JP5473141B2 - Storage power conditioner system - Google Patents

Description

  The present invention relates to a power storage power conditioner system that performs linkage control between a photovoltaic power generation system and a power storage system.

In recent years, a power generation system using a new energy source, particularly a natural energy source, has been actively studied from the viewpoint of preventing global warming.
Among them, the photovoltaic power generation system has been steadily researched and developed so far, and as a result, the power generation cost is approaching the same level as the commercial power price purchased from the existing system.
Against this backdrop, the spread of solar power generation systems is still making good progress.

On the other hand, as solar power generation systems become more widespread, this time, the reverse power flow to the grid, that is, when surplus power is sold to the power company, etc. The flow of electric power (active power) increases, which causes fundamental and social problems such as system voltage rise and system frequency fluctuation.

  In order to alleviate the above problem, a system capable of storing generated energy including surplus generated energy in a solar power generation system in a storage battery and reducing the burden on the system, that is, a solar power generation system and a power storage system A multi-type power conditioner system that can charge the storage battery with the power generation energy of the photovoltaic power generation system is indispensable. At present, various proposals have been made for the multi-type power conditioner system.

By the way, even if a multi-type power conditioner system appears, the existing solar power generation system, which has been widely used so far, is structurally simply added to the above-mentioned multi-type power conditioner system simply by adding a storage system as a retrofit. The same function could not be demonstrated, and therefore, when the equipment was renewed, the existing photovoltaic power generation system or its power conditioner was discarded and replaced with a multi-type power conditioner system. .
However, this has a very heavy burden on the user from the viewpoint of equipment replacement costs, and as a result, has become a major obstacle to popularizing multi-type power conditioner systems.

  Here, the power storage system itself is a system that aims to level the power throughout the day and reduce the electricity bill by charging the battery with cheap late-night power and using it during the day. Also, the storage power conditioner that performs management is not connected to the photovoltaic power generation system. Therefore, while it is possible to construct a system at a relatively low cost, it has been impossible to control the existing photovoltaic power generation system in conjunction with each other (see FIG. 9).

FIG. 9 is a diagram for explaining a conventional example. This figure shows the entire system 100 ′ when the power storage system is installed in a form added to the existing photovoltaic power generation system. The solar power generation system is connected to the solar cell 1 and the solar cell 1 to control the generated power from the solar cell 1 and supply it to the household load R, and also sell power by making it flow backward to the grid G. The PV power conditioner 10 that can also be configured, and a PV control current transformer S1 that can detect the power generation output from the solar cell 1 that flows backward to the grid G. The PV control current transformer S1 is inserted between the power lines of the system G and the PV power conditioner output that outputs the generated power from the solar cell 1, and the signal output detected by the PV control current transformer S1 is PV. Input to the inverter 10.
The power storage system is connected to the storage battery 2 and the storage battery 2, performs charge / discharge control of the storage battery 2, supplies stored power to the household load R, and charges the storage battery 2 with power from the system G. And a power storage control current transformer S2 capable of detecting a current from the system G to the household load R side or the storage battery 2 side. The power storage control current transformer S2 is connected between the power line between the power line G and the power storage power conditioner input / output unit that receives the power from the system G and outputs the discharged power from the storage battery 2 to the household load R. The signal output detected by the power storage control current transformer S2 is input to the power storage power conditioner 20 ′.
As shown in FIG. 9, in the conventional system 100 ′ including the photovoltaic power generation system and the power storage system, the power storage control current transformer S2 is inserted in the subsequent stage of the PV control current transformer S1 when viewed from the system G. It is.
Further, as shown in FIG. 9, in the system 100 ′ according to the conventional example, the PV power conditioner 10 and the storage power conditioner 20 ′ are not signal-connected, and the photovoltaic power generation system and the storage system are linked and controlled. There is nothing.

FIG. 10 is a diagram for explaining a more detailed configuration of the conventional example shown in FIG. In addition, in FIG. 10, the detail is abbreviate | omitted about the charging / discharging circuit of the storage battery with which electrical storage power conditioner 20 'is equipped.
The power storage power conditioner 20 ′ includes a current sensor amplifier 28 ′ that detects at least a current from the system G to the household load R side or the storage battery 2 side from the signal output of the power storage control current transformer S2 input to the power storage power conditioner 20 ′. It has been. The output of the current sensor amplifier 28 ′ is connected to the comparator 29. The output of the comparator 29 that finally sets the control target voltage VB is connected to the control circuit of the inverter 26.

  The operation of the storage power conditioner 20 ′ during discharging and charging of the storage battery 2 will be described. First, during discharging, the bidirectional converter 21 and the bidirectional inverter 24 provided in the storage power conditioner 20 ′ are respectively The discharge converter 23 and the inverter 26 are switched. The switching is performed by the timer 32 or manually through the mode control means 33 '. At the time of discharging, the output voltage VB of the inverter 26 is controlled so that the grid active power VB · IG output from the sensor circuit 27 ′ is zero. This control method corresponds to so-called reverse power flow prevention control. Through such control, the storage power conditioner 20 ′ supplies the discharged power from the storage battery 2 to the household load R within the maximum supply power range.

On the other hand, at the time of charging, the bidirectional converter 21 and the bidirectional inverter 24 provided in the storage power conditioner 20 ′ are switched to the charging converter 22 and the PFC converter 25, respectively. As in discharging, the switching is performed by the timer 32 or manually through the mode control means 33 ′.
The storage battery 2 is charged by constant current (CC) or constant voltage (CV) control at a predetermined current value or voltage value according to the type, maximum capacity, remaining capacity, etc. of the storage battery. At this time, the power required for charging is supplied from the system G.

JP 2007-124864 A JP 2008-72774 A JP 2004-208426 A

  Here, in Patent Document 1, the voltage detection unit (DC power supply power detection unit) 10 connected to the output of the solar cell 2 switches and controls the switching unit 19 according to the amount of power generated by the solar cell 2. It is disclosed that power generation energy is stored in a storage battery 11 or supplied to a household load (AC 100 V).

  Patent Document 2 includes a power detection unit 11 that detects output power of a natural energy power generation facility (solar power generation 7), and charges a storage battery connected to a power conditioner (PCS) according to the detection result. It is disclosed.

  Furthermore, Patent Document 3 discloses that a solar cell output current detection unit is provided and control is performed so that the sum of the solar cell output current and the fuel cell output is equal to the load current according to the detection result.

  However, all of the techniques disclosed in Patent Documents 1 to 3 relate to a so-called centralized control system corresponding to the multi-type power conditioner system. Here, of course, if it is centralized control, it is obvious by a so-called person skilled in the art that the power generated by the solar battery can be charged into the storage battery.

On the other hand, when the existing (or newly installed) photovoltaic power generation system and the power storage systems added to it are each composed of independent control systems (solar power conditioner and storage power conditioner), each system is naturally , Each controlled and operated independently.
That is, the conventional photovoltaic power generation system and the power storage system provided as independent products have not been controlled in cooperation with each other.

  As described above, in the above independent control system provided in the conventional solar power generation system and the power storage system provided as independent products, respectively, the two are linked to each other, for example, the solar power generation system There is a problem that it is not possible to perform control such as charging the storage battery with the generated energy including surplus power obtained in (1).

  Therefore, the present invention solves the above-described problem, and even if the photovoltaic power generation system and the power storage system are controlled by independent control systems, the two can be linked and controlled with each other. It is an object of the present invention to provide an electric storage power conditioner system that makes it possible to charge a storage battery with power generated by the system.

  As a result of various studies to solve the above problems, the inventor of the present application can further monitor the output from the photovoltaic power generation system for the existing (or newly installed) photovoltaic power generation system and the power storage system added thereto. It has been found that the above problem can be solved by connecting a current transformer and inputting a signal output from the current transformer to a power storage power conditioner of the power storage system, thus completing the present invention.

The power storage power conditioner system of the present invention that can solve the above problems is (1) a power storage power conditioner system that performs linkage control between a photovoltaic power generation system and a power storage system,
The solar power generation system is
Solar cells,
A PV control current transformer that is interposed on a main power line having one end connected to the system and the other end connected to a load, and capable of detecting a current flowing into and out of the system;
One end is connected to the solar cell, and the other end is interposed on the PV power line connected to the main power line on the downstream side of the PV control current transformer when the system is on the upstream side, and the generated power from the solar cell is loaded. And a PV power conditioner that controls the output of the converted power based on the current detected by the current transformer for PV control.
The power storage system includes:
A storage battery,
A current transformer for storage control that is interposed on the main power line at a downstream side of a connection portion between the main power line and the PV power line, and that can detect a current from the system toward the load or the storage battery,
One end is connected to the storage battery, and the other end is interposed on the power storage power line connected to the main power line on the downstream side of the power storage control current transformer, and the storage battery is charged based on the current detected by the power storage control current transformer. A storage power conditioner that performs discharge control, and
It further comprises a PV power monitor current transformer capable of detecting the generated power from the solar cell,
In addition to the current detected by the current transformer for power storage control, the power storage power conditioner is obtained by subtracting the power generated by the solar cell from the power consumed by the load using the current detected by the PV power monitor current transformer. And charge / discharge control for the storage battery is performed.

In addition, the power storage power conditioner system according to claim 2 of the present application is (2) the power storage power conditioner system according to claim 1 of the present application,
The PV power monitoring current transformer is provided on the PV power line, is interposed on the output side of the PV power conditioner, and detects a current output from the PV power conditioner. It is.

Further, in the storage power conditioner system according to claim 3 of the present application, (3) the storage power conditioner is provided with a storage battery side input / output portion connected to the storage battery and a backbone side input / output portion connected to the backbone power line. An electric storage power conditioner system according to claim 2, wherein
The power storage power conditioner is:
A bidirectional converter connected to the storage battery side input / output part;
A bidirectional inverter connected between the bidirectional converter and the backbone input / output unit;
A sensor circuit for inputting a current signal output from the power storage control current transformer and a current signal output from the PV power monitor current transformer, and comparing both current levels;
A control circuit for controlling the bidirectional converter and the bidirectional inverter according to a comparison result by the sensor circuit;
It is characterized by comprising.

Moreover, the storage power conditioner system according to claim 4 of the present application is (4) the storage power conditioner system according to claim 3 of the present application,
The bidirectional converter comprises a discharge converter and a charge converter;
The bidirectional inverter comprises an inverter and a PFC converter;
The discharge converter and the inverter are used when the storage battery is discharged, and the charge converter and the PFC converter are used when the storage battery is charged.

In addition, the storage power conditioner system according to claim 5 of the present application is (5) the storage power conditioner system according to claim 4 of the present application,
The control circuit includes mode switching means capable of switching the operation mode of the power storage power conditioner between a charge mode for charging the storage battery and a discharge mode for discharging the storage battery.
The sensor circuit compares the grid current IG detected by the power storage control current transformer and the PV power conditioner current IP detected by the PV power monitor current transformer, and outputs the difference IG-IP.
The mode switching means switches the operation mode between the charge mode and the discharge mode according to the polarity of the differential IG-IP.

In addition, the storage power conditioner system according to claim 6 of the present application is (6) the storage power conditioner system according to claim 5 of the present application,
When the difference IG−IP ≧ 0, the control circuit sets the operation mode to the discharge mode, and controls the average value of VB · (IG−IP) to be zero by changing the output voltage VB of the inverter. While
When the difference IG−IP <0, the control circuit sets the operation mode to the charging mode, and changes the output current ILB of the charging converter corresponding to the charging current to change the output voltage VB · (IG− Control is performed so that the average value of IP) becomes zero.

Moreover, the storage power conditioner system according to claim 7 of the present application is (7) the storage power conditioner system according to claim 3 of the present application,
The sensor circuit is capable of detecting the generated power from the solar cell only by the current detected by the PV power monitor current transformer in addition to the surplus power,
When the PV power conditioner current IP> 0 detected by the PV power monitor current transformer and charging is permitted by control based on a timer or control based on an external command, the control circuit sets the operation mode to the charge mode. And the storage battery is charged with the generated power from the solar battery.

In addition, the storage power conditioner system according to claim 8 of the present application is (8) the storage power conditioner system according to claim 7 of the present application,
The control circuit charges the storage battery in a state where the output current ILB of the charging converter corresponding to the charging current is controlled to be a value obtained by dividing the average value of the output voltage VB · IP of the inverter by the storage battery voltage VLB. It is characterized by doing.

In addition, the storage power conditioner system according to claim 9 of the present application is (9) the storage power conditioner system according to claim 1 of the present application,
The PV power monitoring current transformer is disposed on the main power line, upstream of the connection portion between the PV power line and the main power line, and detects a current flowing into and out of the system. It is a feature.

Further, in the storage power conditioner system according to claim 10 of the present application, (10) the storage power conditioner is provided with a storage battery side input / output part connected to the storage battery and a basic input / output part connected to the main power line. A storage power conditioner system according to claim 9 of the present application,
The power storage power conditioner is:
A bidirectional converter connected to the storage battery side input / output part;
A bidirectional inverter connected between the bidirectional converter and the backbone input / output unit;
A sensor circuit to which a current signal output from the current transformer for power storage control and a current signal output from the PV power monitor current transformer are input;
It comprises a control circuit for controlling the bidirectional converter and the bidirectional inverter according to the polarity of the current output from the PV power monitor current transformer.

Moreover, the storage power conditioner system according to claim 11 of the present application is (11) the storage power conditioner system according to claim 10 of the present application,
The control circuit includes mode switching means capable of switching the operation mode of the power storage power conditioner between a charge mode for charging the storage battery and a discharge mode for discharging the storage battery.
When the current IGO <0 detected by the PV power monitor current transformer and charging is permitted by control based on a timer or control based on an external command, the control circuit sets the operation mode to charge mode, While controlling the average value of the output voltage VB · IGO of the inverter to be zero by changing the output current ILB of the charging converter corresponding to the charging current,
When the current IGO detected by the PV power monitor current transformer is equal to or greater than 0 and discharge is permitted by control based on a timer or control based on an external command, the operation mode is set to discharge mode, and the output voltage of the inverter By changing VB, control is performed such that the average value of the grid current IG · VB detected by the current transformer for power storage control becomes zero.

Further, in the storage power conditioner system according to claim 12 of the present application, (12) the storage power conditioner is provided with a storage battery side input / output portion connected to the storage battery and a backbone side input / output portion connected to the backbone power line. An electric storage power conditioner system according to claim 1, wherein
A load current monitoring current transformer that is interposed on the main power line at a downstream side of a connection portion between the main power line and the power storage power line and capable of detecting a current supplied to the load;
The power storage power conditioner is:
A bidirectional converter connected to the storage battery;
A bidirectional inverter connected between the bidirectional converter and the backbone input / output unit;
A current signal output from the power storage control current transformer, a current signal output from the PV power monitor current transformer, and a current signal output from the load current monitor current transformer are input. A sensor control operation unit that controls the bidirectional converter and the bidirectional inverter;
The sensor control calculation unit is configured to charge the storage battery according to changes in current signals respectively output from the current transformer for power storage control, the PV power monitor current transformer, and the load current monitor current transformer; The operation mode is switched to a discharge mode for discharging the storage battery.

Moreover, the storage power conditioner system according to claim 13 of the present application is (13) the storage power conditioner system according to claim 12 of the present application,
The sensor control calculation unit includes a PV power conditioner current IP detected by the PV power monitor current transformer, a current IB output from the power storage power conditioner, and a power storage control current transformer in the discharge mode. Using the detected system current IG, the load current IL consumed by the load is supplied at a predetermined ratio determined in advance.

According to the present invention, even if the photovoltaic power generation system and the power storage system are controlled by independent control systems, the two can be linked and controlled, and the power generation energy of the photovoltaic power generation system is stored in the storage battery. An electric storage power conditioner system that can be charged can be provided.
In other words, by combining the power storage power conditioner system of the present invention with an existing (or newly installed) solar power generation system regardless of the manufacturer, the same function as a multi-type power conditioner system consisting of a so-called centralized control system is realized. It becomes possible to do.
Further, according to the present invention, the generated power of the existing photovoltaic power generation system can be stored in the storage battery, so that the burden on the system due to the so-called reverse power flow can be reduced.

  Further, according to the present invention, an existing photovoltaic power generation system is converted into a multi-type power conditioner system capable of charging the storage battery with the power generation energy of the photovoltaic power generation system by linking and controlling the photovoltaic power generation system and the power storage system. It is no longer necessary to replace the whole and the equipment replacement cost can be greatly reduced.

  The storage power conditioner system of the present invention has a basic configuration in which a signal output from a current transformer capable of monitoring the output from the photovoltaic power generation system is input to the storage power conditioner of the storage system. It is possible to charge the storage battery with the power generation energy of the solar power generation system without any modification to the existing (or new) solar power generation system. In addition, system construction can be realized at low cost.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram attached to Example 1 of the electrical storage power conditioner system of this invention. It is a schematic diagram explaining the difference with a prior art example and this invention. It is a block diagram attached and demonstrated to the electrical storage power conditioner system of Example 1. FIG. It is a figure attached to the detailed structure of the electrical storage power conditioner system of Example 1. FIG. It is a figure attached to the effect | action of the electrical storage power conditioner system of Example 1. FIG. It is a block diagram attached to Example 2 of the electrical storage power conditioner system of this invention. It is a block diagram attached to Example 3 of the electrical storage power conditioner system of this invention. It is a block diagram attached to Example 4 of the electrical storage power conditioner system of this invention. It is a figure explaining a prior art example. It is a figure attached to the detailed structure of a prior art example.

  Hereinafter, based on an Example, it attaches and demonstrates to the electrical storage power conditioner system of this invention.

[Constitution]
FIG. 1 is a schematic diagram illustrating the first embodiment of the power storage power conditioner system according to the present invention. In the following descriptions, the same reference numerals are used for the same components as in the conventional example.
As shown in FIGS. 1 and 2 (b), the power storage power conditioner system 100 of this embodiment is provided with a PV power monitor current transformer S3 at the output of the PV power conditioner 10 as compared with the conventional example shown in FIG. By monitoring the power generation status of the solar power generation system, linkage control between the existing (or new) solar power generation system and the power storage system added thereto is realized.

  The present invention is based on the premise that the existing (or newly installed) photovoltaic power generation system and the power storage systems added to the system are independent control systems (solar power conditioner and storage power conditioner). This is fundamentally different from that related to a so-called centralized control system.

This is clear even if FIG. 2 (a) and (b) are compared. FIG. 2 is a schematic diagram for explaining the difference between the conventional example and the present invention.
Here, FIG. 2A is a simple arrangement of the system disclosed in Patent Document 3 cited as an example of a so-called centralized control system. In the example of FIG. 2A, the signal output from the sensor SA provided in the front stage of the power conversion device C1 and the sensor SB provided in the front stage of the power conversion device C2 as viewed from the system is the power adjustment device. Input to P (central control unit). Similarly, the signal output from the sensor SC provided in the previous stage of the household load R is also input to the power adjustment device P. The power adjustment device P calculates a command to the power conversion device C1 of the photovoltaic power generation system and the power conversion device C2 of the power storage system based on each signal output. The command output from the power adjustment device P is input to the power conversion devices C1 and C2, whereby the power generation output of the solar cell 1 and the charge / discharge of the storage battery 2 are controlled.

On the other hand, FIG. 2B is a schematic diagram of a system according to the present invention. 2 (b) and FIG. 1 will be sequentially described with respect to the system according to the present invention. The solar power generation system is connected to the solar cell 1 and the solar cell 1, and the generated power from the solar cell 1 is controlled. The power output from the PV power conditioner 10 that can be supplied to the household load R and can also be sold back to the grid G, and the solar cell 1 that flows back to the grid G can be detected. Current control S1 for PV control. The PV control current transformer S1 is inserted between the power lines of the system G and the PV power conditioner output that outputs the generated power from the solar cell 1, and the signal output detected by the PV control current transformer S1 is PV. Input to the inverter 10. That is, the PV control current transformer S1 is interposed on the main power line L1 having one end connected to the system G and the other end connected to the household load R, and can detect a current flowing into and out of the system G. Further, the PV power conditioner 10 is connected to the PV power line L2 connected to the main power line L1 on the downstream side of the PV control current transformer S1 when one end is connected to the solar cell 1 and the other end is set to the upstream side of the system G. Then, the generated power from the solar cell 1 is converted into a state usable for the household load R, and the output of the converted power is controlled based on the current detected by the PV control current transformer S1.
The power storage system is connected to the storage battery 2 and the storage battery 2, performs charge / discharge control of the storage battery 2, supplies stored power to the household load R, and charges the storage battery 2 with power from the system G. And a power storage control current transformer S2 capable of detecting a current from the system G to the household load R side or the storage battery 2 side. The power storage control current transformer S2 is connected between the power line between the power line G and the power storage power conditioner input / output unit that receives the power from the system G and outputs the discharged power from the storage battery 2 to the household load R. The signal output detected by the power storage control current transformer S 2 is input to the power storage power conditioner 20. That is, the power storage control current transformer S2 is interposed on the main power line L1 downstream of the connection portion between the main power line L1 and the PV power line L2, and detects a current from the system G toward the home load R or the storage battery 2 It is possible. The power storage power conditioner 20 is connected to a power storage power line L3 having one end connected to the storage battery 2 and the other end connected to the main power line L1 downstream of the power storage control current transformer S2, and is connected to the power storage control current transformer S2. Based on the detected current, charge / discharge control for the storage battery 2 is performed.
As described above, in the power storage power conditioner system 100 of the present embodiment including the solar power generation system and the power storage system, the power storage control current transformer S2 is inserted in the subsequent stage of the PV control current transformer S1 when viewed from the system G. It is.

Furthermore, in this embodiment, a PV power monitoring current transformer S3 capable of detecting the power generation output from the solar cell 1 is provided. The PV power monitoring current transformer S3 is inserted between the power lines of the grid G and the PV power conditioner output that outputs the generated power from the solar cell 1, and the detected signal output is input to the storage power conditioner 20. Is done. Here, the PV power monitor current transformer S3 is inserted at a position after the PV control current transformer S1 and before the power storage control current transformer S2 when viewed from the system G. In other words, the PV power monitoring current transformer S3 is disposed on the PV power line L2 and on the output side of the PV power conditioner 10, and detects a current output from the PV power conditioner 10.
According to the present embodiment, the power storage power conditioner 20 uses the signal output from the PV power monitor current transformer S3 inserted in the position to perform linkage control between the solar power generation system and the power storage system. It is configured. That is, the power storage power conditioner 20 subtracts the generated power of the solar cell 1 from the power consumed by the household load R using the current detected by the PV power monitor current transformer S3 in addition to the current detected by the current transformer S2 for power storage control. The surplus power is detected and charge / discharge control for the storage battery 2 is performed.

[Operation]
Next, the control of the power storage power conditioner system 100 of this embodiment will be described. Normally, control is performed by software control. FIG. 3 shows a block diagram.
The storage power conditioner 20 includes a bidirectional converter (DC-DC converter) 21 and a bidirectional inverter 24 connected to the control system 52. Specifically, the storage power conditioner 20 is provided with a storage battery side input / output part 20a connected to the storage battery 2 and a basic side input / output part 20b connected to the main power line 11, and a bidirectional converter is provided in the storage battery side input / output part 20a. 21 is connected, and the bidirectional inverter 24 is connected to the trunk side input / output part 20b.
The control system 52 controls the bidirectional converter 21 and the bidirectional inverter 24 based on a command from the software 51 and is also connected to the protection system 53.

  As shown in FIG. 4, the bidirectional converter 21 includes a discharge converter 23 and a charge converter 22, and the bidirectional inverter 24 includes an inverter 26 and a PFC converter 25. The discharge converter 23 and the inverter 26 are used when discharging, and the charge converter 22 and the PFC converter 25 are used when charging. These controls are performed by software 51 that operates the control system 52. Details will be described below with reference to FIG.

  As shown in FIG. 3, the control system 52 is operated by the software 51, and the protection system 53 and the sensor system 54 are also operated by the software 51. The sensor system 54 is connected to the power storage control current transformer S2 and the PV power monitor current transformer S3. In addition to the signal output from the power storage control current transformer S2, the signal output from the PV power monitor current transformer S3 is input. It is comprised so that.

FIG. 4 is a diagram for explaining the control of the storage power conditioner system 100 according to the present embodiment described with reference to FIG. 3 in more detail using a partial circuit expression. As in FIG. 10, the details of the charge / discharge circuit of the storage battery provided in the storage power conditioner 20 are also omitted in FIG. 4.
The difference from the conventional example is also apparent by comparing FIG. 4 with FIG. 10 described above.

Specifically, in this embodiment, a current signal output from the storage control current transformer S2 and a current signal output from the PV power monitor current transformer S3 are input to the sensor circuit 27, and both current levels are compared. It is configured. That is, the current sensor amplifier 28 is a differential input, and the difference between the system current IG and the PV power conditioner current IP (the output current of the PV power conditioner 10 detected by the PV power monitor current transformer S3) is controlled. It is the composition used for.
Further, in this embodiment, the output of the sensor circuit 27 is also connected to the mode control means 33, and as will be described in detail below, a charging mode for charging the storage battery 2 with the polarity of the differential IG-IP And a mode control that automatically switches between a discharge mode for discharging the storage battery 2 is performed. In order to prevent malfunction, the mode control means 33 of the present embodiment is configured such that hysteresis characteristics appear when switching between the charge mode and the discharge mode. The mode control means 33 corresponds to a part of the control system 52 operated by the software 51 in FIG. 3, and the sensor circuit 27 corresponds to the sensor system 54 in FIG.
Further, in this embodiment, the control target is switched depending on the polarity of the differential IG-IP. This point will also be described in detail below. In this embodiment, in order to prevent erroneous operation, a hysteresis characteristic appears when the control target is switched.

  The operation of the storage power conditioner 20 in the discharge mode and the charge mode will be described. First, when IG-IP ≧ 0, the storage power conditioner 20 enters the discharge mode. In the discharge mode, the storage power conditioner 20 changes the output voltage VB of the inverter 26 and is controlled so that the average value of VB · (IG-IP) becomes zero.

  In this embodiment, when the load current IL to the household load R is larger than the PV power conditioner current IP corresponding to the power generation amount of the solar cell 1, the discharge mode is set, and the power generation amount (PV power conditioner current IP) of the solar cell 1 is Insufficient power is supplied from the storage battery 2 through the storage power conditioner 20. That is, in the equilibrium state where IG = IP, an output current of IB = IL-IP is supplied from the storage power conditioner 20 to the household load R.

  Next, when IG-IP <0, the power storage power conditioner 20 is in the charging mode. In the charging mode, the storage power conditioner 20 is controlled so as to change the output current ILB of the charging converter 22 corresponding to the charging current so that the average value of VB · (IG-IP) becomes zero.

  In this embodiment, when the PV power conditioner current IP corresponding to the power generation amount of the solar cell 1 is larger than the load current IL to the household load R, the charging mode is set, and the power generated by the solar cell 1 (PV power conditioner current IP ), The storage battery 2 is charged through the storage power conditioner 20 with surplus power that is not required at the home load R (load current IL). That is, in the equilibrium state where IG = IP, the storage power conditioner 20 charges the storage battery 2 with a charging current ILB which is a value obtained by dividing the average value of VB · (IG-IP) by the storage battery voltage VLB. ing.

[Action]
Based on the operation described above, the operation of the storage power conditioner system 100 of the present embodiment will be described.
FIG. 5 is a diagram illustrating the operation of the power storage power conditioner system 100 according to the present embodiment. According to the present embodiment, the power storage power conditioner 20 can grasp the power generation amount in the solar power generation system.
Therefore, as shown in FIG. 5 (a), during daytime, for example, depending on the situation of the household load, the power generation energy in the solar power generation system may be stored in the storage battery in addition to supplying the household load. it can.
And at night, as shown in FIG. 5B, the power of the storage battery stored in the daytime can be supplied to the home load, and in some cases, it is necessary for the home load without using midnight power. It is possible to cover all day long electric power with a solar power generation system and a power storage system.

  Thus, according to the present embodiment, the PV power conditioner 10 and the storage power conditioner 20 are separately provided, but the PV power monitor current transformer S3 is provided and the PV power monitored by the PV power monitor current transformer S3 is provided. By inputting the conditioner current IP to the storage power conditioner 20 and linking the PV power conditioner 10 and the storage power conditioner 20, functions and operations equivalent to those of the multi-type power conditioner system are realized.

[Constitution]
Next, a second embodiment of the electric storage power conditioner system of the present invention will be described.
FIG. 6 is a block diagram of the power storage power conditioner system according to the present embodiment. As is apparent from comparison with FIG. 4 showing the block diagram according to the first embodiment, in this embodiment, the configuration of the storage power conditioner 20 including the sensor circuit 27 is different from that of the first embodiment.

To explain in sequence, the sensor circuit 27 has a combination of a current sensor amplifier 28 to which the system current IG and the PV power conditioner current IP are input, a comparator 29, a multiplier 30, and an average value calculation means 31. Another set, that is, a combination of a current sensor amplifier 48 to which the PV power conditioner current IP is input, a comparator 49, a multiplier 40, and an average value calculation means 41 is added.
With this configuration, not only charging (see FIG. 5 (a)) for surplus power (power generation amount in the solar power generation system−power consumption in the home load) realized in the configuration of the first embodiment, but also sunlight. It is possible to directly charge the storage battery with the amount of power generated by the power generation system. As described above, according to the present embodiment, it is possible to expand variations of the charging mode.

Specifically, in this embodiment, in addition to the average value calculation means 31, the output of the average value calculation means 41 is also connected to the mode control means 33, depending on the presence or absence of the PV power conditioner current IP. The output of the comparator 49 is switched, the operation mode is switched to the charging mode, and the storage battery 2 can be charged. The outline of the control will be described separately later.
Here, the mode control means 33 is configured to exhibit a hysteresis characteristic when switching between the charge mode and the discharge mode, in order to prevent malfunction, as in the first embodiment.
In this embodiment, the mode control means 33 corresponds to a part of the control system 52 operated by the software 51 in FIG. 3, and the sensor circuit 27 corresponds to the sensor system 54 in FIG.

Further, the output from the average value calculating means 41 is for controlling the charge converter 22 of the bidirectional converter 21 when in the charge mode, and for controlling the inverter 26 of the bidirectional inverter 24 when in the discharge mode. The output from the average value calculation means 31 is selectively used.
Except for the above points, the storage power conditioner system according to the present embodiment is substantially the same as the configuration of the first embodiment.

[Operation]
Next, the control of the power storage power conditioner system 101 of this embodiment will be described.
The storage power conditioner 20 is operated when the PV power conditioner current IP> 0 detected by the PV power monitor current transformer S3 and charging is permitted by control based on the timer 32 or control based on an external command. Is in charging mode. At this time, the storage battery 2 is charged by controlling the value of the output current ILB of the charging converter 22 corresponding to the charging current. According to an example, the storage battery 2 is charged by controlling the ILB to a value obtained by dividing the average value of the output voltage VB · IP of the inverter 26 by the storage battery voltage VLB.
The operation in the case of IP = 0 and in the discharge mode is the same as that described in the first embodiment.
Thus, according to the present Example, it becomes possible to directly charge the storage battery with the power generation amount itself in the solar power generation system.

[Constitution]
Next, a third embodiment of the electricity storage power conditioner system of the present invention will be described.
FIG. 7 is a block diagram of the power storage power conditioner system according to the present embodiment.
In the present embodiment, unlike the first and second embodiments, the PV power monitor current transformer S3 ′ is inserted in the previous stage of the PV control current transformer S1 when viewed from the system G. In other words, the PV power monitor current transformer S3 ′ is disposed on the main power line L1 and upstream from the connection portion between the PV power conditioner 10 (PV power line L2) and the main power line L1. Detect current flowing in and out.
Further, in this embodiment, as is apparent from comparison with FIG. 4 showing the block diagram according to the first embodiment and FIG. 6 showing the block diagram according to the second embodiment, the storage power conditioner including the sensor circuit 27 is also clear. The configuration of 20 is different from the first and second embodiments.

To explain in sequence, the sensor circuit 27 has another set in addition to the combination of the current sensor amplifier 28 to which the system current IG is input, the comparator 29, the multiplier 30, and the average value calculating means 31, that is, the system G. , A current sensor amplifier 48 to which a current IGO detected by the PV power monitor current transformer S3 ′ inserted upstream of the connection portion between the PV power conditioner 10 and the main power line L1 is input, and a comparator 49 A combination of the multiplier 40 and the average value calculation means 41 is added.
Also with this configuration, it is possible to perform charging (see FIG. 5A) for surplus power (the amount of power generated by the photovoltaic power generation system—the amount of power used at home load) realized by the configuration of the first embodiment. .

Even when the PV power monitor current transformer S3 ′ is inserted upstream of the connection portion between the PV power conditioner 10 and the main power line when viewed from the system G, the surplus power is charged as in the first embodiment. As a reason that can be performed, for example, when the storage power conditioner 20 is not in the discharge mode,
PV power monitor power detected by current transformer S3 ′ (power before system) = electric power used at home load R−power generated in solar power generation system = surplus power,
It becomes the relationship. In the present embodiment, the surplus power is controlled using the above relationship.
As described above, the arrangement position of the PV power monitor current transformer can be variously changed as long as the surplus power can be controlled as long as the surplus power can be controlled.

  The configuration in which the output from the current sensor amplifier 28 to which the system current IG is input is finally used for controlling the inverter 26 of the bidirectional inverter 24 is different from the configuration of the conventional example shown in FIG. As understood from this, in the present embodiment, the current storage control current transformer S2 constituting the power storage system is used for reverse power flow control as in the conventional example.

[Operation]
Next, the control of the power storage power conditioner system 102 of this embodiment will be described.
The storage power conditioner 20 of this embodiment has a function of switching the operation mode of the storage power conditioner 20 according to the polarity of the current IGO detected by the PV power monitor current transformer S3 ′. For example, in the present embodiment, when the above IGO <0, the generated power in the photovoltaic power generation system is in reverse power flow, so that the operation mode is switched to the charging mode in order to charge the storage battery with the current. .
In addition, in order to prevent malfunctioning as in the above embodiments, the present embodiment is also configured such that hysteresis characteristics appear when switching between the charge mode and the discharge mode.

  Specifically, when the current IGO detected by the PV power monitor current transformer S3 ′ ≧ 0 and discharge is permitted by control based on the timer 32 or control based on an external command, the operation mode is set to the discharge mode. The storage power conditioner 20 is controlled so that the average value of VB · IG becomes zero by changing the output voltage VB of the inverter 26.

  On the other hand, the storage power conditioner 20 has an operation mode when the current IGO <0 detected by the PV power monitor current transformer S3 ′ and charging is permitted by control based on the timer 32 or control based on an external command. The charging mode is set, and the average value of the output voltage VB · IGO of the inverter 26 is controlled to be zero by changing the output current ILB of the charging converter 22 corresponding to the charging current.

  In this embodiment, when the PV power conditioner current IP corresponding to the power generation amount of the solar cell 1 is larger than the load current IL to the household load R, the charging mode is set, and the power generated by the solar cell 1 (PV power conditioner current) IP), the storage battery 2 is charged through the storage power conditioner 20 with surplus power that is not required at the home load R (load current IL). That is, in the equilibrium state where IG = IP, the storage power conditioner 20 charges the storage battery 2 with a charging current ILB which is a value obtained by dividing the average value of VB · (IP-IL) by the storage battery voltage VLB. ing.

Looking at an example of the control procedure,
PV power monitor Current power detected by the current transformer S3 ′ = Amount of power used at home load R−Discharged power from the storage power conditioner 20−Amount of power generated in the photovoltaic power generation system,
And
i) When the power before the system is less than 0, surplus power is generated, so that the power storage power conditioner 20 is controlled in a direction to reduce the discharge power.
ii) In addition, even if the discharge power from the storage power conditioner 20 is 0, if the power before the system is <0, the power generation amount in the solar power generation system exceeds the power consumption amount in the household load R. Is changed to the charging mode, and the control to charge the storage battery 2 is performed so that the power before the system becomes zero.
In this embodiment, the control for charging the storage battery 2 with surplus power is realized in this way.

[Constitution]
Next, a fourth embodiment of the power storage power conditioner system of the present invention will be described.
FIG. 8 is a block diagram of the power storage power conditioner system according to the present embodiment.
In the storage power conditioner system 103 according to the present embodiment, in addition to the PV control current transformer S1, the storage control current transformer S2, and the PV power monitor current transformer S3, the current supplied to the household load R can be detected. A load current monitoring current transformer S4 is provided. The load current monitoring current transformer S4 is inserted between the power line of the storage power conditioner input / output unit and the household load R, and the signal output detected by the load current monitoring current transformer S4 is input to the storage power conditioner 20. Is done. Here, when viewed from the system G, the load current monitoring current transformer S4 is inserted in the subsequent stage of the power storage control current transformer S2.

  In the present embodiment, the storage power conditioner 20 includes a bidirectional DC / DC converter 21 and a bidirectional inverter 24, a signal output from the storage control current transformer S2, a signal output from the PV power monitor current transformer S3, and a load current. A signal output from the monitoring current transformer S4 is input, and using these inputs, the sensor control calculation unit 37 that controls the bidirectional DC / DC converter 21 and the bidirectional inverter 24, the bidirectional DC / DC converter 21, and The mode switching means 33 is connected to the bidirectional inverter 24 and receives an output from the sensor control calculation unit 37 and controls the operation mode of the bidirectional DC / DC converter 21 and the bidirectional inverter 24.

  In the electricity storage power conditioner system 103 according to the present embodiment, the load current monitoring current transformer S4 is added as described above, and the electricity storage power conditioner 20 has the above configuration, so that the electricity storage control current transformer S2 is provided. The bidirectional DC / DC converter 21 and the bidirectional inverter 24 are controlled in accordance with changes in the signal output from the PV, the PV power monitor current transformer S3, and the signal output from the load current monitoring current transformer S4.

[Operation]
Explaining the control of the storage power conditioner system 103 of the present embodiment, when the operation mode is set to the discharge mode, the storage power conditioner 20 converts, for example, the load current IL into a PV power conditioner having a predetermined ratio. It can be supplied from the negative current IP, the storage battery discharge current IB, and the system current IG.
On the other hand, when the charging mode is set, the charging current ILB to the storage battery 2 is appropriately controlled according to the amount of power used at the household load R and the amount of power generated by the solar power generation system.

[Modification]
As described above, the present invention has been described in detail using each embodiment. However, the present invention is not limited to the configuration described in each embodiment, and various modifications can be made.
For example, the control method between the photovoltaic power generation system and the power storage system described in each embodiment is merely an example, and may be controlled by another control method as necessary.

  In each embodiment, the timer 32 is provided. However, the present invention is not limited to this configuration, and may be omitted.

  Furthermore, in the first embodiment, the protection system 53 is provided, but may be omitted if an equivalent function is ensured by other means.

  As described above, the present invention can link and control both the photovoltaic power generation system and the power storage system with independent control systems. It is clear that the battery storage power conditioner system capable of charging energy to the storage battery is new and useful.

C1, C2 Power converter G System P Power regulator R Household load SA, SB, SC Sensor S1 PV control CT
S2 CT for power storage control
S3, S3 'PV power monitor CT
S4 CT for load current monitoring
DESCRIPTION OF SYMBOLS 1 Solar cell 2 Storage battery 10 PV power conditioner 20, 20 'Accumulation power conditioner 21 Bidirectional converter 22 Charge converter 23 Discharge converter 24 Bidirectional inverter 25 PFC converter 26 Inverter 27, 27' Sensor circuit 28, 28 ', 48 Current Sensor amplifier 29, 49 Comparator 30, 40 Multiplier 31, 41 Average value calculating means 32 Timer 33, 33 'Mode control means 51 Software 52 Control system 53 Protection system 54 Sensor system 100, 101, 102, 103 Power storage power conditioner system

Claims (13)

A power storage power conditioner system that performs linkage control between a photovoltaic power generation system and a power storage system,
The solar power generation system is
Solar cells,
A PV control current transformer that is interposed on a main power line having one end connected to the system and the other end connected to a load, and capable of detecting a current flowing into and out of the system;
One end is connected to the solar cell, and the other end is interposed on the PV power line connected to the main power line on the downstream side of the PV control current transformer when the system is on the upstream side, and the generated power from the solar cell is loaded. And a PV power conditioner that controls the output of the converted power based on the current detected by the current transformer for PV control.
The power storage system includes:
A storage battery,
A current transformer for power storage control that is interposed on the main power line on the downstream side of the connection site between the main power line and the PV power line, and that can detect a current from the system to the load or the storage battery,
One end is connected to the storage battery, and the other end is interposed on the power storage power line connected to the main power line on the downstream side of the power storage control current transformer, and the storage battery is charged based on the current detected by the power storage control current transformer. A storage power conditioner that performs discharge control, and
It further comprises a PV power monitor current transformer capable of detecting the generated power from the solar cell,
In addition to the current detected by the current transformer for power storage control, the power storage power conditioner uses surplus power obtained by subtracting the power generated by the solar cell from the power consumed by the load using the current detected by the PV power monitor current transformer. And a charge / discharge control for the storage battery is performed.   The PV power monitoring current transformer is provided on the PV power line, is interposed on an output side of the PV power conditioner, and detects a current output from the PV power conditioner. Item 2. The electric storage power conditioner system according to Item 1. The storage power conditioner system according to claim 2, wherein the storage power conditioner is provided with a storage battery side input / output portion connected to the storage battery and a backbone side input / output portion connected to the backbone power line,
The power storage power conditioner is:
A bidirectional converter connected to the storage battery side input / output part;
A bidirectional inverter connected between the bidirectional converter and the backbone input / output unit;
A sensor circuit for inputting a current signal output from the power storage control current transformer and a current signal output from the PV power monitor current transformer, and comparing both current levels;
A control circuit for controlling the bidirectional converter and the bidirectional inverter according to a comparison result by the sensor circuit;
A storage power conditioner system characterized by comprising: The bidirectional converter comprises a discharge converter and a charge converter;
The bidirectional inverter comprises an inverter and a PFC converter;
The power storage power conditioner system according to claim 3, wherein the discharge converter and the inverter are used when the storage battery is discharged, and the charge converter and the PFC converter are used when the storage battery is charged. The control circuit includes mode switching means capable of switching the operation mode of the power storage power conditioner between a charge mode for charging the storage battery and a discharge mode for discharging the storage battery.
The sensor circuit compares the grid current IG detected by the power storage control current transformer and the PV power conditioner current IP detected by the PV power monitor current transformer, and outputs the difference IG-IP.
The power storage power conditioner system according to claim 4, wherein the mode switching unit switches an operation mode between the charge mode and the discharge mode according to a polarity of the differential IG-IP. When the difference IG−IP ≧ 0, the control circuit sets the operation mode to the discharge mode, and controls the average value of VB · (IG−IP) to be zero by changing the output voltage VB of the inverter. While
When the difference IG−IP <0, the control circuit sets the operation mode to the charging mode, and changes the output current ILB of the charging converter corresponding to the charging current to change the output voltage VB · (IG− 6. The power storage power conditioner system according to claim 5, wherein an average value of IP) is controlled to be zero. The sensor circuit is capable of detecting the generated power from the solar cell only by the current detected by the PV power monitor current transformer in addition to the surplus power,
When the PV power conditioner current IP> 0 detected by the PV power monitor current transformer and charging is permitted by control based on a timer or control based on an external command, the control circuit sets the operation mode to the charge mode. The storage battery power conditioner system according to claim 3, wherein the storage battery is charged with the generated power from the solar battery.   The control circuit charges the storage battery in a state where the output current ILB of the charging converter corresponding to the charging current is controlled to be a value obtained by dividing the average value of the output voltage VB · IP of the inverter by the storage battery voltage VLB. The power storage power conditioner system according to claim 7.   The PV power monitoring current transformer is disposed on the main power line, upstream of the connection portion between the PV power line and the main power line, and detects a current flowing into and out of the system. The power storage power conditioner system according to claim 1, wherein: The storage power conditioner system according to claim 9, wherein the storage power conditioner is provided with a storage battery side input / output portion connected to the storage battery and a backbone side input / output portion connected to the backbone power line,
The power storage power conditioner is:
A bidirectional converter connected to the storage battery side input / output part;
A bidirectional inverter connected between the bidirectional converter and the backbone input / output unit;
A sensor circuit to which a current signal output from the current transformer for power storage control and a current signal output from the PV power monitor current transformer are input;
A power storage power conditioner system comprising: a control circuit that controls the bidirectional converter and the bidirectional inverter according to a polarity of a current output from the PV power monitor current transformer. The control circuit includes mode switching means capable of switching the operation mode of the power storage power conditioner between a charge mode for charging the storage battery and a discharge mode for discharging the storage battery.
When the current IGO <0 detected by the PV power monitor current transformer and charging is permitted by control based on a timer or control based on an external command, the control circuit sets the operation mode to charge mode, While controlling the average value of the output voltage VB · IGO of the inverter to be zero by changing the output current ILB of the charging converter corresponding to the charging current,
When the current IGO detected by the PV power monitor current transformer is equal to or greater than 0 and discharge is permitted by control based on a timer or control based on an external command, the operation mode is set to discharge mode, and the output voltage of the inverter The power storage power conditioner system according to claim 10, wherein control is performed such that an average value of the system current IG · VB detected by the current transformer for power storage control becomes zero by changing VB. The storage power conditioner system according to claim 1, wherein the storage power conditioner is provided with a storage battery side input / output part connected to the storage battery and a basic side input / output part connected to the main power line,
A load current monitoring current transformer that is interposed on the main power line at a downstream side of a connection portion between the main power line and the power storage power line and capable of detecting a current supplied to the load;
The power storage power conditioner is:
A bidirectional converter connected to the storage battery;
A bidirectional inverter connected between the bidirectional converter and the backbone input / output unit;
A current signal output from the power storage control current transformer, a current signal output from the PV power monitor current transformer, and a current signal output from the load current monitor current transformer are input. A sensor control operation unit that controls the bidirectional converter and the bidirectional inverter;
The sensor control calculation unit is configured to charge the storage battery according to changes in current signals respectively output from the current transformer for power storage control, the PV power monitor current transformer, and the load current monitor current transformer; A power storage power conditioner system, wherein an operation mode is switched to a discharge mode for discharging the storage battery.   The sensor control calculation unit includes a PV power conditioner current IP detected by the PV power monitor current transformer, a current IB output from the power storage power conditioner, and a power storage control current transformer in the discharge mode. 13. The power storage power conditioner system according to claim 12, wherein a load current IL consumed by the load is supplied at a predetermined ratio determined in advance using the detected system current IG.

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