JP3469228B2 - Power storage device charge / discharge control device, charge / discharge control method, and power storage system - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to charge / discharge control of a power storage device.

[0002]

2. Description of the Related Art In recent years, the difference in power demand between night and day has been increasing, and the power demand in the daytime especially in summer is approaching the upper limit of the total power generation capacity. The power generation capacity is configured according to the maximum power demand, but during periods when the power demand declines, the operating rate of the power generation facilities has declined and it is extremely inefficient. Has been. On the other hand, in a distributed generator that does not have interconnection with the power system, it is required that the fluctuation of the output is small, which is more efficient, and does not cause surplus or shortage of power. To meet these demands, electric power storage systems have been developed in recent years. This power storage system stores surplus power from the generator and nighttime power with a low electricity charge in a large power storage device, and uses this stored power when the power demand is high. Can be used.

A secondary battery (cell) such as a lithium-ion battery or a nickel-cadmium battery is used as a power storage device used in a power storage system, and a relatively large amount of power such as 50 kW or 100 kW required at the time of power supply is used. For supply, a plurality of modules in which secondary batteries are connected in series are connected in parallel.

[0004]

A power storage device used in an electric power storage system generally secures a required amount of electric power (for example, 100 kW) for the entire electric power storage system, and generally 10
A life of about a year is required. Since the power storage device deteriorates in proportion to the total amount of electric power charged and discharged, the life of the power storage device can be extended by controlling the charge and discharge of the power storage device and setting the depth of discharge of the power storage device to be shallow. However, if the depth of discharge of the power storage device is shallow, the amount of power that can be extracted from a single power storage device will decrease, so more power storage devices are required to obtain the required power amount of the entire power storage system, and the system becomes larger. In addition, there is a problem that equipment cost increases.

On the other hand, when the depth of discharge is set deep,
Although it is possible to extract a large amount of electric power from a single power storage device, the battery deteriorates in proportion to this amount of electric power, and the life is shortened. Therefore, the power storage device must be replaced frequently, the burden on the user is increased, and the labor required for maintenance is also required, resulting in a problem of lack of convenience.

Therefore, in controlling the power storage device, it is important to set an appropriate depth of discharge in consideration of the balance between the life and the required amount of electric power, and while ensuring the required life, within that period. How efficiently power can be supplied is a major focus in charge / discharge control.

Conventionally, the discharge depth is set in consideration of the balance between the service life and the required power amount, and the discharge is always controlled based on the same discharge depth. According to such discharge control, it is possible to ensure the required life and output the required amount of power to the end. However, since the same depth of discharge is set and charge / discharge control is uniformly performed in all the power storage devices that configure the power storage system, it has not been possible to sufficiently exert the capacity of each power storage device.

The present invention has been made in view of the above circumstances, and more efficiently supplies electric power while ensuring both the life and the required amount of electric power, and increases the electric storage / discharge capacity of each electric storage device. It is an object of the present invention to provide a charge / discharge control device for a power storage device, a charge / discharge control method, and a power storage system that can be sufficiently exhibited.

[0009]

In order to achieve the above object, the present invention is a charge / discharge control device for controlling charge / discharge of a plurality of power storage devices connected in parallel to each other.
Setting means for setting the discharge level for stopping the discharge of the power storage device for each power storage device, updating means for updating the discharge level according to the deterioration state or the period of use of each power storage device, the discharge state of the power storage device, A charge / discharge control device for a power storage device, comprising: a discharge control means for stopping the discharge of the power storage device when the discharge level set for the power storage device is reached.

According to this structure, the discharge is controlled based on the discharge level set according to the deterioration of the power storage device. Specifically, for power storage devices with low deterioration and high battery capacity, the discharge level is set so that as much power as possible is extracted, and for power storage devices with low battery capacity due to deterioration of the power storage device, the power to be extracted is set. The discharge level is set according to the degree of deterioration and the battery capacity. As a result, even for a power storage device that has deteriorated and has a small battery capacity and is near the end of its life, power can be supplied to the end. In this way, even for a power storage device that has deteriorated, by setting a discharge level according to the deterioration and performing discharge control based on this discharge level, the power supply capacity of the power storage device is not fully exhausted It will be possible to demonstrate. As a result, it is possible to increase the total amount of electric power that can be extracted during the period of use of one power storage device, while ensuring the determined life. Examples of the parameters set as the discharge level include the depth of discharge, the remaining capacity at which the discharge is stopped, the inter-terminal voltage of the power storage device at which the discharge is stopped, and the like. As described above, the discharge level may be any parameter that can regulate the amount of electric power extracted from the power storage device.

Further, in the charge / discharge control device for a power storage device of the present invention, the discharge control means causes the power storage device having a high terminal voltage of the power storage device to start discharging first, and at the same time, the one power storage device in a discharge standby state. When the difference between the voltage between terminals and the voltage between terminals of the power storage device being discharged is within a predetermined value, discharging of one power storage device is started.

This makes it possible to prevent an inrush current due to the balance of the battery voltage between the power storage devices.

Further, in order to achieve the above object, the present invention is a charge / discharge control device for controlling charging / discharging of a plurality of power storage devices connected in parallel with each other. A setting unit that sets a level for each power storage device, an updating unit that updates the charging level according to a deterioration state or a usage period of each power storage device, and a charge state of the power storage device are set corresponding to the power storage device. A charging / discharging control device for a power storage device, comprising: a charge control unit that stops charging of the power storage device when the stored charge level is reached.

According to this structure, charging is controlled based on the charging level set according to the deterioration of the power storage device. Specifically, for power storage devices with low deterioration and high battery capacity, set the charge level to store as much power as possible so that as much power as possible can be taken out during discharge, and to prevent power storage devices from deteriorating due to use. Along with this, the charge level is updated so that the power to be taken out is gradually reduced.
As a result, even for a power storage device that has deteriorated and has a small usage capacity and is about to reach the end of its life, it is possible to store the amount of power corresponding to the deterioration until the end and supply the stored amount of power to the load system during discharging. In this way, even for a power storage device that has deteriorated, the charge level is set according to the deterioration, and charging control is performed based on this charge level, so that the stored power is supplied to the load system during discharge. As a result, it is possible to fully utilize the power supply capacity of the power storage device. As a result, while ensuring a fixed life, during the use period of one power storage device,
The total amount of power that can be drawn can be increased. In addition,
Examples of the parameter set as the charge level include the depth of charge, the remaining capacity at which charging is stopped, the terminal voltage of the power storage device at which charging is stopped, and the like. As described above, the charge level may be any parameter that can identify the discharge state.

Further, in the charge / discharge control device for a power storage device of the present invention, the charge control means starts charging from a power storage device having a low inter-terminal voltage of the power storage device, and at the same time, one of the power storage devices on standby for charging. When the difference between the inter-terminal voltage of 1 and the inter-terminal voltage of the power storage device being charged falls within a predetermined value, charging of one power storage device is started.

This makes it possible to prevent an inrush current due to the balance of the battery voltage between the power storage devices.

In order to achieve the above object, the present invention is a charging / discharging control method for controlling charging / discharging of a plurality of power storage devices connected in parallel with each other. The process of setting the level for each power storage device, the process of updating the discharge level according to the deterioration state or the usage period of each power storage device, and the discharge state of the power storage device are set corresponding to the power storage device. A charge / discharge control method for a power storage device, the method comprising: stopping the discharge of the power storage device when a certain discharge level is reached.

In order to achieve the above object, the present invention is a charging / discharging control method for controlling charging / discharging of a plurality of power storage devices connected in parallel to each other. The process of setting the level for each power storage device, the process of updating the charging level according to the deterioration state or the usage period of each power storage device, and the charge state of the power storage device are set corresponding to the power storage device. A charge / discharge control method for a power storage device, the method comprising: stopping the charging of the power storage device when a certain charge level is reached.

In order to achieve the above object, the present invention provides a plurality of power storage devices connected in parallel with each other, and a power storage device provided for each of the power storage devices and corresponding to electric power from a power grid. A charging / discharging control device that controls charging and discharging of each power storage device by controlling the operation of each power conversion device and the power conversion device that supplies the power from the corresponding power storage device to the load system The charging / discharging control device includes a setting unit configured to set a charging or discharging level for stopping charging or discharging of the power storage device for each power storage device, and the charging according to a deterioration state or a period of use of each power storage device. Alternatively, when the charging / discharging state of the power storage device and the updating means for updating the discharge level reaches the charge or discharge level set corresponding to the power storage device, the power storage device is updated. Providing power storage system characterized by comprising a control means for stopping the operation of the power conversion means to respond. The control means referred to here is the charge control unit 39 or the discharge control unit 3 in the embodiments described later.
8 or a combination thereof.

In order to achieve the above object, the present invention provides a plurality of power storage devices connected in parallel to each other and a power storage device provided for each of the power storage devices and corresponding to power from a power grid. A charging / discharging control method for a power storage device used in a power storage system, comprising: a power conversion unit that supplies the power from the corresponding power storage device to a load system, and stops charging or discharging of the power storage device. The process of setting the charge or discharge level to be performed for each power storage device, the process of updating the charge or discharge level according to the deterioration state or the usage period of each power storage device, and the charge or discharge state of the power storage device And a step of stopping the operation of the power conversion means corresponding to the power storage device when the charge or discharge level set corresponding to the device is reached. Providing charge and discharge control method of a power storage device to be.

As described above, the power conversion device is provided for each power storage device, and the operation of each power conversion device is controlled according to the charging / discharging state of the power storage device, thereby individually controlling the charging / discharging of the power storage device. You can That is, since the power storage devices are not electrically connected to each other, there is no concern that rush current or the like will flow even if the potential difference between the power storage devices is large. This allows
For example, when starting charging / discharging, charging / discharging can be started at each timing, without considering the voltage difference with another power storage device. Further, at the time of discharging, it is possible to perform control such that necessary electric power is shared according to the capacity of each power storage device.

[0022]

DETAILED DESCRIPTION OF THE INVENTION An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing a schematic configuration of a power storage system 150 according to an embodiment of the present invention. In the figure, a power storage system 150 includes a series battery unit 5 including a power storage device 1 and a battery circuit 11.
While supplying power from the power grid to the power storage device 1,
Electric power conversion device 2 that supplies the electric power of power storage device 1 to the load system
And a charging / discharging control device 3 that drives the power conversion device 2 to control charging / discharging of the power storage device 1.

The power storage device 1 is configured by further connecting a plurality of module batteries, which are configured by directly connecting a plurality of cells (secondary batteries), in series. A lithium ion battery, a nickel cadmium battery, or a nickel hydrogen battery is used as the cell. Then, by connecting a plurality of power storage devices 1 in parallel, a high power storage capacity is realized in the entire power storage system. Further, a switch 6 is provided between each power storage device 1 and the power conversion device 2, and the battery circuit 11 controls the switch 6 to turn on / off the power storage device 1 and the power conversion device 2.
Disconnect from.

The battery circuit 11 includes a cell balance circuit for keeping the battery voltage (remaining capacity) of the cells uniform in order to enhance the reliability and safety of the power storage device 1, as well as overcharge protection and overdischarge of the cells. Each protection circuit for protection, overcurrent protection, overheat protection, etc. is provided. In addition, the battery circuit 11 includes a voltage sensor that detects a voltage of each cell that configures a module battery, a voltage sensor that detects a terminal voltage of the power storage device 1, that is, a voltage sensor that detects a battery voltage of the entire power storage device 1, and a current that flows in the power storage device 1. A current sensor for measurement, a temperature sensor for detecting the temperature of the power storage device, and the like are provided. These various sensors detect a voltage or the like at a predetermined timing and notify the charge / discharge control device 3 of the detection result.

As the cell balance circuit, a well-known cell balance circuit such as a bypass system or a capacitor system can be cited as an example, and the cell voltage at the completion of charging of all cells is suppressed to within 50 mV. This prevents cycle deterioration of the secondary battery. Further, as the protection circuit, a unit monitoring circuit for detecting an abnormality of the secondary battery based on various information transmitted from the voltage sensor or the temperature sensor is provided. The unit monitoring circuit controls the switch 6 interposed between the power storage device 1 and the power conversion device 2 when over-discharging, over-charging, over-heating, over-current or the like is detected based on the above information. Thus, the power storage device 1 is separated from the power conversion device 2, and the power storage device 1 is protected.

Next, the power conversion device 2 generates DC power from the AC power supplied from the power grid, outputs it to the power storage device 1, and generates AC power from the DC power supplied from the power storage device 1. However, it is a so-called bidirectional inverter having a function of supplying to the load system or the power system. The power conversion device 2 includes a plurality of switching elements (for example, thyristor, IGBT, power MOS FE).
The charging / discharging control device 3 performs switching drive of this switching element at a predetermined timing, so that when the power storage device 1 is charged, the AC power from the power grid is rectified to the power storage device 1. It functions as a rectifier that supplies power, and also functions as an inverter that converts the electric power from the power storage device 1 into alternating current and outputs it to a load system or the like during discharge. Also, by changing the duty ratio of this switching on / off, it is possible to increase or decrease the amount of output power in a certain period.

In addition to the general commercial power source, the power system includes wind power generation 50 and fuel cell 5 as shown in FIG.
1, MGT (μ gas turbine) 52, solar power generation 53,
It also includes distributed power sources such as power plant 54. Each of these distributed power sources and the power storage system 1 are connected by a signal line 100, and information such as the power storage state and consumption state of each distributed power source is transmitted via the signal line 100 to the power storage system 150. Will be notified to. Note that the signal line 100 may be any means as long as it can transmit information, and is not particularly limited.

Next, the charge / discharge control device 2 according to the present embodiment.
The configuration will be described with reference to FIG. In the figure, reference numeral 31 is a communication unit that transmits and receives information to and from the battery circuit 11, and reference numeral 32 is a clock unit that counts the usage period of each power storage device 1. Reference numeral 33 is a first storage unit that stores a use period-discharge depth table in which a use period and a discharge depth of the power storage device are associated with each other. Reference numeral 34
Is a second storage unit that stores a power storage device-discharge depth table in which a discharge depth is set for each power storage device that constitutes the power storage system 150.

Reference numeral 35 sets an initial value in the power storage device-discharge depth table stored in the second storage unit 34 based on the use period-discharge depth table stored in the first storage unit 33. It is a setting unit to perform. Reference numeral 36 indicates the set value of the power storage device-discharge depth table stored in the second storage unit 34 based on the use period-discharge depth table and the use period of each power storage device clocked by the clock unit 32. This is an updating unit for updating. Reference numeral 37 is a remaining capacity calculator that calculates the remaining capacity of each power storage device 1 based on the information notified from the battery circuit 11. Reference numeral 38 is a discharge control unit that controls the discharge of each power storage device based on the remaining capacity of each power storage device calculated by the remaining capacity calculation unit 37 and the power storage device-discharge depth table. Reference numeral 39 is
It is a charging control unit that charges each power storage device based on the remaining capacity of the power storage device calculated by the remaining capacity calculation unit 37 until a full charge state is reached.

The clock unit 33 measures the period of use of each power storage device, that is, the period from the time of replacement of the power storage device after installation. Specifically, when the power storage device is replaced, that is, the new power storage device is the power storage system 150.
The period from the time when it is attached to is set as a use period, and when the use period reaches a predetermined period, the setting unit 35 or the updating unit 36 is notified of this. In the present embodiment, the predetermined period of time is two years, four years after installation, and six years after installation.
Years later, eight years later, ten years later.

When a current is flowing in the power storage device 1, the remaining capacity calculation unit 32 obtains the remaining capacity by integrating the current value notified from the battery circuit 11, and the current is stored in the power storage device 1. When not flowing, the remaining capacity is obtained from the open circuit voltage of the power storage device (voltage between terminals when current value = 0). Usually, since the open circuit voltage and the remaining capacity have a correlation, the remaining capacity is obtained by referring to the correlation. Note that the remaining capacity of the power storage device may be calculated by another remaining capacity calculation method instead of such a remaining capacity calculation method.

Next, FIG. 4 shows a use period-discharge depth table stored in the first storage unit 33. As shown in this figure, the shorter the period of use, the higher the depth of discharge is set. This depth of discharge also shortens the life of the power storage device by 10
Since it is the value when set as the year, "53.59055%"
Becomes the final depth of discharge, and when the usage period reaches 10 years, it is replaced with a new power storage device.

Next, FIG. 5 shows an example of the power storage device-discharge depth table stored in the second storage section 34. As shown in this figure, the depth of discharge is set corresponding to each of the power storage devices that form power storage system 150. In the present embodiment, the power storage system 150 is configured by connecting five power storage devices in parallel, and each of these power storage devices is assigned an identification number No. 1 to No. 5.
The depth of discharge is set for each of these power storage devices No. 1 to No. 5. From the power storage device-depth of discharge table shown in FIG. 5, it can be seen that the power storage device No. 1 is the newest and the usage period is long in the order of No. 2, No. 3, No. 4, and No. 5. This is because the usage period is short, so there is little deterioration.For this reason, the depth of discharge is set deep for the power storage device with the largest battery capacity, and the depth of discharge is set shallow for the power storage device that is severely deteriorated due to use and has a small battery capacity. Because it is done.

The first storage unit and the second storage unit are a nonvolatile memory such as a hard disk device, a magneto-optical disk device, a flash memory, or a RAM (Random A).
ccessMemory) such as a volatile memory, or a computer-readable / writable recording medium using a combination thereof. Also, the first
If the recorded contents are known in advance and the contents are not rewritten, such as the storage unit, a readable recording medium such as a ROM may be used. Further, the charge / discharge control device 3 may be connected with peripheral devices such as an input device, a display device, etc. (none of which are shown). Here, the input device refers to an input device such as a keyboard and a mouse.
The display device refers to a CRT (Cathode Ray Tube) display device, a liquid crystal display device, or the like.

Next, the operation of the charging / discharging control device according to this embodiment will be described in order for charging and discharging separately. (1) Operation During Charging (AC → DC) First, during charging, the charging control unit 39 of the charging / discharging control device 3 compares the inter-terminal voltage of each power storage device notified via the communication unit 31, Charging is started from the power storage device having the lowest inter-voltage. That is, the switch 6 that connects the power storage device having the lowest inter-terminal voltage (eg, power storage device No. 1) and the power conversion device 2 is turned on, and then power is supplied to the power storage device (power storage device No. 1). As shown in FIG.
Drive the switching elements in the power converter 2. As a result, the electric power from the electric power system is converted into DC power by the electric power conversion device 2, and charging of the power storage device (power storage device No. 1) having the lowest terminal voltage is started.

Then, as the charging proceeds, the voltage between the terminals of the power storage device (power storage device No. 1) rises, and the voltage with the power storage device having the second lowest voltage between the terminals (eg, power storage device No. 2). When the difference becomes equal to or less than a predetermined value, the charge control unit 39 switches the power storage device (power storage device No. 2) in standby for charging to connect the power storage device (power storage device No. 2) to the power conversion device 2. 6 is turned on and charging of the power storage device is started. In this way, when the voltage difference between the terminal voltage of the power storage device being charged and the terminal voltage of the power storage device waiting to be charged is within a predetermined value, the charging of the power storage device waiting to be charged is performed. To start.

When all of the power storage devices are started to be charged and then the charging is advanced to bring one of the power storage devices into the fully charged state, the charge control unit 39 causes the charged power storage devices to be fully charged. Charging is stopped by turning off the switch 6. In this way, charging is stopped by turning off the switch 6 from the fully charged power storage device. Then, when all the power storage devices are fully charged, the charging control unit 39 ends the charging process. Note that whether or not the battery is in a fully charged state is set in advance with a full charge voltage associated with each power storage device, and the terminal voltage of the power storage device is set to the full charge voltage associated with the power storage device. If it reaches, stop charging. In addition,
Even if the battery is not charged to the fully charged state, the amount of electric power corresponding to the depth of discharge corresponding to the power storage device may be at least charged. This is because the amount of electric power charged in each power storage device can be grasped by integrating the value of the current flowing through each power storage device during charging.

(2) Operation during discharging (DC → AC) Next, the operation of the charge / discharge control device 3 during discharging will be described. During discharging, the discharge control unit 38 of the charge / discharge control device 3 compares the inter-terminal voltage of each power storage device notified via the communication unit 31, and starts discharging from the power storage device having the highest inter-terminal voltage. That is, the switch 6 that connects the power storage device having the highest inter-terminal voltage (eg, power storage device No. 1) and the power conversion device 2 is turned on, and then the power is loaded from the power storage device (power storage device No. 1). The discharge control unit 38 switches and drives the switching elements in the power conversion device 2 so as to be supplied to the grid. As a result, the electric power stored in the power storage device is converted into AC power by the power conversion device 2 and supplied to the load system. As a result, discharging of the power storage device (power storage device No. 1) having the highest terminal voltage is started. At the same time when this discharge starts, the remaining capacity calculation unit 3
7 starts detection of the remaining capacity of the power storage device by current integration, and notifies the discharge control unit 38 of the remaining capacity of the power storage device (power storage device No. 1) at a predetermined timing.

Subsequently, as the discharge progresses, the voltage between the terminals of the power storage device (power storage device No. 1) decreases, and the voltage with the power storage device having the next highest voltage between terminals (eg, power storage device No. 2). When the difference becomes equal to or less than the predetermined value, the discharge control unit 38 turns on the switch 6 of the power storage device (power storage device No. 2) to connect the power storage device (power storage device No. 2) and the power conversion device 2. , The electric storage device is also started to discharge. This makes it possible to prevent an inrush current due to the balance of the battery voltage between the power storage devices.

At the time of discharging, the discharge control unit 38 receives a signal relating to the required power amount from the load system, and controls the driving of the switching elements of the power conversion device 2 in accordance with the required power amount. , Controls the amount of power supplied from the power storage system 150 to the load system.
That is, when the required power amount of the load system is large, the amount of power that can be supplied is increased by lengthening the ON time of the switching element of the power conversion device 2. On the other hand, when the required amount of power is small, the on-time of the switching element is shortened to suppress the amount of power released from the power storage system, so that the stored amount of power is used efficiently.

Further, the discharge control unit 38 controls the discharge of the power storage device based on the required power amount from the load system described above, and at the same time, determines the remaining capacity notified from the remaining capacity calculation unit 37 for each power storage device. It is determined whether or not the discharge depth of the power storage device, which is obtained based on the discharge depth, has reached the discharge depth set in the second storage unit 34. For example, power storage device No. 1
Then, if the depth of discharge reaches the depth of discharge “122.093%” set in the power storage device-discharge depth table, the discharge of the power storage device No. 1 is stopped. This discharge is stopped by turning off the switch 6 of the power storage device No. 1.

Then, the discharge depths of all the power storage devices reach the discharge depths of the power storage device-discharge depth table stored in the second storage section 34, whereby all the power storage devices and the power conversion devices are discharged. When the connection with 2 is disconnected, the discharge control unit 38 ends the discharge process.

(3) Creation / Changing of Power Storage Device-Discharge Depth Table Next, the process of creating / updating the power storage device-discharge depth table stored in the second storage unit will be described. First,
When the setting unit 35 receives the notification that the power storage device has been replaced from the time counting unit 32, the setting unit 35 has an initial value (use period 1 to 2 years) as the depth of discharge corresponding to the replaced power storage device, "122.093." % "Is set. For example, when a notification indicating that the power storage device No. 5 has been replaced is received from the time counting unit 32, “122.093%” is set as the discharge depth corresponding to the power storage device No. 5 in the power storage device-discharge depth table.

In addition, the updating unit 36 indicates the depth of discharge corresponding to the power storage device when the usage period of each power storage device reaches 2 years, 4 years, 6 years, 8 years and 10 years. 1
It is updated based on the use period-discharge depth table stored in the storage unit 33. For example, suppose that the user has now been notified that the usage period of power storage device No. 2 has reached a full four years. In this case, the updating unit 36 uses the usage period 5 to 6 years from the usage period-discharge depth table stored in the first storage unit 33.
We acquired "80.88899%" which is the depth of discharge corresponding to the year,
The depth of discharge of power storage device No. 2 is updated to this depth of discharge. As a result, thereafter, discharge control is performed on the power storage device No. 2 based on the discharge depth “80.88899%” until the usage period reaches 6 years.

In this way, the setting unit 35 and the updating unit 36 create and update the power storage device-discharge depth table according to the usage period of each power storage device, so that the discharge control unit 3
8 makes it possible to perform discharge control according to the deterioration state of the power storage device.

(4) Calculation Method of Discharge Depth Next, a calculation method of the discharge depth in the use period-discharge depth table shown in FIG. 4 will be described. Here, a case will be described in which an electric storage device having an initial capacity of 150% of the rated value and being usable for 70 years at a constant discharge of 10% is set with a depth of discharge according to its deterioration. First, since the deterioration of the power storage device is proportional to the amount of discharged electric power, the one-year deterioration rate a per 1% of the discharged electric power is calculated by the following equation (1). a = (150-70) /70×10=0.1143 (1)

Here, the deterioration rate a is set to be constant regardless of the depth of discharge, and the depth of discharge of the power storage device for a certain period (two years in this embodiment) becomes equal to the battery capacity at the end of the certain period. Set to. At this time, if the battery capacity at the beginning of the period is Dn-1 and the battery capacity at the end is Dn, then Dn
Can be obtained from the following equation (2). a = (Dn-1−Dn) / (Dn × Y) → Dn = Dn−1 / (a × Y + 1) (2) In the above formula (2), Y is a constant period, that is, Y = 2.

As a result, D1 (2 years from the beginning of use;
(1 to 2 years) can be calculated from equation (2) as D1 = 150 / (0.1143 × 2 + 1) = 122.093. The result of calculating D1 to D5 in this way is the depth of discharge shown in FIG.

(5) Verification of Effects of the Present Invention Next, when the discharge depth is kept constant at 70% and the discharge control is performed at a life of 10 years, and when the discharge depth is updated every two years, the discharge control is performed. The effect of performing the charging / discharging control according to the present invention will be verified by comparing with the case.

FIG. 6 is a diagram when the discharge control is performed while keeping the depth of discharge constant at 70%. The broken line shows the battery capacity according to the period of use of the power storage device, and the bar graph shows the discharge capacity. . The integrated value of this bar graph is the total amount of electric power discharged in the power storage device alone. That is, it is the amount of power that the power storage device can supply to the load system before the end of its life. On the other hand, FIG. 7 is a diagram when the discharge depth is updated every two years and discharge control is performed, and the polygonal line shows the battery capacity according to the usage period of the power storage device as in FIG. The bar graph shows the discharge capacity.

Here, when the discharge depth is updated every two years and discharge control is performed (in the case of FIG. 7), about 84% (D1 + D2 + D3 + D4 + D5 / 5) of total electric energy is discharged on an average annual basis. can do. On the other hand, when the discharge control is performed at the constant 70% shown in FIG. 6, the average is 70%. From this, it can be seen that when the depth of discharge is set according to the deterioration of the power storage device, a larger amount of power can be supplied to the load system when viewed from the power storage device alone. Further, the power storage system as a whole must output the required amount of power required by the load system. In this case as well, a case where five power storage devices having the above-mentioned discharge depth set to a constant 70% are connected in parallel and a case where the above-mentioned five power storage devices have different discharge depths (see FIG. 5) are set,
Comparing with the case of performing discharge control, it can be seen that the former average discharge power amount is 70%, while the latter average discharge power amount is 84%. As a result, as a whole system, it is possible to supply electric power more efficiently when the discharge depth of each power storage device is set to a different value and to perform discharge control, and the power of the power storage device can be fully exerted. .

The parts of the charging / discharging device in the first and second embodiments shown in FIGS. 1 and 8 (specifically, the setting part, the updating part, the remaining capacity calculating part, the discharging control part, the charging control) Part)
May be realized by dedicated hardware, respectively, or a program for realizing the functions of these units may be recorded in a computer-readable recording medium and recorded in this recording medium. Various processes may be executed by loading the program into a computer system and executing the program. The “computer system” mentioned here includes an OS and hardware such as peripheral devices.

The "computer-readable recording medium" is, for example, an optical disk such as a CD-ROM or M
It refers to a magneto-optical disk such as O and MD, a magnetic storage medium such as HDD and FD, a portable recording medium such as a semiconductor memory such as a flash memory, and a storage device such as a hard disk built in a computer system. Further, the "computer-readable recording medium" is a volatile memory (RAM) inside a computer system which serves as a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In addition, those that hold the program for a certain period of time are also included.

Further, the above program may be transmitted from a computer system that stores the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the "transmission medium" for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. Further, the program may be a program for realizing some of the functions described above. further,
It may be a so-called difference file (difference program) that can realize the above-mentioned functions in combination with a program already recorded in the computer system.

Although the embodiment of the present invention has been described in detail above with reference to the drawings, the specific configuration is not limited to this embodiment, and includes a design etc. within the scope not departing from the gist of the present invention. Be done.

For example, as another embodiment, as shown in FIG. 8, a power converter is installed corresponding to each power storage device,
The charge / discharge control device 41 may drive the power conversion device according to the charge state or the discharge state of each power storage device. In this way, the power conversion device 2 corresponds to each power storage device.
By including, it becomes possible to perform fine charge / discharge control corresponding to each power storage device. Further, in this case, when charging or discharging is stopped, it is sufficient to stop driving of the power conversion device itself. Therefore, like the power storage system 150 shown in FIG. The switch 6 for controlling the connection with the device 2 can be omitted.

Further, in the configuration shown in FIG. 8, each battery circuit 21 may be provided with a function of controlling charging / discharging of the corresponding power storage device. That is, in the power storage system 150 shown in FIG.
Since only one was provided, the charge / discharge control device 3 centrally performed charge / discharge control of each power storage device 1.
As shown in FIG. 8, the power conversion device 2 is provided corresponding to each power storage device 1 so that the charge / discharge control device 41 controls the battery circuit 21 in a unified manner. It is also possible to omit the installation of the charging / discharging control device 41 by performing the dispersion. In this case, while each battery circuit 21 monitors the charge / discharge state of the power storage device 1 provided corresponding to itself, discharge control based on the depth of discharge and the like is performed by controlling the operation of the power conversion device 2.

In the above-described embodiment, the depth of discharge is set and the discharge of the power storage device is controlled based on this depth of discharge. However, instead of this depth of discharge, the depth of charge is set. By controlling the charging, the amount of power supplied according to the deterioration of the power storage device 1 may be controlled. That is, in the present invention, the discharge depth, charge / discharge control based on the charge depth, charge / discharge control based on the remaining capacity, or
If the amount of electric power supplied from the power storage device to the load system can be changed with the deterioration of the power storage device regardless of the charge / discharge control based on the voltage between terminals, the same as in the present invention regardless of the means for realizing it. It is possible to achieve the effect of.

[0059]

As described above, according to the charge / discharge control device and charge / discharge control method for a power storage device of the present invention, the discharge is controlled based on the discharge level set according to the deterioration of the power storage device. It is possible to supply electric power to the last even for a power storage device that has deteriorated and has a small usage capacity and is near the end of its life. In this way, even for a power storage device that has deteriorated, by setting a discharge level according to the deterioration and performing discharge control based on this discharge level, the power supply capacity of the power storage device is not fully exhausted Can be demonstrated. As a result, it is possible to increase the total amount of electric power that can be extracted during the period of use of one power storage device, while ensuring the determined life.

Further, according to the charge / discharge control device for a power storage device of the present invention, the power storage device having a high terminal voltage of the power storage device is caused to start discharging first, and the voltage between terminals of one power storage device in a discharge standby state is started. And the voltage across the terminals of the power storage device being discharged are within a predetermined value, discharge of one power storage device is started, so inrush current due to the battery voltage balance between power storage devices is prevented. be able to.

Further, according to the charging / discharging control device and the charging / discharging control method for the power storage device of the present invention, the charging is controlled based on the charge level set according to the deterioration of the power storage device. Specifically, for power storage devices with low deterioration and high battery capacity, set the charge level to store as much power as possible so that as much power as possible can be taken out during discharge, and to prevent power storage devices from deteriorating due to use. Along with this, the charge level is updated so that the power to be taken out is gradually reduced. As a result, even for a power storage device that has deteriorated and has a small usage capacity and is about to reach the end of its life, it is possible to store the amount of power corresponding to the deterioration until the end and supply the stored amount of power to the load system during discharging. In this way, even for a power storage device that has deteriorated, the charge level is set according to the deterioration, and charging control is performed based on this charge level, so that the stored power is supplied to the load system during discharge. As a result, it is possible to fully utilize the power supply capacity of the power storage device. As a result, it is possible to increase the total amount of electric power that can be extracted during the period of use of one power storage device, while ensuring the determined life.

Further, according to the power storage system and the charge / discharge control method of the power storage device of the present invention, the power conversion device is provided for each power storage device, and the operation of each power conversion device is performed according to the charge / discharge state of each power storage device. Since the control is performed, it is possible to individually control the charge / discharge of each power storage device. That is, since the power storage devices are not electrically connected to each other, there is no concern that rush current or the like will flow even if the potential difference between the power storage devices is large. Thereby, for example, when charging / discharging is started, charging / discharging can be started at each timing, without considering the voltage difference with another power storage device. Further, at the time of discharging, it is possible to perform control such that necessary electric power is shared according to the capacity of each power storage device.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a power storage system according to an embodiment of the present invention.

FIG. 2 is a diagram for explaining a power system in the same embodiment.

FIG. 3 is a block diagram showing a configuration of a charge / discharge control device in the same embodiment.

FIG. 4 is a diagram showing an example of a usage period-discharge depth table.

FIG. 5 is a diagram showing an example of a power storage device-discharge depth table.

FIG. 6 is a diagram showing changes in battery capacity and total discharge capacity over 10 years when discharging is performed with the depth of discharge set to be constant at 70%.

FIG. 7 is a diagram showing a change in battery capacity and a total discharge capacity in 10 years when the discharge depth is updated every two years and discharging is performed.

FIG. 8 is a diagram showing a configuration of a power storage system according to another embodiment of the present invention.

[Explanation of symbols]

1 power storage device 2 Power converter 3,41 Charge / discharge control device 5,61 Series battery unit 11,21 Battery circuit 31 Communications Department 32 Clock Department 33 First storage unit 34 Second storage unit 35 setting unit (setting means) 36 Update unit (update means) 37 Remaining capacity calculator 38 Discharge control unit (discharge control means) 39 Charge control unit (charge control means) 150,160 Electric power storage system

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hidehiko Tajima 1-1 1-1 Atsunoura-machi, Nagasaki-shi, Nagasaki Mitsubishi Heavy Industries, Ltd. Nagasaki Shipyard (72) Inventor Daisuke Tsukamoto 1-1 1-1 Atsunoura-cho, Nagasaki-shi, Nagasaki Mitsubishi Heavy Industry Co., Ltd. Nagasaki Shipyard (56) References JP 2001-128385 (JP, A) JP 2000-116014 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H02J 7 / 00-7/12 H02J 7/34-7/36 H01M 10/42-10/48

Claims (9)

(57) [Claims] 1. A charging / discharging control device for controlling charging / discharging of a plurality of power storage devices connected in parallel to each other, wherein a setting means for setting a discharge level for stopping the discharge of the power storage devices for each power storage device, Update means for updating the discharge level according to the deterioration state or the period of use of each power storage device, and when the discharge state of the power storage device reaches the discharge level set corresponding to the power storage device, A charge / discharge control device for a power storage device, comprising: a discharge control means for stopping the discharge of the power storage device. 2. The charging / discharging of the power storage device according to claim 1, wherein the discharge level is set such that the power storage device having a higher battery capacity has a higher amount of electric power discharged from the power storage device. Control device. 3. The discharge control means starts discharging first from a power storage device having a high inter-terminal voltage of the power storage device, and at the same time, the inter-terminal voltage of one power storage device in a discharge standby state and the terminal of the power storage device being discharged. The charging / discharging control device according to claim 1 or 2, wherein the discharge of one power storage device is started when the difference from the inter-voltage is within a predetermined value. 4. A charging / discharging control device for respectively controlling charging / discharging of a plurality of power storage devices connected in parallel to each other, and setting means for setting a charge level for stopping charging of the power storage devices for each power storage device, Update means for updating the charge level according to the deterioration state or the period of use of each power storage device, and when the charge state of the power storage device reaches the charge level set corresponding to the power storage device, A charging / discharging control device for a power storage device, comprising: a charge control unit that stops charging of the power storage device. 5. The charge control means starts charging first from a power storage device having a low inter-terminal voltage of the power storage device, and at the same time, the inter-terminal voltage of one power storage device on standby for charging and the terminal of the power storage device being charged. The charging / discharging control device according to claim 4, wherein charging of one power storage device is started when the difference between the voltage and the inter-voltage is within a predetermined value. 6. A charging / discharging control method for controlling charging / discharging of a plurality of power storage devices connected in parallel to each other, comprising a step of setting a discharge level for stopping the discharging of the power storage devices for each power storage device, The process of updating the discharge level according to the deterioration state or the usage period of the power storage device and the power storage device when the discharge state of the power storage device reaches the discharge level set corresponding to the power storage device And a step of stopping the discharge of the electric storage device. 7. A charging / discharging control method for controlling charging / discharging of a plurality of power storage devices connected in parallel to each other, wherein a step of setting a charge level for stopping charging of the power storage devices for each power storage device, The process of updating the charge level according to the deterioration state or the usage period of the power storage device, and when the charge state of the power storage device reaches the charge level set corresponding to the power storage device, the power storage device And a step of stopping the charging of the power storage device. 8. A plurality of power storage devices that are connected in parallel to each other, and are provided for each of the power storage devices, supply power from a power grid to the corresponding power storage devices, and power from the corresponding power storage devices. Is provided to the load system, and a charge / discharge control device that controls the charging / discharging of each power storage device by controlling the operation of each power conversion device, wherein the charge / discharge control device is a power storage device. Setting means for setting the charge or discharge level for stopping the charge or discharge of each of the power storage devices, updating means for updating the charge or discharge level according to the deterioration state or the usage period of each power storage device, When the charge or discharge state reaches the charge or discharge level set for the power storage device,
A power storage system comprising: a control unit that stops the operation of the power conversion unit corresponding to the power storage device. 9. A plurality of power storage devices connected in parallel with each other, and a plurality of power storage devices provided for each of the power storage devices to supply electric power from a power grid to the corresponding power storage devices, respectively. A charging / discharging control method for a power storage device used in a power storage system including power conversion means for supplying power to a load system, wherein a charge or discharge level for stopping charging or discharging of the power storage device is set for each power storage device. The process, the process of updating the charge or discharge level according to the deterioration state or the period of use of each power storage device, and the charge or discharge state of the power storage device that is set corresponding to the power storage device. When you reach the level,
And a step of stopping the operation of the power conversion means corresponding to the power storage device.