JPWO2015059873A1 - Power management equipment - Google Patents

Abstract

An object of the present invention is to suppress sulfation without increasing the size or cost, and to extend the life of a lead-acid battery. The power management device (10) of the present invention includes a charging device (11), a conversion device (12), a monitoring device (13), and a control device (30). The control device (30) acquires the remaining capacity of the lead storage battery (20) from the monitoring device (13), and controls the charging device (11) and the conversion device (12). In the control device (30), the setting unit (34) sets a lower limit value and an upper limit value for the remaining capacity of the lead storage battery (20). A judgment part (35) will instruct | indicate a converter (12) to stop discharge of a lead storage battery (20), when remaining capacity falls to a lower limit. A judgment part (35) permits discharge of a lead storage battery (20), if the remaining capacity rises to the permission value set between the lower limit and the upper limit after stopping discharge of a lead storage battery (20). The conversion device (12) is instructed as follows.

Description

  The present invention relates generally to power management devices, and more particularly to power management devices that charge and discharge lead acid batteries.

  A lead storage battery has a problem that a phenomenon called sulfation occurs when the battery is overdischarged or left in a discharged state, resulting in a short life. The sulfation is a deterioration phenomenon of the lead storage battery caused by adhesion of lead sulfate to the electrode. When the sulfation occurs, the capacity of the lead storage battery decreases.

  Therefore, a technique for suppressing sulfation by applying sound waves to the battery during the period of leaving the lead storage battery has been proposed (see, for example, Japanese Patent Application Publication No. 2002-56897 (hereinafter referred to as “Document 1”)). . In addition, a technique for activating an electrode by flowing a charging current or a discharging current in a pulsed (intermittent) manner (for example, Japanese Patent Application Publication No. 2006-244993 (hereinafter referred to as “Document 2”) has been proposed. reference).

  The technique described in Document 1 requires a device for applying sound waves, and a device unrelated to charging or discharging of the lead storage battery is added. Moreover, when using many lead acid batteries, the apparatus for giving a sound wave may enlarge.

  On the other hand, since the technique described in Document 2 controls a relatively large charging current or a relatively large discharging current to flow in a pulsed manner, a charging circuit or a discharging circuit having a large current capacity corresponding to the large current is necessary. Yes, it can lead to high costs.

  An object of the present invention is to provide a power management apparatus that suppresses sulfation without increasing the size or cost, and extends the life of a lead-acid battery.

  The power management device according to the present invention includes a charging device that charges a lead storage battery, a conversion device that converts DC power output from the lead storage battery into AC power, and supplies the AC power to an electric load, and the lead A monitoring device that monitors a remaining capacity of the storage battery; and a control device that acquires the remaining capacity of the lead storage battery from the monitoring device and controls the charging device and the conversion device, the control device including the lead storage battery A setting unit that sets a lower limit value and an upper limit value for the remaining capacity, and a determination unit that instructs the conversion device to stop discharging the lead storage battery when the remaining capacity decreases to the lower limit value, The determination unit permits discharge of the lead storage battery when the remaining capacity rises to a permission value set between the lower limit value and the upper limit value after stopping the discharge of the lead storage battery. You .

Preferred embodiments of the invention are described in more detail. Other features and advantages of the present invention will be better understood with reference to the following detailed description and accompanying drawings.
It is a block diagram which shows embodiment. 2A and 2B are diagrams illustrating a configuration example for measuring the remaining capacity of the lead storage battery in the embodiment. It is a figure which shows the operation example of embodiment. It is a figure which shows the operation | movement of embodiment with a flowchart. It is a figure which shows operation | movement of embodiment. It is a figure which shows operation | movement of a comparative example.

  As shown in FIG. 1, the power management device 10 includes a charging device 11, a conversion device 12, a monitoring device 13, and a control device 30. The charging device 11 charges the lead storage battery 20, and the conversion device 12 converts the DC power output from the lead storage battery 20 into AC power and supplies the AC power to the electric load 40. The monitoring device 13 monitors the remaining capacity of the lead storage battery 20. The control device 30 acquires the remaining capacity of the lead storage battery 20 from the monitoring device 13 and controls the charging device 11 and the conversion device 12. In addition, the control device 30 includes a setting unit 34 and a determination unit 35. The setting unit 34 sets a lower limit value and an upper limit value for the remaining capacity of the lead storage battery 20. The determination unit 35 instructs the converter 12 to stop discharging the lead storage battery 20 when the remaining capacity decreases to the lower limit value. Furthermore, after stopping the discharge of the lead storage battery 20, the determination unit 35 permits the discharge of the lead storage battery 20 when the remaining capacity rises to a permission value set between the lower limit value and the upper limit value. 12 is instructed.

  According to such a power management device 10, since the discharge of the lead storage battery 20 is suppressed and the battery is charged immediately after the discharge, it is possible to suppress sulfation without increasing the size or cost. There is. As a result, the life of the lead storage battery 20 is extended.

  The power management apparatus 10 preferably further includes a power supply adjustment device 14 that adjusts the supply of AC power to the electric load 40. In this case, it is desirable that the control device 30 instructs the power supply adjustment device 14 so that the AC power supplied to the electric load 40 is adjusted according to the remaining capacity.

  The charging device 11 is desirably used as the power for charging the lead storage battery 20 with the power of the power generation facility 50 that generates power using natural energy. In this case, the control device 30 desirably includes a prediction unit 38 that predicts the amount of power that the power generation facility 50 generates during a predetermined period. The determination unit 35 estimates the amount of power that can be supplied to the electrical load 40 in a predetermined period based on the amount of power predicted by the prediction unit 38 and the remaining capacity of the lead storage battery 20 monitored by the monitoring device 13. Further, the determination unit 35 gives an instruction to the power supply adjustment device 14 based on the amount of power that can be supplied to the electrical load 40.

  It is preferable that the monitoring device 13 estimates the remaining capacity of the lead storage battery 20 using at least one of the battery voltage of the lead storage battery 20 and the internal impedance of the lead storage battery 20. The monitoring device 13 may estimate the remaining capacity of the lead storage battery 20 using at least one of the battery voltage of the lead storage battery 20 and the internal impedance of the lead storage battery 20 and the open voltage of the lead storage battery 20. . In this case, the battery voltage of the lead storage battery 20 is a voltage after a predetermined time has elapsed since the pseudo load 21 (see FIG. 2) having a known resistance value is connected to the lead storage battery 20. The internal impedance is the impedance of the lead storage battery 20 after the predetermined time has elapsed since the pseudo load 21 is connected to the lead storage battery 20. As the open circuit voltage, the voltage of the lead storage battery 20 in a state where the pseudo load 21 is not connected to the lead storage battery 20 is used.

  It is desirable that the monitoring device 13 measures information (value) for estimating the remaining capacity in a time zone in which the power for charging or discharging the lead storage battery 20 is equal to or less than a predetermined reference value.

  Moreover, it is preferable that the power management apparatus 10 is further provided with the temperature control apparatus 15 which maintains the temperature of the lead storage battery 20 in a predetermined allowable range.

  The setting unit 34 estimates the degree of deterioration of the lead storage battery 20 based on the transition of the remaining capacity of the lead storage battery 20 monitored by the monitoring device 13, and sets the upper limit value and the lower limit value based on the degree of deterioration. It is desirable to do.

  The control device 30 preferably includes a notification unit 36 that outputs a notification signal to the notification device 60 when the determination unit 35 stops the discharge of the lead storage battery 20.

  When the remaining capacity of the lead storage battery 20 reaches the upper limit value, the determination unit 35 preferably instructs the power supply adjustment device 14 to allow an increase in power consumed by the electric load 40.

  In addition, the power management apparatus 10 desirably includes a backup power supply 52 that supplies power to the electric load 40 when the conversion apparatus 12 stops.

  Hereinafter, the embodiment will be described in more detail. Here, description will be made assuming a non-electrified area where no distribution network is laid. That is, a configuration example in which power necessary for operation of a plurality of electric loads 40 (two electric loads in the illustrated example) is supplied by combining the power generation facility 50 and the lead storage battery 20 without receiving power from the power system. explain. In addition, although the structural example demonstrated below assumes the scale of several thousand-several tens of thousands kWh, even if it is a case where it is smaller or larger than the scale assumed in embodiment, the technical idea demonstrated below Is applicable.

  The power generation facility 50 generates power using natural energy. In the present embodiment, the solar power generation facility 51 is described as an example of the power generation facility 50, but other power generation facilities 50 such as a wind power generation facility and a hydropower generation facility may be used. In the power generation facility 50 using this kind of natural energy, the output power varies with time. Compared with the solar power generation facility 51 and the wind power generation facility, the hydropower generation facility has a relatively stable output, but the amount of water used for power generation is not constant and varies depending on the weather and the like.

  When the distribution network of the power system is established, it is possible to stabilize the power by using the power generation facility 50 that generates power by natural energy together with the system power source having a stable voltage. In the non-electrified area, the power system cannot be used. For this reason, the power generation facility 50 is used in combination with a storage battery. If the output of the power generation facility 50 is excessive, the storage battery is charged. If the output of the power generation facility 50 is insufficient, the storage battery is discharged. It is considered.

  Currently, nickel hydride storage batteries, lithium ion storage batteries, and lead storage batteries 20 can be listed as candidates for storage batteries that can be used for this type of application. Lithium ion batteries have a high power density, but they are complex and have high material costs and are currently the most expensive. In addition, since the nickel metal hydride storage battery has a memory effect, it is not suitable for applications in which charging and discharging are repeated in combination with the power generation facility 50 with unstable output.

  On the other hand, the lead storage battery 20 has an energy density lower than that of the lithium ion battery, but has an advantage that the structure is simple, the material is easily available, and the cost is low as compared with the lithium ion battery. It is important that the equipment cost is low when an electrified area is assumed. That is, it can be said that combining the lead storage battery 20 with the power generation facility 50 that generates power using natural energy is a realistic response in the current non-electricity area.

  Moreover, it is not limited to a non-electrified area, providing a lead storage battery 20 in a region where the frequency of power failure of the power system is high, or a region where the voltage of the power system is unstable is for a user who uses a plurality of electrical loads 40. It can be said that it is desirable as a realistic countermeasure for power stabilization.

  However, the lead storage battery 20 has a problem that a phenomenon called sulfation occurs when the battery is over-discharged or left in a discharged state, resulting in a short life. The lead storage battery 20 is also provided with a deep cycle battery having a configuration in which sulfation hardly occurs, but is not suitable for the purpose of reducing the equipment cost as much as possible.

  In the present embodiment, the lead storage battery 20 is used over a long period of time even if the lead storage battery 20 has not taken countermeasures against sulfation by controlling charging and discharging of the lead storage battery 20 so that sulfation is less likely to occur. It is possible to do.

  The lead storage battery 20 is charged with electric power generated by the solar power generation facility 51. The DC power generated by the solar power generation facility 51 is supplied to the lead storage battery 20 through the charging device 11. The charging device 11 controls the current and voltage conditions for charging the lead storage battery 20 based on the power generated by the photovoltaic power generation facility 51 and the battery voltage (open voltage) of the lead storage battery 20.

  Since the output of the photovoltaic power generation facility 51 fluctuates according to the amount of sunlight, the charging device 11 performs electric power output from the photovoltaic power generation facility 51 by performing maximum power point tracking (MPPT) control. It is desirable to be configured to use without waste. In addition, since the solar power generation facility 51 has a limitation in the current supply capability, the charging device 11 sets a threshold value that is an upper limit for the voltage when charging the lead storage battery 20, and further has an upper limit for the current during charging. It is desirable to set a threshold value such that

  With this configuration, the charging device 11 enables charging in a short time by maximizing the current for charging the lead storage battery 20 in the range up to the upper limit during a period when the remaining capacity of the lead storage battery 20 is small. In addition, when the remaining capacity of the lead storage battery 20 increases (when the battery voltage reaches a predetermined threshold), the charging device 11 reduces the current for charging the lead storage battery 20. Furthermore, when the lead storage battery 20 is fully charged (when the charging current decreases to a predetermined value), the charging device 11 desirably performs trickle charging.

  The operation of the charging device 11 described above is an example, and other operations (for example, two-stage constant voltage charging that sets the battery voltage in two stages) may be employed. However, whatever operation is employed, it is necessary to limit the charging current and the battery voltage.

  In order to control the charging of the lead storage battery 20 as described above, the charging device 11 employs a configuration using a switching power supply. The charging device 11 has a function of monitoring the battery voltage and the charging current, and the content of the control is automatically determined using the battery voltage and the charging current. However, regarding the start and stop of charging, instructions from the control device 30 described later are followed.

  The control device 30 includes a device including a processor that operates according to a program as a main hardware element. This type of processor may be realized by a microcontroller (microcomputer) in which a memory is mounted together with the processor, or may have a configuration in which the memory is connected separately. The program is written in advance in a ROM (Read Only Memory), provided through an electric communication line such as the Internet, or provided by a computer-readable recording medium.

  The electric power charged in the lead storage battery 20 is supplied to the plurality of electric loads 40 through the converter 12 that converts DC power into AC power. That is, the conversion device 12 includes an inverter circuit. Moreover, the converter 12 may contain the DC-DC converter in order to adjust a voltage. The conversion device 12 also has a function of converting DC power generated by the solar power generation facility 51 into AC power. The converter 12 may include a configuration for converting DC power output from the lead storage battery 20 into AC power and a configuration for converting DC power output from the photovoltaic power generation facility 51 into AC power. desirable.

  The configuration corresponding to the photovoltaic power generation facility 51 in the conversion device 12 performs maximum power point tracking control, similarly to the charging device 11. In the case where the conversion device 12 can satisfy the power (power amount) consumed by the plurality of electric loads 40 with the power (power amount) generated by the solar power generation facility 51, the power of the solar power generation facility 51 is supplied to each electric load. 40. Moreover, the converter 12 supplies the electric power which the lead storage battery 20 outputs to each electric load 40, when the electric power consumed by the some electric load 40 cannot be satisfied with the electric power which the solar power generation equipment 51 generates.

  Here, it is assumed that the lead storage battery 20 performs so-called floating charging, in which charging is performed in a state where discharging is possible. Therefore, when the electric power required for the operation of the plurality of electric loads 40 is insufficient only by the electric power output by the photovoltaic power generation facility 51, the shortage is satisfied by the electric power output by the lead storage battery 20. Also, at night when the solar power generation facility 51 cannot generate power, or when the output of the solar power generation facility 51 is cloudy or rainy, the plurality of electric loads 40 can be operated by making up for the shortage with the power of the lead storage battery 20. It becomes possible.

  By the way, as described above, if the lead-acid battery 20 is left with a small remaining capacity, sulfation occurs. Therefore, the present embodiment employs a technology that preferentially charges the lead storage battery 20 as much as possible so that the duration of the state in which the remaining capacity of the lead storage battery 20 is small is shortened. Further, in order to maintain the remaining capacity of the lead storage battery 20, a technique for prohibiting (stopping) discharge from the lead storage battery 20 when the remaining capacity decreases to a lower limit value, and a plurality of electric loads when the remaining capacity of the lead storage battery 20 decreases. And a technology for reducing the power supplied to 40. These techniques will be specifically described below.

  Since it is necessary to manage the remaining capacity of the lead storage battery 20 in order to implement the above-described technology, the power management apparatus 10 monitors the remaining capacity (SOC: State Of Charge) of the lead storage battery 20. It has. The monitoring device 13 basically estimates the remaining capacity of the lead storage battery 20 by measuring the battery voltage of the lead storage battery 20. That is, in the lead storage battery 20, the remaining capacity can be estimated from the battery voltage by utilizing the characteristic that the relationship between the discharge amount and the battery voltage is substantially linear. Since other techniques for estimating the remaining capacity of the lead storage battery 20 are known, the monitoring device 13 may estimate the remaining capacity of the lead storage battery 20 using other techniques. Other techniques for measuring the remaining capacity of the lead storage battery 20 will be described later.

  The power management device 10 includes a control device 30 that controls the charging device 11 and the conversion device 12 using the remaining capacity of the lead storage battery 20 monitored by the monitoring device 13. The control device 30 includes a setting unit 34 that sets a lower limit value and an upper limit value for the remaining capacity of the lead storage battery 20. The lower limit value and the upper limit value set in the setting unit 34 are not only set according to the specifications of the lead storage battery 20, but are adjusted according to the degree of deterioration of the lead storage battery 20.

  The degree of deterioration of the lead storage battery 20 is estimated from the internal impedance. Specifically, it is estimated from the relationship between the current value when the battery is fully charged and the battery voltage. In other words, the degree of deterioration of the lead storage battery 20 is estimated from the above-described transition of the upper limit value. The setting unit 34 lowers the upper limit value as the deterioration of the lead storage battery 20 progresses. The lower limit value is set to have a certain difference from the upper limit value. Therefore, the lower limit value is lowered as the deterioration of the lead storage battery 20 progresses. The lower limit value is not a remaining capacity corresponding to the discharge end voltage, but is set to a value larger than this remaining capacity. In addition to the setting unit 34, the control device 30 includes a first instruction unit 31, a second instruction unit 32, a third instruction unit 33, and a determination unit 35.

  When the remaining capacity acquired from the monitoring device 13 decreases to the lower limit value, the determination unit 35 instructs the conversion device 12 to stop through the first instruction unit 31 in order to prohibit (stop) the discharge of the lead storage battery 20. After the 1st instruction | indication part 31 prohibits the discharge of the lead storage battery 20, the converter 12 continues a stop state until the conditions which permit discharge are satisfied. That is, the remaining capacity of the lead storage battery 20 is prevented from becoming less than the lower limit value. In this embodiment, natural discharge is negligible in practical use, and the lower limit is set with a margin. Therefore, if the lower limit value is set appropriately, overdischarge of the lead storage battery 20 can be avoided and the occurrence of sulfation due to overdischarge can be prevented.

  When the condition for permitting the discharge of the lead storage battery 20 is satisfied after the first instruction unit 31 stops the conversion device 12 and the discharge of the lead storage battery 20 is stopped, the determination unit 35 converts the conversion device through the second instruction unit 32. 12 is instructed to permit driving. The condition for permitting the discharge of the lead storage battery 20 is determined by the remaining capacity of the lead storage battery 20.

  That is, when the remaining capacity of the lead storage battery 20 increases to a permission value set between the lower limit value and the upper limit value, the determination unit 35 instructs the conversion device 12 to allow operation through the second instruction unit 32. give. Since the charging device 11 charges the lead storage battery 20 while the operation of the conversion device 12 is stopped, if the photovoltaic power generation facility 51 is generating power, the charging is prohibited (stopped). During this period, the remaining capacity of the lead storage battery 20 can be charged to the permitted value in a relatively short time. The upper limit value of the remaining capacity of the lead storage battery 20 is set to about the remaining capacity when the lead storage battery 20 is fully charged, and the permission value is set to a remaining capacity that is lower than the upper limit value but close to full charge. It is desirable. For example, the permission value is set to a value obtained by subtracting a certain value from the upper limit value. The permission value is, for example, a value set by the setting unit 34 by an input by the user. In this case, the setting unit 34 has a function of setting a permission value.

  By the way, as shown in FIG. 1, a power supply adjusting device 14 that adjusts the supply of AC power to each electric load 40 is provided in a path for supplying power from the conversion device 12 to the plurality of electric loads 40. Although the power supply adjusting device 14 is not essential, the power discharged from the lead storage battery 20 can be reduced by providing the power supply adjusting device 14. An instruction to the power supply adjustment device 14 is made through the third instruction unit 33.

  For example, the power supply adjustment device 14 selects a distribution board or a distribution board (not shown) for branching a path for supplying power from the converter 12 to the plurality of electric loads 40 into a plurality of systems, and whether to supply power for each system. A controller (not shown). That is, the distribution board or the distribution board includes a breaker or a switch for selecting whether to energize the electric circuit for each system. The breaker or the switch is configured to select whether or not to energize the electric circuit for each system according to the control signal, and the controller is configured to supply the control signal to the breaker or the switch.

  In response to the instruction from the control device 30, the power supply adjustment device 14 selects the electric load 40 that supplies power from the conversion device 12 from among the plurality of electric loads 40. The control device 30 sets priorities for the plurality of electric loads 40 in advance, and when the remaining capacity of the lead storage battery 20 decreases to a predetermined threshold, the electric loads 40 having a low priority (that is, may be stopped). The power supply adjusting device 14 is instructed to stop power supply to the power supply.

  The threshold regarding the remaining capacity of the lead storage battery 20 may be determined in a plurality of stages. In this case, power supply is stopped in order from the electric load 40 having a lower priority for each threshold level. Therefore, the electric load 40 having the highest priority is supplied with power until the remaining capacity of the lead storage battery 20 reaches the lower limit value.

  Incidentally, in the configuration example described above, the monitoring device 13 estimates the remaining capacity of the lead storage battery 20 by monitoring the battery voltage of the lead storage battery 20. In order to estimate the remaining capacity of the lead storage battery 20, it is possible to use the internal impedance of the lead storage battery 20 in addition to the battery voltage of the lead storage battery 20. Further, instead of estimating the remaining capacity from one of the battery voltage and the internal impedance, an average value or a weighted average value may be estimated for the remaining capacity estimated using both. Alternatively, it is also possible to use a change (for example, a transient response) between the battery voltage and the internal impedance of the lead storage battery 20.

  For example, after a predetermined time has elapsed since the pseudo load 21 having a known resistance value is connected to the lead storage battery 20, at least one of the battery voltage and the internal impedance and the battery of the lead storage battery 20 before the pseudo load 21 is connected. From the voltage (open voltage), the monitoring device 13 may estimate the remaining capacity of the lead storage battery 20. In this case, it is desirable that the monitoring device 13 has a table in which the battery voltage and the internal impedance after a predetermined time has elapsed since the pseudo load 21 is connected are associated with the open circuit voltage.

  2A and 2B schematically show a configuration example when the pseudo load 21 is used. In the illustrated configuration, a series circuit of a pseudo load 21 and a switch 22 is connected between lines of an electric circuit connected to the lead storage battery 20. As shown in FIG. 2A, the monitoring device 13 turns off the switch 22 and measures the open circuit voltage. Next, as shown in FIG. 2B, the monitoring device 13 turns on the switch 22 and measures at least one of the battery voltage and the internal impedance when a predetermined time has elapsed since the switch 22 was turned on. The monitoring device 13 obtains the remaining capacity of the lead storage battery 20 by comparing at least one of the measured battery voltage and internal impedance and the open voltage with a table and performing an interpolation calculation if necessary.

  When estimating the remaining capacity based on the battery voltage of the lead storage battery 20, the monitoring device 13 can continuously estimate the remaining capacity of the lead storage battery 20 in real time. On the other hand, as described above, when the remaining capacity of the lead storage battery 20 is estimated by connecting the pseudo load 21 to the lead storage battery 20, the monitoring device 13 estimates the remaining capacity of the lead storage battery 20 in real time. Can not. If the power consumed by the plurality of electrical loads 40 (the amount of power) and the power generated by the photovoltaic power generation facility 51 (the amount of power) are measured in real time, the monitoring device 13 determines the remaining capacity of the lead storage battery 20 as follows: Even if it is not measured in real time, it is possible to estimate continuously.

  Now, let P1 [W] be the power generated by the photovoltaic power generation facility 51, P2 [W] be the power consumed by the plurality of electric loads 40, and P3 [W] be the power that the lead storage battery 20 is discharging or charging. If loss due to power conversion is ignored, P1−P2 ± P3 = 0 holds. Here, the power P3 is within a range in which the lead storage battery 20 can be charged and discharged. In other words, all the electric power P1 generated by the solar power generation equipment 51 is used by the plurality of electric loads 40 and the lead storage battery 20, and all the electric power consumed by the plurality of electric loads 40 is the solar power generation equipment 51 and It is assumed that supply from the lead storage battery 20 is possible.

  However, in reality, the power P1 generated by the solar power generation facility 51 exceeds the sum of the power P2 consumed by the plurality of electric loads 40 and the power P3 that can be charged in the lead storage battery 20 (P1> P2 + P3). ). Moreover, in the total of the electric power P1 generated by the photovoltaic power generation facility 51 and the electric power P3 that can be output from the lead storage battery 20, there is a state where the electric power P2 required by the plurality of electric loads 40 is insufficient (P1 + P3 <P2). The former state is dealt with by limiting the output of the photovoltaic power generation equipment 51, and the latter state is dealt with by restricting at least one operation of the plurality of electric loads 40. Therefore, these states are not considered here.

  When the electric power P2 requested by the plurality of electric loads 40 exceeds the electric power P1 generated by the photovoltaic power generation facility 51 (P1 <P2), the lead storage battery 20 is discharged (P3> 0). On the other hand, when the electric power P2 requested by the plurality of electric loads 40 is lower than the electric power P1 generated by the photovoltaic power generation facility 51 (P1 <P2), the lead storage battery 20 is charged (P3 <0).

  An example of the daily operation in this case is shown in FIG. In FIG. 3, P <b> 1 indicates power generated by the solar power generation facility 51, and P <b> 2 indicates power consumed by the plurality of electric loads 40. During the day, P1> P2 is generally established, and the lead storage battery 20 is charged during this time. On the other hand, P1 = 0 during the period from night to morning and from evening to night, and the lead storage battery 20 is discharged during the period of P2> 0 in this period. In FIG. 3, although P1> P2 in the daytime, a state where the lead storage battery 20 is fully charged and cannot be charged is indicated by a region D1. In the region D1, the output of the photovoltaic power generation facility 51 is suppressed.

  By the way, in FIG. 3, there are periods T1, T2, and T3 in which P1 <P2 temporarily during the day. As described above, when only the magnitudes of the electric powers P1, P2, and P3 are used for the discharge conditions of the lead storage battery 20, the lead storage battery 20 is discharged in all the periods T1, T2, and T3. On the other hand, since this embodiment does not discharge until the remaining capacity reaches the allowable value after the lead storage battery 20 is discharged to the lower limit value, for example, if the lead storage battery 20 is discharged to the lower limit value at night, The lead storage battery 20 is not discharged during the periods T1 and T2, but is discharged only during the period T3.

  Of course, when the remaining capacity of the lead storage battery 20 has reached the allowable value before the period T1, the lead storage battery 20 is also discharged during the period T1. That is, whether or not the lead storage battery 20 is discharged in the periods T1, T2, and T3 depends on the remaining capacity when the lead storage battery 20 is fully charged, the power P2 consumed by the plurality of electric loads 40, and the photovoltaic power generation equipment 51. It depends on the relationship with the electric power P1 to be generated.

  As described above, the remaining capacity of the lead storage battery 20 is not measured in real time, but the remaining capacity at a specific point in time, the power P1 generated by the solar power generation facility 51, and the power P2 consumed by the plurality of electric loads 40. If it is understood, it is possible to estimate in real time. That is, whether or not the remaining capacity P has decreased to the lower limit value using the remaining capacity P (t) at time t, the integrated value ΣP1 of power P1 and the integrated value ΣP2 of power P2 after x hours from time t. In other words, the remaining capacity P (x) after x hours from the time t is obtained by calculation. In actual calculation, it is necessary to correct the conversion efficiency of the charging device 11 and the conversion device 12. If a data table based on actual measurement is used instead of calculation, the remaining capacity P (x) after x hours can be obtained by incorporating correction.

  When the remaining capacity of the lead storage battery 20 is measured using the pseudo load 21, the remaining capacity of the lead storage battery 20 cannot be obtained in real time. However, as described above, the remaining capacity of the lead storage battery 20 at a specific time is calculated. By determining, it is possible to estimate the transition of the remaining capacity. What is necessary is just to set the time interval which measures remaining capacity in about 1 day to 1 week. Moreover, when measuring the remaining capacity of the lead storage battery 20, the period when the fluctuation | variation of the remaining capacity of the lead storage battery 20 is small is desirable. Therefore, the monitoring device 13 measures information (value) for estimating the remaining capacity of the lead storage battery 20 in a time zone in which the power discharged from the lead storage battery 20 is equal to or less than a predetermined reference value.

  By the way, when the remaining capacity of the lead storage battery 20 decreases to the lower limit value, the discharge of the lead storage battery 20 is prohibited (stopped), so that the power that can be supplied to the power (power amount) required by the plurality of electrical loads 40 ( The amount of power) may be insufficient. Therefore, the control device 30 may notify the users of the plurality of electrical loads 40 that the discharge from the lead storage battery 20 is prohibited (stopped) when the remaining capacity of the lead storage battery 20 decreases to the lower limit value. desirable.

  Specifically, the control device 30 includes a notification unit 36 that outputs a notification signal to the notification device 60 when an instruction to prohibit (stop) the discharge of the lead storage battery 20 is given from the first instruction unit 31 to the conversion device 12. Prepare. By notifying the user through the notification device 60 that the discharge of the lead storage battery 20 is prohibited (stopped), the user is encouraged to reduce the power consumed by the plurality of electric loads 40 (power amount). It becomes possible.

  The control device 30 may adopt a configuration in which the notification unit 36 outputs a notification signal when the remaining capacity of the lead storage battery 20 decreases to the lower limit value, but when the remaining capacity of the lead storage battery 20 is greater than the lower limit value. Therefore, it is desirable to adopt a configuration in which the notification unit 36 outputs a notification signal. When the latter configuration is adopted, before the remaining capacity of the lead storage battery 20 reaches the lower limit value and discharge is prohibited (stopped), the user is warned and the power consumed by the plurality of electrical loads 40 (the amount of power) ) Can be performed by the user. That is, it is possible to prevent the remaining capacity of the lead storage battery 20 from reaching the lower limit, and to extend the time for which power can be used.

  In addition, the notification unit 36 of the control device 30 notifies the notification device 60 that the available power (amount of power) has increased when the state in which the lead storage battery 20 is fully charged exceeds a predetermined time. May be. The user can increase the power (power consumption) consumed by the plurality of electric loads 40 according to the content of the notification presented on the notification device 60.

  When the notification device 60 notifies the users of the plurality of electrical loads 40 of an increase in usable power, it is possible to use the electrical loads 40 that are refrained from use during normal times, for example. For example, when there is a surplus in the supply of electric power, the user can use the electric load 40 with a high degree of freedom in the time zone to be used like a washing machine or a vacuum cleaner. When this configuration is adopted, the user can avoid the power shortage and enjoy the convenience of the electric load 40.

  In the configuration example described above, when the power generated by the photovoltaic power generation facility 51 cannot satisfy the power consumed by the plurality of electrical loads 40, the shortage of power is supplied from the lead storage battery 20 to the plurality of electrical loads 40. Yes. As described above, in the configuration in which the shortage of electric power is supplied from the lead storage battery 20, when the discharge from the lead storage battery 20 is prohibited (stopped), the electric power that can be supplied to the plurality of electric loads 40 is insufficient. The quality of convenience that can be enjoyed by the electric load 40 may be reduced. Further, in this configuration, some operations of the plurality of electric loads 40 may be stopped when the discharge of the lead storage battery 20 is prohibited (stopped). Here, depending on the type of the electric load 40 to be stopped, inconveniences such as resetting of information set in the electric load 40 to be stopped may occur.

  In order to avoid such a problem, it is desirable to provide a backup power source 52 that compensates for the shortage of power supplied to the plurality of electric loads 40 in a state where discharging of the lead storage battery 20 is prohibited (stopped). The backup power source 52 includes a storage battery (not shown), and this storage battery is used for both the charging of the lead storage battery 20 and the operation of each electric load 40 among the power generated by the solar power generation facility 51. Charged with no power.

  The capacity of the backup power source 52 is desirably large enough to satisfy the power from when the discharge of the lead storage battery 20 is prohibited (stopped) until the discharge is restarted. However, the backup power source 52 having such a capacity is used. It becomes expensive and it is against the purpose. Therefore, the capacity of the backup power source 52 may be such that each electric load 40 can be stopped normally. Moreover, since the backup power source 52 has a small remaining capacity when fully charged and less frequent charging and discharging compared to the lead storage battery 20, any storage battery can be used as the backup power source 52. Good.

  In order to reduce the capacity of the backup power source 52, the backup power source 52 discharges each electric load 40 to the power necessary for a normal stop when the discharge from the lead storage battery 20 is prohibited (stopped). Thereafter, power may be supplied only to the control device 30. In addition, since the control device 30 cannot operate during a period in which the discharge of the lead storage battery 20 is prohibited (stopped) and the photovoltaic power generation facility 51 is not generating power, the backup power source 52 supplies power to the control device 30 during this period. It is desirable to supply. Note that the control device 30 may include a battery power supply in order to supply an internal power supply only during a period in which power is not supplied from the outside.

  By the way, the electric power feeding adjustment apparatus 14 can select whether to energize the electric circuit for every system | strain. Therefore, if the amount of power that can be supplied from the lead storage battery 20 and the photovoltaic power generation facility 51 to the plurality of electrical loads 40 is known, the amount of power that can be consumed by the plurality of electrical loads 40 is determined. Since the solar power generation facility 51 generates power during the day, the amount of power generated by the solar power generation facility 51 is predicted before the power generation of the solar power generation facility 51 starts on the day. Further, if the remaining capacity of the lead storage battery 20 is estimated, the amount of power that can be used thereafter is determined.

  The power generation amount of the solar power generation facility 51 can be estimated using the amount of sunlight and the temperature as main variables. The amount of sunshine is estimated from the weather according to the weather forecast, the solar altitude and the sunshine duration according to the season (month and day), and the temperature is estimated from the weather forecast.

  In the configuration example shown in FIG. 1, the prediction unit 38 provided in the control device 30 acquires weather forecast information from the server 70 through the telecommunication network 71 such as the Internet. The prediction unit 38 obtains seasonal information from the clock unit 37 built in the control device 30. In addition, in order to raise prediction accuracy, it is also possible to use together the sensor which measures temperature, humidity, and solar radiation (brightness). By using the information obtained from these sensors, it is possible to correct an error between the information on the weather forecast announced on a regional basis and the information on the location where the photovoltaic power generation facility 51 is actually installed. .

  If the remaining capacity of the lead storage battery 20 is measured, the amount of power required to charge the remaining capacity of the lead storage battery 20 to an allowable value is required. Accordingly, the prediction unit 38 predicts the amount of power that the photovoltaic power generation facility 51 generates thereafter. If the remaining capacity of the lead storage battery 20 is estimated by the monitoring device 13, it is possible to estimate the amount of power that can be supplied to the plurality of electrical loads 40 in the power supply adjustment device 14. In addition, the power supply adjustment device 14 distributes the power to the plurality of electrical loads 40 so that the amount of power that can be supplied is equal to the amount of power consumed by the plurality of electrical loads 40. By this operation, excess or deficiency of electric power (power amount) supplied to the plurality of electric loads 40 is suppressed.

  The power management apparatus 10 may include a temperature adjustment device 15 that maintains the temperature of the lead storage battery 20 within a predetermined allowable range. That is, the temperature of the lead storage battery 20 is monitored by the temperature sensor 16, and the temperature adjustment device 15 adjusts the temperature of the lead storage battery 20 so as to maintain the temperature monitored by the temperature sensor 16 within an allowable range. As the temperature adjusting device 15, a Peltier element, a heat pump, or the like is used.

  When the temperature of the lead storage battery 20 is maintained within an allowable range (for example, 25 ° C.), the power supply adjustment device 14 can estimate the remaining capacity of the lead storage battery 20 without considering the temperature. That is, the monitoring device 13 can accurately estimate the remaining capacity of the lead storage battery 20 without performing correction by temperature.

  FIG. 4 is a flowchart showing an operation example of the power management apparatus 10 according to the present embodiment. In the operation example shown in FIG. 4, the remaining capacity of the lead storage battery 20 is estimated from the battery voltage of the lead storage battery 20. Further, when the state in which the remaining capacity of the lead storage battery 20 is equal to or lower than the lower limit (the battery voltage is equal to or lower than the lower limit) continues for a predetermined time (5 minutes in the illustrated example), the operation of prohibiting (stopping) the discharge from the lead storage battery 20 Is adopted. When the state in which the remaining capacity of the lead storage battery 20 is higher than the upper limit value (battery voltage is higher than the upper limit value) continues for a predetermined time (5 minutes in the illustrated example), the power consumed by the plurality of electric loads 40 is increased. .

  Hereinafter, the operation example shown in FIG. 4 will be described. The amount of power generated by the solar power generation facility 51 is predicted the day before. The prediction unit 38 of the control device 30 predicts the amount of power generated by the solar power generation facility 51 the next day (S11), and the monitoring device 13 monitors the remaining capacity of the lead storage battery 20 (S12).

  The determination unit 35 estimates the amount of power (distribution amount) that can be supplied to the plurality of electrical loads 40 the next day by using the amount of power generated by the photovoltaic power generation facility 51 and the remaining capacity of the lead storage battery 20 (S13). ). Further, the setting unit 34 estimates the degree of deterioration of the lead storage battery 20, and determines the upper limit value and the lower limit value of the remaining capacity based on the degree of deterioration (S14). The processing of steps S11 to S14 is performed at midnight on the previous day in preparation for supplying power to the plurality of electric loads 40 on the next day. Further, the remaining capacity and the degree of deterioration of the lead storage battery 20 are assumed to be obtained by the monitoring device 13 connecting the pseudo load 21 and measuring the internal impedance of the lead storage battery 20.

  Thereafter, the determination unit 35 instructs charging or discharging of the lead storage battery 20 based on the relationship between the amount of power generated by the photovoltaic power generation facility 51 and the amount of power consumed by the plurality of electric loads 40 (S21). The monitoring device 13 estimates the remaining capacity of the lead storage battery 20 by measuring the battery voltage of the lead storage battery 20 (S22). During the period when the battery voltage of the lead storage battery 20 is higher than the lower limit (S23: No), until the battery voltage reaches the upper limit (S24: No), through the first instruction unit 31 and the second instruction unit 32, Charging or discharging the lead storage battery 20 is performed.

  On the other hand, when the battery voltage of the lead storage battery 20 becomes equal to or lower than the lower limit (S23: Yes), it is determined whether or not the state continues for a predetermined time (for example, 5 minutes) (S25). Even if the battery voltage is equal to or lower than the lower limit, if the state is temporary and has not continued for a predetermined time (S25: No), the process returns to step S24. When the state where the battery voltage is lower than the lower limit value continues for a predetermined time (S25: Yes), the notification unit 36 outputs a notification signal (S26), and the first instruction unit 31 instructs the converter 12 to stop discharging. (S27).

  After the first instruction unit 31 instructs the converter 12 to stop, the second instruction unit 32 instructs the charging device 11 to charge the lead storage battery 20 (S28), and the remaining capacity of the lead storage battery 20 is an allowable value. (S29: No), the lead storage battery 20 is continuously charged. After the remaining capacity of the lead storage battery 20 reaches an allowable value (S29: Yes), the process returns to step S21 and the lead storage battery 20 is charged or discharged.

  By the way, in step S24, when the battery voltage of the lead storage battery 20 has reached the upper limit (S24: Yes), the determination unit 35 determines whether or not this state continues for a predetermined time (for example, 5 minutes). Judgment is made (S30). That the battery voltage has reached the upper limit value means that the lead storage battery 20 is substantially fully charged. Even if the battery voltage reaches the upper limit value, if the state is temporary and does not continue for a predetermined time (S30: No), the process returns to step S21 and the lead storage battery 20 is repeatedly charged or discharged. When the state where the battery voltage exceeds the upper limit value continues for a predetermined time (S30: Yes), the third instruction unit 33 instructs the power supply adjustment device 14 to increase the power supplied to the plurality of electric loads 40 ( S31).

  When the power management apparatus 10 performs the operation described above, the remaining capacity of the lead storage battery 20 and the amount of power generated by the solar power generation facility 51 change as shown in FIG. 5, for example. FIG. 5 shows the relationship between the remaining capacity U1 of the lead storage battery 20 and the amount of power U2 generated by the solar power generation facility 51 for one year. The upper end of the remaining capacity U1 corresponds to the above-described upper limit value, and the lower end of the remaining capacity U1 corresponds to the above-described lower limit value. From the figure, it can be read that the upper limit value and the lower limit value decrease with time. This phenomenon means that the capacity of the lead storage battery 20 is gradually decreased due to deterioration.

  For comparison, FIG. 6 shows an operation example in the case where discharge to the discharge end voltage is permitted without setting a lower limit value for the remaining capacity of the lead storage battery. FIG. 6 also shows the relationship between the remaining capacity U3 of the lead storage battery and the amount of power U4 generated by the solar power generation facility. As can be seen from the figure, in this example, since a lower limit value is not set for the remaining capacity U3 of the lead storage battery, deep discharge is performed in a part of the period. Therefore, compared with the operation of the present embodiment shown in FIG. 5, the upper end of the remaining capacity U3 after one year has greatly decreased from the initial value (ΔA <ΔB). It can be seen that the deterioration of the lead storage battery is more advanced than in the present embodiment.

  That is, it was found that the progress of deterioration of the lead storage battery 20 can be suppressed by employing the technology described in the present embodiment. The above-described configuration example is an example, and it goes without saying that various modifications can be made without departing from the technical idea of the present invention.

  For example, although the configuration example described above uses the solar power generation facility 51 in combination with the lead storage battery 20, the above-described technology can be applied to the power generation facility 50 that generates power using natural energy. Moreover, the lead storage battery 20 contributes to the stabilization of electric power even when it is used in combination with an electric power system without providing the power generation facility 50. That is, the technology of the present embodiment can be applied even when it is not in a non-electrified area.

  The power management apparatus 10 according to the above-described embodiment is not limited to the case where power is supplied to the plurality of electric loads 40. The power management apparatus can perform the above-described operation even when supplying power to only one electrical load.

  While the invention has been described in terms of several preferred embodiments, various modifications and variations can be made by those skilled in the art without departing from the true spirit and scope of the invention, ie, the claims.

Claims (11)

A charging device for charging a lead-acid battery;
A converter for converting direct current power output from the lead acid battery into alternating current power, and supplying the alternating current power to an electric load;
A monitoring device for monitoring the remaining capacity of the lead acid battery;
A controller that acquires the remaining capacity of the lead storage battery from the monitoring device and controls the charging device and the converter;
The control device includes:
A setting unit for setting a lower limit value and an upper limit value for the remaining capacity of the lead-acid battery;
A determination unit that instructs the converter to stop discharging the lead-acid battery when the remaining capacity decreases to the lower limit;
The determination unit
After the discharge of the lead storage battery is stopped, the conversion device is instructed to permit the discharge of the lead storage battery when the remaining capacity rises to a permission value set between the lower limit value and the upper limit value. A power management apparatus characterized by that. A power supply adjusting device for adjusting supply of the AC power to the electric load;
The power management device according to claim 1, wherein the control device instructs the power supply adjustment device to adjust the AC power supplied to the electric load according to the remaining capacity. The charging device is used as power for charging the lead storage battery with power from a power generation facility that generates power using natural energy,
The control device includes:
A prediction unit for predicting the amount of power generated by the power generation facility in a predetermined period
The determination unit estimates the amount of power that can be supplied to the electrical load in the predetermined period based on the amount of power predicted by the prediction unit and the remaining capacity of the lead storage battery monitored by the monitoring device, and The power management apparatus according to claim 2, wherein an instruction is given to the power supply adjustment device based on an amount of power that can be supplied to the load. The monitoring device
The power management apparatus according to any one of claims 1 to 3, wherein the remaining capacity of the lead storage battery is estimated using at least one of a battery voltage of the lead storage battery and an internal impedance of the lead storage battery. The monitoring device
The battery voltage of the lead storage battery after a predetermined time has elapsed since a pseudo load having a known resistance value is connected to the lead storage battery, and the predetermined time has elapsed since the pseudo load was connected to the lead storage battery At least one of the internal impedance of the later lead acid battery,
The power management device according to any one of claims 1 to 3, wherein the remaining capacity of the lead storage battery is estimated using an open-circuit voltage of the lead storage battery in a state where the pseudo load is not connected to the lead storage battery. . The monitoring device
The power management apparatus according to claim 4 or 5, wherein information for estimating the remaining capacity is measured in a time zone in which power for charging or discharging the lead storage battery is equal to or less than a predetermined reference value. The power management apparatus according to any one of claims 1 to 6, further comprising a temperature adjustment device that maintains a temperature of the lead storage battery within a predetermined allowable range. The setting unit estimates a degree of deterioration of the lead storage battery based on a transition of the remaining capacity of the lead storage battery monitored by the monitoring device, and determines the upper limit value and the lower limit value based on the degree of deterioration. The power management device according to any one of claims 1 to 7. The control device includes:
The power management device according to claim 1, further comprising a notification unit that outputs a notification signal to a notification device when the determination unit stops discharging of the lead storage battery. The power management apparatus according to claim 2, wherein when the remaining capacity of the lead storage battery reaches the upper limit value, the determination unit instructs the power supply adjustment apparatus to permit an increase in power consumed by the electric load. The power management apparatus according to any one of claims 1 to 10, further comprising a backup power supply that supplies power to the electric load when the conversion apparatus stops.

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