JP2014054084A - Control device and photovoltaic power generation system comprising the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control device capable of easily determining whether a photovoltaic power generation system including a storage battery is in a power selling state or a power purchasing state.SOLUTION: A control device comprises a display screen 83. The display screen 83 includes: a generated power display section 831; a charge/discharge power display section 832: a power consumption display section 833; a power selling/power purchasing state display section 834; and an LED 835. At least the generated power display section 831, the charge/discharge power display section 832, and the power consumption display section 833 are arranged in order of the generated power display section 831, the charge/discharge power display section 832, and the power consumption display section 833 in the direction from left to right facing the display screen 83. The LED 835 emits blue light when the power selling/power purchasing state display section 834 displays a state of power selling, and emits orange light when the power selling/power purchasing state display section 834 displays a state of power purchasing.

Description

  The present invention relates to a control device and a solar power generation system including the control device.

  Conventionally, an energy equipment operation status display monitor that visually gives motivation for energy saving is known (Patent Document 1).

  This energy equipment operation status display monitor includes a power generation information display unit and a power consumption information display unit. The power generation information display unit and the power consumption information display unit are arranged adjacent to the screen of the energy equipment operation status display monitor.

  In the power generation information display unit, the total power generation amount from the count start time on the current day to the current time is displayed as a bar graph. In the power consumption information display unit, the total consumption from the count start time of the day to the current time is displayed as a bar graph.

  As a result, the difference between the total power generation amount and the total consumption amount can be understood at a glance, which is a strong motivation for energy saving after the current time.

JP 2008-141843 A

  However, since the energy equipment operation status display monitor described in Patent Document 1 does not display the charge / discharge power for charging / discharging the storage battery, the state of the solar power generation system including the storage battery is the power sale state and the power purchase. There is a problem that it is difficult to display the status.

  According to the embodiment of the present invention, there is provided a control device that can easily determine whether the state of a photovoltaic power generation system including a storage battery is a power sale state or a power purchase state.

  Further, according to the embodiment of the present invention, there is provided a photovoltaic power generation system including a control device that can easily determine whether the state of the photovoltaic power generation system including the storage battery is a power sale state or a power purchase state. provide.

  According to the embodiment of the present invention, the control device is a control device used in a solar power generation system including a solar cell, a power system, a storage battery, and a load, and includes a power detection unit, a display screen, and a control unit. With. The power detection means detects generated power generated by the solar battery, charge / discharge power when charging / discharging the storage battery, and power consumption in the load. The display screen includes a generated power display section that displays generated power, a charge / discharge power display section that displays charge / discharge power, a power consumption display section that displays power consumption, and a power sale that is in a state of selling power to the power system. A power sale / power purchase state display unit that displays either the state or the power purchase state in which power is purchased from the power system. The control means determines whether the state of the photovoltaic power generation system is a power sale state or a power purchase state based on a current flowing through the power system, and generates power, charge / discharge power, power consumption, and the power generation system. The display screen is controlled so that the state is displayed on the generated power display unit, the charge / discharge power display unit, the power consumption display unit, and the power sale / purchase status display unit, respectively. And at least the generated power display unit, the charge / discharge power display unit, and the power consumption display unit are in the order of the generated power display unit, the charge / discharge power display unit, and the power consumption display unit in the direction from left to right toward the display screen. Has been placed.

  According to the embodiment of the present invention, the photovoltaic power generation system includes a solar battery that generates electric power, an electric power system that supplies electric power from an electric power company, a storage battery that accumulates electric power, and a load that consumes electric power. And a control device according to any one of claims 1 to 7.

  In the control device according to the embodiment of the present invention, at least the generated power display unit, the charge / discharge power display unit, and the power consumption display unit are arranged such that the generated power display unit, the charge / discharge power in the direction from left to right toward the display screen. The display unit and the power consumption display unit are arranged in this order. Further, the current state of the photovoltaic power generation system (power sale state or power purchase state) is calculated by the calculation of (generated power) ± (charge / discharge power) − (power consumption). As a result, the formula of (generated power) ± (charge / discharge power) − (power consumption) for calculating the current state of the photovoltaic power generation system is realized on the display screen.

  Therefore, it can be easily determined whether the state of the photovoltaic power generation system including the storage battery is the power sale state or the power purchase state.

  Moreover, the photovoltaic power generation system by embodiment of this invention is provided with the control apparatus mentioned above.

  Therefore, as described above, it can be easily determined whether the current state of the photovoltaic power generation system including the storage battery is the power sale state or the power purchase state.

1 is a schematic view of a photovoltaic power generation system according to an embodiment of the present invention. It is the schematic which shows the structure of the control apparatus shown in FIG. It is the schematic which shows the structure of the display screen shown in FIG. It is the schematic which shows another structure of the display screen shown in FIG. It is the schematic which shows the operation state of the solar energy power generation system shown in FIG. It is a figure which shows the specific example of a display screen when a solar energy power generation system is the operation state shown in FIG. It is the schematic which shows another operation state of the solar energy power generation system shown in FIG. It is a figure which shows the specific example of a display screen when a solar energy power generation system is the operation state shown in FIG. It is the schematic which shows another operation state of the solar energy power generation system shown in FIG. It is a figure which shows the specific example of a display screen when a solar energy power generation system is the operation state shown in FIG. It is the schematic which shows another operation state of the solar energy power generation system shown in FIG. It is a figure which shows the specific example of a display screen when a solar energy power generation system is the operation state shown in FIG. It is the schematic which shows another operation state of the solar energy power generation system shown in FIG. It is a figure which shows the specific example of a display screen when a solar energy power generation system is the operation state shown in FIG. It is the schematic which shows another operation state of the solar energy power generation system shown in FIG. It is a figure which shows the specific example of a display screen when a solar energy power generation system is the operation state shown in FIG. It is the schematic which shows another operation state of the solar energy power generation system shown in FIG. It is the schematic which shows another operation state of the solar energy power generation system shown in FIG.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

  FIG. 1 is a schematic diagram of a photovoltaic power generation system according to an embodiment of the present invention. Referring to FIG. 1, a photovoltaic power generation system 100 according to an embodiment of the present invention includes a solar cell 10, power conditioners 20 and 30, a storage battery box 40, a power system 50, a trading sensor 60, and a current sensor. 70, a control device 80, a home load 90, and a home dedicated load 110.

  The power conditioner 20 includes a DC / DC converter 21, a DC / AC converter 22, a protection relay 23, an interconnection relay 24, and a self-supporting relay 25.

  The power conditioner 30 includes a DC / DC converter 31, a bidirectional DC / AC converter 32, a bidirectional DC / DC converter 33, a protection relay 34, an interconnection relay 35, and a self-supporting relay 36. .

  Storage battery box 40 includes a breaker 41, a storage battery 42, and a changeover switch 43.

  The solar cell 10 is connected to the DC / DC converter 21 of the power conditioner 20 by the wiring w1, and is connected to the DC / DC converter 31 of the power conditioner 30 by the wirings w1 and w2.

  The DC / DC converter 21 is connected to the DC / AC converter 22 by the wiring w3. The DC / AC converter 22 is connected to the protection relay 23 by the wiring w4 and is connected to the self-supporting relay 25 by the wirings w4 and w7.

  The protection relay 23 is connected to the interconnection relay 24 by the wiring w5. The interconnection relay 24 is connected to the wiring w6.

  The DC / DC converter 31 is connected to the bidirectional DC / AC converter 32 by the wiring w8, is connected to the bidirectional DC / DC converter 33 by the wirings w8 and w10, and is connected to the DC / DC converter by the wirings w3 and w9. 21 and a DC / AC converter 22. The bidirectional DC / AC converter 32 is connected to the protection relay 34 by the wiring w11, and is connected to the self-supporting relay 36 by the wirings w11 and w13.

  The protection relay 34 is connected to the interconnection relay 35 by the wiring w12. The interconnection relay 35 is connected to the wiring w17. The self-supporting relay 36 is connected to the changeover switch 43 by the wiring w15.

  The breaker 41 is connected to the bidirectional DC / DC converter 33 by the wiring w14. The storage battery 42 is connected to the breaker 41.

  The changeover switch 43 includes a switch 431 and terminals 432 and 433. The switch 431 is connected to the home dedicated load 110 by the wiring w19. Terminal 432 is connected to self-supporting relay 36 by wiring w15. The terminal 433 is connected to the wiring w18.

  The electric power system 50 is connected to the wiring w6, the home load 90 is connected to the wiring w16, and the home dedicated load 110 is connected to the wiring w19.

  The solar cell 10 generates electric power with sunlight. And the solar cell 10 supplies the generated electric power PW1 generated to the DC / DC converter 21 of the power conditioner 20 through the wiring w1. Further, the solar cell 10 supplies the generated power PW2 that is generated to the DC / DC converter 31 of the power conditioner 30 via the wirings w1 and w2.

  More specifically, the solar cell 10 includes three blocks BLK1 to BLK3 and supplies the generated power PW1 generated by the two blocks BLK1 and BLK2 to the DC / DC converter 21 of the power conditioner 20 via the wiring w1. Then, the generated power PW2 generated by the block BLK3 is supplied to the DC / DC converter 31 of the power conditioner 30 via the wirings w1 and w2.

  The power conditioner 20 transmits the power generation information PG1 indicating the generated power PW1 from the solar cell 10 to the control device 80 by RS485 communication.

  The DC / DC converter 21 of the power conditioner 20 converts the generated power PW1 (= direct current power) from the solar cell 10 into direct current power having a desired direct current voltage, and the converted direct current power is converted to DC through the wiring w3. / AC converter 22 is supplied.

  The DC / AC converter 22 converts the DC power received from the DC / DC converters 21 and 31 into AC power. The DC / AC converter 22 is connected to the DC / AC converter 22 via the protection relay 23, the interconnection relay 24, and the wirings w4 to w6 when the protection relay 23 and the interconnection relay 24 are turned on and the self-supporting relay 25 is turned off. AC power is supplied to the power system 50 and the home load 90, or AC power is supplied to the power system 50, the home load 90, and the power conditioner 30 via the protection relay 23, the interconnection relay 24, and the wirings w4 to w6. Alternatively, AC power is supplied to the home load 90 and the power conditioner 30 via the protection relay 23, the interconnection relay 24, and the wires w4 to w6, or via the protection relay 23, the interconnection relay 24, and the wires w4 to w6. AC power is supplied to the household load 90.

  Each of the protection relay 23 and the interconnection relay 24 is turned on when there is no power failure, and turned off when there is a power failure.

  The self-supporting relay 25 is turned off when there is no power failure, and is turned on when the user instructs the return from the power failure.

  The power conditioner 30 receives, from the storage battery box 40, storage battery information BPW including charge / discharge power CP / DCP for charging / discharging the storage battery 42. Then, the power conditioner 30 transmits the power generation information PG2 indicating the generated power PW2 from the solar battery 10 and the storage battery information BPW to the control device 80 by RS485 communication. The charging / discharging power CP / DCP includes charging power CPW for charging the storage battery 42 or discharging power DPW for discharging from the storage battery 42.

  The DC / DC converter 31 of the power conditioner 30 converts the generated power PW2 (= DC power) received from the solar cell 10 into DC power having a desired DC voltage. The DC / DC converter 31 supplies the converted DC power to the DC / AC converter 22 of the power conditioner 20 via the wiring w9 in the operation mode and the interconnection mode. Further, in the self-supporting mode, the DC / DC converter 31 supplies the converted DC power to the bidirectional DC / AC converter 32 and the bidirectional DC / DC converter 33 via the wirings w8 and w10, or The converted DC power is supplied to the bidirectional DC / AC converter 32 via the wiring w8.

  When the bidirectional DC / AC converter 32 receives AC power via the wiring w11, the bidirectional DC / AC converter 32 converts the received AC power into DC power, and supplies the converted DC power to the bidirectional DC / DC converter 33. .

  In addition, when bidirectional DC / AC converter 32 receives DC power from DC / DC converter 31 and / or bidirectional DC / DC converter 33, bidirectional DC / AC converter 32 converts the received DC power into AC power. The bidirectional DC / AC converter 32 supplies the converted AC power to the wiring w11 when the protection relay 34 and the interconnection relay 35 are turned on and the self-supporting relay 36 is turned off. The bidirectional DC / AC converter 32 supplies the converted AC power to the changeover switch 43 via the wiring w15 when the protection relay 34 and the interconnection relay 35 are turned off and the self-supporting relay 36 is turned on. To do.

  When bidirectional DC / DC converter 33 receives DC power from DC / DC converter 31 and / or bidirectional DC / AC converter 32, bidirectional DC / DC converter 33 converts the received DC power into DC power having a desired DC voltage. Then, the storage battery 42 is charged via the breaker 41 with the converted DC power.

  Each of the protection relay 34 and the interconnection relay 35 is turned on when there is no power failure, and turned off when there is a power failure.

  The self-supporting relay 36 is turned off when there is no power failure, and turned on when there is a power failure.

  The storage battery box 40 outputs the storage battery information BPW to the power conditioner 30.

  The breaker 41 of the storage battery box 40 is turned on / off by the storage battery box 40. The storage battery 42 is charged by the DC power from the bidirectional DC / DC converter 33 or the DC power is discharged to the bidirectional DC / DC converter 33 when the breaker 41 is turned on. That is, the storage battery 42 accumulates electric power or discharges the accumulated electric power. The charging / discharging of the storage battery 42 is controlled by the control device 80.

  The switch 431 of the changeover switch 43 is connected to the terminal 433 by the switching signal EX from the control device 80 when there is no power failure, and is connected to the terminal 432 by the switching signal EX when there is a power failure.

  The switching signal EX is, for example, at an H (logic high) level or an L (logic low) level. The switch 431 is connected to the terminal 433 when it receives the H level switching signal EX from the control device 80, and is connected to the terminal 432 when it receives the L level switching signal EX from the control device 80.

  The power system 50 supplies AC power from the power company to the home load 90 and the power conditioner 30 via the wirings w6 and w16, or AC power from the power company to the home load 90 via the wirings w6 and w16. To supply. Further, the power system 50 supplies a part of the generated power PW from the power conditioner 20 to the power company. Furthermore, the power system 50 supplies AC power from the power company to the home dedicated load 110 via the wirings w6, w16, w17, w18, the changeover switch 43, and the wiring w19.

The trading sensor 60 detects a current I _UG composed of a current I1 flowing in the direction of the power conditioner 20 from the power grid 50 or a current I _UG composed of a current I2 flowing in the direction of the power grid 50 from the power conditioner 20. Then, the detected current _IUG is transmitted to the control device 80 by communication of RS485.

  The current sensor 70 detects a current flowing through the wiring w6 and outputs the detected current to the power conditioner 30.

Control device 80 receives current _IUG from trading sensor 60, receives power generation information PG1 from power conditioner 20, and receives power generation information PG2 / storage battery information BPW from power conditioner 30.

The control device 80 determines whether the state of the photovoltaic power generation system 100 is a power sale state or a power purchase state based on the current _IUG . More specifically, the control device 80 determines that the state of the photovoltaic power generation system 100 is a power purchase state when the current I _UG is composed of the current I1, and when the current I _UG is composed of the current I2, It determines with the state of the electric power generation system 100 being a power sale state.

  Based on the power generation information PG1 and PG2, the control device 80 adds the power generation power PW1 indicated by the power generation information PG1 and the power generation power PW2 indicated by the power generation information PG2 to calculate the power generation power PW generated by the solar cell 10.

  When the storage battery 42 is being discharged and the state of the photovoltaic power generation system 100 is a power sale state, the control device 80 calculates the power consumption CSM by the following equation.

Power consumption = (generated power) + (discharged power)-(power sold power) (1)
In addition, when the state of the photovoltaic power generation system 100 is the power sale state, the control device 80 calculates the power sale power based on the current I2.

  Moreover, the control apparatus 80 calculates the power consumption CSM by following Formula, when the storage battery 42 is discharging and the state of the solar power generation system 100 is a power purchase state.

Power consumption = (Generated power) + (Discharged power) + (Power purchased) (2)
In addition, when the state of the photovoltaic power generation system 100 is a power purchase state, the control device 80 calculates the power purchase power based on the current I1.

  Further, when the storage battery 42 is being charged and the state of the solar power generation system 100 is the power sale state, the control device 80 calculates the power consumption CSM by the following formula.

Power consumption = (generated power)-(charged power)-(power sold power) (3)
Furthermore, when the storage battery 42 is being charged and the state of the solar power generation system 100 is a power purchase state, the control device 80 calculates the power consumption CSM by the following equation.

Power consumption = (generated power)-(charged power) + (purchased power) (4)
Then, the control device 80 displays the generated power PW, the charge / discharge power CP / DCP, the power consumption CSM, and the state of the solar power generation system 100 on the display screen by a method described later.

  Furthermore, the control device 80 controls the mode of the power conditioners 20 and 30 to any one of the operation mode, the stop mode, the interconnection mode, and the self-sustaining mode, and controls the charging / discharging of the storage battery 42.

  Further, the control device 80 turns on the self-supporting relay 36 of the power conditioner 30 and turns on the protection relay 34 and the interconnection relay 35 when the power system 50 is interrupted and the “operation switching button” on the display screen is touched by the user. The power conditioner 30 is controlled to be turned off, the storage battery box 40 is controlled so that the storage battery 42 is discharged or charged, and the storage battery box 40 is controlled to connect the switch 431 to the terminal 432. As a result, the generated power PW2 and the discharged power DPW from the storage battery 42 or the generated power PW2 are supplied to the home dedicated load 110.

  The household load 90 is composed of electrical devices that are generally present in the home, such as televisions, air conditioners, refrigerators, washing machines, and lighting. The household dedicated load 110 is made up of electrical equipment that needs to be turned on during a power failure. More specifically, the household dedicated load 110 is composed of lighting, a refrigerator, and the like.

  The home load 90 and the home dedicated load 110 consume power.

  FIG. 2 is a schematic diagram showing the configuration of the control device 80 shown in FIG. Referring to FIG. 2, control device 80 includes a power detection means 81, a control means 82, and a display screen 83.

The power detection means 81 receives the current _IUG from the trade sensor 60, receives the power generation information PG1 from the power conditioner 20, and receives the power generation information PG2 / storage battery information BPW from the power conditioner 30.

And the electric power detection means 81 determines whether the state of the solar power generation system 100 is a power sale state or a power purchase state by the method mentioned above based on the electric current _IUG .

  Further, the power detection means 81 calculates the power generation power PW generated by the solar cell 10 by adding the power generation power PW1 indicated by the power generation information PG1 and the power generation power PW2 indicated by the power generation information PG2 based on the power generation information PG1 and PG2. To do.

  Furthermore, the power detection means 81 detects charge / discharge power CP / DCP from the storage battery information BPW. The charge / discharge power CP / DCP is composed of charge power CPW or discharge power DPW.

  Furthermore, the power detection means 81 calculates the purchased power based on the current I1, and calculates the sold power based on the current I2.

  If it does so, the electric power detection means 81 will calculate the power consumption CSM using either of Formula (1)-Formula (4).

  Then, the power detection unit 81 outputs the generated power PW, the charge / discharge power CP / DCP, the power consumption CSM, and the state of the solar power generation system 100 to the control unit 82.

  The control means 82 receives the generated power PW, the charge / discharge power CP / DCP, the power consumption CSM, and the state of the photovoltaic power generation system 100 from the voltage detection means 81, and the received generated power PW, charge / discharge power CP / DCP, consumption The display screen 83 is controlled so as to display the state of the power CSM and the photovoltaic power generation system 100 by a method described later.

  In this case, when the charge / discharge power CP / DCP is composed of the discharge power DPW, the control means 82 changes the background color of the portion displaying the charge / discharge power CP / DCP to the same color as the background color of the portion displaying the generated power PW. The display screen 83 is controlled to set. Further, when the charging / discharging power CP / DCP is composed of the charging power CPW, the control means 82 sets the background color of the portion displaying the charging / discharging power CP / DCP to the same color as the background color of the portion displaying power consumption. The display screen 83 is controlled as described above.

  Thus, the charge / discharge power CP / DCP is the power supplied to the household load 90 in the same manner as the generated power PW, or the charge / discharge power CP / DCP is the power consumed in the same manner as the power consumption CSM. The user can be visually recognized.

  In addition, when the “operation switching button” on the display screen is touched by the user, the control unit 82 detects that the return of the solar power generation system 100 is instructed.

  Furthermore, the control means 82 controls the mode of the power conditioners 20 and 30 to any one of the operation mode, the stop mode, the interconnection mode, and the self-sustaining mode, and controls the charging / discharging of the storage battery 42.

  Further, the control means 82 outputs an H level switching signal EX to the changeover switch 43 when the mode of the photovoltaic power generation system 100 is the operation mode or the interconnection mode. Further, the control means 82 outputs an L level switching signal EX to the changeover switch 43 when the mode of the photovoltaic power generation system 100 is the self-sustaining mode.

  The display screen 83 displays the generated power PW, the charge / discharge power CP / DCP, the power consumption CSM, and the state of the solar power generation system 100 according to the control from the control means 82.

  FIG. 3 is a schematic diagram showing the configuration of the display screen 83 shown in FIG. Referring to FIG. 3, display screen 83 includes a generated power display unit 831, a charge / discharge power display unit 832, a power consumption display unit 833, a power sale / power purchase state display unit 834, and an LED (Light Emitting Device). 835 and an operation switching button 836.

  The generated power display unit 831, the charge / discharge power display unit 832, the consumed power display unit 833, and the power sale / power purchase state display unit 834 are directed toward the display screen 83 in the direction from left to right. The charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834 are arranged in this order.

  The LED 835 is disposed at the lower part of the display screen 83 at the approximate center in the left-right direction of the display screen 83.

  The operation switching button 836 is arranged in the lower left part of the display screen 83. The operation switching button 836 is not limited to the arrangement at the lower left portion of the display screen 83, and may be arranged on the side surface of the display device having the display screen 83.

  The generated power display unit 831 is arranged on the leftmost side because the generated power PW displayed on the generated power display unit 831 is always a positive value.

  The charge / discharge power display unit 832 is displayed between the generated power display unit 831 and the power consumption display unit 833 because the charge / discharge power CP / DCP displayed on the charge / discharge power display unit 832 is generated power. This is because the power is supplied to the household load 90 in the same manner as PW or consumed in the same way as the consumed power CSM, and is added to the generated power PW or added to the consumed power CSM. In this case, when the charge / discharge power CP / DCP includes the discharge power DPW, the charge / discharge power CP / DCP is a positive value and is added to the generated power PW. When the charge / discharge power CP / DCP is composed of the charge power CPW, the charge / discharge power CP / DCP is a negative value and is added to the power consumption CSM.

  Furthermore, the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834 are directed toward the display screen 83 from the left to the right. The reason why the 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / purchase status display unit 834 are arranged in this order is as follows.

  The generated power PW, the charge / discharge power CP / DCP, and the power consumption CSM displayed on the generated power display unit 831, the charge / discharge power display unit 832, and the power consumption display unit 833, respectively, are the current state of the photovoltaic power generation system 100 (= (Power sale state or power purchase state), and when the generated power PW, the charge / discharge power CP / DCP, and the consumed power CSM, which are the factors for calculating the state of the photovoltaic power generation system 100, are mutually added or subtracted, This is because it is possible to realize on the display screen 83 a formula that the power sale state or the power purchase state as an answer is calculated.

  The generated power display unit 831 displays the generated power PW. The charge / discharge power display unit 832 displays the charge / discharge power CP / DCP. The power consumption display unit 833 displays the power consumption CSM. The power sale / power purchase status display unit 834 displays the power sale status or the power purchase status.

  When the charge / discharge power CP / DCP is composed of the discharge power DPW, the background color of the charge / discharge power display unit 832 is set to the same color as the background color of the generated power display unit 831. Further, when the charge / discharge power CP / DCP includes the charge power CPW, the background color of the charge / discharge power display unit 832 is set to the same color as the background color of the power consumption display unit 833.

  The LED 835 emits blue light when the state of the solar power generation system 100 is a power sale state, and emits orange light when the state of the solar power generation system 100 is a power purchase state.

  The operation switching button 836 is touched by the user when the solar power generation system 100 is returned after the power system 50 is blacked out and the solar power generation system 100 is stopped.

  FIG. 4 is a schematic diagram showing another configuration of the display screen 83 shown in FIG. In the embodiment of the present invention, the display screen 83 may be the display screen 83A shown in FIG.

  Referring to FIG. 4, display screen 83 </ b> A changes the arrangement position of power sale / purchase status display unit 834 on display screen 83 shown in FIG. 3 from the right side of power consumption display unit 833 to the left side of generated power display unit 831. The rest is the same as the display screen 83.

  As described above, on the display screen 83A, the power sale / purchase status display unit 834, the generated power display unit 831, the charge / discharge power display unit 832, and the power consumption display unit 833 are displayed from the left to the right toward the display screen 83A. The power sale / power purchase state display unit 834, the generated power display unit 831, the charge / discharge power display unit 832, and the power consumption display unit 833 are arranged in this order in the direction toward the direction.

  In the display screen 83A, the power sale / power purchase state display unit 834, the generated power display unit 831, the charge / discharge power display unit 832, and the power consumption display unit 833 are directed from the left to the right toward the display screen 83. The reason why the power sale / purchase status display unit 834, the generated power display unit 831, the charge / discharge power display unit 832, and the power consumption display unit 833 are arranged in this order is the generated power display unit 831, the charge / discharge power display unit. 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834 toward the display screen 83 in the direction from left to right, the generated power display unit 831, the charge / discharge power display unit 832, and the power consumption display unit. This is the same as the reason for arranging in the order of 833 and the power sale / power purchase status display unit 834.

  As described above, the control device 80 includes the display screen 83 shown in FIG. 3 or the display screen 83A shown in FIG. Therefore, on the display screen of the control device 80, generally, at least the generated power display unit 831, the charge / discharge power display unit 832 and the power consumption display unit 833 generate power in a direction from left to right toward the display screen. The display unit 831, the charge / discharge power display unit 832, and the power consumption display unit 833 may be arranged in this order.

  By arranging the generated power display unit 831, the charge / discharge power display unit 832 and the power consumption display unit 833 as described above, the user generates power PW that is a factor for calculating the current state of the photovoltaic power generation system 100, The charge / discharge power CP / DCP and the power consumption CSM can be easily added or subtracted from each other, and it is easy to visually understand whether the state of the photovoltaic power generation system 100 is a power sale state or a power purchase state. Because it can.

  FIG. 5 is a schematic diagram illustrating an operation state of the photovoltaic power generation system 100 illustrated in FIG. 1. FIG. 6 is a diagram showing a specific example of display screens 83 and 83A when the photovoltaic power generation system 100 is in the operation state shown in FIG.

  FIG. 5 shows a power sale state in the operation mode.

  Referring to FIG. 5, in the operation mode, control means 82 of control device 80 controls power conditioners 20 and 30 so as to operate in the operation mode, and the storage battery box so as to turn off breaker 41 of storage battery box 40. 40 is controlled.

  The power conditioner 20 turns on the protection relay 23 and the interconnection relay 24 and turns off the self-supporting relay 25 according to the control from the control device 80. Further, the power conditioner 30 turns on the protection relay 34 and the interconnection relay 35 and turns off the self-supporting relay 36 in accordance with control from the control device 80. Furthermore, the storage battery box 40 turns off the breaker 41 in accordance with control from the control device 80.

  The solar cell 10 supplies the generated power PW1 to the power conditioner 20 through the wiring w1 and supplies the generated power PW2 to the power conditioner 30 through the wirings w1 and w2. In the power conditioner 30, the DC / DC converter 31 converts the generated power PW2 supplied from the solar cell 10 into direct current power having a desired direct current voltage, and the converted direct current power is connected via the wirings w9 and w3. To the DC / AC converter 22 of the power conditioner 20.

  On the other hand, in the power conditioner 20, the DC / DC converter 21 converts the generated power PW 1 supplied from the solar cell 10 into DC power having a desired DC voltage, and the converted DC power is converted into the DC / AC converter 22. To supply.

  The DC / AC converter 22 of the power conditioner 20 receives DC power from the DC / DC converter 21 and the DC / DC converter 31 of the power conditioner 30, and converts the received DC power into AC power. The converted AC power is supplied to the power system 50 via the wiring w4, the protection relay 23, the wiring w5, the interconnection relay 24, and the wiring w6, and the wiring w4, the protection relay 23, the wiring w5, the interconnection relay 24, and the wiring w6. Supply to domestic load 90 via w16.

  As described above, in the operation mode in the power sale state, the power conditioner 20 supplies a part of the generated power PW to the domestic load 90 and supplies the remaining generated power PW to the power system 50.

  Then, the power conditioner 20 transmits the power generation information PG1 to the control device 80, and the power conditioner 30 transmits the power generation information PG2 / storage battery information BPW to the control device 80. In this case, the storage battery information BPW consists of 0W.

Further, the trading sensor 60 detects a current I _UG composed of a current I 2 flowing through the wiring w 6, and transmits the detected current I _UG (= I 2) to the control device 80.

Then, in control device 80, voltage detection means 81 receives current I _UG (= I2) from trading sensor 60, receives power generation information PG1 from power conditioner 20, and generates power generation information PG2 / storage battery information BPW from power conditioner 30. Receive.

Based on the current I _UG (= I2), the power detection unit 81 determines that the state of the photovoltaic power generation system 100 is the power sale state by the method described above. And the electric power detection means 81 calculates electric power selling power (= 1.05 kW) using the electric current I2.

  Further, the power detection unit 81 adds the generated power PW1 indicated by the power generation information PG1 and the generated power PW2 indicated by the power generation information PG2 based on the power generation information PG1 and PG2, and generates power PW (= 3.59 kW).

  Furthermore, the power detection means 81 detects that the charge / discharge power CP / DCP is 0 W based on the storage battery information BPW.

  Then, the power detection means 81 substitutes the generated power PW (= 3.59 kW), the sold power (= 1.05 kW), and the charge / discharge power CP / DCP (= 0 W) into the formula (1), thereby consuming the power consumption CSM. (= 2.54 kW) is calculated.

  Then, the power detection means 81 is configured to generate power PW (= 3.59 kW), charge / discharge power CP / DCP (= 0 W), power consumption CSM (= 2.54 kW), and the state of the solar power generation system 100 (= power sales). Medium) is output to the control means 82.

  The control means 82 sets the generated power PW (= 3.59 kW), the charge / discharge power CP / DCP (= 0 W), the power consumption CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= currently selling). The generated power PW (= 3.59 kW), charge / discharge power CP / DCP (= 0 W), power consumption CSM (= 2.54 kW), and the state of the solar power generation system 100 (= The display screen 83 (or 83A) is controlled so as to be displayed on the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834, respectively. The display screen 83 (or 83A) is controlled so that the LED 835 emits blue light.

  Then, the display screen 83 (or 83A) displays the generated power PW (= 3.59 kW), the charge / discharge power CP / DCP (= 0 W), and the power consumption CSM (=) according to control from the control device 80 (= control means 82). = 2.54 kW) and the state of the photovoltaic power generation system 100 (= during power sale) in the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834, respectively. In addition to the display, the LED 835 emits blue light (see FIGS. 6A and 6B).

  In this case, the generated power (= 3.59 kW) and the power consumption (= 2.54 kW) are displayed by a bar graph.

  FIG. 7 is a schematic diagram illustrating another operation state of the photovoltaic power generation system 100 illustrated in FIG. 1. FIG. 8 is a diagram showing a specific example of display screens 83 and 83A when the photovoltaic power generation system 100 is in the operation state shown in FIG.

  FIG. 7 shows a power purchase state in the operation mode.

  Referring to FIG. 7, in the power purchase state in the operation mode, power conditioners 20 and 30 operate in the same manner as in the power sale state in the operation mode shown in FIG. 5, and storage battery box 40 stops operating.

  As a result, the power conditioner 20 converts the generated power PW obtained by adding the generated power PW1 received from the solar cell 10 and the generated power PW2 received from the power conditioner 30 into AC power, and the converted AC power is connected to the wiring w4, The power is supplied to the home load 90 via the protection relay 23, the wiring w5, the interconnection relay 24, and the wirings w6 and w16. In addition, the power system 50 supplies AC power to the home load 90 via the wirings w6 and w16.

  Thus, in the operation mode in the power purchase state, the power conditioner 20 supplies the generated power to the home load 90, and the power system 50 supplies the AC power to the home load 90.

  Then, the power conditioner 20 transmits the power generation information PG1 to the control device 80, and the power conditioner 30 transmits the power generation information PG2 / storage battery information BPW to the control device 80. Also in this case, the storage battery information BPW consists of 0W.

Also, trading sensor 60 detects the current _{I UG} consisting current I1 flowing through the wires w6, and transmits the detected current _I UG a (= I1) to the control device 80.

Then, in control device 80, voltage detection means 81 receives current I _UG (= I1) from trading sensor 60, receives power generation information PG1 from power conditioner 20, and generates power generation information PG2 / storage battery information BPW from power conditioner 30. Receive.

Based on the current I _UG (= I1), the power detection unit 81 determines that the state of the solar power generation system 100 is the power purchase state by the method described above. And the electric power detection means 81 calculates the purchased electric power (= 0.95kW) using the electric current I1.

  Further, the power detection unit 81 adds the generated power PW1 indicated by the power generation information PG1 and the generated power PW2 indicated by the power generation information PG2 based on the power generation information PG1 and PG2, and generates power PW (= 1.59 kW).

  Furthermore, the power detection means 81 detects that the charge / discharge power CP / DCP is 0 W from the storage battery information BPW.

  Then, the power detection means 81 substitutes the generated power PW (= 1.59 kW), the purchased power (= 0.95 kW), and the charge / discharge power CP / DCP (= 0 W) into the formula (2), and the power consumption CSM. (= 2.54 kW) is calculated.

  And the electric power detection means 81 is the electric power generation power PW (= 1.59 kW), charging / discharging electric power CP / DCP (= 0 W), electric power consumption CSM (= 2.54 kW), and the state (= power purchase) of the solar power generation system 100. Medium) is output to the control means 82.

  The control means 82 determines the generated power PW (= 1.59 kW), the charge / discharge power CP / DCP (= 0 W), the power consumption CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= during power purchase). The generated power PW (= 1.59 kW), charge / discharge power CP / DCP (= 0 W), power consumption CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= The display screen 83 (or 83A) is controlled so as to display on the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834, respectively. The display screen 83 (or 83A) is controlled so that the LED 835 emits orange light.

  Then, the display screen 83 (or 83A) displays the generated power PW (= 1.59 kW), the charge / discharge power CP / DCP (= 0 W), and the power consumption CSM (in accordance with control from the control device 80 (= control means 82). = 2.54 kW) and the state of the photovoltaic power generation system 100 (= during power purchase) in the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834, respectively. In addition to displaying, the LED 835 emits orange light (see FIGS. 8A and 8B).

  In this case, the generated power (= 1.59 kW) and the power consumption (= 2.54 kW) are displayed by a bar graph.

  FIG. 9 is a schematic diagram illustrating still another operation state of the photovoltaic power generation system 100 illustrated in FIG. 1. FIG. 10 is a diagram showing a specific example of display screens 83 and 83A when the photovoltaic power generation system 100 is in the operation state shown in FIG.

  FIG. 9 shows a power sale state and a discharge state in the interconnection mode.

  Referring to FIG. 9, in the power selling state in the interconnection mode, power conditioners 20 and 30 operate in the same manner as the power selling state in the operation mode shown in FIG.

  And the control means 82 of the control apparatus 80 controls the storage battery box 40 so that the storage battery 42 may discharge while turning on the breaker 41. FIG. The storage battery box 40 turns on the breaker 41 and discharges power from the storage battery 42 in accordance with control from the control means 82.

  Then, the storage battery 42 supplies the discharge power DPW to the bidirectional DC / DC converter 33 of the power conditioner 30 via the breaker 41 and the wiring w14. Moreover, the storage battery box 40 transmits the storage battery information BPW composed of the discharge power DPW to the power conditioner 30 by RS485 communication.

  The bidirectional DC / DC converter 33 of the power conditioner 30 converts the discharge power DPW (= DC power) from the storage battery 42 into DC power having a desired DC voltage, and the converted DC power is connected to the wirings w8 and w10. To the bidirectional DC / AC converter 32.

  The bidirectional DC / AC converter 32 receives direct current power from the bidirectional DC / DC converter 33, converts the received direct current power into alternating current power, and the converted alternating current power is connected to the wiring w11 and the protection relay 34. , And supplied to the home load 90 via the wiring w12, the interconnection relay 35, and the wirings w17 and w16.

  Thus, in the interconnection mode in the power sale state and the discharge state, the power conditioner 20 supplies the generated power PW to the power system 50 and the home load 90, and the power conditioner 30 discharges from the storage battery box 40. Electric power DPW is supplied to household load 90.

  Then, the power conditioner 20 transmits the power generation information PG1 to the control device 80. In addition, the power conditioner 30 receives the storage battery information BPW from the storage battery box 40 and transmits the power generation information PG 2 / storage battery information BPW (= discharge power DPW) to the control device 80.

Further, the trading sensor 60 detects a current I _UG composed of a current I 2 flowing through the wiring w 6, and transmits the detected current I _UG (= I 2) to the control device 80.

Then, in control device 80, voltage detection means 81 receives current I _UG (= I2) from trading sensor 60, receives power generation information PG1 from power conditioner 20, and generates power generation information PG2 / storage battery information BPW from power conditioner 30. Receive.

Based on the current I _UG (= I2), the power detection unit 81 determines that the state of the photovoltaic power generation system 100 is the power sale state by the method described above. And the electric power detection means 81 calculates electric power selling power (= 2.25 kW) using the electric current I2.

  Moreover, the electric power detection means 81 calculates the electric power PW (= 3.59 kW) generated by the solar cell 10 based on the electric power generation information PG1 and PG2, as described above.

  Furthermore, the power detection means 81 detects that the charge / discharge power CP / DCP is composed of the discharge power DPW and the discharge power DPW is 1.20 W based on the storage battery information BPW.

  Then, the power detection unit 81 substitutes the generated power PW (= 3.59 kW), the sold power (= 2.25 kW), and the discharged power DPW (= 1.20 W) into the formula (1), thereby consuming the power consumption CSM ( = 2.54 kW).

  And the electric power detection means 81 is power generation power PW (= 3.59 kW), discharge power DPW (= 1.20 W), power consumption CSM (= 2.54 kW), and the state of the solar power generation system 100 (= power selling) ) To the control means 82.

  The control means 82 sets the generated power PW (= 3.59 kW), the discharged power DPW (= 1.20 W), the consumed power CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= currently selling) as a voltage. The received generated power PW (= 3.59 kW), the discharged power DPW (= 1.20 W), the consumed power CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= power sales) The display screen 83 (or 83A) and the LED 835 so that the generated power display unit 831, the charging / discharging power display unit 832, the power consumption display unit 833, and the power sale / purchase status display unit 834 are displayed. The display screen 83 (or 83A) is controlled so as to emit light in blue.

  Further, the control means 82 controls the display screen 83 (or 83A) so as to set the background color of the charge / discharge power display unit 832 to the same color as the background color of the generated power display unit 831.

  Then, the display screen 83 (or 83A) displays the generated power PW (= 3.59 kW), the discharge power DPW (= 1.20 W), and the power consumption CSM (=) according to control from the control device 80 (= control means 82). 2.54 kW) and the state of the photovoltaic power generation system 100 (= power selling) are displayed on the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834, respectively. In addition, the LED 835 emits blue light (see FIGS. 10A and 10B).

  In this case, the generated power PW (= 3.59 kW) and the power consumption CSM (= 2.54 kW) are displayed by a bar graph.

  In addition, the background color of the charge / discharge power display unit 832 is the same as the background color of the generated power display unit 831.

  Further, in the charge / discharge power display portion 832, an arrow is displayed in the direction of exiting from the storage battery 42. This arrow indicates that the storage battery 42 is being discharged (hereinafter the same).

  FIG. 11 is a schematic diagram illustrating still another operation state of the photovoltaic power generation system 100 illustrated in FIG. 1. FIG. 12 is a diagram showing a specific example of display screens 83 and 83A when the photovoltaic power generation system 100 is in the operation state shown in FIG.

  FIG. 11 shows a power sale state and a charge state in the interconnection mode.

  Referring to FIG. 11, control means 82 of control device 80 operates power conditioners 20 and 30 and storage battery box 40 in the power selling state and the charged state in the interconnection mode.

  Then, as described above, the power conditioner 30 supplies the generated power PW2 from the solar cell 10 to the power conditioner 20, and the power conditioner 20 generates the generated power PW1 from the solar cell 10 and the power conditioner 30 as described above. , PW2.

  Then, the power conditioner 20 converts the generated power PW, which is the sum of the generated power PW1 and PW2, through the wiring w4, the protection relay 23, the wiring w5, the interconnection relay 24, and the wiring w6, the power system 50, the household load 90, and the power Supply to conditioner 30.

  And the power conditioner 30 receives alternating current power via the wiring w17. The bidirectional DC / AC converter 32 of the power conditioner 30 receives AC power via the interconnection relay 35, the wiring w12, the protection relay 34, and the wiring w11, converts the received AC power into DC power, and converts the power. The direct current power thus supplied is supplied to the bidirectional DC / DC converter 33 via the wirings w8 and w10.

  The bidirectional DC / DC converter 33 converts the direct current power from the bidirectional DC / AC converter 32 into direct current power having a desired direct current voltage, and charges the storage battery 42 with the converted direct current power.

  Thus, in the interconnection mode in the power sale state and the charge state, the power conditioner 20 supplies the generated power PW to the power system 50, the home load 90, and the storage battery box 40.

  Then, the power conditioner 20 transmits the power generation information PG1 to the control device 80. Moreover, the storage battery box 40 transmits the storage battery information BPW composed of the charging power CPW to the power conditioner 30 by RS485 communication. Then, the power conditioner 30 receives the storage battery information BPW (= charging power CPW) from the storage battery box 40 and transmits the power generation information PG2 / storage battery information BPW (= charging power CPW) to the control device 80.

Further, the trading sensor 60 detects a current I _UG composed of a current I 2 flowing through the wiring w 6, and transmits the detected current I _UG (= I 2) to the control device 80.

Then, in control device 80, voltage detection means 81 receives current I _UG (= I2) from trading sensor 60, receives power generation information PG1 from power conditioner 20, and generates power generation information PG2 / storage battery information BPW from power conditioner 30. Receive.

Based on the current I _UG (= I2), the power detection unit 81 determines that the state of the photovoltaic power generation system 100 is the power sale state by the method described above. And the electric power detection means 81 calculates electric power selling power (= 2.25 kW) using the electric current I2.

  Further, as described above, the power detection unit 81 calculates the generated power PW (= 5.59 kW) by the solar cell 10 based on the power generation information PG1 and PG2.

  Furthermore, the power detection means 81 detects that the charging power CPW is 0.80 W from the storage battery information BPW.

  Then, the power detection means 81 substitutes the generated power PW (= 5.59 kW), the sold power (= 2.25 kW), and the charging power CPW (= 0.80 W) into the formula (3), thereby consuming the power consumption CSM ( = 2.54 kW).

  And the electric power detection means 81 is the electric power generation power PW (= 5.59kW), charging electric power CPW (= 0.80W), electric power consumption CSM (= 2.54kW), and the state (= electric power selling) of the photovoltaic power generation system 100 ) To the control means 82.

  The control means 82 converts the generated power PW (= 5.59 kW), the charged power CPW (= 0.80 W), the power consumption CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= currently selling) into a voltage. The received generated power PW (= 5.59 kW), the charged power CPW (= 0.80 W), the consumed power CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= power sales) The display screen 83 (or 83A) and the LED 835 so that the generated power display unit 831, the charging / discharging power display unit 832, the power consumption display unit 833, and the power sale / purchase status display unit 834 are displayed. The display screen 83 (or 83A) is controlled so as to emit light in blue.

  In addition, the control unit 82 controls the display screen 83 (or 83A) so that the background color of the charge / discharge power display unit 832 is set to the same color as the background color of the power consumption display unit 833.

  Then, the display screen 83 (or 83A) displays the generated power PW (= 5.59 kW), the charged power CPW (= 0.80 W), and the consumed power CSM (=) according to control from the control device 80 (= control means 82). 2.54 kW) and the state of the photovoltaic power generation system 100 (= power selling) are displayed on the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834, respectively. In addition, the LED 835 emits blue light (see FIGS. 12A and 12B).

  In this case, the generated power PW (= 5.59 kW) and the power consumption CSM (= 2.54 kW) are displayed by a bar graph.

  In addition, the background color of the charge / discharge power display unit 832 is the same as the background color of the power consumption display unit 833.

  Further, in the charge / discharge power display unit 832, an arrow is displayed in a direction to enter the storage battery 42 from the outside. This arrow indicates that the storage battery 42 is being charged (hereinafter the same).

  FIG. 13 is a schematic diagram illustrating still another operation state of the photovoltaic power generation system 100 illustrated in FIG. 1. FIG. 14 is a diagram showing a specific example of display screens 83 and 83A when the photovoltaic power generation system 100 is in the operation state shown in FIG.

  FIG. 13 shows a power purchase state and a discharge state in the interconnection mode.

  Referring to FIG. 13, control means 82 of control device 80 operates power conditioners 20 and 30 and storage battery box 40 in the power purchase state and the discharge state in the interconnection mode. In this case, the control means 82 controls the storage battery box 40 so as to discharge power from the storage battery 42.

  Then, as described above, the power conditioner 30 supplies the generated power PW2 from the solar cell 10 to the power conditioner 20, and the power conditioner 20 generates the generated power PW1 from the solar cell 10 and the power conditioner 30 as described above. , PW2.

  Then, the power conditioner 20 supplies the generated power PW, which is the sum of the generated power PW1 and PW2, to the home load 90 via the wiring w4, the protection relay 23, the wiring w5, the interconnection relay 24, and the wirings w6 and w16.

  Further, the grid power 50 supplies the purchased power to the home load 90 via the wirings w6 and w16.

  Furthermore, the storage battery box 40 discharges DC power from the storage battery 42 in accordance with control from the control device 80. Then, the storage battery 42 supplies the discharge power DPW (= DC power) to the bidirectional DC / DC converter 33 of the power conditioner 30 via the breaker 41 and the wiring w14. And the storage battery box 40 transmits the storage battery information BPW which consists of discharge electric power DPW to the power conditioner 30 by communication of RS485.

  The bidirectional DC / DC converter 33 of the power conditioner 30 converts the discharge power DPW (= DC power) from the storage battery 42 into DC power having a desired DC voltage, and the converted DC power is connected to the wirings w10 and w8. To the bidirectional DC / AC converter 32.

  The bidirectional DC / AC converter 32 converts the DC power from the bidirectional DC / DC converter 33 into AC power, and the converted AC power is connected to the wiring w11, the protection relay 34, the wiring w12, and the interconnection relay. 35 and the wirings w17 and w16 are supplied to the home load 90.

  Thus, in the interconnection mode in the power purchase state and the discharge state, the power conditioner 20 supplies the generated power PW to the home load 90, and the system power 50 supplies the power purchase power to the home load 90. Then, the power conditioner 30 supplies the discharged power DPW from the storage battery box 40 to the domestic load 90.

  Then, the power conditioner 20 transmits the power generation information PG1 to the control device 80. Further, the power conditioner 30 receives the storage battery information BPW (= discharge power DPW) from the storage battery box 40 and transmits the power generation information PG 2 / storage battery information BPW (= discharge power DPW) to the control device 80.

Also, trading sensor 60 detects the current _{I UG} consisting current I1 flowing through the wires w6, and transmits the detected current _I UG a (= I1) to the control device 80.

Then, in control device 80, voltage detection means 81 receives current I _UG (= I1) from trading sensor 60, receives power generation information PG1 from power conditioner 20, and generates power generation information PG2 / storage battery information BPW from power conditioner 30. Receive.

Based on the current I _UG (= I1), the power detection unit 81 determines that the state of the solar power generation system 100 is the power purchase state by the method described above. And the electric power detection means 81 calculates purchased electric power (= 0.45kW) using the electric current I1.

  Moreover, the electric power detection means 81 calculates the electric power PW (= 1.59 kW) generated by the solar cell 10 based on the electric power generation information PG1 and PG2, as described above.

  Furthermore, the power detection means 81 detects that the charge / discharge power CP / DCP is composed of the discharge power DPW and the discharge power DPW is 0.50 W based on the storage battery information BPW.

  Then, the power detection means 81 substitutes the generated power PW (= 1.59 kW), the purchased power (= 0.45 kW), and the discharged power DPW (= 0.50 W) into the formula (2), and consumes power CSM ( = 2.54 kW).

  And the electric power detection means 81 is the power generation power PW (= 1.59 kW), the discharge power DPW (= 0.50 W), the power consumption CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= buying power) ) To the control means 82.

  The control means 82 sets the generated power PW (= 1.59 kW), the discharged power DPW (= 0.50 W), the consumed power CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= currently purchasing power) as a voltage. The received generated power PW (= 1.59 kW), the discharged power DPW (= 0.50 W), the consumed power CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= buy power) The display screen 83 (or 83A) and the LED 835 so that the generated power display unit 831, the charging / discharging power display unit 832, the power consumption display unit 833, and the power sale / purchase status display unit 834 are displayed. The display screen 83 (or 83A) is controlled to emit light in orange.

  Further, the control means 82 controls the display screen 83 (or 83A) so as to set the background color of the charge / discharge power display unit 832 to the same color as the background color of the generated power display unit 831.

  Then, the display screen 83 (or 83A) displays the generated power PW (= 1.59 kW), the discharged power DPW (= 0.50 W), and the consumed power CSM (=) according to control from the control device 80 (= control means 82). 2.54 kW) and the state of the photovoltaic power generation system 100 (= during power purchase) are displayed on the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834, respectively. In addition, the LED 835 emits orange light (see FIGS. 14A and 14B).

  In this case, the generated power PW (= 1.59 kW) and the power consumption CSM (= 2.54 kW) are displayed by a bar graph.

  In addition, the background color of the charge / discharge power display unit 832 is the same as the background color of the generated power display unit 831.

  Further, in the charge / discharge power display portion 832, an arrow is displayed in the direction of exiting from the storage battery 42.

  FIG. 15 is a schematic diagram illustrating still another operation state of the photovoltaic power generation system 100 illustrated in FIG. 1. FIG. 16 is a diagram showing a specific example of display screens 83 and 83A when the photovoltaic power generation system 100 is in the operation state shown in FIG.

  FIG. 15 shows a power purchase state and a charge state in the interconnection mode.

  Referring to FIG. 15, control means 82 of control device 80 operates power conditioners 20 and 30 and storage battery box 40 in the power purchase state and the charge state in the interconnection mode. In this case, the control means 82 controls the power conditioner 30 and the storage battery box 40 so as to charge the storage battery 42.

  Then, as described above, the power conditioner 30 supplies the generated power PW2 from the solar cell 10 to the power conditioner 20, and the power conditioner 20 generates the generated power PW1 from the solar cell 10 and the power conditioner 30 as described above. , PW2.

  Then, the power conditioner 20 supplies the generated power PW, which is the sum of the generated power PW1 and PW2, to the wiring w6 via the wiring w4, the protection relay 23, the wiring w5, and the interconnection relay 24. The grid power 50 supplies the purchased power to the wiring w6.

  Then, the power on the wiring w6 (= the generated power PW + the purchased power) is supplied to the home load 90 through the wiring w16 and to the power conditioner 30 through the wirings w16 and w17.

  The bidirectional DC / AC converter 32 of the power conditioner 30 receives AC power through the interconnection relay 35, the wiring w12, the protection relay 34, and the wiring w11, and converts the received AC power into DC power. Then, the bidirectional DC / AC converter 32 supplies the converted DC power to the bidirectional DC / DC converter 33 via the wirings w8 and w10.

  The bidirectional DC / DC converter 33 converts the direct current power from the bidirectional DC / AC converter 32 into direct current power having a desired direct current voltage, and charges the storage battery 42 with the converted direct current power.

  Thus, in the interconnection mode in the power purchase state and the charge state, the power conditioner 20 and the system power 50 supply the generated power PW and the purchased power to the domestic load 90 and the storage battery 42, respectively.

  Then, the power conditioner 20 transmits the power generation information PG1 to the control device 80. The storage battery box 40 transmits the storage battery information BPW made up of the charging power CPW to the power conditioner 30 through RS485 communication. The power conditioner 30 receives the storage battery information BPW including the charging power CPW from the storage battery box 40, and transmits the power generation information PG2 / storage battery information BPW (= charging power CPW) to the control device 80.

Also, trading sensor 60 detects the current _{I UG} consisting current I1 flowing through the wires w6, and transmits the detected current _I UG a (= I1) to the control device 80.

Then, in control device 80, voltage detection means 81 receives current I _UG (= I1) from trading sensor 60, receives power generation information PG1 from power conditioner 20, and generates power generation information PG2 / storage battery information BPW from power conditioner 30. Receive.

Based on the current I _UG (= I1), the power detection unit 81 determines that the state of the solar power generation system 100 is the power purchase state by the method described above. And the electric power detection means 81 calculates the purchased electric power (= 1.55 kW) using the electric current I1.

  Moreover, the electric power detection means 81 calculates the electric power PW (= 1.80 kW) generated by the solar cell 10 based on the electric power generation information PG1 and PG2, as described above.

  Furthermore, the power detection means 81 detects that the charging power CPW is 0.81 W from the storage battery information BPW.

  Then, the power detection means 81 substitutes the generated power PW (= 1.80 kW), the purchased power (= 1.55 kW), and the charging power CPW (= 0.81 W) into the formula (4), and consumes power CSM ( = 2.54 kW).

  Then, the power detection means 81 includes the generated power PW (= 1.80 kW), the charged power CPW (= 0.81 W), the consumed power CSM (= 2.54 kW), and the state of the solar power generation system 100 (= buying power) ) To the control means 82.

  The control means 82 sets the generated power PW (= 1.80 kW), the charging power CPW (= 0.81 W), the power consumption CSM (= 2.54 kW), and the state of the photovoltaic power generation system 100 (= currently purchasing power). The received generated power PW (= 1.80 kW), the charged power CPW (= 0.81 W), the consumed power CSM (= 2.54 kW), and the state of the solar power generation system 100 (= buy power) The display screen 83 (or 83A) and the LED 835 so that the generated power display unit 831, the charging / discharging power display unit 832, the power consumption display unit 833, and the power sale / purchase status display unit 834 are displayed. The display screen 83 (or 83A) is controlled to emit light in orange.

  In addition, the control unit 82 controls the display screen 83 (or 83A) so that the background color of the charge / discharge power display unit 832 is set to the same color as the background color of the power consumption display unit 833.

  Then, the display screen 83 (or 83A) displays the generated power PW (= 1.80 kW), the charging power CPW (= 0.81 W), and the power consumption CSM (=) according to the control from the control device 80 (= control means 82). 2.54 kW) and the state of the photovoltaic power generation system 100 (= during power purchase) are displayed on the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase state display unit 834, respectively. At the same time, the LED 835 emits orange light (see FIGS. 16A and 16B).

  In this case, the generated power PW (= 1.80 kW) and the power consumption CSM (= 2.54 kW) are displayed by a bar graph.

  In addition, the background color of the charge / discharge power display unit 832 is the same as the background color of the power consumption display unit 833.

  Further, in the charge / discharge power display unit 832, an arrow is displayed in a direction to enter the storage battery 42 from the outside.

  FIG. 17 is a schematic diagram illustrating still another operation state of the photovoltaic power generation system 100 illustrated in FIG. 1. FIG. 17 shows the state of charge in the self-supporting mode.

  Referring to FIG. 17, in the charging state in the self-sustaining mode, power conditioner 20 stops operation because protection relay 23 and interconnection relay 24 are turned off due to a power failure, and power conditioner 30 is connected to protection relay 34 and interconnection relay 24. Since the system relay 35 is turned off due to a power failure, the operation is stopped.

  Then, when the “operation switching button” 836 on the display screen 83 (or 83A) is touched, the control means 82 of the control device 80 detects that the user has instructed the return of the solar power generation system 100.

  Then, the control means 82 of the control device 80 turns on the self-supporting relay 36 and controls the power conditioner 30 so as to charge the storage battery 42, and outputs an L level switching signal EX to the changeover switch 43.

  Then, the power conditioner 30 turns on the self-supporting relay 36 in accordance with control from the control means 82 of the control device 80. The changeover switch 43 connects the switch 431 to the terminal 432 in response to the L level changeover signal EX.

  Further, the DC / DC converter 31 of the power conditioner 30 converts the generated power PW2 from the solar cell 10 into DC power having a desired DC voltage, and the converted DC power is converted into a bidirectional DC / AC converter 32 and The bidirectional DC / DC converter 33 is supplied.

  The bidirectional DC / DC converter 33 converts the DC power from the DC / DC converter 31 into DC power having a desired DC voltage, and charges the storage battery 42 with the converted DC power.

  On the other hand, the bidirectional DC / AC converter 32 converts the DC power from the DC / DC converter 31 into AC power, and the converted AC power is connected to the wiring w13, the self-supporting relay 36, the wiring w15, the changeover switch 43, and the wiring. Supplied to home load 110 via w19.

  As a result, the home dedicated load 110 is driven by the generated power PW2 of the solar cell 10 even when the power system 50 is in a power outage.

  In this case, since neither the power sale state nor the power purchase state occurs, the control means 82 displays the generated power PW, the charge / discharge power CP / DCP, the consumed power CSM, and the status of the photovoltaic power generation system 100 on the screen 83 (or 83A). ) Is not displayed.

  FIG. 18 is a schematic diagram illustrating still another operation state of the photovoltaic power generation system 100 illustrated in FIG. 1. FIG. 18 shows a discharge state in the self-supporting mode.

  Referring to FIG. 18, in the discharge state in the self-sustained mode, power conditioner 20 stops its operation because protection relay 23 and interconnection relay 24 are turned off due to a power failure, and power conditioner 30 is connected to protection relay 34 and interconnection relay 24. Since the system relay 35 is turned off due to a power failure, the operation is stopped.

  Then, when the “operation switching button” 836 on the display screen 83 (or 83A) is touched, the control means 82 of the control device 80 detects that the user has instructed the return of the solar power generation system 100.

  Then, the control means 82 of the control device 80 turns on the self-supporting relay 36 and controls the power conditioner 30 so as to discharge power from the storage battery 42, and outputs an L level switching signal EX to the changeover switch 43.

  Then, the power conditioner 30 turns on the self-supporting relay 36 in accordance with control from the control means 82 of the control device 80. The changeover switch 43 connects the switch 431 to the terminal 432 in response to the L level changeover signal EX.

  Further, the storage battery 42 supplies the discharge power DPW to the bidirectional DC / DC converter 33 of the power conditioner 30 via the breaker 41 and the wiring w14.

  The bidirectional DC / DC converter 33 converts the discharged power DPW (= DC power) from the storage battery 42 into DC power having a desired DC voltage, and the converted DC power is converted into the bidirectional DC / AC converter. 32.

  Further, the DC / DC converter 31 of the power conditioner 30 converts the generated power PW2 from the solar cell 10 into DC power having a desired DC voltage, and the converted DC power is supplied to the bidirectional DC / AC converter 32. Supply.

  The bidirectional DC / AC converter 32 converts the DC power from the DC / DC converter 31 and the bidirectional DC / DC converter 33 into AC power, and the converted AC power is connected to the wiring w13, the self-supporting relay 36, and the wiring. This is supplied to the home dedicated load 110 via w15, the changeover switch 43 and the wiring w19.

  As a result, the home dedicated load 110 is driven by the generated power PW2 of the solar battery 10 and the discharged power DPW from the storage battery 42 even when the power system 50 is in a power failure.

  Also in this case, since neither the power sale state nor the power purchase state occurs, the control means 82 displays the generated power PW, the charge / discharge power CP / DCP, the power consumption CSM, and the state of the photovoltaic power generation system 100 on the screen 83 (or 83A) is not displayed.

  As described above, when the mode of the photovoltaic power generation system 100 is the operation mode or the interconnection mode, the control device 80 generates the generated power PW, the charge / discharge power CP / DCP, the consumed power CSM, and the state of the photovoltaic power generation system 100. (= Selling or buying power) is displayed on the display screen 83 (or 83A).

  As a result, the user can easily visually recognize whether the photovoltaic power generation system 100 is in the power sale state or the power purchase state.

  In addition, the generated power PW, the charge / discharge power CP / DCP, and the power consumption CSM, which are the factors for calculating the current state of the photovoltaic power generation system 100, are directed from left to right toward the display screen 83 (or 83A). Since the generated power PW, the charge / discharge power CP / DCP, and the power consumption CSM are displayed in this order, the generated power PW and the charge / discharge power CP / DCP, which are factors that the user calculates the current state of the photovoltaic power generation system 100, are displayed. And the power consumption CSM can be easily added or subtracted from each other.

  In the above description, the generated power PW and the consumed power CSM have been described as being displayed by a bar graph. However, in the embodiment of the present invention, the present invention is not limited thereto, and the generated power PW and the consumed power CSM are displayed by a pie chart. In general, it may be displayed by any method.

  Further, in the above, the LED 835 emits blue light when the state of the solar power generation system 100 is the power sale state, and emits orange light when the state of the solar power generation system 100 is the power purchase state. Although explained to emit light, in the embodiment of the present invention, not limited to this, the LED 835 generally emits light in the first color when the state of the photovoltaic power generation system 100 is a power sale state, When the state of the photovoltaic power generation system 100 is a power purchase state, light may be emitted in a second color different from the first color.

  Furthermore, in the above, the display screen 83 (or 83A) includes the LED 835 that emits light indicating the state (= power purchase state or power sale state) of the photovoltaic power generation system 100, and the operation switching button 836. As described above, in the embodiment of the present invention, the display screen 83 (or 83A) may not include the LED 835 and the operation switching button 836.

  Even if the display screen 83 (or 83A) does not include the LED 835 and the operation switching button 836, the generated power display unit 831, the charge / discharge power display unit 832, the power consumption display unit 833, and the power sale / power purchase status display unit 834 are displayed. If it is provided, an expression of (generated power) ± (charge / discharge power) − (power consumption) that determines the state (= power purchase state or power sale state) of the photovoltaic power generation system 100 is displayed on the display screen 83 (or 83A). This is because it can be realized.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and is intended to include meanings equivalent to the scope of claims for patent and all modifications within the scope.

  The present invention is applied to a control device and a solar power generation system including the control device.

       10 solar cell, 20, 30 power conditioner, 21, 31 DC / DC converter, 22 DC / AC converter, 23, 34 protection relay, 24, 35 interconnection relay, 25, 36 free standing relay, 32, 33 bidirectional DC / AC converter, 43 changeover switch, 40 storage battery box, 41 breaker, 42 storage battery, 50 power system, 60 trading sensor, 70 current sensor, 80 control device, 81 voltage detection means, 82 control means, 83, 83A display screen , 90 Household load, 100 Solar power generation system, 110 Household dedicated load, 431 switch, 432, 433 terminal, 831 Power generation display, 832 Charge / discharge power display, 833 Power consumption display, 834 Electricity status display part, 835 LED, 836 operation switching button.

Claims (8)

A control device used in a solar power generation system including a solar battery, a power system, a storage battery, and a load,
Power detection means for detecting generated power generated by the solar cell, charge / discharge power when charging / discharging the storage battery, and power consumption in the load;
The generated power display unit that displays the generated power, the charge / discharge power display unit that displays the charge / discharge power, the power consumption display unit that displays the power consumption, and the power sale that is in a state of selling power to the power system A display screen including a power sale / power purchase state display unit that displays either the state or the power purchase state in which power is purchased from the power system;
It is determined whether the state of the photovoltaic power generation system is the power sale state or the power purchase state based on the current flowing through the power system, and the generated power, the charge / discharge power, the power consumption, and the sun Control means for controlling the display screen to display the state of the photovoltaic power generation system on the generated power display unit, the charge / discharge power display unit, the power consumption display unit, and the power sale / power purchase status display unit, respectively. Prepared,
At least the generated power display unit, the charge / discharge power display unit, and the power consumption display unit are arranged such that the generated power display unit, the charge / discharge power display unit, and the power consumption in a direction from left to right toward the display screen. A control device arranged in the order of the display units.   2. The control device according to claim 1, wherein the power sale / power purchase state display unit is arranged on a right side of the power consumption display unit toward the display screen.   The control device according to claim 1, wherein the power sale / power purchase state display unit is arranged on a left side of the generated power display unit toward the display screen.   When the charge / discharge power is a discharge power, the control means sets the generated power and the charge / discharge power to the same background color of the generated power display unit and the background color of the charge / discharge power display unit, respectively. The control device according to claim 1, wherein the control device displays the generated power display unit and the charge / discharge power display unit.   When the charge / discharge power is charge power, the control means sets the background color of the power consumption display unit and the background color of the charge / discharge power display unit to be the same as the charge / discharge power and the power consumption, respectively. The control device according to any one of claims 1 to 3, wherein the control device displays on a charge / discharge power display unit and the power consumption display unit. A light emitting unit that emits light of different colors according to the power sale state and the power purchase state,
The control means controls the light emitting unit to emit light of a first color when the state of the solar power generation system is the power sale state, and the state of the solar power generation system is the power purchase state. 6. The control device according to claim 1, wherein the light emitting unit is controlled to emit light of a second color different from the first color.   The control means controls the light emitting unit to emit blue light when the state of the solar power generation system is the power sale state, and when the state of the solar power generation system is the power purchase state The control device according to claim 6, wherein the light emitting unit is controlled to emit orange light. A solar cell for generating electric power,
A power system that supplies power from the power company;
A storage battery for storing electric power;
A load that consumes power,
A solar power generation system provided with the control apparatus of any one of Claims 1-7.

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