JP5942079B2 - Grid interconnection system - Google Patents

Description

  The present invention relates to a grid interconnection system that combines power supplied from a plurality of solar cells via a booster circuit, converts the combined DC power into AC power, and links the solar cell to a commercial power system.

Conventionally, a plurality of booster circuits that are connected to a plurality of solar cells, respectively, boost the output voltage of the solar cells, and DC power that combines the power output from the plurality of booster circuits is input, and the DC power is converted to AC power. And the grid connection system provided with the power conditioner which connects a solar cell to a commercial power grid | system is proposed (patent document 1).
JP2003-9537

  In such a grid-connected system, the plurality of booster circuits monitor the output power of the solar cells connected to each other, and increase or decrease the boost ratio of the booster circuit so that the output power is maximized (Maximum (Power Point Tracking). In MPPT control, the output power of the solar cell is monitored by increasing or decreasing the boost ratio of the booster circuit. If the output power of the solar cell increases by changing the boost ratio, continue to increase the boost ratio. If the power decreases, the boost ratio is adjusted to the opposite side (decrease if the boost ratio is increased, increase if it decreases). By adjusting the output power, the output power of the solar cell is kept at the maximum value.

  The grid interconnection system described in Patent Document 1 performs such MPPT control for each of the plurality of booster circuits in order by using a common control circuit for the plurality of booster circuits. By doing in this way, the output of the solar cell, which fluctuates when the booster circuit performs the MPPT operation, does not affect the MPPT operation performed by the other booster circuits.

  However, in such a grid-connected system, since the common control circuit determines the booster circuit for performing the MPPT operation, a circuit (or software) for determining the order of performing the MPPT control is required. . For this reason, every time the number of solar cells is increased or decreased, it is necessary to set the information of the booster circuit that increases or decreases in a common control circuit, which requires troublesome work such as circuit changes and software updates. There was a problem of becoming.

  The present invention has been made in view of the above problems, and an object thereof is to provide a grid interconnection system that can easily increase or decrease the number of solar cells.

The present invention is respectively connected to the plurality of solar cells, a plurality of temperature for boosting the output voltage of said solar cell
A power conditioner that uses a voltage circuit, inputs DC power obtained by combining DC power output from the plurality of booster circuits, converts the DC power into AC power, and links the solar cell to a commercial power system; In the grid interconnection system comprising:
MPPT control that operates by changing the step-up ratio so as to output the first signal and maximize the output power of the solar cell, and constant step-up ratio control that operates the output voltage of the solar cell at a constant step-up ratio one of the control is performed by selecting the boost control circuit, the boost control circuit, said MP
When the predetermined time from the start of the PT control has elapsed, the MPPT control using the last set has been step-up ratio by the MPPT control causes a shift to the boost ratio stabilization control, the MPPT
Among the plurality of boosting circuit at the start of the control, after the predetermined time the start of the MPPT control when receiving the first signal output while the other step-up circuit is performing the MPPT control , It is determined whether the first signal is received, and is performed when the first signal is not received .

  According to the present invention, in order to cause each booster circuit to perform the MPPT operation by prohibiting the MPPT control when another booster control circuit receives a signal indicating that the MPPT control is being performed, Even if the number of batteries increases or decreases and the number of booster circuits also increases or decreases, there is no need to inform the booster control circuit of that information. For this reason, the grid connection system of this invention can increase or decrease the number of solar cells easily.

  In the invention described above, the boost control circuit ends the MPPT control and stops outputting the first signal after a predetermined time has elapsed since the MPPT control was started.

  In the above-described invention, when the boosting control circuit executes the MPPT control, when the output power of the solar cell falls within a predetermined fluctuation range, the boosting ratio is constant from the MPPT control. Control or switching to the constant voltage control, and the output of the first signal is stopped after a predetermined time has elapsed from the start of the MPPT control.

  In the above-described invention, the boost control circuit stores a boost ratio at the start of MPPT control and a boost ratio at the end of the MPPT control, and these boost ratios are increased or decreased compared to each other. The boost control circuit that outputs the second signal indicating whether or not and performs the MPPT control after the boost control circuit that has output the second signal indicates the first change in the boost ratio by the second signal. It is characterized by being changed with the same content.

  In the above-described invention, when each boosting circuit connected to each other starts up, the boosting control circuit assigns numbers in the order of startup, and the boosting control circuit ends the MPPT control, and the first signal When the output of the first signal is stopped, another boost control circuit to which the number next to the number assigned to the boost control circuit that has stopped outputting the first signal performs the MPPT control. To do.

  The present invention provides a grid interconnection system that can easily increase or decrease the number of solar cells.

It is a lineblock diagram showing photovoltaic power generation system 100 concerning this embodiment. 6 is a flowchart when the boost control circuit 42 executes MPPT control. 6 is a time chart when the boost control circuit executes MPPT control. It is a flowchart which shows operation | movement of the pressure | voltage rise control circuit 42 at the time of discounting a number. It is a block diagram which shows the solar power generation system 100 which connected the power condition control circuit 22 and the pressure | voltage rise control circuits 42a-42c with the communication line.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a configuration diagram illustrating a photovoltaic power generation system 100 according to the present embodiment. As shown in this figure, the photovoltaic power generation system 100 includes a plurality of solar cells 1a to 1c and a grid interconnection system 50, and the grid interconnection system 50 summarizes the power supplied by the plurality of solar cells 1a to 1c. To the commercial power system 30.

  The plurality of solar cells 1a to 1c are each configured by connecting cells of a plurality of solar cells in series. Since the number of cells of each of the solar cells 1a to 1c varies depending on the area where the solar cells 1a to 1c are installed, the number of cells varies depending on the solar cells 1a to 1c.

  The grid interconnection system 50 includes a connection box 4 and a power conditioner 2.

  The junction box 4 includes a plurality of boosting units 40a to 40c, and the boosting unit 40 includes a plurality of boosting circuits 41a to 41c connected in series to the plurality of solar cells 1a to 1c, respectively. . Each booster circuit 41a to 41c is provided with booster control circuits 42a to 42c. The boost control circuits 42a to 42c control the operation of the boost circuits 41a to 41c connected thereto.

  Each booster circuit 41a to 41c boosts the output voltage of each solar cell 1a to 1c. Further, the output sides of the respective booster circuits 41a to 41c are connected in parallel with each other in the junction box 4, and the junction box 4 collects the DC power boosted and output by these booster circuits 41a to 41c, The collected DC power is output to the power conditioner 2.

  The respective boost control circuits 42a to 42c are solar cells 1a to 1c connected to the boost circuits 41a to 41c that perform operation control (solar cells 1a to 1c connected to the respective boost control circuits 42a to 42c). The MPPT control is performed to operate the booster circuits 41a to 41c connected to each other by changing the booster ratio so that the output power of the output is maximized. Each boost control circuit 42a to 42c executes constant boost ratio control for operating the output voltages of the solar cells 1a to 1c at a constant boost ratio.

  In this embodiment, the same numerals are assigned to the same components (1 for solar cells), and the same alphabetic symbols are assigned to those having a connection relationship between the components (solar cell 1). And the step-up circuit 41 are connected to the solar cell 1a and the step-up circuit 41a).

  In the same configuration, if the same operation is performed, it is redundant if the same description is performed. Henceforth, in order to simplify the description, the symbols a, b, and c at the end are used in order to simplify the description. May be omitted.

  The boost control circuit 42 executes MPPT control in the following manner. The boost control circuit 42 calculates and stores the power (output power of the solar cell) input to the booster circuit from the voltage and current input to the booster circuit 41. Next, the boosting ratio of the booster circuit is changed, and the power input to the booster circuit is similarly calculated. Then, compare the power before and after changing the boost ratio, and if the power increases, change the boost ratio with the same content as the previous boost ratio change (increase if the boost ratio is increased) If the power is decreasing, the boost ratio is changed with a content that is different from the content that changed the previous boost ratio (decrease if the boost ratio is increased, increase if the boost ratio is decreased) . It is preferable to determine in advance whether the change of the first step-up ratio after the start of MPPT control is to be increased or decreased. The MPPT control is continued until a predetermined time elapses or the amount of change in power before and after the step-up ratio is changed is equal to or less than a predetermined value.

  The power conditioner 2 includes a booster circuit 21 that boosts DC power output from the connection box 4, an inverter circuit 23 that converts DC power output from the booster circuit 21 into AC power, and operations of the booster circuit 21 and the inverter circuit 23. And a power control circuit 22 that controls the plurality of solar cells 1 a to 1 c to the commercial power system 30.

  The power conditioner 2 operates using the booster circuit 21 and the inverter circuit 23 so that the DC power obtained by combining the power output from the plurality of solar cells 1a to 1c is maximized (the power conditioner control circuit 22 performs MPPT control). Run). Since the DC power obtained by combining the power output from the plurality of solar cells 1 a to 1 c can be approximated to the output current of the inverter circuit 23, the MPPT control uses the power control circuit 22 to increase the voltage boosted by the booster circuit 21. This is performed by controlling the current output from the inverter circuit 23.

  The respective boost control circuits 42a to 42c are connected by a communication line L, and MPPT control is executed while communicating with each other. Specifically, each of the boost control circuits 42a to 42c outputs a first signal indicating that the MPPT control is being performed, and receives the first signal from another boost control circuit when executing the MPPT control. In addition, the MPPT control is prohibited from being executed, and the constant boost ratio control or the constant voltage control is executed.

  FIG. 2 shows a flowchart when the boost control circuit 42 executes the MPPT control. In order to simplify the description, a case where the boost control circuit 42a performs MPPT control will be described, but the same control is performed for the other boost control circuits 42b and 42c.

  When starting the MPPT control, the boost control circuit 42a controls the boost circuit 41a so that the boost ratio of the boost circuit 41a is constant, and the first signal is sent to the other boost control circuits 42b, 42c. It is determined whether it is received from (step S11). When the boost control circuit 42a receives the first signal from the other boost control circuits 42b and 42c, a predetermined time elapses (for example, from when the other boost control circuit starts executing the MPPT control to when it ends. Step S11 is repeated again. That is, execution of the MPPT control is prohibited, and constant boost ratio control or constant voltage control is executed.

  In step S11, when the boost control circuit 42a has not received the first signal, the boost control circuit 42a proceeds to step S13 and outputs the first signal to the other boost control circuits 42b and 42c. Thereafter, the boost control circuit 42a starts timing from the time point when the MPPT control starts using a timer (step S14). Then, the boost control circuit 42a detects the voltage and current input to the booster circuit 41a, calculates and stores the input power (output power of the solar cell) to the booster circuit 41a, and the first booster circuit 41a. The step-up ratio is changed and MPPT control is started (step S15). At this time, the boost control circuit 42a stores whether the boost ratio has been increased or decreased.

  Next, the boosting control circuit 42a determines whether or not a predetermined time has elapsed due to the timer (step S16). In step S16, when the boost control circuit 42a determines that the predetermined time has elapsed, the boost ratio constant control by the boost ratio last set in the MPPT control is executed (step S17), and the first signal The output is stopped (step S18) and the MPPT control is terminated.

  In this way, the boost control circuit 42a ends the MPPT control and stops outputting the first signal after a predetermined time has elapsed since the start of the MPPT control. For this reason, the MPPT control can be periodically executed also in the other boost control circuits 42b and 42c.

  If the boost control circuit 42a determines in step S16 that the predetermined time has not elapsed, the process proceeds to step S19. In step S19, the boost control circuit 42a again detects the voltage and current input to the boost circuit 41a and calculates the input power to the boost circuit 41a. Then, the boost control circuit 42a obtains a difference ΔP between the calculated input power and the stored input power (step S19).

  After obtaining ΔP, the boost control circuit 42a determines whether or not the absolute value of ΔP is smaller than a predetermined threshold value Pth (step S20). When the boost control circuit 42a determines that the absolute value of ΔP is smaller than the predetermined threshold value Pth, the boost ratio constant control is performed without changing the boost ratio, that is, the boost ratio set last in the MPPT control. (Step S21), the process returns to Step S16 (the input power stored at this time is not updated).

  By doing so, the boost control circuit 42a allows the boost ratio set last in the MPPT control when the output power of the solar cell falls within a predetermined fluctuation range during the execution of the MPPT control. Thus, the MPPT control is switched to the step-up ratio constant control. Even if the boost control circuit 42a performs a control with a constant boost ratio, the output of the first signal is stopped after a predetermined time has elapsed from the start of the MPPT control. The MPPT control is prohibited in the boost control circuits 42b and 42c.

  As a result, the plurality of boost control circuits 42a to 42c perform MPPT control slowly and alternately over a predetermined time with respect to the MPPT control on the power conditioner side, thereby reducing the influence on the MPPT control on the power conditioner side. it can.

  When the boost control circuit 42a determines that the absolute value of ΔP is larger than the predetermined threshold Pth, if ΔP is positive (input power is increasing), the boost control circuit 42a stores the If ΔP is negative (input power is decreasing), the boost ratio is changed to the opposite direction to the one stored in the boost control circuit 42a (step S22). At this time, the boost control circuit 42 updates the stored input power and whether the boost ratio is increased or decreased.

  FIG. 3 shows a time chart when the boost control circuit 42 executes the MPPT control. The hatched portion indicates that the boost control circuits 42a to 42c are executing the MPPT control, and the white portion indicates that the boost ratio constant control is being performed.

  As shown in the figure, when the boost control circuit is performing MPPT control, MPPT control is prohibited in other boost control circuits, and constant boost ratio control is performed.

  As described above, when the other boost control circuits 42b and 42c receive a signal indicating that the MPPT operation is being performed, the boost control circuit 41a prohibits the MPPT operation and is set last in the MPPT control. Even if the number of solar cells is increased or decreased and the number of booster circuits is also increased / decreased, the booster control circuit is informed of the information in order to cause each booster circuit to perform the MPPT operation by executing the constant booster ratio control by the booster ratio There is no need. For this reason, the grid connection system of this invention can increase or decrease the number of solar cells easily.

  As mentioned above, although one Embodiment of this invention was described, the above description is for making an understanding of this invention easy, and does not limit this invention. It goes without saying that the present invention can be changed and improved without departing from the gist thereof, and that the present invention includes equivalents thereof.

  In the present embodiment, when the boost control circuits 42a to 42c perform the MPPT control, when the boost ratio is increased or decreased for the first time, it has been increased or decreased in a predetermined direction. For example, as shown below Anyway.

  The step-up control circuit 42a stores the step-up ratio when starting the MPPT control and the step-up ratio when ending the MPPT control, and outputs a second signal indicating whether the step-up ratio is increased or decreased. The boost control circuits 42b and 42c that perform the MPPT control next to the boost control circuit 42a that outputs and outputs the second signal change the first boost ratio change with the same contents as indicated by the second signal. .

  MPPT control is performed in a certain boost control circuit, and whether or not the finally changed boost ratio has increased or decreased as compared to the start of MPPT control is the same for the boost control circuit that performs MPPT control next. Therefore, the maximum power point can be followed promptly by doing as described above.

  Such control can be realized by changing the boost ratio based on the second signal received when the first boost ratio change is performed in step 15 of FIG.

  Further, for example, each of the boost control circuits 42a to 42c has a sufficient output from the solar cells 1a to 1c. When the circuit 41a finishes the MPPT control and stops outputting the first signal, the other boost control circuit to which the number next to the number assigned to the boost control circuit 41a that stopped outputting the first signal is assigned 42b and 42c may perform MPPT control.

  FIG. 3 is a flowchart showing the operation of the boost control circuit 42 when assigning a number. FIG. 3A shows the operation of the boost control circuit 42 that determines its own number when the corresponding boost circuit 41 starts up. FIG. 3B shows the boost control circuit 42 in which the corresponding boost circuit 41 has already started. Shows the operation. Here, for the sake of simplicity, the case where the booster circuit 41a connected to the booster control circuit 42a starts up will be described.

  As shown in FIG. 3A, in the boost control circuit 42a, the output of the solar cell 1 is sufficient, and the connected booster circuit 41a is started up (power sufficient to operate the booster circuit 41 from the solar cell 1a). Is supplied), an activation signal indicating that the booster circuit 41a is activated is output to the other booster control circuits 42b and 42c, and a timer is activated (step S31). Then, the boost control circuit 42a waits for the number registered in the other boost control circuits 42b and 42c to be returned.

  In step S32, the boost control circuit 42a determines whether or not a number is returned from the other boost control circuits 42b and 42c. When a number is returned from the other boost control circuits 42b and 42c, the boost control circuit 42a stores that the number is used in the other boost control circuit 42, and returns to step S32. If there is no reply from the other boost control circuits 42b and 42c in step S32, the boost control circuit 42a determines whether or not a predetermined time has elapsed since the start of the timer (step S34).

  The predetermined time here may be set to a time sufficient for the boost control circuit 42a to complete communication with the other boost control circuits 42b and 42c.

  In step S32, when the boost control circuit 42a determines that the predetermined time has not elapsed since the timer was started, the boost control circuit 42a determines that the communication between the plurality of boost control circuits 42a to 42c has not ended, and step Return to S32. In step S32, when the boost control circuit 42a determines that a predetermined time has elapsed since the start of the timer, the boost control circuit 42a shifts to step S35, assuming that communication has ended between the plurality of boost control circuits 42a to 42c.

  In step S35, if the boost control circuit 42a returns a number from the other boost control circuits 42b and 42c, it stores the number returned from the other boost control circuits 42b and 42c. The number is allocated (registered) to itself as an own number. Then, the boost control circuit 42a transmits the number registered as its own number to the other boost control circuits 42b and 42c, and completes the process of assigning its own number.

  During the process of assigning the own number, the boost control circuit 42 in which the corresponding boost circuit 41 has already started up operates as shown in FIG. Here, for the sake of simplicity, it is assumed that the booster circuit 41b connected to the booster circuit 42b has started up, and that the booster control circuit 42b has already been assigned its own number.

  The boost control circuit 42b determines whether or not an activation signal output from the other boost control circuits 42a and 42c has been received (step S41). When the boost control circuit 42b determines that the activation signal output from the other boost control circuits 42a and 42c has been received, the boost control circuit 42b stores its own number for the other boost control circuits 42a and 42c (own number). And returns to step S41. In this way, the boost control circuit 42b informs the boost control circuit 42 that has started the activation that the output number has already been used.

  Further, when the boost control circuit 42b determines in step S41 that it has not received an activation signal from the other boost control circuits 42a and 42c, the numbers registered from the other boost control circuits 42a and 42c are the numbers registered respectively. It is determined whether or not the number has been received (step S43).

  In step S43, when the boost control circuit 42b determines that the number is output from the other boost control circuits 42a and 42c and has received the number, the number is used by the other boost control circuits 42a and 42c. This is stored and the process returns to step S41. If the boost control circuit 42b determines in step S43 that a number has been output from the other boost control circuits 42a and 42c and has not been received, the process returns to step S41.

  In this way, the boost control circuit 42b can know the numbers assigned to the other boost control circuits 42a and 42c even after the boost circuit 41b rises and registers its own number.

  When performing the MPPT control, the boost control circuit 42 to which the numbers are assigned in this way outputs its own number to the other boost control circuits 42 after step S18 shown in FIG. After determining in step S11 that the first signal has not been output, the number that has been output is confirmed. If the output number is the next number after the registered own number, the process proceeds to step S13. Start control. At this time, if the output number is not the number next to the registered number, the other boost control circuit 42 returns to step S11 and waits without performing MPPT control (constant boost ratio control). I do).

  By doing in this way, since the MPPT control can be executed in order in the plurality of boost control circuits 42a to 42c, unevenness in the frequency of performing the MPPT control among the plurality of boost control circuits 42a to 42c can be eliminated ( (A situation where only one boost control circuit performs MPPT control and MPPT control is not performed in another boost control circuit can be avoided).

  For example, as shown in FIG. 4, the power control circuit 22 and the boost control circuits 42 a to 42 c may be connected by a communication line so that the period for performing the MPPT control including the power control circuit may be shifted. By doing so, MPPT control is performed independently between the power control circuit 22 and the boost control circuits 42a to 42c. Therefore, when the MPPT control is performed, the other control circuits 22, 42a to 42c The MPPT control to be performed does not interfere with each other, and accurate MPPT control can be performed.

Further, for example, in the present embodiment, the boost control circuits 42a to 42c perform the constant boost ratio operation in the section in which the MPPT control is prohibited, but the voltage input to the boost circuits 41a to 41c is constant. It is also possible to perform a constant voltage control that operates in a continuous manner. When the boost control circuits 42a to 42c perform a constant boost ratio operation, it is easy to perform overall optimization because the output voltage of the solar cell is changed when MPPT control is performed on the power conditioner 2 side. In addition, when the boost control circuits 42a to 42c perform a constant voltage operation, the voltage input to the boost circuits 41a to 41c (the output voltage of the solar cell) is fixed, so the MPPT operation is performed on the power conditioner 2 side. When performing, it can suppress that the MPPT control performed on the power conditioner 2 side interferes with the MPPT operation performed on the boost control circuits 42a to 42c side, and it becomes easy to maintain the maximum power point of the solar cell.

DESCRIPTION OF SYMBOLS 1a-1c Solar cell 2 Power conditioner 4 Connection box 21 Booster circuit 22 Power conditioner control circuit 23 Inverter circuit 30 Commercial power system 40a-40c Booster unit 41a-41b Booster circuit 42a-42c Booster control circuit 50 Grid interconnection system

Claims (4)

They are respectively connected to the plurality of solar cells, a plurality of boosting circuit that boosts an output voltage of said solar cell
A power conditioner that inputs DC power obtained by combining the DC power output from the plurality of booster circuits, converts the DC power into AC power, and links the solar cell to a commercial power system. In grid interconnection system,
The booster circuit includes:
MPPT control that operates by changing the step-up ratio so as to output the first signal and maximize the output power of the solar cell, and constant step-up ratio control that operates the output voltage of the solar cell at a constant step-up ratio Either one of the controls is selected by the boost control circuit,
The boost control circuit includes:
When the predetermined time has elapsed from the start of the MPPT control, the MPPT control using the last set has been step-up ratio by the MPPT control causes a shift to the boost ratio stabilization control, at the start of the MPPT control wherein the plurality of boosting circuit, after the predetermined time the start of the MPPT control when receiving the first signal output while the other step-up circuit is performing the MPPT control, receiving a first signal It is determined whether or not the first signal is received, and the system interconnection system is performed when the first signal is not received . The boost control circuit outputs the first signal from the start of the MPPT control, and the MPP
The output of the first signal is stopped after a predetermined time has elapsed from the start of T control.
Item 5. The grid interconnection system according to item 1. The boost control circuit controls the boost ratio when starting MPPT control and the MPPT control.
The step-up ratio at the end is memorized, and whether these step-up ratios are increased or decreased compared
Output a second signal,
  A step-up control circuit that performs the MPPT control next to the step-up control circuit that outputs the second signal,
Change the first step-up ratio change with the same content as indicated by the second signal.
The grid interconnection system according to claim 2, wherein The plurality of boost control circuits are started up when the boost circuit connected to each of them is started up.
Number in order
  When the boost control circuit ends the MPPT control and stops outputting the first signal
The number next to the number assigned to the boost control circuit that stopped outputting the first signal is assigned.
The other step-up control circuit is configured to execute the MPPT control.
Grid connection system.