JP2016184476A - Power storage system and managing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power storage system suitable for use in cold districts.SOLUTION: A first storage module 10a and a second power storage module 10b which is of a different type from the first power storage module 10a, and has a higher low-temperature characteristic than the first power storage module 10a are connected to each other in parallel. The first power storage module 10a, the second power storage module 10b, a power generation source and a load 3 are connected to a current path 30. A management device 50 prohibits charging to the first power storage module 10a when the detection temperature of the first power storage module 10a is lower than the set lowest charging temperature of the first power storage module 10a.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power storage system and a management device in which a plurality of power storage modules are connected in parallel.

  In recent years, power storage systems using lithium ion batteries have become widespread. The power storage system can be used for backup and peak shift during power outages. In a power storage system, generally, a plurality of power storage modules are connected in parallel to increase the capacity. Lithium ion batteries are widely used in power storage systems because they have high energy density and are suitable for large capacity.

  Patent Document 1 discloses a charging system that sequentially charges a plurality of power storage units.

JP 2010-4627 A

  Lithium ion batteries cannot be charged normally at low temperatures, and are therefore designed not to charge when the temperature falls below a set temperature. When a solar power generation system is connected to a power storage system that uses lithium-ion batteries, the power generated by the solar battery cannot be charged to the lithium-ion battery at low temperatures, and the output of the solar battery must be limited. was there.

  This invention is made | formed in view of such a condition, The objective is to provide the electrical storage system and management apparatus suitable for use in a cold region.

  In order to solve the above problems, a power storage system according to an aspect of the present invention is a first power storage module and a second power storage module that is different in type from the first power storage module and has a lower temperature characteristic than the first power storage module. A second power storage module connected in parallel with the first power storage module, a current path to which the first power storage module, the second power storage module, the power generation source and the load are connected, and a detected temperature of the first power storage module Includes a management device that prohibits charging of the first power storage module when the temperature is lower than the set minimum charging temperature of the first power storage module.

  Another aspect of the present invention is a management device. This device is a first power storage module and a second power storage module that is different in type from the first power storage module and has a lower temperature characteristic than the first power storage module, and is connected in parallel to the first power storage module. A management device to be used for a power storage system comprising a module and a current path to which the first power storage module, the second power storage module, a power generation source, and a load are connected, The temperature of the first power storage module is acquired, and when the temperature is lower than the set minimum charging temperature of the first power storage module, charging to the first power storage module is prohibited.

  According to the present invention, a power storage system suitable for use in a cold region can be realized.

It is a figure which shows the structure (a DC-DC converter is included) of the electrical storage system which concerns on embodiment of this invention. It is a flowchart for demonstrating charging / discharging control (a DC-DC converter is included) of a 1st electrical storage module by the management apparatus which concerns on embodiment of this invention. It is a figure which shows the structure (a DC-DC converter is not included) of the electrical storage system which concerns on embodiment of this invention. It is a flowchart for demonstrating charging / discharging control (a DC-DC converter is not included) of the 1st electrical storage module by the management apparatus which concerns on embodiment of this invention. It is a figure which shows the structure of the electrical storage system which concerns on the modification 1. It is a figure which shows the structure of the electrical storage system which concerns on the modification 2.

  FIG. 1 is a diagram showing a configuration of a power storage system 1 according to an embodiment of the present invention. The power storage system 1 includes a first power storage module 10a and a second power storage module 10b of different types. The first power storage module 10a and the second power storage module 10b are connected in parallel. The first power storage module 10a includes a lithium ion battery 11a and a control unit 12a, and the second power storage module 10b includes a nickel metal hydride battery 11b and a control unit 12b.

  In the present embodiment, a lithium ion battery 11a and a battery having excellent charging characteristics at a lower temperature than the lithium ion battery 11a are used. In the following description, an example in which the nickel metal hydride battery 11b is used as the battery will be described. However, a lead battery or a lithium ion battery having good low-temperature characteristics may be used. An electric double layer capacitor may also be used. The low temperature characteristics are considered to have a large discharge capacity in a low temperature environment and a low minimum temperature that can be input and output.

  The lithium ion battery 11a included in the first power storage module 10a includes a plurality of lithium ion battery cells connected in series or in series and parallel. The controller 12a monitors and controls the lithium ion battery 11a, and includes a voltage detector 121a, a current detector 122a, and a temperature detector 123a. The voltage detector 121a detects each voltage of the plurality of lithium ion battery cells. The current detector 122a detects the current flowing through the lithium ion battery 11a using, for example, a shunt resistor or a Hall element. The temperature detection unit 123a detects the temperature of the lithium ion battery 11a using, for example, a thermistor. The control unit 12 transmits the detected voltage, current, and temperature of the lithium ion battery 11a to the management device 50 via the communication line. The management device 50 is a device that comprehensively manages the power storage system 1.

  The nickel metal hydride battery 11b included in the second power storage module 10b is also composed of a plurality of nickel metal hydride battery cells connected in series or series-parallel. The controller 12b monitors and controls the nickel metal hydride battery 11b, and includes a voltage detector 121b, a current detector 122b, and a temperature detector 123b. The voltage detector 121b detects the voltage of the nickel metal hydride battery 11b. Since nickel-metal hydride batteries do not require strict voltage management in units of cells, it is not necessary to detect voltages in units of cells unlike the lithium ion battery 11a. The current detector 122b detects the current flowing through the nickel metal hydride battery 11b. The temperature detector 123b detects the temperature of the nickel metal hydride battery 11b. The control unit 12b transmits the detected voltage, current, and temperature of the nickel metal hydride battery 11b to the management device 50 via the communication line.

  The system power supply 2 and the load 3 are connected to the current path 30 to which the first power storage module 10a and the second power storage module 10b are connected in parallel. A bidirectional power conditioner 40 is provided on the current path 3 between the system power supply 2 and the first power storage module 10a and the second power storage module 10b. The first power storage module 10a and the second power storage module 10b are connected to the current path 30 on the DC side of the bidirectional power conditioner 40, and the system power supply 2 and the load 3 are connected to the current path 30 on the AC side of the bidirectional power conditioner 40. Connected. Furthermore, the solar power generation device 60 is connected to the current path 30 on the DC side of the bidirectional power conditioner 40.

  The first DC-DC converter 20a and the first switch S1 are inserted between the current path 30 and the first power storage module 10a, and the second DC-DC converter 20b and the second switch S2 are inserted between the current path 30 and the second power storage module 10b. Is inserted.

  The bidirectional power conditioner 40 switches the operation mode according to an instruction from the management device 50. There are a grid connection mode and a self-sustained operation mode for discharging. In the grid connection mode, the bidirectional power conditioner 40 converts direct current power supplied from at least one of the first power storage module 10a, the second power storage module 10b, and the solar power generation device 60 into alternating current power. Output to the AC side of the path 30. At that time, the control circuit for driving and controlling the bidirectional inverter causes the bidirectional inverter to output an alternating current synchronized with the frequency and phase of the alternating waveform supplied from the system power supply 2.

  The self-sustained operation mode is a mode that should be selected at the time of power failure of the system power supply 2. Even in the self-sustained operation mode, the bidirectional inverter converts the DC power supplied from at least one of the first power storage module 10a, the second power storage module 10b, and the solar power generation device 60 into AC power, and generates AC in the current path 30. Output to side 3. At that time, the control circuit outputs an AC voltage having a preset frequency from the bidirectional inverter. Accordingly, an AC voltage can be supplied to the AC side of the current path 30 even during a power failure, and power can be supplied to the load 3 connected to the AC side of the current path 3. At the time of charging, the bidirectional inverter converts AC power supplied from the system power supply 2 into DC power and outputs it to the DC side of the current path 30.

  When the first DC-DC converter 20a receives a discharge instruction from the management device 50, the first DC-DC converter 20a controls to discharge from the first power storage module 10a to the DC side of the current path 30 at a specified discharge rate. In addition, when the first DC-DC converter 20a receives a charge instruction from the management device 50, the first DC-DC converter 20a performs control so that the first power storage module 10a is charged from the bidirectional power conditioner 40 and / or the solar power generation device 60 at a specified charge rate. . The operation of the second DC-DC converter 20b is the same as that of the first DC-DC converter 20a.

  The first switch S <b> 1 receives a control signal from the management device 50 and conducts / non-conducts between the first power storage module 10 a and the current path 30. The first switch S1 can be configured by a relay, for example. The first power storage module 10a and the current path 30 may be made conductive / non-conductive by the operation / non-operation of the first DC-DC converter 20a without providing the first switch S1. In this case, the first DC-DC converter 20a also functions as a switch. Similarly to the first switch S1, the second switch S2 receives the control signal from the management device 50, and conducts / discontinues between the second power storage module 10b and the current path 30.

  A third DC-DC converter 70 is inserted between the current path 30 and the photovoltaic power generator 60. When the third DC-DC converter 70 receives an operation instruction from the management device 50, the third DC-DC converter 70 controls the power generated by the solar power generation device 60 to be output to the direct current side of the current path 30 at a specified rate. In addition, when a stop instruction is received from the management device 50, the photovoltaic power generation device 60 and the current path 30 are electrically disconnected.

  A heater 80 is connected to the AC side of the current path 30 as one of the loads. The heater 80 is provided in the housing of the power storage system 1 and heats the first power storage module 10a. Only the 1st electrical storage module 10a may be heated, and both the 1st electrical storage module 10a and the 2nd electrical storage module 10b may be heated. A third switch S <b> 3 is inserted between the current path 30 and the heater 80. When the detected temperature of the lithium ion battery 11a acquired from the first power storage module 10a becomes lower than the set heating start temperature, the management device 50 controls the third switch S3 to be turned on and operates the heater 80. Further, when the temperature becomes higher than the set heating end temperature, the third switch S3 is controlled to be turned off, and the heater 80 is stopped.

  When the lithium ion battery 11a used in the first power storage module 10a is charged at a low temperature, a dendritic crystal is deposited on the electrode, causing deterioration and problems. Therefore, in the present embodiment, when the temperature of the lithium ion battery 11a is low, the heater 80 is operated to increase the temperature of the lithium ion battery 11a.

  However, at the time of a power failure of the system power supply 2, it is necessary to supply the power of the heater 80 from the battery in the power storage system 1, and the battery capacity supplied to the other loads 3 is reduced. Further, when the lithium ion battery 11a cannot be charged due to low temperature, the power generated by the solar power generator 60 cannot be charged to the lithium ion battery 11a. Therefore, in the present embodiment, these problems are addressed by connecting a nickel-metal hydride battery 11b that is resistant to low-temperature charging in parallel with the lithium ion battery 11a.

  FIG. 2 is a flowchart for explaining charge / discharge control of first power storage module 10a by management device 50 according to the embodiment of the present invention. The parameter used in the charge / discharge control is the temperature value of the lithium ion battery 11a. The management device 50 acquires the temperature value from the control unit 12a of the first power storage module 10a via the communication line.

  First, when the detected temperature of the lithium ion battery 11a is lower than the set minimum discharge temperature (for example, -10.0 ° C.) of the lithium ion battery 11a (Y of S10), the management device 50 turns off the first switch S1. (S15). When a relay is used for the first switch S1, the relay is opened. Thereby, the lithium ion battery 11a is electrically disconnected from the current path 30, and the lithium ion battery 11a is protected.

  When the detected temperature of the lithium ion battery 11a is equal to or higher than the minimum discharge temperature (N in S10), the management device 50 sets the detected temperature and the set minimum charge temperature (for example, 5.0 ° C.) of the lithium ion battery 11a. Are compared (S11). When the detected temperature is equal to or higher than the minimum charging temperature (N in S11), the management device 50 controls the first switch S1 to be on (S13). When a relay is used for the first switch S1, the relay is closed. It is a normal operation, and the lithium ion battery 11 a is controlled to be in conduction with the current path 30. In FIG. 2, control of the first switch S1 by overdischarge, overcharge, and overcurrent is ignored.

  When the detected temperature of the lithium ion battery 11a is lower than the minimum charging temperature (Y of S11), the management device 50 controls the first DC-DC converter 20a to be discharged (S14). Specifically, power conversion from the first power storage module 10a to the current path 30 is permitted, and power conversion from the current path 30 to the first power storage module 10a is prohibited. Instead of controlling the first DC-DC converter 20a to discharge, the first switch S1 may be simply controlled to be off.

  FIG. 3 is a diagram of a configuration in which the first DC-DC converter 20a and the second DC-DC converter 20b are removed from the configuration of the power storage system 1 of FIG. FIG. 4 is a flowchart for explaining charge / discharge control of the first power storage module 10a by the management device 50 of FIG. The parameters used in the charge / discharge control are the temperature value of the lithium ion battery 11a and the current value of the lithium ion battery 11a. The management device 50 acquires the temperature value and the current value from the control unit 12a of the first power storage module 10a via the communication line.

  First, when the detected temperature of the lithium ion battery 11a is lower than the set minimum discharge temperature (for example, -10.0 ° C.) of the lithium ion battery 11a (Y of S10), the management device 50 turns off the first switch S1. (S15). When the detected temperature of the lithium ion battery 11a is equal to or higher than the minimum discharge temperature (N in S10), the management device 50 sets the detected temperature and the set minimum charge temperature (for example, 5.0 ° C.) of the lithium ion battery 11a. Are compared (S11). When the detected temperature is equal to or higher than the minimum charging temperature (N in S11), the management device 50 controls the first switch S1 to be on (S13).

  When the detected temperature of the lithium ion battery 11a is lower than the minimum charging temperature (Y in S11), the management device 50 determines whether the current of the lithium ion battery 11a is in the charging direction or the discharging direction (S12). The direction of the current of the lithium ion battery 11a can be determined based on the current value detected by the current detection unit 122a. The direction of the current of the lithium ion battery 11a is estimated by estimating the current balance of the lithium ion battery 11a based on the power generation amount of the solar power generation device 60, the power consumption amount of the load 3, the charge / discharge amount of the nickel metal hydride battery 11b, etc. You may judge.

  When the current of the lithium ion battery 11a is in the charging direction (Y in S12), the management device 50 controls the first switch S1 to be off (S15), and in the discharging direction (N in S12), the management device 50 sets the first switch S1. Control is turned on (S13). When the second power storage module 10b is being charged and the voltage of the lithium ion battery 11a is higher than the voltage of the nickel metal hydride battery 11b, a charging current flows from the lithium ion battery 11 to the nickel metal hydride battery 11b. In this case, the capacity of the entire power storage system 1 does not increase, and wiring loss and conversion loss in the DC-DC converter occur. Therefore, the first switch S1 is turned off so that no current flows from the lithium ion battery 11a to the nickel metal hydride battery 11b.

  In addition, the structure which removes 1st switch S1 and 2nd switch S2 from the structure of the electrical storage system 1 of FIG. 1 is also possible. In this case, the first power storage module 10a and the current path 30 are made conductive / interrupted not by turning on / off the first switch S1 but by operating / stopping the first DC-DC converter 20a.

  As described above, according to the present embodiment, by providing the nickel metal hydride battery 11b in parallel with the lithium ion battery 11a, the power storage system 1 suitable for use in a cold region can be realized. For example, even when the lithium ion battery 11a cannot be charged at a low temperature during the discharge of the solar power generation device 60, the nickel metal hydride battery 11b can be charged. Therefore, it is not necessary to stop or limit the output of the solar power generation device 60, and the operating rate of the solar power generation device 60 can be increased. In addition, when the power storage system 1 is operating independently due to a power failure, the heater 80 can be supplied with power from the nickel metal hydride battery 11b even when the lithium ion battery 11a cannot be discharged due to low temperatures. Therefore, the heater 80 can heat the lithium ion battery 11a, and can raise the temperature of the lithium ion battery 11a to a temperature at which it can be discharged.

  The present invention has been described based on the embodiments. The embodiments are exemplifications, and it will be understood by those skilled in the art that various modifications can be made to combinations of the respective constituent elements and processing processes, and such modifications are within the scope of the present invention. .

  FIG. 5 is a diagram illustrating a configuration of the power storage system 1 according to the first modification. The power storage system 1 shown in FIG. 5 has a configuration in which the solar power generation device 60 and the third DC-DC converter 70 are removed from the power storage system 1 shown in FIG. The technique according to the embodiment of the present invention can also be applied to the first modification. By providing the second power storage module 10b, it is possible to secure the power supply of the heater 80 during a power failure.

  FIG. 6 is a diagram illustrating a configuration of the power storage system 1 according to the second modification. 1 and 5 show a configuration in which the power storage system 1 is linked to the system power supply 2, but FIG. 4 shows a configuration in which only the photovoltaic power generation apparatus 60 is connected to the grid power supply 2 without being linked. For example, the power storage system 1 according to the modified example 2 can be used for outdoor illumination lamps installed in mountainous areas. In the modification 2, the load 3 is a DC load 3a such as a DC-driven LED illumination. A DC-AC inverter 90 is added in front of the heater 80. If a DC-AC inverter is added in this way, an AC load such as a fluorescent lamp or an AC-driven LED illumination can be used.

  In the configuration in which power cannot be supplied from the system power supply 2 to the heater 80 as in the second modification, it is highly necessary to provide the nickel-metal hydride battery 11b and secure the power supply for the heater 80.

  In the above-described FIGS. 1 and 6, the example in which the solar power generation device 60 is connected to the power storage system 1 has been described. The solar power generation device 60 is an example of a power generation device that generates power based on renewable energy. For example, a power generation device such as a wind power generation device or a micro hydraulic power generation device may be connected to the current path 30b.

  In the above embodiment, an example in which two types of power storage modules are connected in parallel has been described. However, three or more types of power storage modules may be connected in parallel. For example, a power storage module including a lithium ion battery, a power storage module including a nickel metal hydride battery, and a power storage module including a lead battery may be connected in parallel.

  The embodiment may be specified by the following items.

[Item 1]
A first power storage module (10a);
The second power storage module (10b), which is different in type from the first power storage module (10a) and has a lower temperature characteristic than the first power storage module (10a), is connected in parallel to the first power storage module (10a). Two power storage modules (10b);
A current path (30) to which the first power storage module (10a), the second power storage module (10b), a power generation source (2 and / or 60), and a load (3) are connected;
When the detected temperature of the first power storage module (10a) is lower than the set minimum charging temperature of the first power storage module (10a), the management device (50) prohibiting charging to the first power storage module (10a) )When,
A power storage system (1) comprising:
Thereby, the electrical storage system (1) suitable for use in a cold region can be constructed.
[Item 2]
A system power supply (2) is connected to the current path (30) as the power generation source,
The power storage system (1)
A bidirectional inverter (40) is further provided between the system power supply (2) and the first power storage module (10a) and the second power storage module (10b) on the current path (30). The power storage system (1) according to item 1.
Thereby, the electrical storage system (1) connected with the system power supply (2) suitable for use in a cold region can be constructed.
[Item 3]
Item 3. The power generation device (60) according to item 2, further comprising a power generation device (60) connected to the DC side of the bidirectional inverter (40) on the current path (30) based on renewable energy. Power storage system (1).
Thereby, the electrical storage system (1) connected with the system | strain (2) and the electric power generating apparatus (60) suitable for use in a cold region can be constructed | assembled.
[Item 4]
One of the items (1) to (3), wherein a heater (80) for heating the first power storage module (10a) is connected to the current path (30) as one of the loads (3). The electrical storage system as described in (1).
By heating the first power storage module (10a), the first power storage module (10a) can be warmed to a temperature at which the first power storage module (10a) can be charged or discharged.
[Item 5]
The power storage system (1) according to item 1, further comprising a power generation device (60) connected to the current path (30) as the power generation source and configured to generate power based on renewable energy.
Thereby, the electrical storage system (1) connected with the direct current output power generation device (60) suitable for use in a cold region can be constructed.
[Item 6]
The management device (50)
When the detected temperature of the first power storage module (10a) is not less than the set minimum discharge temperature of the first power storage module (10a) and not less than the set minimum charge temperature of the first power storage module (10a), A switch (S1) inserted between the current path (30) and the first power storage module (10a) is turned on;
When the detected temperature of the first power storage module (10a) is equal to or higher than the set minimum discharge temperature of the first power storage module and lower than the set minimum charge temperature of the first power storage module (10a), the first The switch (S1) is controlled to be turned on when the current of the power storage module (10a) is in a charging direction, and the switch (S1) is controlled to be turned off when the current is in a discharging direction. Power storage system (1).
Thereby, the whole electrical storage system 1 can be charged efficiently, protecting the 1st electrical storage module (10a).
[Item 7]
A first power storage module (10a);
The second power storage module (10b), which is different in type from the first power storage module (10a) and has a lower temperature characteristic than the first power storage module (10a), is connected in parallel to the first power storage module (10a). Two power storage modules (10b);
A current path (30) to which the first power storage module (10a), the second power storage module (10b), a power generation source (2 and / or 60), and a load (3) are connected;
A management device (50) to be used in a power storage system (1) comprising:
When the temperature of the first power storage module (10a) is acquired from the first power storage module (10a) and the temperature is lower than the set minimum charging temperature of the first power storage module (10a), the first power storage module A management device (50) characterized by prohibiting charging of the module (10a).
Thereby, the electrical storage system (1) suitable for use in a cold region can be constructed.

  DESCRIPTION OF SYMBOLS 1 Power storage system, 2 system | strain power supply, 3 Load, 3a DC load, 10a 1st electrical storage module, 11a Lithium ion battery, 12a Control part, 121a Voltage detection part, 122a Current detection part, 123a Temperature detection part, 10b 2nd electrical storage module 11b Nickel metal hydride battery, 12b control unit, 121b voltage detection unit, 122b current detection unit, 123b temperature detection unit, 20a first DC-DC converter, 20b second DC-DC converter, S1 first switch, S2 second switch, S3 3rd switch, 30 current path, 40 bidirectional power conditioner, 50 management device, 60 solar power generation device, 70 3rd DC-DC converter, 80 heater, 90 DC-AC inverter.

Claims (7)

A first power storage module;
A second power storage module of a type different from the first power storage module and having a lower temperature characteristic than the first power storage module and connected in parallel with the first power storage module;
A current path to which the first power storage module, the second power storage module, a power generation source, and a load are connected;
A management device that prohibits charging of the first power storage module when the detected temperature of the first power storage module is lower than the set minimum charging temperature of the first power storage module;
A power storage system comprising: A system power supply is connected to the current path as the power generation source,
The power storage system includes:
The power storage system according to claim 1, further comprising a bidirectional inverter between the system power supply and the first power storage module and the second power storage module on the current path.   The power storage system according to claim 2, further comprising a power generation device that generates power based on renewable energy, connected to a direct current side of the bidirectional inverter on the current path.   The power storage system according to any one of claims 1 to 3, wherein a heater for heating the first power storage module is connected to the current path as one of the loads.   The power storage system according to claim 1, further comprising a power generation device that is connected to the current path as the power generation source and that generates power based on renewable energy. The management device
When the detected temperature of the first power storage module is equal to or higher than the set minimum discharge temperature of the first power storage module and equal to or higher than the set minimum charge temperature of the first power storage module, the current path and the first power storage module Control the switch inserted between
When the detected temperature of the first power storage module is equal to or higher than the set minimum discharge temperature of the first power storage module and lower than the set minimum charge temperature of the first power storage module, the current of the first power storage module is charged. The power storage system according to any one of claims 1 to 5, wherein the switch is controlled to be turned on when the direction is set, and the switch is turned off when the direction is set to be discharged. A first power storage module;
A second power storage module of a type different from the first power storage module and having a lower temperature characteristic than the first power storage module and connected in parallel with the first power storage module;
A current path to which the first power storage module, the second power storage module, a power generation source, and a load are connected;
A management device to be used in a power storage system comprising:
Obtaining the temperature of the first power storage module from the first power storage module, and prohibiting charging of the first power storage module when the temperature is lower than the set minimum charge temperature of the first power storage module. Management device characterized.

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