JP5778822B1 - Photovoltaic power generation control device, solar power generation system, and control method of solar power generation system - Google Patents

Abstract

A solar power generation control device, a solar power generation system, and a control method for a solar power generation system capable of easily performing interconnection are provided. A communication unit that is provided between a power system and a photovoltaic power generation facility and that communicates with an external device; when the power system recovers from a power failure and the communication unit receives an instruction from the external device; A photovoltaic power generation facility and an interconnection control unit that interconnects an electric power system. [Selection] Figure 9

Description

  The present invention relates to a solar power generation control device, a solar power generation system, and a control method for a solar power generation system.

  Conventionally, a solar power generation system that reversely flows power generated by a solar power generation unit to an electric power system has been used (for example, Patent Document 1). In order to transmit power from the solar power generation facility to the power system, the solar power generation facility and the power system are linked.

JP 2003-61364 A

  When the power system fails, this connection is also cut off. After returning from the power outage (recovery), power is connected again to transmit power. Before re-connecting, permission from the power company may be required. For example, for facilities that generate large power, such as 50 kW or higher, permission may be required for interconnection. In this case, it is not possible to use a system that automatically links, and the user performs a link operation after receiving permission from the power company.

  However, when a plurality of photovoltaic power generation facilities are installed, it takes a lot of labor to perform interconnection work for each facility. For example, when a plurality of photovoltaic power generation facilities are provided on a vast site, the user must move to each facility to perform work. In particular, solar power generation facilities may be distributed in the site. In this case, the movement becomes even more difficult.

  In view of the above problems, an object of the present invention is to provide a solar power generation control device, a solar power generation system, and a control method for a solar power generation system that can be easily interconnected.

The present invention is provided between a power system and a plurality of solar power generation facilities that transmit generated power to the power system, and a power recovery detection unit that detects power recovery of the power system, and the solar power generation There line communication with an external device that the user has the facility, when the power recovery detection unit detects the power recovery, power recovery Mr. the power recovery and a communication unit configured to notify the external device, the power system from power failure And when the said communication part receives the instruction | indication of interconnection from the said external apparatus, it is a photovoltaic power generation control apparatus which comprises the said photovoltaic power generation equipment and the interconnection control part which connects with the said electric power grid | system. is there.

  The said structure WHEREIN: It has the electric power generation detection part which detects that the electric power generation by the said solar power generation facility is performed, and when the said electric power generation detection part detects the said electric power generation, the said communication part is performing the said electric power generation Can be configured to notify the external device.

  The said structure WHEREIN: The power failure detection part which detects the power failure of the said electric power grid | system is provided, and when the said power failure detection part detects the said power failure, it can be set as the structure which notifies the said power failure to the said external device.

  In the above configuration, when the power of the power system is lost for a time shorter than a predetermined time, the power failure detection unit does not detect a power failure of the power system, and the power of the power system is lost for a time longer than the predetermined time. When it does, the said power failure detection part can be set as the structure which detects the power failure of the said electric power grid | system.

The present invention comprises a plurality of photovoltaic power generation facilities that transmit the generated power to a power system, and a control device provided between the power system and the plurality of solar power generation facilities, the control device, a power recovery detection unit for detecting a power recovery of the power system, the have line communicating with an external device that the user has the photovoltaic facility, when the power recovery detection unit detects the power recovery, the power recovery When the communication unit for notifying the external device and the power system recovers from a power failure and the communication unit receives an interconnection instruction from the external device, the photovoltaic power generation facility and the power system are connected. It is the solar power generation system which comprises the interconnection control part which performs system | strain.

The present invention includes a step of notifying an external device of a power recovery after the power system recovers from a power failure , a plurality of photovoltaic power generation facilities that transmit generated power from the external device to the power system, and the power system. depending on receiving the instruction instructs the interconnection between, anda step of interconnection between the photovoltaic power generation facilities and the power system, the user of the photovoltaic power generation facilities are the external device Is a control method of a photovoltaic power generation system having

  ADVANTAGE OF THE INVENTION According to this invention, the solar power generation control apparatus, solar power generation system, and control method of a solar power generation system which can perform connection easily can be provided.

FIG. 1 is a schematic diagram illustrating a photovoltaic power generation system according to an embodiment. FIG. 2 is a front view showing the control device. FIG. 3 is a diagram showing a part of the control device. FIG. 4 is a sequence diagram of the control device. FIG. 5 is a diagram showing the configuration of the control device. FIG. 6 is a functional block diagram illustrating the configuration of the control unit. FIG. 7A is a flowchart showing processing of the control device during power generation. FIG. 7B is a flowchart showing processing of the control device when power generation is stopped. FIG. 8A is a time chart corresponding to FIGS. 7A and 7B. FIG. 8B is a time chart in the momentary power failure. FIG. 9 is a flowchart showing processing of the control device at the time of power recovery. FIG. 10A and FIG. 10B are time charts corresponding to FIG.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic diagram showing a photovoltaic power generation system 100 according to an embodiment. The solar power generation system 100 includes a commercial power system 1 (sometimes simply referred to as the power system 1), five solar power generation facilities 7, and a control device 10. The output power of one solar power generation facility 7 is, for example, 10 kW, and the output of the entire solar power generation system 100 illustrated in FIG. 1 is, for example, 50 kW.

  The power system 1 is a 200V AC power system. The power system 1 and the power conditioner 7b of the solar power generation facility 7 are connected by power lines 4 and 4a. The three-phase power line 4 is connected to the power system 1 and branches into a plurality of power lines 4 a in the current collector panel 6. Each power line 4a is connected to a power conditioner 7b. Electric power generated by the solar power generation facility 7 is collected on the current collector 6 through the power line 4 a and transmitted to the power system 1 through the power line 4. The electric power thus generated is purchased by an electric power company.

  The power line 4 is provided with power meters 2 and 3, a switch 5, a control device 10, and a current collector panel 6 from the power system 1 side. The wattmeter 2 measures the power supplied from the power system 1 to the solar power generation facility 7. This power is purchased from the power company by the owner of the solar power generation facility 7. The wattmeter 3 measures the power supplied from the solar power generation facility 7 to the power system 1. This power is purchased from the owner by the power company.

  When the switch 5 is closed, the power system 1 and the photovoltaic power generation facility 7 are connected by the power line 4. When the switch 5 is opened, the power system 1 and the photovoltaic power generation facility 7 are disconnected. The current collector panel 6 includes a switch 6a and a plurality of switches 6b. The switch 6a is provided on the power line 4, and the switch 6b is provided on each of the plurality of power lines 4a.

  The solar power generation facility 7 includes a solar power generation panel 7a and a power conditioner 7b. The solar power generation panel 7a receives sunlight to generate power. The power conditioner 7b converts the generated DC power into AC power. Note that, when the power system 1 is powered down, the power conditioner 7b is turned off. However, the power conditioner 7b can be set to automatically turn on when the power system 1 is restored.

  The control device 10 is provided between the switch 5 and the current collector panel 6. Hereinafter, the control device 10 will be described. FIG. 2 is a front view showing the control device 10.

  In FIG. 2, among the configurations included in the control device 10, the box 11, the magnetic contactor 12, the relays 15, 22 to 34 and 39, the CTU (capacitor trip device) 13, the SPD (Surge Protective Device: SPD) ) 14, ELB (leakage breaker) 16 and 17, current converter 18, transformer 19, AC / DC converter 20, CP (Circuit Protector) 21, and remote control unit 40 are illustrated. The remote control unit 40 can be an electronic device that is removable from the box 11. The above configuration can be protected by attaching a cover (not shown) to the box 11.

  FIG. 3 is a diagram showing a part of the control device 10. The upper side of FIG. 3 is the power system 1 side (primary side), and the lower side is the photovoltaic power generation equipment 7 side (secondary side).

  As shown in FIG. 3, the power line 4 is provided with a main contact 12 a of the electromagnetic contactor 12 and a current converter 18 in order from the power system 1 side. By closing the main contact 12a, the power system 1 and the solar power generation facility 7 are interconnected, and power is transmitted from the solar power generation facility 7 to the power system 1.

  SPD 35, ELBs 16 and 17 are connected to the power system 1 side of the main contact 12a. A relay 15 is connected to the ELB 16. The SPB 14 is connected to the ELB 17, and the AC voltage of the power system 1 is applied to the control device 10 as the control power sources R and S via the ELB 17. The relay 15 is connected to the current converter 18, and the contact of the relay 15 is opened and closed by the current flowing from the current converter 18.

  FIG. 4 is a sequence diagram of the control device 10. FIG. 5 is a diagram illustrating a configuration of the control device 10.

  An AC voltage of 200 V is applied between the control power sources S and R shown in FIGS. As shown in FIG. 4, the switch 37 is a switch that can be manually switched, for example, and includes a contact point 37a and a contact point 37b. If the contact point 37a is on, the contact point 37b is off. In this case, the relay 28 can be used to control the interconnection. If the contact point 37a is off, the contact point 37b is on. In this case, the remote control unit 40 can control the interconnection.

  The relay 22 includes contacts 22a, 22b and 22d, and a coil 22c. The relay 23 includes contacts 23a, 23b and 23d, and a coil 23c. FIG. 4 shows the coil 24 c of the relay 24.

  The relay 25 includes a contact point 25a and a coil 25c, and the relay 26 includes a contact point 26a and a coil 26c. Relays 25 and 26 are each in a pulse operation mode. The relay 28 includes contacts 28a and 28b and a coil 28c shown in FIG. 4, and further includes a contact 28d shown in FIG.

  The relay 29 includes contacts 29a and 29b shown in FIG. 4, a contact 29d shown in FIG. 5, and a coil 29c. As shown in FIG. 5, the relay 30 includes a contact 30a and a coil 30c. The relay 31 includes two contacts 31b1 and 31b2 and a coil 31c. The relay 32 includes a contact 32a, two contacts 32b1 and 32b2, and a coil 32c. The relay 33 includes a contact 33a and a coil 33c. The relay 34 includes a contact 34b and a coil 34c.

  The electromagnetic contactor 12 includes a main contact 12a shown in FIG. 3, contacts 12b and 12c as auxiliary contacts shown in FIG. 4, coils 12d and 12e, and terminals 12f to 12i.

  As shown in FIG. 4, the coils 27c and 28c are connected between the control power sources S and R, respectively. One end of the coil 22c is connected to the control power source R via the contact point 37a, and the other end is connected to the control power source S. One end of the coil 23c is connected to the control power source R via the contact point 37b, and the other end is connected to the control power source S. The contacts 22b and 23b and the coil 24c are connected between the control power sources R and S.

  One end of the contact 28b is connected to the control power source R, and the other end is connected to the control power source S via the contact 22a and the coil 25c. One end of a contact 29a is connected between the contact 22a and the coil 25c, and the other end of the contact 29a is connected to the control power supply R via the contact 23a.

  One end of the contact 28a is connected to the control power source R, and the other end is connected to the control power source S via the contact 22d and the coil 26c. One end of a contact 29b is connected between the contact 22d and the coil 26c, and the other end of the contact 29b is connected to the control power source R through the contact 23d.

  One end of the contact 25a is connected to the control power source R, and the other end is connected to the control power source S via the terminal 12f, the contact 12b, the coil 12d, and the terminal 12g of the electromagnetic contactor 12. One end of the contact 26a is connected to the control power source R, and the other end is connected to the control power source S via the terminal 12h, the contact 12c, the coil 12e, and the terminal 12i of the electromagnetic contactor 12.

  One end of a contact 27b of the relay 27 is connected between the contact 26a and the terminal 12h. The other end of the contact 27 b is connected to one of the terminals of the CTU 13. The other two terminals of the CTU 13 are connected to the control power sources R and S.

  As shown in FIG. 5, one end of the contact 28 d of the relay 28 is connected to the control power source R, and the other end is connected to the control power source S via the coil 31 c of the relay 31.

  An AC voltage converted to 100 V by the transformer 19 is applied to the terminal of the AC / DC converter 20 via the CP 21. The AC / DC converter 20 converts an AC voltage into a DC voltage of 12V, for example. The positive terminal 20a of the AC / DC converter 20 is connected to the terminal 40a of the remote control unit 40 through the contacts 31b1 and 32b1, and the negative terminal 20b is connected to the terminal 40b of the remote control unit 40 through the contacts 31b2 and 32b2. The A battery 36 is connected to the AC / DC converter 20. The battery 36 can be used as an emergency power source for the remote control unit 40, for example. 5 is connected to the plus terminal 20a of the AC / DC converter 20, and the control power source N is connected to the minus terminal 20b.

  One end of the contact 27a and one end of the switch 38a are connected to the control power source P. The other end of the contact 27a is connected to the control power supply N via a coil 39c.

  One end of the contact 39b, one end of the contact 33a, and one end of the contact 32a are connected in parallel to the other end of the switch 38a. The other end of the contact 39b is connected to the control power supply N through the contact 29d and the coil 33c. The other end of the contact 33a is connected to the control power supply N via the contact 34b and the coil 32c. The other end of the contact 32a is connected to the control power supply N via the coil 34c. The other end of the contact 32a is connected between the contact 33a and the contact 34b. The switch 38a, the contacts 29d, 32a, 33a, 34b, 39b and the coils 32c to 34c are referred to as a circuit 38.

  The contact 30 a is connected to the electronic device 50. The electronic device 50 is, for example, an alarm device or a camera, and can be attached to the control device 10 as an option. When the remote control unit 40 excites and demagnetizes the coil 30c, the electronic device 50 can be operated.

  Terminals 40 c and 40 d of the remote control unit 40 are connected to a contact 39 a of the relay 39. Terminals 40e and 40f of the remote control unit 40 are connected to a contact 15a of the relay 15. Terminals 40g and 40i are connected to a control power source P. The terminal 40h is connected to the control power supply N via the coil 29c. The terminal 40j is connected to the control power supply N via the coil 30c.

  The remote operation unit 40 includes a control unit 41 and an interface (I / F) 42. The control unit 41 is an arithmetic device such as a CPU (Central Processing Unit). The I / F 42 is an interface for connecting to a network 60 such as the Internet or a LAN (Local Area Network). The remote operation unit 40 communicates with an external device 61 outside the control device 10 through the network 60.

  The external device 61 is, for example, a mobile phone, a smartphone, a personal computer (PC: Personnel Computer), or a tablet terminal. As will be described later, the remote control unit 40 can notify the user's external device 61 by, for example, an e-mail or a mobile phone call, and can receive a signal from the external device 61. In addition, an application for controlling the photovoltaic power generation system 100 can be installed in the external device 61, a notification from the remote operation unit 40 can be received, and an instruction can be transmitted to the remote operation unit 40.

  FIG. 6 is a functional block diagram illustrating the configuration of the control unit 41. As illustrated in FIG. 6, the control unit 41 functions as a power failure detection unit 43, a power recovery detection unit 44, a communication unit 45, an interconnection control unit 46, and a power generation detection unit 47. The power failure detection unit 43 detects a power failure of the power system 1. The power recovery detection unit 44 detects power recovery of the power system 1. The communication unit 45 communicates with the external device 61 through the I / F 42 of FIG. The interconnection control unit 46 interconnects the power system 1 and the solar power generation facility 7 illustrated in FIG. 1 and cancels the interconnection. The power generation detection unit 47 detects that the solar power generation facility 7 is generating power.

  The operation of the control device 10 will be described. First, a case where the solar power generation facility 7 generates power during the day will be described. Here, a case where the control device 10 is controlled using the remote operation unit 40 without using the relay 28 will be described. In this case, by turning off the contact 37a and turning on the contact 37b shown in FIG. 4, the contacts 22a and 22d are turned off and the contacts 23a and 23d are turned on.

  FIG. 7A is a flowchart showing processing of the control device 10 during power generation. As shown in FIG. 7A, the communication unit 45 determines whether there is a connection instruction from the external device 61 (step S1). If no, step S1 is repeated. In the case of Yes, a process transfers to step S2.

  The interconnection control unit 46 performs interconnection (step S2). Specifically, the interconnection control unit 46 applies a voltage to the coil 29c shown in FIG. 5 to excite it. By the excitation of the coil 29c, the contact 29a shown in FIG. 4 is turned on, and the coil 25c is excited. The contact 25a is turned on by excitation of the coil 25c, and a voltage is applied between the terminals 12f and 12g. Thereby, the main contact 12a shown in FIG. 3 is turned on, and interconnection is performed.

  The power generation detection unit 47 determines whether power generation by the solar power generation facility 7 is being performed (step S3). With power generation, a current larger than the standby current flows from the current converter 18 shown in FIG. 3 to the relay 15, and the contact 15a of the relay 15 shown in FIG. 5 is turned on. As a result, a voltage is applied to the terminals 40e and 40f of the remote control unit 40. That is, the power generation detection unit 47 determines that the solar power generation facility 7 is not generating power if the contact 15a is off (No). In this case, step S1 is repeated. If the contact 15a is on, the power generation detection unit 47 determines that the solar power generation facility 7 is generating power (Yes). In this case, the communication unit 45 notifies the external device 61 that power is being generated (step S4). After step S4, the process ends.

  Next, a case where the solar power generation facility 7 does not generate power (nighttime stoppage) such as at night will be described. When power generation is not performed, the interconnection is also released. FIG. 7B is a flowchart showing processing of the control device 10 when power generation is stopped.

  As shown in FIG. 7B, the communication unit 45 determines whether there is an instruction to cancel the connection from the external device 61 (step S5). If no, step S5 is repeated. In the case of Yes, the process proceeds to step S6.

  The interconnection control unit 46 cancels the interconnection (step S6). Specifically, the interconnection control unit 46 stops applying the voltage to the coil 29c shown in FIG. The demagnetization of the coil 29c turns off the contact 29a shown in FIG. 4 to demagnetize the coil 25c, and the contact 29b turns on and the coil 26c is excited. The contact 26a is turned on by excitation of the coil 26c, and a voltage is applied between the terminals 12h and 12i. As a result, the main contact 12a shown in FIG. 3 is turned off, and the interconnection is released.

  The power generation detection unit 47 determines whether power generation is being performed (step S7). If the contact point 15a is on, it is determined that the photovoltaic power generation facility 7 is generating power (Yes), and step S5 is repeated. If the contact point 15a is off, it is determined that the photovoltaic power generation facility 7 is not generating power (No), and the communication unit 45 notifies the external device 61 that power is being generated (step S8). After step S8, the process ends.

  FIG. 8A is a time chart corresponding to FIGS. 7A and 7B. The horizontal axis indicates time, and the contacts 29a, 29b, 25a, 26a and the main contact 12a are turned on / off sequentially from the top.

  Time T1 in FIG. 8A is the sunrise time, the contacts 29a and 25a and the main contact 12a are turned on, and the contacts 29b and 26a are turned off (step S2 in FIG. 7A). Time T2 is sunset time, the contacts 29b and 26a are turned on, and the contacts 29a and 25a and the main contact 12a are turned off (step S6 in FIG. 7B). The contacts 25a and 26a are turned on for 0.5 seconds, for example.

  In addition, by inputting the sunset time (sunset time) and sunrise time of the area where the solar power generation facility 7 is installed in the external device 61 in advance, the external device 61 is automatically operated remotely according to the sunrise and sunset. A connection instruction and a connection release instruction can be transmitted to the unit 40. Moreover, the electric power grid | system 1 and the photovoltaic power generation equipment 7 may be always connected. In this case, the main contact 12a is always on in FIG.

  It is also possible to control the interconnection using the relay 28. In this case, by turning on the contact 37a and turning off the contact 37b, the contacts 22a and 22b are turned on and the contacts 23a and 23d are turned off. The relay 28 receives the sunset time and sunrise time of the area where the photovoltaic power generation facility 7 is installed, and functions as a solar timer. At the sunrise time, the coil 28c is demagnetized, the contact 28a is turned off, and the contact 28b is turned on. As a result, the main contact 12a is turned on and connected. At the sunset time, the coil 28c is excited, the contact 28a is turned on, and the contact 28b is turned off. As a result, the main contact 12a is turned off and the interconnection is released.

  Next, the case of instantaneous power failure (instantaneous power failure) will be described. FIG. 8B is a time chart in the momentary power failure. The control power supplies R and S (hereinafter sometimes simply referred to as “control power supply”), the contact 27a and the main contact 12a are turned on / off in order from the top. The control power supply is lost for a very short time (for example, less than 2 seconds) such as time T3 to T4. The relay 27 is an off-delay timer, and for example, the contact 27a shown in FIG. 5 is kept on and the contact 27b shown in FIG. 4 is kept off (disconnected state) for 2 seconds after the loss of the control power supply. To do. For this reason, no voltage is applied to the terminals 12h and 12i. Accordingly, the main contact 12a shown in FIG. 3 is kept on. In this way, the interconnection is maintained even if a momentary power failure occurs.

  Next, the case of power failure and power recovery will be described. FIG. 9 is a flowchart showing processing of the control device 10 at the time of power failure and power recovery.

  As shown in FIG. 9, the power failure detection unit 43 in FIG. 6 determines whether a power failure in the power system 1 has been detected (step S9). At the time of a power failure, the control power sources S and R shown in FIG. 4 are turned off to demagnetize the coil 27c, the contact 27a shown in FIG. 5 is turned off, and the coil 39c is demagnetized. As a result, the contact 39a is turned off. That is, if the contact point 39a is on, it is determined that there is no power failure (No), and step S9 is repeated. If the contact point 39a is off, the power failure detection unit 43 detects a power failure (Yes), and the communication unit 45 notifies the external device 61 that the power system 1 has failed (step S10).

  After step S10, the power recovery detection unit 44 determines whether power recovery of the power system 1 has been detected (step S11). If the contact point 39a is off, the power recovery detection unit 44 determines that the power system 1 has not recovered power (No), and step S11 is repeated. If the contact point 39a is on, the power recovery detection unit 44 determines that the power system 1 has recovered power (Yes), and the communication unit 45 notifies the external device 61 that power has been recovered (step S12). .

  After step S12, the interconnection control unit 46 determines whether there is an instruction from the external device 61 to link the power system 1 and the photovoltaic power generation facility 7 (step S13). If the determination is No, step S13 is repeated. After obtaining permission for interconnection from the power company, the user issues an interconnection instruction to the control device 10 using the external device 61. The instruction is transmitted by e-mail or an operation in the application, for example. When the communication unit 45 receives the connection instruction, the determination is Yes, and the connection control unit 46 performs the connection (step S14). In step S14, the same process as step S2 of FIG. 7A is performed.

  After step S14, the power generation detection unit 47 determines whether power generation by the solar power generation facility 7 is being performed (step S15). In step S15, the same process as step S3 is performed. If no, step S15 is repeated. In the case of Yes, the communication unit 45 notifies the external device 61 that power is being generated (step S16). After step S16, the process ends.

  FIG. 10A and FIG. 10B are time charts corresponding to FIG. FIG. 10A shows the case of a power failure, and shows on / off of the control power supplies R and S, the contact 27a, the contact 27b, and the main contact 12a in order from the top. At time T5, the control power supply is turned off. In response to the time T5 to T6 being 2 seconds or more, the contact 27b is turned on and the contact 27a and the main contact 12a are turned off at the time T6 (Yes in step S9 in FIG. 9).

  FIG. 10B shows the case of power recovery, and shows on / off of the control power supply, the contact 29a, the contact 25a, and the main contact 12a in order from the top. At time T7, the control power supply is turned on (Yes in step S11 in FIG. 9). At this time, the power supply of the power conditioner 7b shown in FIG. 1 is also turned on. At time T8, a connection instruction is issued from the external device 61. At this time, the contacts 29a and 25a are turned on, and the main contact 12a is turned on (step S14 in FIG. 9).

  As described above, according to the present embodiment, a user who has received permission for interconnection from an electric power company remotely operates the control device 10 using the external device 61. When there is a connection instruction from the user, the connection control unit 46 of the control device 10 performs connection (step S14). Therefore, the user does not have to move to the power conditioner 7b, and the interconnection can be easily performed. Even when a plurality of photovoltaic power generation facilities 7 are provided as shown in FIG. 1, the user does not have to move to each facility. For example, even if the power conditioner 7b is provided in a place where movement is difficult, the user does not have to move. Therefore, labor and time for interconnection are greatly reduced.

  When the power generation detection unit 47 detects that power generation by the solar power generation facility 7 is being performed, the communication unit 45 notifies the user that power generation is being performed. Thereby, the user can confirm whether the interconnection has been performed. If power generation is not performed despite the transmission of the interconnection instruction, the control device 10 and the solar power generation facility 7 may be out of order. That is, in response to the absence of notification, the user can perform inspection and repair at an early stage.

  Since the power failure detection unit 43 detects the power failure and the communication unit 45 notifies the user, the user can quickly know the power failure. That is, the user can know that the interconnection has been canceled. When a user who knows that there is a power outage transmits a connection instruction, electric power is purchased by an electric power company. This reduces the user's economic loss.

  As shown in FIG. 8B, even if the power of the power system 1 is lost for a time shorter than a predetermined time (for example, 2 seconds), the power failure detection unit 43 does not detect a power failure. Thereby, even if a momentary power failure occurs, the interconnection is maintained. That is, since it is not necessary to perform the interconnection work after the momentary power failure, the user's labor is reduced. Moreover, as shown to Fig.10 (a), if the electric power of the electric power grid | system 1 is lost for the time longer than predetermined time, the power failure detection part 43 will detect a power failure. By changing the set time of the relay 27, the time during which the interconnection can be maintained can be changed. What is necessary is just to make the time (discrimination time) which distinguishes the instantaneous stop and power failure in an electric power company, and the setting time of the relay 27 the same. Thereby, operation | movement of the electric power grid | system 1 and operation | movement of the solar power generation system 100 respond | correspond, and a user's labor is reduced.

  A case where the power company distinction time is longer than the set time of the relay 27 will be described. When the power loss time is 3 to 4 seconds, such as 3 to 4 seconds longer than the set time of the relay 27 (for example, 2 seconds), the power company determines that the power failure has occurred, and the power company Do not contact. However, the control apparatus 10 performs the operation | movement at the time of a power failure as shown in FIG.9 and FIG.10 (a), and interrupts | blocks interconnection. At this time, a state in which no power generation is performed without the user knowing the power failure may continue for a long period of time such as several days. Since power is not purchased by the power company, the user incurs an economic loss. According to this embodiment, since the power failure detection unit 43 detects a power failure and the communication unit 45 notifies the user, the user can know that the grid connection has been canceled without a power failure notification from the power company. it can. The user confirms whether or not a power failure has occurred in the power company, and instructs the control device 10 to perform interconnection, thereby establishing interconnection. As a result, power can be generated quickly even after a momentary power failure, and economic loss is reduced.

  When the power recovery detection unit 44 detects power recovery, the communication unit 45 notifies the user. As a result, the user can know the power recovery, and after the power recovery, the user can contact the electric power company and confirm whether the connection is possible. Prompt interconnection will reduce economic losses.

  In addition, an instruction to release the connection can be transmitted from the external device 61 to the control device 10, and the connection control unit 46 releases the connection in response to the instruction. Thereby, for example, when the connection is mistaken or when the photovoltaic power generation facility 7 is inspected, the connection can be easily released.

  If the power system 1 is maintained even after a power failure, the power system 1 will be connected without permission from the power company when power is restored. Therefore, when the electric power system 1 fails, it is preferable to cancel the interconnection by turning off the power supply of the remote operation unit 40. By transmitting a power off instruction from the external device 61 to the remote operation unit 40, the control unit 41 turns off the power of the remote operation unit 40. Because the power is off, after power is restored, no connection is made until a connection instruction is transmitted from the external device 61.

  In addition, the power of the remote operation unit 40 can be turned on by transmitting a power-on instruction from the external device 61 to the remote operation unit 40. The power recovery detection unit 44 can detect power recovery by turning the power on again after the power of the remote control unit 40 is turned off. The user can send an instruction to turn on / off the remote control unit 40 by operating the external device 61. Further, when there is a power failure notification (step S10 in FIG. 9) to the external device 61, a power-off instruction is automatically transmitted, and when there is a power recovery notification (step S12 in FIG. 9), the power is turned on. It may be set so that an ON instruction is automatically transmitted.

  Note that the circuit 38 shown in FIG. 5 can be used to turn on / off the power source of the remote control unit 40. In order to operate the circuit 38, the switch 38a is turned on. When a power failure occurs, the contact 27a is turned off, the coil 39c is demagnetized, and the contact 39b is turned on. The coil 33c is excited and the contact 33a is turned on. The coil 32c is excited, the contact 32a is turned on, and the contacts 32b1 and 32b2 are turned off. When the contacts 32b1 and 32b2 are turned off, the supply of the power supply voltage to the remote operation unit 40 is stopped, and the power supply of the remote operation unit 40 is turned off. For example, a holding time of about 2 to 5 seconds may be set in the relay 33 so that the power is not turned off in the case of a momentary power failure. Thus, the contact 33a remains on for 5 seconds after the contact 27a is turned off, and the power source of the remote control unit 40 remains on.

  The relay 34 is a timer, and can be set so that the contact 34b is turned off, for example, several minutes after the power source of the remote control unit 40 is turned off. When the contact 34b is turned off, the coil 32c is demagnetized and the contacts 32b1 and 32b2 are turned on. Thereby, supply to the power supply voltage to the remote operation unit 40 is resumed, and the power supply of the remote operation unit 40 is turned on. Since the power source of the remote control unit 40 is on, power recovery can be detected.

  The relay 28 has a timer function, and turns on the contact 28d shown in FIG. 5 at, for example, 0:00 and off at 0:01. When the contact 28d is turned on, the coil 31c is excited and the contact 31b is turned off. Thereby, the DC voltage to the remote operation unit 40 is stopped, and the remote operation unit 40 is refreshed. By refreshing once a day, the operation of the remote control unit 40 can be stabilized.

  In FIG. 1, the photovoltaic power generation equipment 7 has an output of 10 kW and is five, but the number and scale of the photovoltaic power generation equipment 7 may be changed according to the scale of the user's facility. For example, one solar power generation facility 7 may be installed in a house. A large-scale facility such as a factory can be provided with a plurality of solar power generation facilities 7 such as 10 or more. As described above, since the user can be linked using the external device 61, even if a plurality of solar power generation facilities 7 are provided, the labor is reduced.

  In addition, you may install the control apparatus 10 in places other than between the switch 5 and the current collection board 6. FIG. For example, the control device 10 may be installed in place of the switch 5, or may be installed in place of the switch 6 a of the current collector panel 6. It is possible to collectively control the interconnection between the plurality of photovoltaic power generation facilities 7 and the power system 1. Further, one control device 10 may be provided instead of each of the plurality of switches 6 b of the current collector panel 6. One control device 10 may be provided for each of the power lines 4 a on the secondary side of the current collector 6. By providing the control device 10 for each power line 4a, interconnection control is possible for each photovoltaic power generation facility 7.

  Although the embodiments of the present invention have been described in detail above, the present invention is not limited to such specific embodiments, and various modifications and changes can be made within the scope of the gist of the present invention described in the claims. It can be changed.

DESCRIPTION OF SYMBOLS 1 Electric power system 7 Solar power generation equipment 10 Control apparatus 40 Remote operation part 41 Control part 43 Power failure detection part 44 Power recovery detection part 45 Communication part 46 Interconnection control part 47 Power generation detection part 61 External equipment

Claims (6)

Provided between the power system and a plurality of photovoltaic power generation facilities that transmit the generated power to the power system ,
A power recovery detector for detecting power recovery of the power system;
The have lines communicating with an external device that the user has the photovoltaic facility, when the power recovery detection unit detects the power recovery, and a communication unit that notifies the power recovery to the external device,
When the power system is restored from a power failure and the communication unit receives a connection instruction from the external device, a connection control unit that performs connection between the solar power generation facility and the power system, A photovoltaic power generation control device comprising: A power generation detection unit that detects that power generation by the solar power generation facility is performed,
The photovoltaic power generation control device according to claim 1, wherein when the power generation detection unit detects the power generation, the communication unit notifies the external device that the power generation is being performed. A power failure detection unit for detecting a power failure of the power system,
The photovoltaic power generation control device according to claim 1 or 2, wherein when the power failure detection unit detects the power failure, the communication unit notifies the external device of the power failure. When power of the power system is lost for a time shorter than a predetermined time, the power failure detection unit does not detect a power failure of the power system,
The photovoltaic power generation control device according to claim 3, wherein the power failure detection unit detects a power failure of the power system when the power of the power system is lost for a longer time than a predetermined time. A plurality of photovoltaic power generation facilities that transmit the generated power to the power system, and a control device provided between the power system and the plurality of solar power generation facilities,
The control device includes:
A power recovery detector for detecting power recovery of the power system;
The have lines communicating with an external device that the user has the photovoltaic facility, when the power recovery detection unit detects the power recovery, and a communication unit that notifies the power recovery to the external device,
When the power system recovers from a power failure and the communication unit receives a connection instruction from the external device, the solar power generation facility and a connection control unit that connects the power system, A photovoltaic power generation system comprising: A step of notifying the external device of the power recovery after the power system recovers from the power failure ;
From the external device, receiving an indication of interconnection between the plurality of photovoltaic power generation facilities and the power system for transmitting electric power generated in the power system,
Linking the power system and the photovoltaic power generation facility in response to the instruction ,
A method of controlling a solar power generation system, wherein a user of the solar power generation facility has the external device .

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