JP2009303426A - Power generating system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power generating system which allows a terminal device to function, even if either a commercial power supply or a power generator goes out. <P>SOLUTION: The power generating system 1 includes a first power line 21 connected to an external commercial power supply 4; the power generator 2; a power converting unit 7 connected to a load 5 via the first power line; a first switch 8, disposed in between the power converting unit and the load on the first power line; a first connector 13 connected between the first switch and the commercial power supplyon the first power line; a second power line 22 connected between the power converting unit and the first switch on first power line; a second connector 11d connected to the second power line; a control unit 9, which controls the power converting unit and acquires information on the operation status of the power converting unit to transmit the acquired information to a terminal device 6; and the terminal device 6, which is freely connected or disconnected, to and from the first and second connectors and to acquire power and information. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a power generation system including a power generation device installed in a house or the like and a terminal device that grasps an operation state of the power generation device.

  Solar cells, wind power generators, etc. are known as simple and clean energy sources that do not emit global warming gas that uses natural energy to output DC power. For example, a solar cell is installed on the roof or site of an existing building, and the DC power obtained by the solar cell is converted into AC power, and then the AC power is output to a load in the building. Solar power generation systems are known. Some solar power generation systems can be sold to an electric power company or the like by being connected to a commercial power system and causing excess power to flow backward to the commercial power system.

  For example, Japanese Patent Laid-Open No. 10-150778 (Patent Document 1) discloses a grid interconnection inverter. According to Japanese Patent Laid-Open No. 10-150778 (Patent Document 1), this grid-connected inverter includes a solar cell, an inverter main body that converts the output of the solar cell into alternating current power, and outputs it to the system power line, and remotely operates the inverter main body. It consists of a remote controller. This grid-connected inverter includes a communication interface unit of an inverter main body and a remote controller. The communication interface unit includes an A / D conversion circuit, an encoding circuit, a modulation circuit, a band pass filter, a demodulation circuit, a decoding circuit, and a D / A conversion circuit.

  Japanese Patent Laid-Open No. 10-150778 (Patent Document 1) also discloses a configuration in which a remote control unit is connected to an inverter device via a cable.

In Japanese Patent Laid-Open No. 9-322554 (Patent Document 2), the inverter output waveform is subjected to distortion that causes fluctuations in the output frequency when the inverter device is operated independently, so that the power factor in the load impedance is close to 1. It has been disclosed to detect an independent operation of an inverter device by generating a frequency fluctuation in the inverter output even when disconnected from the AC power system.
Japanese Patent Laid-Open No. 10-150778 JP-A-9-322554

  However, in the power generation system described in Japanese Patent Laid-Open No. 10-150778 (Patent Document 1), the remote control unit is connected to the commercial power system side from the interconnection protection switch, and the commercial power is caused by an accident or disaster. The connection protection switch is configured to be disconnected when the system fails. Therefore, the remote control unit does not function when the commercial power system fails. That is, when the commercial power system fails, the user cannot grasp the operation state of the inverter device.

  Further, in the configuration in which the remote control unit is connected to the inverter device described in JP-A-10-150778 (Patent Document 1) via a cable, the remote control unit and the inverter device main body are connected by a dedicated cable. There is a need to. In other words, it is necessary to lay a dedicated cable, which may increase the wiring work cost.

  The present invention has been made to solve such problems, and the main object of the present invention is to provide power for the power generation apparatus when the commercial power supply fails and the power generation apparatus is capable of generating power. It is providing the electric power generation system which can supply a terminal device to function a terminal device.

  A power generation system according to an aspect of the present invention includes a power generation device, a first power line connected to an external commercial power source and a load, a power conversion unit connected between the power generation device and the first power line, And a first switch arranged on one power line. The first switch is disposed between the power conversion unit and the load, and connects / disconnects the power conversion unit and the load. The power generation device includes: a first switch; a first connector electrically connected between the first switch of the first power line and the commercial power supply; a power conversion unit of the first power line; A second power line electrically connected to the switch; at least one second connector electrically connected to the second power line; a control unit for controlling the power conversion unit; And a terminal device configured to be detachable from the second connector. A control part acquires the information regarding the driving | running state of a power converter, and transmits information to a terminal device via at least one of a 1st and 2nd power line. The terminal device operates by acquiring power from the power conversion unit via at least one of the first and second power lines, and acquires information via at least one of the first and second power lines.

  Preferably, the power generation system further includes a first detection unit that detects whether the commercial power supply is a power failure. The first switch is disconnected when the commercial power supply is out of power, and the first switch is connected when the commercial power supply is not out of power and when the power generation device is capable of generating power.

  Preferably, the power generation system is inserted in the second power line to connect / disconnect the second connector and the first power line, and whether the terminal device is connected to the second connector. And a second detection unit for detecting the above. The second switch is connected when the terminal device is connected to the second connector, and the second switch is blocked when the terminal device is not connected to the second connector.

  Preferably, the control unit transmits an information acquisition unit that acquires information about the operation state of the power conversion unit, a device storage unit that stores information acquired by the information acquisition unit, and the information to the terminal device. And a transmission / reception unit for receiving the command.

  Preferably, the transmission / reception unit transmits the information stored in the device storage unit to the terminal device after the commercial power supply power failure state is started when the commercial power supply power failure state ends based on the signal from the first detection unit. Send.

  Preferably, the transmission / reception unit, based on the signal from the second detection unit, when the terminal device is connected to the second connector, the information stored in the device storage unit after starting the power failure state of the commercial power supply, The data is transmitted to the terminal device via the second power line and the second connector.

  Preferably, the terminal device includes a plug that can be attached to and detached from the first and second connectors, a terminal storage unit that stores information from the control unit, a display unit that displays information stored in the terminal storage unit, An operation unit that receives a command from the outside, and a terminal transmission / reception unit that receives information from the control unit via the plug and transmits the command to the control unit via the plug.

  Preferably, the power generation device is a solar cell that generates direct-current power using sunlight. The power conversion device converts DC power into AC power and outputs it.

  According to the present invention, when the commercial power supply fails, and when the power generation device is in a state capable of generating power, the power of the power generation device can be supplied to the terminal device to cause the terminal device to function.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals, and when the names and functions of the parts are the same, detailed description of the parts will not be repeated.
<Schematic configuration of power generation system>
Below, the outline of a structure of the electric power generation system 1 which concerns on this Embodiment is demonstrated. FIG. 1 is a schematic diagram illustrating a configuration of a power generation system 1 according to the present embodiment. As shown in FIG. 1, a power generation system 1 according to the present embodiment includes a solar cell 2, a power conversion device 3, a commercial power system 4, a load 5, and a terminal device 6, which are representative examples of power generation devices. The first connector (outlet) 13 and the system power line 21 are provided. The power conversion device 3 includes a power conversion unit 7, a first switch 8, a device control unit 9, a device interface 10, and a self-supporting output unit 11.

  However, the power generation device is not limited to the solar battery 2 and may be any device that can generate power independently from the commercial power system 4, and may be, for example, a wind power generation device or another private power generation device.

  The system power line 21 and a later-described independent power line 22 according to the present embodiment are used as a data communication line for transmitting power and transmitting data. That is, the power generation system 1 according to the present embodiment uses so-called PLC (Power Line Communication) technology.

  FIG. 2 is a schematic diagram of the power generation system 1 in a state where the terminal device 6 is connected to the self-supporting output unit 11. As shown in FIGS. 1 and 2, in the power generation system 1 according to the present embodiment, the terminal device 6 is electrically connected to a system power line 21 that connects the power conversion unit 7 and the commercial power system 4. 1, and a second connector (outlet) 11 a that is electrically connected to a self-supporting output unit 11 that is connected to the power conversion unit 7 side of the system power line 21. Therefore, when the commercial power system 4 is operating normally, the user can cause the terminal device 6 to function by connecting the terminal device 6 to the first connector 13. Then, the user functions the terminal device 6 by connecting the terminal device 6 to the second connector 11a when the commercial power system 4 is out of power and when the power generation device is capable of generating power. Can be made.

Hereinafter, a configuration for realizing such a function will be described in detail.
<Hardware configuration of power generation system 1>
A hardware configuration of the power generation system 1 will be described with reference to FIGS. 1 and 2. First, the solar cell 2 is provided on a building such as a house or facility having the power generation system 1. The solar cell 2 generates DC power from solar energy (light energy). The solar cell 2 is connected to the power conversion unit 7 and outputs the generated DC power to the power conversion unit 7.

  The power conversion device 3 is installed on a wall surface inside or outside a building such as a house or a facility. The power conversion unit 7 is connected to the solar cell 2. The power conversion unit 7 is connected to the load 5 and the commercial power system 4 via the system power line 21. The power conversion unit 7 converts the DC power output from the solar cell 2 into AC power, and outputs the AC power to the system power line 21. The power conversion unit 7 is connected to the device control unit 9 and is controlled by the device control unit 9. The power conversion unit 7 and the solar cell 2 can also be controlled by the terminal device 6 described later via the device control unit 9.

  The system power line 21 is electrically connected to the power converter 7 and the external commercial power system 4. The system power line 21 is connected via a distribution board 55 to a load 5 used in a building such as a house or a facility. The system power line 21 is provided with a first switch 8 for disconnecting the power generation system 1 from the commercial power system 4 when the commercial power system 4 fails.

  Specifically, a power failure detection unit 56 that monitors the system voltage and frequency is provided inside the power conversion device 3. The power failure detection unit 56 detects a power failure in the commercial power system 4. When the power failure detection unit 56 detects a power failure of the commercial power system 4, the first switch 8 is shut off. In the power generation system 1 according to the present embodiment, the power failure detection unit 56 is connected to the device control unit 9, and the device control unit 9 connects the first switch 8 based on a signal from the power failure detection unit 56. /Cut off.

  Further, the first connector 13 is electrically connected between the first switch 8 of the system power line 21 and the commercial power system 4. The 1st connector 13 should just be formed in the shape (for example, socket shape etc.) which the terminal device 6 can connect. However, it is preferable that the 1st connector 13 is the structure similar to the 100V connector installed in the house, and it is preferable that the said 100V is substituted.

  A first signal line 23 is connected to the system power line 21 on the system side of the first switch 8. The first signal line 23 has one end connected to the system power line 21 and the other end connected to the device interface 10. The first signal line 23 is provided with a first communication switch 12 for turning on / off the connection between the system power line 21 and the device interface 10. The first communication switch 12 is connected to the device control unit 9, and on / off is controlled by the device control unit 9.

  The device control unit 9 is realized by an arithmetic device such as a CPU (Central Processing Unit). The device control unit 9 is connected to the power conversion unit 7, the device interface 10, the power failure detection unit 56, various switches, and the like. The device control unit 9 controls each unit of the power conversion device 3 by transmitting a signal to each unit of the power conversion device 3. In addition, the device control unit 9 receives an operation command from the terminal device 6 through the device interface 10, the system power line 21, and a self-supporting power line 22 described later.

  Here, the apparatus control unit 9 is realized as cooperation of hardware and software by a computer having a known configuration executing a program. Alternatively, part or all of the device control unit 9 may be realized by hardware such as a combination of circuit elements that realize each process. Then, the device control unit 9 determines each part of the power conversion device 3 based on the operation input given to the power conversion device 3 or based on the fact that a preset condition is established inside the power conversion device 3. To control the operation.

  The device interface 10 is connected to the device control unit 9, the first signal line 23, and the second signal line 24. The device interface 10 transmits a signal from the device control unit 9 to the system power line 21 via the first signal line 23, and outputs the signal to the independent power line 22 via the second signal line 24. In addition, the device interface 10 outputs a signal from the terminal device 6 to the device control unit 9.

  The independent output unit 11 includes a plurality of second connectors 11a, a second switch 11b, an independent power line 22, a detection switch 11d, and a second communication switch 11e.

  One end of the independent power line 22 is electrically connected between the power conversion unit 7 on the system power line 21 and the first switch 8, and the other end is electrically connected to the second connector 11 a.

  The second connector 11a has a shape similar to that of the first connector 13 and is formed in a shape to which the terminal device 6 can be connected. Preferably, the independent output unit 11 is formed with a plurality of second connectors 11 a that are electrically connected to the independent power line 22.

  The independent power line 22 is provided with a second switch 11b for turning on / off the connection between the system power line 21 and the second connector 11a. The second switch 11 b is connected to the device control unit 9. The second switch 11b turns on / off the connection between the system power line 21 and the second connector 11a based on a signal from the device control unit 9.

  A second signal line 24 is connected between the second switch 11b and the second connector 11a of the independent power line 22. As a result, the signal from the device interface 10 reaches the second connector 11 a via the self-supporting power line 22. The second signal line 24 is provided with a second communication switch 11e for turning on / off the connection between the independent power line 22 and the device interface 10. The second communication switch 11 e is connected to the device control unit 9 and is controlled to be turned on / off by the device control unit 9.

  The second connector 11a is provided with a detection switch 11d for detecting whether a dedicated load such as the terminal device 6 is inserted into the second connector 11a. The detection switch 11d is, for example, a switch on a protrusion provided on the surface of the second connector 11a, and when a dedicated load such as the terminal device 6 is inserted into the second connector 11a, the second connector 11a 11a is pushed into the interior. The detection switch 11 d is connected to the device control unit 9. The detection switch 11d transmits a signal indicating that a dedicated load such as the terminal device 6 is inserted into the second connector 11a to the device control unit 9.

  The terminal device 6 receives an operation command for the power conversion device 3 and the solar cell 2 and displays the operation state of the power conversion device 3 and the solar cell 2. More specifically, the terminal device 6 includes a terminal interface 6a, a display unit 6b, a plug 6c, a terminal control unit 6d, a terminal storage unit 6e, an operation unit 6f, and a power supply unit 6g.

  The terminal interface 6a is connected to the terminal control unit 6d and the plug 6c. The terminal interface 6a converts the data related to the operation command from the terminal control unit 6d into a signal and outputs the signal to the plug 6c, and the terminal control uses the signal from the plug 6c as data related to the operating state of the power conversion device 3 and the solar cell 2. To the unit 6d. Since the power generation system 1 according to the present embodiment uses the system power line 21 or the independent power line 22 as a data communication line, the terminal interface 6a and the device interface 10 serve as a PLC modem.

  The display unit 6b is realized by, for example, a liquid crystal display device, an organic EL (Electro Luminescence) display device, an LED (Light Emitting Diode), a character display device, or the like. The display unit 6b is connected to the terminal control unit 6d. Based on information from the terminal control unit 6d, an image or text is displayed outside. Specifically, data relating to the operation state of the power conversion device 3 and the solar cell 2 stored in the terminal storage unit 6e is received from the terminal control unit 6d, and information is displayed based on the data.

  The plug 6c is configured to be connectable to the first connector 13 and the second connector 11a. That is, the user can pull out the plug 6 c of the terminal device 6 from the first connector 13 and insert the terminal device 6 into the second connector 11 a. The plug 6 c is connected to the terminal interface 6 a and outputs a signal generated by the terminal interface 6 a to the system power line 21 and the independent power line 22 via the first connector 13. And the plug 6c receives a signal from the system power line 21 or the independent power line 22 and outputs it to the terminal interface.

  The terminal control unit 6d is realized by an arithmetic device such as a CPU, and is connected to the terminal interface 6a, the display unit 6b, the terminal storage unit 6e, the operation unit 6f, and the like. The terminal control unit 6d controls each unit of the terminal device 6. Specifically, the terminal control unit 6d receives an operation command from the operation unit 6f and outputs data related to the operation command to the terminal interface 6a. The terminal control unit 6d receives a display command from the operation unit 6f, reads data related to the operation state of the power conversion device 3 and the solar cell 2 from the terminal storage unit 6e, and converts power based on the data via the display unit 6b. Information about the operation state of the device 3 and the solar cell 2 is displayed.

  The terminal storage unit 6e is realized by a RAM (Random Access Memory) or the like, and is connected to the terminal control unit 6d. The terminal storage unit 6e stores a program for controlling the terminal control unit 6d, data related to the operating state of the power conversion device 3 and the solar cell 2 received from the device control unit 9, and the like.

  The operation unit 6f is realized by a switch or other input device. The operation unit 6f is connected to the terminal control unit 6d. The operation unit 6f receives an operation command from the user and outputs the operation command to the terminal control unit 6d.

Here, the display unit 6b and the operation unit 6f may be integrally configured, for example, like a touch panel.
<Functional configuration of power generation system 1>
Next, each function of the power generation system 1 according to the present embodiment, particularly the function of the device control unit 9 will be described. However, the description of the hardware configuration described above will not be repeated.

  FIG. 3 is a functional block diagram showing a functional configuration of the power generation system 1. As shown in FIG. 3, the power generation system 1 includes a solar cell 2, a power conversion device 3, a commercial power system 4, a load 5, a terminal device 6, a first connector 13, and a power failure detection unit 56. The system power line 21 is provided. The power conversion device 3 includes a power conversion unit 7, a power generation information acquisition unit 9b, a power determination unit 9c, a communication determination unit 9d, a power generation information transmission / reception unit 9e, a device storage unit 9a, and a first switch 8. , A part of the system power line 21, the self-supporting power line 22, the first signal line 23, the second signal line 24, the second switch 11b, the detection switch 11d, the second connector 11a, 1 communication switch 12 and a second communication switch 11e.

  The power generation information acquisition unit 9b, the power determination unit 9c, the communication determination unit 9d, and the power generation information transmission / reception unit 9e are functions of the device control unit 9 realized by a CPU or the like. More specifically, the power generation information acquisition unit 9b, the power determination unit 9c, the communication determination unit 9d, and the power generation information transmission / reception unit 9e execute, for example, a program stored in the device storage unit 9a by the CPU. This is a function exhibited by However, instead of realizing the function of each block and the process of each step by software, a part or all of them may be realized by a dedicated hardware circuit or the like.

  The power generation information acquisition unit 9b acquires the power generation amount generated by the solar cell 2 from the power conversion unit 7 as needed. For example, the power generation information acquisition unit 9b acquires the instantaneous power (generated power) generated by the solar cell 2 based on the output value from an ammeter or voltmeter provided in the power conversion unit 7. The power generation information acquisition unit 9b accumulates the acquired power generation amount in the device storage unit 9a. The power generation information acquisition unit 9b calculates the integrated power generation amount based on the power generation amount stored in the device storage unit 9a.

  The power determination unit 9 c acquires information on whether or not the commercial power system 4 has a power failure based on information from the power failure detection unit 56.

  The power determination unit 9c is configured to switch the first switch when power is generated by the solar battery 2, for example, when the power generated by the solar battery 2 is equal to or greater than a predetermined threshold (sunny daytime). Turn on 8. The power determination unit 9c is configured to switch the first switch 8 when the solar cell 2 is not generating power, for example, when the power generated by the solar cell 2 is less than a predetermined threshold value (nighttime or rainy weather). Turn off.

  Alternatively, the power determination unit 9c is configured to switch the first switch when the commercial power system 4 is not out of power and the solar cell 2 is generating power (the solar cell 2 is in a state capable of generating power). Turn on 8. And the electric power judgment part 9c turns off the 1st switch 8 when the commercial power grid 4 has a power failure, or when the solar cell 2 is not generating electric power.

  Then, based on the output result of the power failure detection unit 56, the power determination unit 9c determines that the terminal device 6 uses the second connector 11a based on the signal from the detection switch 11d when the commercial power system 4 has a power failure. It is further determined whether it is connected to. And the electric power judgment part 9c turns ON the 2nd switch 11b, when the terminal device 6 is connected to the 2nd connector 11a. On the other hand, the power determination unit 9c turns off the second switch 11b when the terminal device 6 is not connected to the second connector 11a.

  Alternatively, the power determination unit 9c turns on the second switch 11b when the terminal device 6 is connected to the second connector 11a. On the other hand, when the terminal device 6 is not connected to the second connector 11a, the power determination unit 9c turns off the second switch 11b.

  The communication determination unit 9d determines whether or not the terminal device 6 is connected to the second connector 11a based on a signal from the detection switch 11d. Then, when the terminal device 6 is connected to the second connector 11a, the communication determination unit 9d turns off the first communication switch 12 and turns on the second communication switch 11e. On the other hand, when the terminal device 6 is not connected to the second connector 11a, the communication determination unit 9d turns on the first communication switch 12 and turns off the second communication switch 11e.

  Alternatively, the communication determination unit 9d turns off the first communication switch 12 and outputs the second communication when the solar cell 2 generates power and the terminal device 6 is connected to the second connector 11a. The communication switch 11e is turned on. On the other hand, when the terminal device 6 is not connected to the second connector 11a, the communication determination unit 9d turns on the first communication switch 12 and turns off the second communication switch 11e.

  The power generation information transmission / reception unit 9e is realized by the device control unit 9 and the device interface 10. The power generation information transmitting / receiving unit 9 e receives an operation command from the terminal device 6 via the system power line 21 or the independent power line 22. The power generation information transmission / reception unit 9e uses the power conversion unit 7 and the information regarding the operation state of the solar cell 2 stored in the device storage unit 9a (for example, the amount of generated power and the total amount of generated power) as the system power line 21 and the independent power line 22. Is transmitted to the terminal device 6 via.

In addition, the power generation information transmission / reception unit 9e transmits the information stored in the device storage unit 9a to the terminal device 6 before power generation starts after the power failure of the commercial power system 4 ends and power is restored. Alternatively, the power generation information transmission / reception unit 9e is configured to store the information stored in the device storage unit 9a after the commercial power system 4 has failed and the power generation is started after the terminal device 6 is inserted into the second connector 11a. Transmitting to the terminal device 6 via the second signal line 24 and the second connector 11a <Outline of operation of power generation system>
Next, the operation of the power generation system 1 having the above configuration will be described. As shown in FIGS. 1 to 3, when solar radiation 2 is installed on the roof of a building such as a private house or public facility at daytime when the solar radiation intensity is high, the device control unit 9 of the power conversion device 3 Turns on the first switch 8 to connect the power converter 3 and the commercial power system 4. That is, the power conversion device 3 automatically starts the interconnection operation. When the generated power of the power generation system 1 exceeds the power consumption consumed by the electric load 5 used in the building during the interconnected operation, surplus power is reversely flowed to the commercial power system 4.

  At this time, the terminal device 6 is connected to the first connector 13 of the building, and the terminal device 6 acquires power from the commercial power system 4. While the commercial power system 4 is energized, the first communication switch 12 in the power generation system 1 is turned on, and the device control unit 9 is connected to the terminal device 6 via the device interface 10, the first signal line 23, and the system power line 21. Send and receive data. The terminal device 6 displays the current power generation value of the power generation system 1, the accumulated power generation amount for a certain period, and the state of the power generation system 1. The device control unit 9 controls the operation of the power conversion unit 7 and the solar cell 2 based on an operation command from the terminal device 6.

  On the other hand, when the solar radiation intensity almost disappears in the evening, the device control unit 9 of the power conversion device 3 stops the power conversion unit 7 and turns off the first switch 8. That is, the power converter 3 is automatically stopped, the connection between the power converter 3 and the commercial power system 4 is turned off, and the interconnection operation is automatically stopped. At this time, the terminal device 6 is connected to the first connector 13 away from the place where the power conversion device 3 is installed, and power is supplied from the commercial power system 4. Before the switch 8 is turned off, the control unit 9 transmits information on the previous power conversion device 3 to the terminal device 6. While the commercial power system 4 is energized, the manager or the owner can check the information of the power conversion device 3 of the day with the terminal device 6 even at night. The terminal device 6 can display the accumulated power generated on the day using the power from the commercial power system 4 even at night when there is no solar radiation intensity.

  When a power failure occurs in the commercial power system 4 due to a disaster or accident during the daytime when the solar radiation intensity is high, the device control unit 9 of the power conversion device 3 is connected to the commercial power system 4 regardless of the solar radiation intensity. A power failure is detected and the first switch 8 is turned off. That is, the device control unit 9 stops the power conversion unit 7, disconnects the connection between the power conversion device 3 and the commercial power system 4, and automatically stops the interconnection operation. When the commercial power system 4 fails, power is not supplied to the terminal device 6 and the data from the power conversion device 3 cannot be superimposed on the power of the commercial power system 4, so the terminal device 6 does not operate, The integrated power consumption during grid operation cannot be confirmed.

  And the apparatus control part 9 continues a stop of a grid connection operation until the power failure of the commercial power grid | system 4 is restored. Here, in order to operate the system 1 independently, the terminal device 6 is connected to the second connector 11a. Since the second connector 11 a has the same shape as the first connector 13, the manager or user of the power generation system 1 can easily and manually connect the terminal device 6 to the second connector in the self-supporting output unit 11 of the power converter 3. 11a. As a result, even if the power failure state of the commercial power system 4 continues, if the solar radiation intensity is present, the power generation system 1 performs a self-sustaining operation in a state disconnected from the commercial power system 4, and the second connector 11a The generated power can be supplied to the connected dedicated load.

  As described above, the second connector 11a is provided with the protruding detection switch 11d, and when the plug 6c of the terminal device 6 is inserted into the second connector 11a, the protruding detection switch 11d is connected to the plug 6c. The detection switch 11d is turned on. On the other hand, when the plug 6c of the terminal device 6 is pulled out from the second connector 11a, the protruding detection switch 11d is not pushed by the plug 6c, so that the detection switch 11d returns to its original state and turns off.

  Hereinafter, the independent operation of the power generation system 1 will be described. First, when the power conversion device 3 is operating in the daytime when the solar radiation intensity is in operation and the commercial power system 4 fails and communication with the terminal device 6 is stopped, the administrator or user of the power generation system 1 switches the terminal device 6 on. The plug 6 c can be removed from the first connector 13 connected to the commercial power system 4 and can be inserted into the second connector 11 a in the self-supporting output unit 11 of the power conversion device 3. When the plug 6c is inserted into the second connector 11a, the detection switch 11d transmits a signal indicating that the plug 6c is inserted into the second connector 11a to the device controller 9.

  The device control unit 9 receives the signal, turns on the second switch 11b, turns off the first communication switch 12, and turns on the second communication switch 11e. That is, the device control unit 9 electrically connects the second connector 11a to the power conversion unit 7 side rather than the first switch 8 of the system power line 21. Accordingly, the power conversion unit 7 can supply power to the terminal device 6 via the self-supporting power line 22 and the second connector 11a. Then, the manager or the owner manually operates the operation unit of the terminal device 6 to start the independent operation. As a result, the terminal device 6 can operate even when the commercial power system 4 has a power failure.

At this time, electric power is also supplied to other dedicated electric loads connected to the second connector 11a.
<Operation procedure in power generation system 1>
Next, the operation of the power generation system 1 according to the present embodiment will be described in detail with reference to FIG. FIG. 4 is a flowchart showing an operation procedure in the power generation system 1 according to the present embodiment.

  As shown in FIG. 4, first, the device control unit 9 determines whether or not the solar cell 2 can sufficiently generate power based on the input voltage from the solar cell (step S <b> 102). If solar cell 2 is not generating power (NO in step S102), first switch 8 is turned off (step S104). On the other hand, when solar cell 2 can generate power (YES in step S <b> 102), device control unit 9 performs the previous power via device interface 10, first signal line 23, and system power line 21. Information on the conversion device 3 is transmitted to the terminal device 6 (step S105). And the 1st switch 8 is turned ON (step S106), the power converter device 3 starts an operation | movement, and performs a grid connection operation (step S107). The device control unit 9 transmits the generated power amount to the terminal device 6.

  Next, the device control unit 9 determines whether or not the input voltage is equal to or higher than a threshold value (step S108). If the input voltage is equal to or lower than the threshold value (NO in step S108), the current power conversion device 3 information is transmitted to the terminal device 6 (step S109), the power conversion unit 7 is stopped, and the first Is switched off (step S104). On the other hand, when the input voltage is equal to or higher than the threshold value (YES in step S108), device controller 9 next determines whether commercial power system 4 has a power failure based on a signal from power failure detection unit 56. It is determined whether or not (step S110). When commercial power system 4 has not failed (NO in step S110), apparatus control unit 9 repeats the operation from step S107 (steps S107 to S110).

  On the other hand, when commercial power system 4 has a power failure (YES in step S110), power conversion unit 7 is stopped, and device control unit 9 turns off first switch 8 (step S112). That is, the interconnection operation between the power conversion device 3 and the commercial power system 4 is stopped.

  And the apparatus control part 9 judges whether the terminal device 6 was connected to the 2nd connector 11a based on the signal from the detection switch 11d (step S116). If the terminal device 6 is not connected to the second connector 11a, for example, if the terminal device 6 remains connected to the first connector 13 (NO in step S116), the device control unit 9 starts from step S110. The process is repeated (steps S110 to S116).

  On the other hand, when the user removes the terminal device 6 from the first connector 13 and inserts it into the second connector 11a, that is, when the terminal device 6 is connected to the second connector 11a (YES in step S116). The device control unit 9 turns on the second switch 11b, turns off the first communication switch 12, turns on the second communication switch 11e, and operates the power conversion unit 7 (step S118). Thereby, the electric power from the power converter 7 is supplied to the terminal device 6 via the self-supporting power line 22 and the second connector 11a, and the terminal device 6 starts to function.

  Information on the power conversion device 3 before the previous power failure stored in the device storage unit 9a in the device control unit 9 is transmitted to the terminal via the device interface 10, the second signal line 24, and the second connector 11a. It is transmitted to the device 6 (step S120). After that, when the administrator or the owner operates the operation unit 6f of the terminal device 6 and the power conversion device 3 starts a self-sustained operation, the device control unit 9 calculates the instantaneous power amount and transmits it to the terminal device 6 ( Step S122). Thereby, the terminal device 6 can display the operation state of the power converter 7 and the solar cell 2, and can control the power converter 7 and the solar cell 2. In other words, the manager or owner can check the accumulated power generated during the grid operation through the terminal device 6 even during the independent operation, or can grasp the instantaneous power generation amount during the independent operation and the power generation state of the solar cell 2. Or controlling the power converter 7.

  Next, the device control unit 9 determines whether or not the power failure continues based on the signal from the power failure detection unit 56 (step S124). If the power failure continues, the device control unit 9 repeats steps S122 to S124. When the power failure ends and power is restored (NO in S124), the device control unit 9 displays the power restored on the terminal device 6 via the second signal line 24 (S125). And the apparatus control part 9 judges whether the terminal device 6 is connected to the 2nd connector 11a based on the signal from the detection switch 11d (step S128).

  When terminal device 6 is connected to second connector 11a (YES in step S128), device control unit 9 repeats the processing from step S122 (steps S122 to S124).

On the other hand, when the administrator or the owner removes the terminal device 6 from the second connector 11a (NO in step S128), the power conversion unit 7 is stopped, and the device control unit 9 turns off the second switch 11b. In addition, the first communication switch 12 is turned on and the second communication switch 11e is turned off (step S126).
<Summary>
Finally, the difference between the preceding power generation system 101 and the power generation system 1 according to the present embodiment will be described with reference to FIG. FIG. 5 is a schematic diagram showing the preceding power generation system 101.

  As shown in FIG. 5, in the preceding power generation system 101, the terminal device 106 is connected to the commercial power system 104 side from the grid protection switch (first switch) 108, and the power generation system 101 is connected during the daytime. When the commercial power system 104 fails due to an accident or disaster while the power is being generated, the interconnection protection switch 108 is disconnected. Further, the system power line 121 is used as a data communication line. Therefore, it is not necessary to connect the power conversion device 103 and the terminal device 106 with a dedicated wired cable, and there is no need for laying the dedicated cable, and any place where it can be connected to the indoor commercial power system 104 is free. The terminal device 106 can be installed and functioned.

  However, in the power generation system 101 of the prior art, since the power source of the terminal device 106 is supplied only from the indoor system power line 121, the terminal device 106 does not function when the commercial power system 104 fails due to an accident or disaster. . In other words, when the power generation system 101 can generate power during the day, the connection protection switch 108 is disconnected at the time of a power failure of the commercial power system 104, so that the user can check the power generation amount and state of the power generation system 101. become unable.

  Further, when the power conversion device 103 or the solar battery 102 is controlled by the terminal device 106, even if a dedicated load connector or the like is provided in the power conversion device 103, the power generation system 101 cannot supply generated power to the dedicated load. There was a case. More specifically, even if the commercial power system 104 is out of power, the power generation system 101 can supply generated power to a dedicated load independently from the commercial power system 104 as long as the solar battery 102 can generate power. Since the terminal device 106 does not function due to a power failure, the power generation system 101 may not be able to supply generated power to the dedicated load.

  On the other hand, according to the power generation system 1 according to the present embodiment, even if the commercial power system 4 fails due to an accident or disaster, the manager or the owner can easily perform the power generation system 101 as long as the power generation system 101 can generate power during the day. The terminal device 6 can be connected to the second connector 11a, and the terminal device 6 can function. That is, even when the commercial power system 4 has a power failure, the user can check the amount of power generated and the power generation state of the power generation system 1.

  Moreover, even if the commercial power system 4 is out of power, the power generation system 1 is controlled by the terminal device 6 as long as the solar cells in the daytime are radiated and can generate power. The generated power can be supplied to a dedicated load connected to the connector 11a. In addition, since the device control unit 9 can store the integrated power generation amount generated by the power conversion device 3 in a self-sustained operation during a power failure of the commercial power system 4, the terminal device 6 is second after the power failure is restored. When the terminal 11 is connected to the connector 11a, the user can check the accumulated power generation amount in the terminal device 6.

  The disclosed embodiments are to be considered in all respects as illustrative and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

It is the schematic which shows the structure of the electric power generation system which concerns on this Embodiment. It is the schematic of the electric power generation system in the state where the terminal device was connected to the self-supporting output part. It is a functional block diagram which shows the function structure of an electric power generation system. It is a flowchart which shows the operation | movement procedure in the electric power generation system which concerns on this Embodiment. It is the schematic which shows a prior | preceding electric power generation system.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Power generation system, 2 Solar cell, 3 Power converter, 4 Commercial power system, 5 Electrical load, 6 Terminal device, 6a Terminal interface, 6b Display part, 6c Plug, 6d Terminal control part, 6e Terminal storage part, 7 Power conversion Unit, 8 first switch, 9 device control unit, 9a device storage unit, 9b power generation information acquisition unit, 9c power determination unit, 9d communication determination unit, 9e power generation information transmission / reception unit, 10 device interface, 11 independent output unit, 11a 2nd connector, 11b 2nd switch, 11d detection switch, 11e 2nd communication switch, 12 1st communication switch, 13 1st connector, 21 system power line, 22 independent power line, 23 1st signal line, 24 Second signal line, 55 distribution board, 56 power failure detection unit, 101 power generation system, 102 solar cell, 103 electricity Converter, 104 commercial power system, 106 terminal, 108 communication system protective switch, 121 the system power line.

Claims (8)

A power generator,
A first power line connected to an external commercial power source and a load;
A power converter connected between the power generator and the first power line;
A first switch disposed on the first power line,
The first switch is disposed between the power converter and the load, and connects / disconnects the power converter and the load,
A first connector electrically connected between the first switch of the first power line and the commercial power source;
A second power line electrically connected between the power converter of the first power line and the first switch;
At least one second connector electrically connected to the second power line;
A control unit for controlling the power conversion unit;
A terminal device configured to be detachable from the first and second connectors;
The controller is
Obtain information about the operating state of the power converter,
Transmitting the information to the terminal device via at least one of the first and second power lines;
The terminal device
Operate by obtaining power from the power converter via at least one of the first and second power lines;
A power generation system that acquires the information via at least one of the first and second power lines. A first detection unit for detecting whether the commercial power supply is a power failure;
The first switch is shut off when the commercial power source is outage;
The power generation system according to claim 1, wherein the first switch is connected when the commercial power source is not in a power outage and when the power generation device is in a state capable of generating power. A second switch that is inserted into the second power line and connects / disconnects the second connector and the first power line;
A second detector for detecting whether or not the terminal device is connected to the second connector;
The second switch is connected when the terminal device is connected to the second connector;
The power generation system according to claim 2, wherein the second switch is cut off when the terminal device is not connected to the second connector. The controller is
An information acquisition unit for acquiring information on the operation state of the power conversion unit;
A device storage unit for accumulating the information acquired by the information acquisition unit;
The power generation system according to any one of claims 1 to 3, further comprising: a transmission / reception unit that transmits the information to the terminal device and receives a command from the terminal device.   The transmission / reception unit, based on a signal from the first detection unit, stores the information stored in the device storage unit after the commercial power supply power failure state starts when the commercial power supply power failure state ends. The power generation system according to claim 4, which is transmitted to a terminal device.   The transmission / reception unit is stored in the device storage unit after the power failure state of the commercial power supply starts when the terminal device is connected to the second connector based on a signal from the second detection unit. The power generation system according to claim 4, wherein the information is transmitted to the terminal device via the second power line and the second connector. The terminal device
A plug removable from the first and second connectors;
A terminal storage unit for storing the information from the control unit;
A display unit for displaying the information stored in the terminal storage unit;
An operation unit that accepts external commands;
The power generation according to claim 1, further comprising: a terminal transmission / reception unit that receives the information from the control unit via the plug and transmits the command to the control unit via the plug. system. The power generator is a solar cell that generates direct-current power using sunlight,
The power generation system according to any one of claims 1 to 7, wherein the power conversion device converts the DC power into AC power and outputs the AC power.

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