JP2003009399A - System interconnected power generating system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system interconnectional power generation system, in which the line voltage of main line is accurately reflected on the output control of a power generation facility which is a system interconnected with a commercial power supply. SOLUTION: A power conditioner 20 converts the output from a solar battery SB to the output an AC voltage. Output from the power conditioner 20 is applied to a main line Lm in a home distribution board 10 and the power conditioner 20 is system interconnected with a commercial power supply AC. Line voltage of the main line Lm is monitored at a voltage rise detecting section 26b, provided in the home distribution board 10, and when it increases, deviating from the normal range, the voltage rise detecting section 26b instructs a system protective section 26 provided in the power conditioner 20 so as to suppress output from the power conditioner 20.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a grid-connected power generation system.

[0002]

2. Description of the Related Art Conventionally, a grid-connected power generation system has been proposed in which a small-scale power generation facility is grid-connected to a commercial power grid. For power generation equipment for which demand is increasing for general homes, the DC voltage output from solar cells installed on the roof of a house is converted into a sine wave AC voltage by an inverter circuit, and grid-connected operation with a commercial power source is performed. There is a power generation facility that is designed to allow it.

In a system interconnection system using this kind of power generation equipment, for example, as shown in FIG. 4, in a residential distribution board 10 as a distribution board, a power generation equipment using a solar battery SB as a power source and a commercial power supply AC. Is provided, and between the commercial power source AC and the residential distribution board 10, a power meter M1 for selling power is provided.
Also, an electric power meter M2 for selling power is inserted. Main switchgear 11 which is an earth leakage breaker is connected to power receiving point Pr of commercial power supply AC inside house distribution board 10, and three main lines Lm are connected to the load side of main switchgear 11. A plurality of branch switches 12 are connected to the main line Lm via a branch line Lb,
A load circuit is connected to each branch switch 12. A switch 13 for power generation equipment is also connected to the main line Lm. The DC voltage output from the solar battery SB is converted into an AC voltage by the power conditioner 20 that manages the output of the power generation equipment, and the AC voltage output from the power conditioner 20 is passed through the power generation equipment switch 13 to the main line Lm. Is applied. Therefore, the load side of the switch 13 for power generation equipment becomes the interconnection point. In addition, in this configuration, the solar cell SB and the power conditioner 20 constitute a power generation facility.

By the way, the power conditioner 20 is
A chopper circuit 21 that boosts the DC voltage output from the solar cell SB and an inverter circuit 22 that converts the DC voltage output from the chopper circuit 21 into a sine wave AC voltage are provided, and the output of the inverter circuit 22 is two. Parallel switch 2
It is output from the power conditioner 20 via 3a and 23b. Here, the output of the inverter circuit 22 is a single phase 2
In the residential distribution board 10, the main line Lm is a single-phase three-wire, so that the output of the inverter circuit 22 is divided by the series circuit of the two choke coils L1 and L2 on the output side of the disconnecting switch 23b. The connection point of both choke coils L1 and L2 is connected to the neutral line of the main line Lm.

The power conditioner 20 is provided with a chopper control circuit 24 and an inverter control circuit 25 for controlling the chopper circuit 21 and the inverter circuit 22. The inverter control circuit 25 uses the inverter circuit 22.
Turn on and off the switching element provided in
PWM control is performed in which the ON period is changed over time so that the average voltage of ON / OFF times changes sinusoidally. Furthermore, the inverter control circuit 25 uses the commercial power supply AC.
Of the chopper control circuit 24 and the inverter control circuit 2 in response to an abnormality in the output voltage and an excessive increase in the output voltage of the inverter circuit 22.
5, a system protection unit 26 is provided for giving instructions to 5 and controlling opening / closing of the disconnecting switches 23a and 23b.
The system protection unit 26 also has a function of giving an instruction to the inverter control circuit 25 to match the phase of the voltage output from the power conditioner 20 with the voltage phase of the commercial power supply AC. Thus, when the parallel disconnect switches 23a and 23b are turned on, the grid interconnection is performed, and the parallel disconnect switches 23a and 23b are connected.
System separation is performed in the state where 3b is disconnected.

The system protection unit 26 includes a choke coil L1.
A system abnormality detection unit 26a that monitors the voltage across L2 and determines that the voltage is abnormal when the monitored voltage falls below the lower limit of the normal range, and an abnormality when the monitored voltage exceeds the upper limit of the normal range. And a voltage rise detection unit 26b as a voltage detection unit for determining. When the system abnormality detector 26a detects an abnormality, the system disconnection switches 23a and 23b are disconnected to separate the system and the operation of the inverter circuit 22 is stopped. When the voltage rise detection unit 26b detects an abnormality, the chopper control circuit 24 and the inverter control circuit 2
5 is given to decrease the output voltage.

[0007]

By the way, in the above-mentioned configuration, the power conditioner 20 is provided with the chopper circuit 21.
And an inverter circuit 22 are provided for the solar cell SB.
Since a direct current flows between the power conditioner 20 and the power conditioner 20, it is desirable to shorten the wiring between the solar cell SB and the power conditioner 20 in order not to increase the loss. Therefore, the wiring length between the house distribution board 10 and the power conditioner 20 is often relatively large.

On the other hand, since the voltage of the commercial power supply AC is monitored by the system abnormality detecting section 26b of the power conditioner 20, there is a voltage drop ΔV between the residential distribution board 10 and the power conditioner 20. Therefore, the voltage detected as the voltage of the commercial power supply AC in the system abnormality detection unit 26b is lower than the voltage at the power receiving point Pr by at least the voltage drop ΔV. Since the degree of the voltage drop ΔV changes depending on the wiring length and the type of wiring between the house distribution board 10 and the power conditioner 20, generally the voltage drop ΔV is ignored and the system abnormality detection unit 2
The operation of 6a is defined. That is, assuming that the allowable voltage range of the power receiving point Pr is set to 101 ± 6V or 202 ± 20V, the normal range is set to 101 ± 6V or 202 ± 20V also in the system protection unit 26 ( The normal range is shown in the "Grid interconnection technical requirement guideline").

With such a setting, the following problems occur. Now, assume that the voltage drop ΔV is 0.5 V, and the output voltage of the inverter circuit 22 is 10 V, for example.
Suppose it has reached 7.5V. In this case, since the voltage at the power receiving point Pr is 107 V due to the voltage drop ΔV, the main line L
The line voltage of m is in the normal range. However, the voltage rise detection unit 26b detects 107.5V and determines that there is an abnormality, and the output voltage of the power conditioner 20 is suppressed.

The present invention has been made in view of the above circumstances, and an object of the invention is to accurately reflect the line voltage of a main line in the output control of a power generation facility that is grid-connected to a commercial power source. To provide a power generation system.

[0011]

According to the invention of claim 1, a main switch which is housed in a distribution board and connected to a commercial power source and a load side of the main switch which is housed in the distribution board together with the main switch. The branch switch connected via the main line and the distribution board are provided separately from each other and electrically connected to the main line of the distribution board to enable output control for grid-connected operation with the commercial power supply. The power generation equipment, the power generation equipment is provided with an interconnection protection unit that controls the output voltage of the power generation equipment according to an instruction from the outside, detects the line voltage of the main line, and keeps the line voltage within a predetermined normal range. A voltage detecting unit for instructing the interconnection protection unit of the power generation facility to keep the voltage is stored in the distribution board. According to this configuration, since the voltage detection unit monitors the line voltage of the main line of the distribution board, the wiring length between the distribution board and the power generation equipment is relatively large, and A relatively large voltage drop occurs between the mains in the distribution board, but the output voltage of the power generation equipment is out of the normal range even though the line voltage of the main line is in the normal range. It is possible to prevent the output of the power generation equipment from being controlled as necessary. In particular, if the output of the power generation equipment is suppressed when the output of the power generation equipment is high, the power sold to the commercial power source due to reverse flow may be reduced, while the output of the power generation equipment is unnecessarily suppressed. Since there is nothing to do, the loss of power sold will be suppressed.

According to a second aspect of the present invention, in the first aspect of the present invention, an electric power detection unit for detecting electric power passing through the main line is added between the main switch and the branch switch, and the power generation facility is A monitor device for displaying the electric power detected by the electric power detector is provided. According to this configuration, by providing the power detection unit in a region near the power receiving point of the distribution board, it is possible to obtain the trading power relatively accurately,
Moreover, since the power generation equipment is provided with the monitor device for displaying the trading power, the trading power can be monitored separately from the watt hour meter. Further, since the power detection unit detects the current and the voltage of the main line, it can share a part of the configuration with the voltage detection unit. By sharing a part of the configuration of the power detection unit and the voltage detection unit, power distribution can be performed. The occupied space in the board can be made relatively small.

According to a third aspect of the present invention, in the first or second aspect of the present invention, a plurality of the power generation facilities are provided, and each power generation facility can communicate with the interconnection protection unit provided in each power generation facility. An interface is added, and an instruction from the voltage detection unit is received by the interconnection protection unit provided in any one of the power generation facilities, and this instruction is transferred to the interconnection protection unit of another power generation facility through the interface. Is characterized by. According to this configuration, when operating a plurality of power generation facilities, an instruction from one voltage detection unit is transferred to each power generation facility, so that all power generation facilities can be linked so as to perform the same operation. become.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION (First Embodiment) In this embodiment, as shown in FIG. 1, the basic configuration is the same as the conventional configuration shown in FIG. In contrast to the voltage rise detection unit 26b that monitors the output voltage of the circuit 22 being provided in the power conditioner 20, in the present embodiment, the voltage rise detection unit 26b is provided in the house distribution board 10. Therefore, in this embodiment, the voltage rise detection unit 26b detects the line voltage of the main line Lm. Main line Lm detected by the voltage rise detection unit 26b
The line voltage of is input to the system protection unit 26 of the power conditioner 20 and is used to control the inverter control circuit 26 as in the conventional configuration.

As described above, the voltage rise detector 26b provided in the residential distribution board 10 detects the line voltage of the main line Lm, and the detected line voltage causes the power conditioner 2 to operate.
Since the output control of 0 is performed, it is determined that the voltage detected by the voltage rise detection unit 26b deviates from the normal range although the line voltage of the main line Lm is in the normal range as in the conventional configuration. Therefore, it is possible to prevent a malfunction due to a voltage drop ΔV in the wiring between the residential distribution board 10 and the power conditioner 20. The voltage detector 26
It is desirable that b is connected between the main switch 11 and the branch switch 12, and at this position, the line voltage of the main line Lm can be detected at a portion near the power receiving point Pr. Here, since the voltage rise detection unit 26b only needs to transmit a binary signal indicating whether or not the upper limit value of the normal range is exceeded,
The voltage drop between the voltage rise detection unit 26b and the power conditioner 20 can be ignored. Other configurations and operations are similar to the conventional configuration.

(Second Embodiment) This embodiment is shown in FIG.
As shown in FIG. 7, the power distribution detecting panel 26c is incorporated in the house distribution board 10 in addition to the voltage rise detecting section 26b. The power detection unit 26c detects the current flowing between the main switch 11 and the branch switch 12 by the current sensor CT, and also detects the line voltage of the main line Lm.
The instantaneous value of the trading power is obtained by the product of the current value detected by T and the line voltage of the main line Lm. In addition, the power detection unit 2
At 6c, the obtained trading power is transmitted to the power conditioner 20. In the power detector 26c, the voltage rise detector 26b
Since the line voltage of the trunk line Lm is detected in the same manner as described above, it becomes possible to share some of the functions of the voltage rise detection unit 26b and the power detection unit 26c, and the voltage rise detection unit 26b and the power detection unit 26c can be used together. By sharing a part of the above, it is possible to make the occupied space in the residential distribution board 10 relatively small while having two functions. Here, if the output of the power detection unit 26c is transmitted to the power conditioner 20 as an analog value, the voltage drop cannot be ignored, so it is desirable to convert it into a digital value and transmit it.

In the electric power calculation unit 26d provided in the power conditioner 20, the instantaneous value of the electric power received from the electric power detection unit 26c is used as a guideline for the instantaneous value of the trading power, and the integrated power is further calculated to obtain the instantaneous value and the integrated power. It is output to the outside via a communication interface 27 such as RS485. The data output to the outside through the interface 27 can output not only the instantaneous value of the power but also the integrated value of the power. When the integrated value of electric power is output from the interface 27 to the outside, the system protection unit 26
The integrated value of the electric power may be obtained at
It is also possible to obtain the integrated value of electric power in 6c.

A monitor device 30 is connected to the interface 27, and an instantaneous value of power or an integrated value of power can be displayed on a display unit 31 provided in the monitor device 30. The monitor device 30 also includes a switch group 32 such as an operation switch and a stop switch, and by giving an instruction from the monitor device 30 to the system protection unit 26, it is possible to give an instruction to operate or stop the power conditioner 20. . The switch group 32 includes one that switches the display content of the display unit 31. Further, since the system protection unit 26 monitors the output of the inverter circuit 22, it is possible to obtain the generated power, and in the configuration of the present embodiment, the generated power can also be displayed on the monitor device 30. is there. Further, if the power detection unit 26c detects the current flowing from the main switch 11 toward the main line Lm and the generated power is obtained, the sum of the power detected by the power detection unit 26c and the generated power is consumed by the load. If the electric current corresponding to the electric power, that is, the electric current from the main line Lm to the main switchgear 11 is detected by the electric power detection unit 26c and the generated electric power is obtained, the difference obtained by subtracting the electric power detected by the electric power detection unit 26c from the generated electric power is obtained. It corresponds to the power consumption in the load, and if the generated power is not detected, the power detected by the power detection unit 26c corresponds to the power consumption in the load. Therefore, it is possible to display the power consumption in the load on the monitor device 30. Other configurations and operations are similar to those of the first embodiment.

(Third Embodiment) This embodiment is shown in FIG.
As shown in FIG. 2, two power conditioners 20 used in the second embodiment shown in FIG. 2 are used together.
By having two inverters 20,
Switch 13 for power generation equipment housed in the distribution board 10 of the house
Requires two units corresponding to each power conditioner 20, but the voltage rise detection unit 26b and the power detection unit 26
The output of c is given to only one power conditioner 20, and the monitor device 30 is connected to the interface 27 of this power conditioner 20.

The voltage rise detector 26b and the power detector 2
The information obtained in 6c is used for other power conditioners 20
Are transferred through the interface 27. In addition, the information obtained in the system protection unit 26 of the other power conditioner 20 is transferred to the monitor device 30 via the interface 27. Therefore, the two power conditioners 20 can be interlocked by the output of the voltage rise detection unit 26b, and the operation of the two power conditioners 20 can be monitored by the single monitor device 20. Here, in the monitor device 30, it is necessary to switch the operation of each power conditioner 20 so that it can be monitored.

The configuration of the present embodiment can be applied to the case where three or more power conditioners 20 are operated in parallel. By sharing the voltage rise detection unit 26b in a plurality of power conditioners 20, each power conditioner 20 can be used. It is possible to interlock the conditioner 20.
Other configurations and operations are similar to those of the second embodiment.

[0022]

According to the invention of claim 1, the main switch which is housed in the distribution board and connected to the commercial power source, and the main switch which is housed in the distribution board together with the main switch via the main line to the load side of the main switch. A branch switch to be connected and a power generation facility that is provided separately from the distribution board and is electrically connected to the main line of the distribution board and that can control the output for grid-connected operation with a commercial power source. Prepare,
The power generation equipment is provided with an interconnection protection unit that controls the output voltage of the power generation equipment according to an instruction from the outside, detects the line voltage of the main line, and keeps the line voltage within a predetermined normal range. The voltage detection unit that gives instructions to the interconnection protection unit is housed in the distribution board, and the voltage detection unit monitors the line voltage of the main line of the distribution board. Even though the line voltage of the main line in the distribution board is within the normal range due to the relatively large wiring length between the equipment and the relatively large voltage drop between the power generation equipment and the distribution board. It is possible to prevent the output of the power generation facility from being unnecessarily controlled when the output voltage of the power generation facility deviates from the normal range. Especially,
If the output of the power generation facility is suppressed when the power generation facility has a high output, the power sold to the commercial power source may be reduced due to reverse flow, whereas the output of the power generation facility is unnecessarily suppressed. Since there is no such thing, the loss of power sold will be suppressed.

According to a second aspect of the present invention, in the first aspect of the present invention, an electric power detection unit for detecting electric power passing through the main line is added between the main switch and the branch switch, and the power generation facility is In addition to the effect of the invention of claim 1, a monitor device for displaying the electric power detected by the electric power detection unit is provided. Since the power generation equipment is provided with the monitor device that can relatively accurately determine the trading power, the trading power can be monitored separately from the power meter. Further, since the power detection unit detects the current and the voltage of the main line, it can share a part of the configuration with the voltage detection unit. By sharing a part of the configuration of the power detection unit and the voltage detection unit, power distribution can be performed. The occupied space in the board can be made relatively small.

According to a third aspect of the present invention, in the first or second aspect of the invention, a plurality of the power generation facilities are provided, and each power generation facility can communicate with the interconnection protection unit provided in each power generation facility. An interface is added, and an instruction from the voltage detection unit is received by the interconnection protection unit provided in any one of the power generation facilities, and this instruction is transferred to the interconnection protection unit of another power generation facility through the interface. In addition to the effect of the invention of claim 1 or claim 2, when operating a plurality of power generation facilities, an instruction from one voltage detection unit is transferred to each power generation facility, so that all power generation facilities are It becomes possible to interlock so that the same operation is performed.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a first embodiment of the present invention.

FIG. 2 is a circuit diagram showing a second embodiment of the present invention.

FIG. 3 is a circuit diagram showing a third embodiment of the present invention.

FIG. 4 is a circuit diagram showing a conventional example.

[Explanation of symbols]

10 residential distribution board 11 Main switch 12 branch switches 20 power conditioner 26 Interconnection protection unit 26b Voltage rise detector 26c Power detection unit 27 interfaces 30 monitor AC commercial power supply Lm main line SB solar cell

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Hiromichi Inoue             1048, Kadoma, Kadoma-shi, Osaka Matsushita Electric Works Co., Ltd.             Inside the company F-term (reference) 5G066 HA13 HA30 HB06                 5H007 AA05 AA17 BB07 CA01 CB04                       CB05 CC03 CC12 DA06 DB01                       DC05 FA01 GA09                 5H420 BB02 BB12 CC03 DD03 DD09                       DD10 EA11 EA39 EA45 EA49                       EB09 EB16 EB39 FF03 FF24                       FF25 LL02

Claims (3)

[Claims] 1. A main switch which is housed in a distribution board and connected to a commercial power source, and a branch switch which is housed together with the main switch in a distribution board and connected to the load side of the main switch via a main line. , Equipped with a power supply facility that is provided separately from the distribution board and is electrically connected to the main line of the distribution board and that can be controlled in output for commercial power supply and grid-connected operation. According to the instruction of the power generation equipment to control the output voltage of the interconnection protection unit, to detect the line voltage of the main line and to maintain this line voltage in the normal range specified in advance to the power generation equipment interconnection protection unit A grid-connected power generation system characterized in that a voltage detection unit for giving an instruction is housed in the distribution board. 2. A monitor for displaying electric power detected by the electric power detection unit, wherein an electric power detection unit for detecting electric power passing through the main line is added between the main switch and the branch switch. The grid-connected power generation system according to claim 1, further comprising a device. 3. A plurality of said power generation facilities are provided, each power generation facility is provided with an interface for enabling communication between said interconnection protection units provided in each power generation facility, and is provided in any one power generation facility. The grid interconnection unit according to claim 1 or 2, wherein the grid interconnection protection unit receives an instruction from the voltage detection unit, and the instruction is transferred to the grid interconnection protection unit of another power generation facility through an interface. Power generation system.