JP2017212787A - Control device for DC power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To utilize the surplus power of a photovoltaic power generation device to the maximum, and to maintain the SOC of a storage battery at a high state in preparation for blackout caused by a disaster.SOLUTION: A control device 52 includes: a parameter determination unit 533 which, based on weather forecast information, determines the SOC of a storage battery 40 at the time when the surplus power of a photovoltaic power generation device 30 is started to occur in a target day; and a mode shift unit 535 which executes a discharge mode to control the discharge of the storage battery 40 in a manner to come to the determined SOC. The parameter determination unit 533 determines the SOC of the storage battery 40 at the time when the surplus power is started to occur, in order to obtain a full charge state of the storage battery 40 by the charge of maximum surplus electric energy, which is estimated to occur in the target day on the basis of the weather forecast information.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a control device for a DC power supply system, and more specifically to a control device for a DC power supply system including a solar power generation device and a storage battery.

  In recent years, the use of natural energy such as solar power generation has attracted attention, and solar power generation devices are often installed in facilities and houses. At present, most of the DC power generated by the solar power generation apparatus is converted into AC power by a power conditioner. By the way, some loads such as communication devices use DC power as input power. In the event of a power outage due to a disaster or the like, it is desirable to supply the DC power generated by the solar power generation device to the communication device, but it is assumed that the power generated by the solar power generation device is converted to alternating current as described above. The DC power cannot be supplied to the communication device. From the viewpoint of securing an emergency power supply (backup power supply) in the event of a disaster, a direct current that employs a configuration that can supply direct current power generated by solar power generation equipment to a communication device so that direct current power can be supplied to the communication device even during a power outage Power systems are getting attention.

  An outline of a conventional DC power supply system for a radio base station will be described with reference to FIG. FIG. 1 is a block diagram showing an outline of a conventional DC power supply system. As shown in FIG. 1, a conventional DC power supply system 1 includes a rectifier 5 that converts AC power from a commercial power supply 6 into DC power, a solar power generation device 3, a storage battery 4, a rectifier 5, and a solar power generation device. 3 and a communication device (load) 2 to which DC power is supplied from the storage battery 4. The solar power generation device 3 is directly connected to a 48V bus (a line having the same potential as the node N), and the generated power of the solar power generation device 3 is preferentially supplied to the communication load 2 (arrow AR2). In the DC power supply system 1, it is desirable that the generated power of the solar power generation device 3 can be used with priority over the output power of the rectifier 2 (the flow of power as indicated by the arrow AR2 is preferable to the arrow AR1). By setting the output voltage of the solar power generation device 3 to be equal to or higher than the output voltage of the rectifier 5 within a range satisfying the input voltage range of the communication device 2, the generated power of the solar power generation device 3 is preferentially supplied to the communication device 2. Yes (arrow AR2).

  In the event of a power failure due to a disaster, AC power from the commercial power supply 6 cannot be used, but according to the DC power supply system 1 in FIG. 1, DC power can be supplied from the solar power generation device 3 and the storage battery 4 to the communication device 2. (Arrows AR2, AR3). That is, the solar power generation device 3 and the storage battery 4 function as an emergency power source (backup power source) for supplying power to the communication device 2 at the time of a disaster (at the time of a power failure).

JP 2014-42417 A

  When a power conditioner is used for a solar power generation device, it can be effectively utilized by, for example, reverse power flow to the system when the generated power exceeds the load on the facility. However, in the DC power supply system (DC supply system) as described above, when the generated power of the photovoltaic power generation device exceeds the power consumption of the load of the facility, the surplus power is released as heat, so it can be used effectively. Can not. As a means to solve this, in order to utilize the surplus power of the photovoltaic power generation device by charging and discharging the storage battery, the remaining battery level for the conventional emergency power supply remains (the remaining battery level for the conventional emergency power supply) In addition to the above, there is a method of increasing the capacity of the storage battery by the amount of surplus power charge, but there is an increase in cost, installation space, etc., and therefore the capacity of the storage battery is limited. Even if the capacity of the storage battery is increased, if almost no surplus power is generated, such as on a rainy day, the capacity of the increased storage battery cannot be filled (charged) with surplus power and cannot be used effectively. From this point, it can be said that the capacity of the storage battery is limited. However, at present, there are not so many methods for making maximum use of generated power when the capacity of a storage battery is limited. Furthermore, in order to enable long-time power supply to a load such as a communication device when a power failure occurs due to a disaster, it is necessary to make the remaining capacity (SOC: State Of Charge) of the storage battery as high as possible in preparation for a disaster. desirable.

  This invention is made | formed in view of the said subject, and while using the surplus electric power of a solar power generation device to the maximum with the limited storage battery capacity, it keeps SOC of a storage battery high in preparation for the power failure by a disaster. It is an object to provide a control device for a DC power supply system that can perform the above-described operation.

  A control device according to an aspect of the present invention is a control device provided in a DC power supply system that includes a photovoltaic power generation device and a storage battery and supplies DC power to a load, and based on weather forecast information, The determining means for determining the SOC of the storage battery at the time when generation of surplus power that is not consumed by the load of the generated power of the photovoltaic power generation apparatus starts, and the determining means at the time when the SOC of the storage battery starts generating surplus power An execution means for executing a discharge mode for controlling the discharge of the storage battery so as to achieve the determined SOC, and the determination means is the largest surplus that is predicted to occur on the target day based on the weather forecast information The SOC of the storage battery at the time when the generation of surplus power starts is determined so that the storage battery is fully charged by charging the electric energy.

  According to the control device of the DC power supply system described above, the SOC of the storage battery at the time when the generation of surplus power starts is determined on the target date, and the SOC of the storage battery is set to the determined SOC at that time. Discharge is controlled (discharge mode is executed). Here, the SOC of the storage battery at the time when the generation of surplus power starts is charged by charging the maximum surplus power amount that is predicted to be generated on the target day based on the weather forecast information. As determined. Therefore, it is possible to charge all surplus power generated on the target day by the storage battery after discharging while keeping the discharge of the storage battery in the discharge mode to a minimum (while keeping the SOC high). In particular, since the SOC of the storage battery at the time when generation of surplus power starts is determined based on weather forecast information, discharge control of the storage battery according to the weather becomes possible. For example, when the weather on the target day is predicted to be cloudy or rainy, the surplus power becomes smaller than that on a clear day, and accordingly, the discharge amount of the storage battery in the discharge mode is reduced and the storage battery SOC is increased accordingly. All the surplus power can be charged into the storage battery while maintaining the state. Therefore, it is possible to make maximum use of surplus power of the solar power generation device with a limited storage battery capacity and to keep the SOC of the storage battery at a high level in preparation for a power failure due to a disaster.

  The execution means may control the charging / discharging of the storage battery so as to interrupt the execution of the discharge mode and maintain the SOC of the storage battery at a maximum when there is a possibility of a disaster based on the weather forecast information. Thereby, when a disaster occurs, the time of the electric power supply to load can be lengthened by using the fully charged storage battery as an emergency power source.

  The execution means calculates the discharge time required until the SOC of the storage battery reaches the SOC determined by the determination means, and discharges the storage battery from the time when the generation of surplus power starts until the calculated discharge time is reached. You may start. Thereby, the time before the storage battery starts discharging, that is, the time when the SOC of the storage battery is high can be made as long as possible.

  The execution means may discharge the storage battery until the SOC of the storage battery reaches a predetermined SOC after the surplus power is not generated on the target date. Thereby, the surplus electric power charged in the storage battery can be effectively used while preventing the SOC of the storage battery from falling below a predetermined SOC.

  The determination means is the same as the maximum surplus power amount of each surplus power amount generated on the day before the target date that was the weather indicated in the weather forecast information and during the predetermined period. You may determine SOC of a storage battery in the time which generation | occurrence | production of surplus electric power starts so that a storage battery may be in a full charge state by charging the electric energy of magnitude | size. Thereby, the SOC of the storage battery at the time when the generation of surplus power starts can be determined with reference to the surplus power amount generated in the past which was the weather indicated by the weather forecast information.

  The determination means estimates the surplus power generated on the target date from the weather forecast information, and generates surplus power so that the storage battery is fully charged by charging the power corresponding to the estimated surplus power. May determine the SOC of the storage battery at the time of starting. Thereby, the SOC of the storage battery at the time when the generation of surplus power starts can be determined with reference to the surplus power amount estimated from the weather information.

  ADVANTAGE OF THE INVENTION According to this invention, while using the surplus electric power of a solar power generation device with the limited storage battery capacity to the maximum, it becomes possible to keep SOC of a storage battery in a high state in preparation for the time of a power failure by a disaster.

It is a figure which shows schematic structure of the conventional DC power supply system. It is a figure showing a schematic structure of a direct-current power supply system provided with a control device concerning an embodiment. It is a figure which shows the hardware constitutions of a control part. It is a figure which shows notionally the example of charging / discharging control of a storage battery. It is a figure which shows an example of the detailed structure of a control part. It is a flowchart which shows an example of operation | movement of a DC power supply system. It is a figure which shows another example of the detailed structure of a control part. It is a flowchart which shows another example of operation | movement of a DC power supply system.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant descriptions are omitted.

[Basic configuration of DC power supply system]
FIG. 2 is a diagram illustrating a schematic configuration of a DC power supply system in which the control device according to the embodiment is provided. The DC power supply system 10 is configured to be able to use power (external power) from the commercial power supply 6. DC power supply system 10 includes a communication device 20, a solar power generation device 30, a storage battery 40, and a rectifier 50. The control device according to the present embodiment is realized as a control device 52 included in a rectifier 50 described later.

  The communication device 20 is a load that operates by receiving power, and includes a radio base station. This load differs from a load such as a general home or office, in particular, in that DC power is consumed and in that the fluctuation of power consumption is small and can be regarded as almost constant.

  The solar power generation device 30 is a power generation device that receives direct sunlight and generates DC power having a magnitude corresponding to the amount of solar radiation, and includes a solar panel and the like. In the DC power supply system 10, the solar power generation device 30 generates power to be supplied to the communication device 20. The output voltage of the solar power generation device (solar power generation device output voltage Vpv) is set to a constant voltage (for example, 55 V).

  In the DC power supply system 10, the storage battery 40 charges power (surplus power) that is not consumed by the communication device 20 among the power generated by the solar power generation device 30. The storage battery 40 supplies power to the communication device 20 by discharging.

  When a power outage occurs due to a disaster and the power from the commercial power source 6 becomes unavailable, DC power can be supplied to the communication device 20 by using the solar power generation device 30 and the storage battery 40 as backup power sources.

  The power line PL is a bus line that electrically connects the communication device 20, the solar power generation device 30, the storage battery 40, and the rectifier 50. The voltage of the bus line (bus voltage) is controlled to be a voltage (for example, 48 V) that does not exceed the rated voltage (for example, 57 V) of the communication device 20. Power line PL includes a power line PL1 and a power line PL2. The power line PL1 is a part that connects the communication device 20 and the solar power generation device 30 to a terminal TERM2 of the rectifier 50 described later. The power line PL2 is a part that connects the storage battery 40 and a terminal TERM3 of a rectifier 50 described later. Note that the connection point of the terminal TERM2, the communication device 20, and the solar power generation device 30 is conceptually illustrated as a node N1.

  The rectifier 50 is a power conversion device that converts AC power into DC power and outputs it. In the DC power supply system 10, the rectifier 50 is electrically connected to the communication device 20 and the storage battery 40, converts AC power from the commercial power supply 6 (external power supply) into DC power, and moves toward the communication device 20 and the storage battery 40. Output. The rectifier 50 includes terminals TERM1 to TERM3, a rectifier 51, a control device 52, current sensors 56a and 56b, a voltage sensor 57a, and a relay RL.

  The terminal TERM1 is an input terminal to which AC power is input, and is connected to the commercial power source 6. The terminal TERM <b> 2 is an input / output terminal that receives DC power or outputs DC power, and is connected to the communication device 20 and the solar power generation device 30. Similarly to the terminal TERM2, the terminal TERM3 is an input / output terminal and is connected to the storage battery 40. Thereby, the communication apparatus 20, the solar power generation device 30, and the storage battery 40 are electrically connected via the power line PL, the terminals TERM2, T3, and the relay RL. Note that the relay RL is in an open state (non-conductive state) in order to prevent overcharge of the storage battery 40, and is normally in a closed state (conductive state).

  The rectifying unit 51 converts AC power input to the terminal TERM1 into DC power. The rectifier 51 is configured by combining a rectifier circuit and a voltage conversion circuit (booster circuit or step-down circuit). The voltage of the DC power output from the rectifier 51 is the output voltage of the rectifier 50 (rectifier output voltage Vrc), and can be adjusted by controlling the circuit that constitutes the rectifier 51.

  The control device 52 controls the DC power supply system 10 by controlling elements included in the rectifier 50, in particular, the rectifying unit 51. The control device 52 controls the rectifying unit 51 using a control signal sent from the control device 52 to the rectifying unit 51 or a communication signal transmitted and received between the control device 52 and the rectifying unit 51. The control device 52 includes a control unit 53, a current detection unit 56, a voltage detection unit 57, and an acquisition unit 58.

The control unit 53 is a part that performs overall control of the control device 52. In particular, the control unit 53 controls charging and discharging of the storage battery 40. The storage battery 40 is charged and discharged by controlling the rectifier 51 and adjusting the rectifier output voltage Vrc. In order to discharge the storage battery 40, the rectifier output voltage Vrc is adjusted to a voltage (V _D ) sufficiently lower than the storage battery voltage Vbat. In order to charge the storage battery 40, the rectifier output voltage Vrc is adjusted to a voltage (V _U ) sufficiently higher than the storage battery voltage Vbat. When surplus power is generated, the rectifier output voltage Vrc may be equal to or lower than the storage battery voltage Vbat. Further, in order not to charge or discharge the storage battery 40 (make the storage battery 40 stand by), the rectifier output voltage Vrc is adjusted to be equal to the storage battery voltage Vbat. In addition, in order to forcibly stop charging and discharging of the storage battery 40, the above-described control for opening the relay RL may be performed. The open state and the closed state of relay RL are switched by a control signal from control unit 53.

  Here, the hardware configuration of the control unit 53 will be described with reference to FIG. As shown in FIG. 3, the control unit 53 physically includes one or more CPUs (Central Processing Units) 61, a RAM (Random Access Memory) 62 and a ROM (Read Only Memory) 63 that are main storage devices. Hardware such as a communication module 66 that is a data transmission / reception device, an auxiliary storage device 67 such as a semiconductor memory, an input device 68 that receives user input such as an operation panel (including operation buttons) and a touch panel, and an output device 69 such as a display It is comprised as a computer provided with. The function of the control unit 53 is, for example, by reading one or a plurality of predetermined computer software (programs) on hardware such as the CPU 61 and the RAM 62, thereby controlling the communication module 66, the input device 68, This can be realized by operating the output device 69 and reading and writing data in the RAM 62 and the auxiliary storage device 67. The same applies to the control unit 55 described later.

  Returning to FIG. 2 again, the current detector 56 detects the current flowing between the rectifier 51 and the node N2 using the current sensor 56a. Node N2 is a connection node of rectification unit 51, terminal TERM2, and relay RL (terminal TERM3 when relay RL is closed). The current detection unit 56 detects a current flowing between the node N2 and the terminal TERM2 using the current sensor 56b. From the difference between the current detected by the current sensor 56a and the current detected by the current sensor 56b, the current detection unit 56 can also detect the charge / discharge current of the storage battery 40.

  The voltage detection unit 57 detects the voltage between the rectification unit 51 and the terminal TERM2 using the voltage sensor 57a. This voltage is the voltage of the power line PL (bus voltage) and also the voltage of the storage battery 40. If the charge / discharge current and voltage of the storage battery 40 are detected by the current detection unit 56 and the voltage detection unit 57, the charge / discharge power of the storage battery 40 can be known, so the SOC of the storage battery 40 can also be detected.

  In a system such as the DC power supply system 10 described above, the capacity of the storage battery 40 is limited. Therefore, it is desirable to perform charge / discharge control of the storage battery 40 so as to make maximum use of the generated power of the solar power generation device 30 under such restrictions. In addition, when a power failure occurs due to a disaster, it is possible to supply power to the communication device 20 for a long time (so that a communication service can be continued for a certain period of time in an emergency), so that it can be used as an emergency power source in case of a disaster. Thus, it is desirable to keep the SOC of the storage battery 40 as high as possible.

  Therefore, in the present embodiment, the control device 52 of the solar power generation device 30 that occurs on a certain day (hereinafter referred to as “target day”) based on weather forecast information including weather information and sunshine (sunlight) information. Charging / discharging of the storage battery 40 is controlled so that all the surplus power is charged in the storage battery 40 and the SOC of the storage battery 40 is maintained as high as possible.

  A method for the control device 52 to obtain weather forecast information is not particularly limited. For example, in the DC power supply system 10, the weather information may be received via a network. In the example illustrated in FIG. 2, the control device 52 includes an acquisition unit 58 as a part for acquiring such weather information.

[Overview of charge / discharge control]
FIG. 4 is a diagram conceptually illustrating an example of charge / discharge control of the storage battery 40 executed in the DC power supply system 10 on the target day. The horizontal axis of this graph indicates time, and the vertical axis indicates SOC (%) of the storage battery 40. Here, charging / discharging control of the storage battery 40 is performed according to the result of the weather forecast information for the target day (weather “sunny”, “cloudy”, or “rainy”). Time t1 indicates the time at which surplus power generation starts on the target date. Time t2 indicates the time when the generation of surplus power ends. The period T1 is a period in which surplus power is generated, and is a period from time t1 to t2. The period T2 is a period in which a later-described regression charge or regression discharge (steps S81 to S85 in FIG. 6) is performed, and is a period from time t2 to t3.

  First, based on the weather forecast information, the SOC of the storage battery 40 at the time t1 when generation of surplus power of the solar power generation device 30 starts is determined on the target day. The means for making this determination (determination means) is realized, for example, by a parameter determination unit 533 (FIG. 5) described later. The time t1 at which the generation of surplus power starts is obtained from past performance values and the like. The SOC determined here is an SOC in which the storage battery 40 is fully charged (SOC = 100%) by charging the maximum surplus power amount that is predicted to occur on the target date based on the weather forecast information. . The surplus power amount is the amount of surplus power generated in the period T1 during which surplus power is generated. The amount of surplus power varies depending on the weather. Since the maximum surplus power amount that is expected to occur on a rainy day is relatively small, the determined SOC is a relatively large value (shown as “SOC rain”). Since the maximum amount of surplus power that is expected to occur on a clear day is relatively large, the determined SOC is a relatively small value (shown as “SOC clear”). For cloudy days, the value is between them (shown as “SOC cloudy”).

  And the discharge mode which controls discharge of the storage battery 40 is performed so that SOC of the storage battery 40 becomes the above-determined SOC at the time t1 when generation of surplus power starts. The means for executing this discharge mode (execution means) is realized, for example, by a mode transition unit 535 (FIG. 5) described later. In the example shown in FIG. 4, since the SOC of the storage battery 40 is originally “SOC rain”, when the SOC of the storage battery 40 is “SOC clear” or “SOC cloudy”, the time t fine before the time t1. Alternatively, the discharge of the storage battery 40 is started at the time t cloudy. The time t fine or the time t cloudy is set to a time that is longer than the time t1 by the time required for discharge (discharge time). The time required for discharge (discharge time) can be determined by utilizing the fact that the power consumption of the communication device 20 is approximately constant. For example, the discharge time can be calculated by dividing the discharge power amount of the storage battery 40 by the discharge power of the storage battery 40 (that is, the power consumption of the communication device 20).

  Thus, on the target date, the SOC of the storage battery 40 at the time t1 when the generation of surplus power starts is determined, and the discharge of the storage battery 40 is controlled so that the SOC of the storage battery 40 becomes the determined SOC at that time. (Discharge mode is executed). The SOC of the storage battery 40 at the time t1 is set so that the storage battery 40 is fully charged by charging the maximum surplus power amount that is predicted to occur on the target date (in the period T1) based on the weather forecast information. ,It is determined. Therefore, all the surplus electric power generated on the target day can be charged by the storage battery 40 after the discharge while keeping the discharge of the storage battery 40 in the discharge mode to a minimum (while keeping the SOC high). In particular, since the SOC of the storage battery 40 at the time t1 when generation of surplus power starts is determined based on weather forecast information, the discharge control of the storage battery 40 according to the weather becomes possible. For example, when the weather on the target day is predicted to be cloudy or rainy, the surplus power is smaller than that on a clear day, and accordingly, the discharge amount of the storage battery 40 in the discharge mode is reduced and the SOC of the storage battery 40 is reduced accordingly. All the surplus power can be charged into the storage battery 40 while keeping the battery in a high state. Therefore, the surplus power of the photovoltaic power generator 30 can be utilized to the maximum with a limited storage battery capacity, and the SOC of the storage battery 40 can be kept high in preparation for a power failure due to a disaster. In addition, as described above, the discharge time of the storage battery 40 is calculated, and the discharge of the storage battery 40 is started at the time ("tunny", "t cloudy") obtained by the calculated discharge time from the time t1, The state before the storage battery 40 starts discharging, that is, the time during which the SOC of the storage battery 40 is high can be made as long as possible.

  Furthermore, in this embodiment, when there is a possibility of a disaster based on weather forecast information, the execution of the above-described discharge mode is interrupted. And charging / discharging of the storage battery 40 is controlled so that SOC of the storage battery 40 is maintained to the maximum (so that SOC is maintained at 100%). Thereby, when a disaster occurs, the time for supplying power to the communication device 20 can be extended by using the fully charged storage battery 40 as an emergency power source.

  Further, as shown in FIG. 4, the discharge of the storage battery 40 is controlled until the SOC of the storage battery 40 reaches a predetermined SOC after the time t <b> 2 when the surplus power is not generated on the target date. In this example, the predetermined SOC is the same as the SOC rain. Further, at time t3, the SOC of the storage battery 40 becomes a predetermined SOC. In this way, the surplus power charged in the storage battery 40 can be discharged (that is, supplied to the communication device 20) so that the SOC of the storage battery 40 does not fall below a predetermined SOC, so that the surplus power can be effectively utilized. .

  In order to determine the SOC of the storage battery 40 at the time t1, several methods are conceivable as to how to estimate the amount of surplus power generated on the target day.

  The first method refers to the surplus power generated on the target day with reference to the surplus power generated on the past day (the day before the target day) that was the same weather as the target day indicated in the weather forecast information. This is a method of estimating the amount of electric power. The weather on the target day indicated in the weather forecast information here means the type of weather such as sunny, cloudy, and rainy. The surplus power amount used as a reference is each surplus power amount generated during a predetermined period (for example, one month) on the day before the target date. For example, the maximum surplus power amount of each surplus power amount is estimated as the surplus power amount generated on the target day. The SOC of the storage battery 40 at the time t1 is determined so that the storage battery 40 is fully charged by charging the same amount of power as the estimated surplus power.

  The second method is a method of estimating the amount of surplus power generated on the target day from the weather forecast information. The weather forecast information here includes sunshine (sunlight) information, temperature information, and the like. The generated power of the solar power generation device 30 can be predicted from such weather forecast information, and the surplus power amount of the solar power generation device 30 can be estimated (calculated) from the difference from the power consumption of the communication device 20. The SOC of the storage battery 40 at time t1 is determined so that the storage battery 40 is fully charged by charging the same amount of power as the surplus power estimated in this way. In addition, when estimating surplus power from weather forecast information such as solar radiation information and temperature information in this way, it is possible to estimate surplus power with higher accuracy than when estimating surplus power from the type of weather. it can. For example, as described above, when the surplus power amount is estimated from the weather type, three different surplus power amounts are estimated according to three weather types such as sunny, cloudy, and rainy. On the other hand, if the surplus power amount is estimated from weather forecast information such as solar radiation information and temperature information, it is possible to estimate more than three (for example, 10 or more) different surplus power amounts.

Control of charging / discharging of the storage battery 40 in the DC power supply system 10 as described above is realized by the control unit 53. Hereinafter, more specific functional blocks and control contents of the control unit 53 will be described with reference to FIGS. 5 and 6. In the examples of FIGS. 5 and 6, the surplus power amount is estimated by the first method described above.
Each function of the control unit 53 is realized by using the hardware configuration of FIG. 3 described above.

  FIG. 5 is a diagram illustrating an example of a detailed configuration of the control unit 53. FIG. 6 is a flowchart showing an example of the operation of the DC power supply system 10 under the control of the control unit 53 shown in FIG.

  In step S1, SOC rain is input. This process is executed by the data input unit 531. In this example, the data input unit 531 accepts SOC rain as the SOC of the storage battery 40 at time t3 described above with reference to FIG. For example, a user (administrator) of the DC power supply system 10 inputs data to the data input unit 531.

  In step S2, the shortest surplus power generation start time t1 and the maximum surplus charge amount P in the past month are confirmed and set as the surplus power amount generated on the above-described time t1 (FIG. 4) and the target date. This process is performed using the data storage unit 532. In this example, information on the past shortest surplus power generation start time and maximum surplus charge amount in the DC power supply system 10 is stored in the data storage unit 532, and information of the past one month is extracted and confirmed. Is done.

  In steps S31 to S33, the SOC value corresponding to the type of weather and the time corresponding to the SOC value are determined. This process is executed by the parameter determination unit 533. In this example, since the SOC rain is determined in the previous step S1, the parameter determination unit 533 determines (calculates) the SOC clear and the SOC cloud. In step S31, the SOC clear is determined as SOC clear = 100−P / FCC. P is the maximum surplus charge amount P described above. FCC is the full charge capacity of the storage battery 40. In step S32, the SOC cloud is determined as SOC cloud = (SOC rain + SOC clear) / 2. In step S33, the time t fine (or t cloudy) is determined as t fine (cloudy) = T− (FCC × (SOC rain−SOC fine (cloudy)) / Q). Q is the power consumption (load power) of the communication device 20.

  In step S4, a mode determination process is performed. This process is executed by the mode determination unit 534. In this example, the mode in which the storage battery 40 is discharged so that the SOC of the storage battery 40 at time t1 becomes SOC clear (first mode), and the mode in which the storage battery 40 is discharged so that the SOC becomes cloudy (second mode). And the mode determination part 534 determines which mode of the mode (3rd mode) which discharges the storage battery 40 so that it may become SOC rain should be performed. This determination is made based on weather forecast information. For example, if the weather on the target day indicated by the weather forecast information is sunny, it is determined that the first mode should be executed. The weather forecast information may be acquired in step S4, or may be acquired in a stage prior to step S4. The weather forecast information is input and acquired, for example, in the data input unit 531.

  Furthermore, in step S4, it is also determined whether or not there is a possibility of a disaster occurring on the target day. This process is also executed by the mode determination unit 534. For example, when the weather forecast information includes information indicating the possibility of a disaster occurring, it is determined from the information that there is a possibility that a disaster will occur on the target day. Further, if a thunderstorm or heavy rain is predicted by the weather forecast information, it is determined that there is a possibility that a disaster will occur.

  In steps S51 to S55, the process is shifted to each mode so that the mode determined in step S4 described above is executed. This transition process is executed by the mode transition unit 535. In the first mode (illustrated as “sunny” in FIG. 6), the process waits until the time t becomes t clear (step S52: NO), and in the second mode (“cloudy” in FIG. 6). ”Is illustrated) until the time t becomes t cloudy (step S53: NO), and thereafter (step S52: YES, step S53: YES), the discharge of the storage battery 40 is started (step S54). ). The discharge of the storage battery 40 is continued until the time t reaches t1 (step S55: NO), and then the process proceeds to step S71 (step S55: YES). In the case of the third mode (illustrated as “rain” in FIG. 6), in this example, the process proceeds to step S71 without discharging the storage battery 40. These processes are executed by the mode transition unit 535 by acquiring the information on the time t from the time management unit 539 and using the acquired information on the time t.

  On the other hand, if it is determined in step S4 that there is a possibility of a disaster occurring on the target day, the process proceeds to step S61. At this time, the mode transition unit 535 sends FLAG indicating information that a disaster may occur on the target day to the disaster operation unit 536 together with the SOC rain input in the previous step S1.

  In steps S61 to S65, control for maintaining the SOC of the storage battery 40 as high as possible is executed in preparation for a power failure due to a disaster. This process is executed by the disaster operation unit 536. In this example, the storage battery 40 is maintained in a fully charged state by forced charging or the like until a power failure occurs (step S61, step S62: NO). When a power failure occurs (step S62: YES), as described above, the storage battery 40, or the solar power generation device 30 and the storage battery 40 serve as backup power sources, and power is supplied to the communication device 20 until the power failure is recovered. Supply (step S63: NO). With this power supply, the SOC of the storage battery 40 can be reduced. When the power failure is recovered (step S63: YES), the storage battery 40 is charged until the SOC of the storage battery 40 becomes SOC rain (step S64, step S65: NO). Thereafter (step S65: YES), the process proceeds to step S86. These processes are executed by the disaster operation unit 536 by acquiring the SOC information of the storage battery 40 from the battery monitoring unit 540 and using the acquired SOC information.

  In steps S71 to S72, the PV surplus charging process is executed until the evening discharge start time (time t2 in FIG. 4) (step S71, step S72: NO). This process is executed by the PV surplus charging unit 537. The surplus power of the solar power generation device 30 generated in the time zone where surplus power is generated (period T in FIG. 4) is charged in the storage battery 40. When the evening discharge start time is reached (step S72: YES), the process proceeds to step S81. These processes are executed by the PV surplus charging unit 537 by acquiring the information on the time t from the time management unit 539 and using the acquired information on the time t.

  In steps S <b> 81 to S <b> 85, charge / discharge control (return charge or return discharge) of the storage battery 40 is performed so that the SOC of the storage battery 40 approaches SOC rain. This process is executed by the regression processing unit 538. When the SOC of the storage battery 40 is greater than the SOC rain (step S81: YES), the storage battery 40 is discharged until the SOC of the storage battery 40 becomes SOC rain (step S82, step S83: NO), and thereafter (step S83: YES), the process proceeds to step S86. Conversely, when the SOC of the storage battery 40 is less than the SOC rain (step S81: NO), the storage battery 40 is charged until the SOC of the storage battery 40 becomes SOC rain (step S84, step S85: NO), and thereafter (Step S85: YES), the process proceeds to Step S86. In these processes, the regression processing unit 538 acquires the SOC rain input in the previous step S1 (for example, via the mode transition unit 535 and the PV surplus charging unit 537), and the battery monitoring unit 540 The information of the SOC is acquired and executed using each acquired information.

  In step S <b> 86, the process waits for the next target day (the next day after the current target day) until the time at which the above-described flow process is started again. When the time is reached, the process returns to step S1. If there is no change in the input SOC in the process of step S1, the process of step S1 may be skipped.

[Numeric example]
Numerical examples in the processing described with reference to FIGS. 5 and 6 are shown. For example, the remaining battery level to be satisfied by the storage battery 40 as an emergency power supply is 80 Wh, and the full charge capacity of the storage battery 40 is 100 Wh. In addition, the maximum surplus charge amount (maximum surplus power amount) per day for the past month is set to 50 Wh, and the surplus charge amount (surplus power amount) actually generated on the target date is set to 40 Wh. The power consumption of the communication device 20 is 10 W (the power consumption per hour is 10 Wh). The earliest time from the actual surplus power start time (the time when surplus power generation starts) in the past month is 8:00, and the evening discharge start time is 17:00. In this case, the SOC clear is determined as 50%, the SOC fog is 65%, the SOC rain is 80%, the t clear is 5:00, and the t cloud is 6:30. At this time, when clear weather is acquired as the weather forecast information for the next day at 17:00 on the day before the target day, discharging of the storage battery 40 is started at 5:00 on the target day, and the standby state is set from 8:00 to 17:00. In principle, charging / discharging of the storage battery 40 is controlled so that the storage battery 40 charges only the surplus power when surplus power is generated. After that, since the SOC of the storage battery 40 is 90% at 17:00, discharging is performed until the SOC reaches 80%, and the state shifts to a standby state after the SOC reaches 80%.

  In the examples of FIGS. 5 and 6 described above, the surplus power amount is estimated by the first method described above. On the other hand, in the example of FIG. 7 and FIG. 8 to be described next, the surplus power amount is estimated by the second method described above. In this example, the control unit 55 shown in FIG. 7 is used. In the following, only portions of FIGS. 7 and 8 that are different from FIGS. 5 and 6 will be described.

In step S201, SOC ₁ is input. This process is executed by the data input unit 551. This SOC ₁ may be the same value as or different from the above-described SOC rain. In addition, in response to the input of SOC _{1 in} step S201, the reference for the SOC used in the processes of steps S65, S81, S83, and S85 is also set to SOC ₁ .

In steps S231 to S233, the N SOC values corresponding to the surplus power amount estimated from the weather forecast information and the time corresponding to the SOC value are determined. N may be an integer of 10 or greater, for example. This process is executed by the parameter determination unit 553. In this example, parameter determination section 553 _determines the value of N SOC to SOC 1 ～SOC _N respectively. Among these, SOC ₁ is the smallest and SOC _N is the largest. In step S231, SOC _N is determined as SOC _N = 100−P / FCC. In step S232, SOC _k (k is an integer between _{1 and N} ) is determined as SOC _k = SOC ₁ − (SOC ₁ −SOC _N ) × k / N. In step S233, the time t _k is determined as t _k = t 1− (FCC × (SOC ₁ −SOC _k ) / Q).

In step S204, a mode determination process is performed. This processing is executed by the mode determination unit 554. In this example, as the SOC of the battery 40 is SOC _k at time _{t k,} as a mode of discharging the battery 40, k is whether to perform the mode of any value 1 to N, the mode determination unit 554 judge. This determination is made based on the surplus power estimated from the weather forecast information. For example, when the amount of solar radiation in the weather forecast information is the largest, such as a sunny day, it is determined that the mode of k = N should be executed.

In steps S51 to S55, the process is shifted to each mode so that the mode determined in step S4 described above is executed. This transition process is executed by the mode transition unit 555. If k is any one of 2 to N-1, the process until the time t becomes t _k is waiting, then the discharge of the storage battery 40 is started. In the example shown in FIG. 8, the case of k = 2 to (N−1) and k = N is shown. In other words, when k = 2 to (N−1), the process waits until time t reaches t _k (step S252: NO), and when k = N, time t becomes t _N. (Step S253: NO), and thereafter (step S252: YES, step S253: YES), the discharge of the storage battery 40 is started (step S54).

  The other parts in FIGS. 7 and 8 are the same as the corresponding parts in FIGS. 5 and 6, and thus the description thereof is omitted here.

[Numeric example]
Numerical examples in the processing described with reference to FIGS. 7 and 8 are shown. For example, the remaining battery level to be satisfied by the storage battery 40 as an emergency power supply is 80 Wh, and the full charge capacity of the storage battery 40 is 100 Wh. In addition, the surplus charge amount (surplus power amount) on the target date estimated using weather forecast information (prediction information such as solar radiation amount) is 42 Wh, and the surplus charge amount actually generated on the target date is 43 Wh. The power consumption of the communication device 20 is 10 W (the power consumption per hour is 10 Wh). N = 10, and the earliest time from the actual power generation start time (time when surplus power generation starts) in the past month is 8:00, and the evening discharge start time is 17:00. In this case, k = 1 when the surplus charge amount is 0 to 5 Wh, k = 2 when 5 to 10 Wh, k = 3 when 10 to 15 Wh, and k = 4 when 15 to 20 Wh, K = 5 at 20-25 Wh, k = 6 at 25-30 Wh, k = 7 at 30-35 Wh, k = 8 at 35-40 Wh, 40-45 Wh Assuming k = 9 and k = 10 when 45 to 50 Wh and k is obtained from a surplus power amount estimated (calculated) from weather forecast information with a constant range, in this case, k = 9 is obtained (determination) can do. SOC ₁ is determined as 95% so that the maximum surplus power amount (5 Wh) can be charged when k = 1, and SOC ₁₀ is determined as 50% so that the maximum surplus power amount (50 Wh) when k = 10 can be charged. Therefore, SOC9 is obtained as 55%. In addition, _{t 9} is obtained as 3:30. For example, when relatively large solar radiation amount information such as a clear day is acquired as the weather forecast information for the target day at 17:00 on the day before the target day, the storage battery 40 starts to be discharged at 3:30 on the target day. The charging / discharging of the storage battery 40 is controlled so that the storage battery 40 charges only the surplus power when surplus power is generated, as a general rule, from 8:00 to 17:00. After that, since the SOC of the storage battery 40 is 98% at 17:00, discharging is performed until the SOC reaches 95%, and the state shifts to a standby state after the SOC reaches 95%.

  As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said embodiment. When the communication device 20 such as a radio base station is provided with the charge / discharge control device for the storage battery 40, the charge / discharge control of the storage battery 40 by the charge / discharge control device is not performed (adjustment) of the rectifier output voltage Vrc. The storage battery 40 may be charged / discharged / standby. Further, in the above-described embodiment, the control units 53 and 55, the current detection unit 56, and the voltage detection unit 57 are provided inside the control device 52, but these may be installed outside the control device 52. In the above embodiment, the surplus power of the solar power generation device 30 is effectively used in the DC power supply system 10, but the use of this system is not limited to the communication device 20 such as a radio base station. May be.

DESCRIPTION OF SYMBOLS 10 ... DC power supply system, 20 ... Communication apparatus (load), 30 ... Solar power generation device, 40 ... Storage battery, 52 ... Control apparatus, 533, 553 ... Parameter determination part (determination means), 535, 555 ... Mode transition part ( Execution means).

Claims (6)

A control device provided in a DC power supply system that includes a photovoltaic power generation device and a storage battery and supplies DC power to a load,
Determining means for determining the SOC of the storage battery at a time when generation of surplus power that is not consumed by the load of the generated power of the photovoltaic power generation apparatus starts on the target date based on weather forecast information;
Execution means for executing a discharge mode for controlling the discharge of the storage battery so that the SOC of the storage battery becomes the SOC determined by the determination means at the time when generation of the surplus power starts.
With
The determining means starts generating the surplus power so that the storage battery is fully charged by charging a maximum surplus power amount that is predicted to occur on the target date based on the weather forecast information. Determining the SOC of the storage battery at the time to
Control device.   The execution means interrupts the execution of the discharge mode when there is a possibility of occurrence of a disaster based on the weather forecast information, and controls charging / discharging of the storage battery so as to maintain the SOC of the storage battery at a maximum. The control device according to claim 1.   The execution means calculates a discharge time required until the SOC of the storage battery reaches the SOC determined by the determination means, and from a time when generation of the surplus power starts to a time obtained by the calculated discharge time. The control device according to claim 1, wherein discharge of the storage battery is started.   The said execution means discharges the said storage battery until the SOC of the said storage battery becomes predetermined SOC after the said surplus electric power no longer generate | occur | produces on the said target day. The control device described.   The determining means is the maximum surplus power among the surplus power generated on the day before the target date that is the weather indicated in the weather forecast information and during a predetermined period. The SOC of the storage battery at a time when the generation of the surplus power starts is determined so that the storage battery is fully charged by charging the same amount of power as the amount. The control device according to claim 1.   The determining means estimates from the weather forecast information the amount of surplus power generated on the target day, and charges the amount of power corresponding to the estimated surplus power amount so that the storage battery is in a fully charged state. The control apparatus of any one of Claims 1-4 which determines SOC of the said storage battery in the time when generation | occurrence | production of the said surplus electric power starts.

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