system which concerns on this invention. It is a circuit diagram which shows 3rd embodiment of the grid connection system which concerns on this invention. It is a circuit diagram which shows 4th embodiment of the grid connection system which concerns on this invention. It is a circuit diagram which shows 5th embodiment of the grid connection system which concerns on this invention. It is a circuit diagram which shows 6th embodiment of the grid connection system which concerns on this invention. It is a specific circuit diagram for demonstrating the interlocking relationship of the switch in 3rd and 5th embodiment. It is a specific circuit diagram for demonstrating the interlocking relationship of the switch in 4th and 6th embodiment. It is a circuit diagram which shows an example of the conventional grid connection system. It is a circuit diagram which shows the other example of the conventional grid connection system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 DC power supply 12 AC power supply system 13 Inverter 14 Switch 14b B contact 14a ', 14b' contact 15 1st control power supply 16 2nd control power supply

Claims (4)

  An inverter connected between a DC power supply and an AC power supply system, and AC-converting the output of the DC power supply; a first control power supply for supplying control power before system connection operation of the inverter; and a DC side of the inverter Connected to the second control power source for supplying the control power during the grid-connected operation of the inverter, and connected to the AC side of the inverter, and when the phase and amplitude of the inverter output coincide with the AC power source system, the inverter A system interconnection system comprising a switch linked to an AC power supply system based on a control signal from a control circuit, wherein the first control power supply is already installed in the switch and is connected to the inverter control circuit. A grid interconnection system, characterized in that the grid interconnection system is connected to an AC power supply system via a B contact that is linked to a control signal.   An inverter connected between a DC power supply and an AC power supply system, and AC-converting the output of the DC power supply; a first control power supply for supplying control power before system connection operation of the inverter; and a DC side of the inverter Connected to the second control power source for supplying the control power during the grid-connected operation of the inverter, and connected to the AC side of the inverter, and when the phase and amplitude of the inverter output coincide with the AC power source system, the inverter A system interconnection system comprising a switch linked to an AC power supply system based on a control signal from a control circuit, wherein the first control power supply is already installed in the switch and is connected to the inverter control circuit. A system interconnection system, characterized in that it is connected to an arbitrary power supply system installed separately from the AC power supply system via a B contact linked to a control signal.   An inverter connected between a DC power supply and an AC power supply system, and AC-converting the output of the DC power supply; a first control power supply for supplying control power before system connection operation of the inverter; and a DC side of the inverter Connected to the second control power source for supplying the control power during the grid-connected operation of the inverter, and connected to the AC side of the inverter, and when the phase and amplitude of the inverter output coincide with the AC power source system, the inverter A system interconnection system comprising a switch for linking with an AC power supply system based on a control signal from a control circuit, wherein the first control power supply is switched on and off based on a control signal from an inverter control circuit. A system interconnection system characterized by being connected to an AC power supply system through a contact that opens and closes in conjunction with the vessel.   An inverter connected between a DC power supply and an AC power supply system, and AC-converting the output of the DC power supply; a first control power supply for supplying control power before system connection operation of the inverter; and a DC side of the inverter Connected to the second control power source for supplying the control power during the grid-connected operation of the inverter, and connected to the AC side of the inverter, and when the phase and amplitude of the inverter output coincide with the AC power source system, the inverter A system interconnection system comprising a switch for linking with an AC power supply system based on a control signal from a control circuit, wherein the first control power supply is switched on and off based on a control signal from an inverter control circuit. A system interconnection system characterized in that the system is connected to an arbitrary power system installed separately from the AC power system through a contact that opens and closes in conjunction with the vessel.