KR20130071957A - Apparatus for battery management using battery's state of health and method thereof - Google Patents

Abstract

PURPOSE: A battery maintenance apparatus is provided to extend lifetime of a battery, to minimize effect for repairing battery, and to efficiently operate a battery. CONSTITUTION: A battery maintenance apparatus (1) selectively controlling use of a battery according to degree of battery degradation comprises switches (14) which is electrically connects or blocks a batter assembly unit (100); a unit battery maintenance part (11) which calculates degradation of a battery; and a master battery maintenance part (12) which connects a battery assembly unit with a low degree of degeneration, through connection of the switch, after comparing degradation of each battery, by receiving the degree of degeneration. [Reference numerals] (11,AA,BB,CC) Unit battery maintenance apparatus; (12) Master battery maintenance apparatus; (DD) Inverter

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery management apparatus and a battery management method using a degradation degree of a battery,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery management apparatus and a battery management method, and more particularly, to a battery management apparatus and a battery management method for connecting a battery to a system in priority order according to a sequence of battery degradation measured in the battery system.

The battery system is a power source that supplies and stores idle power, and a power source that supplies stored power when needed. A battery system is installed in an energy storage system (Smart Grid or Micro Grid) to control the storage and supply of power.

The battery system is composed of a battery assembly. The battery assembly includes a cell as a minimum unit of power storage and supply, a battery module as an aggregate of a plurality of cells, a battery pack as an aggregate of a plurality of modules, A battery system composed of packs constitutes a battery plant. Of course, as the physical connection of the battery assembly unit increases, high capacity and high voltage power storage and supply becomes possible.

Usually, the battery system begins to degenerate after a period of time since the initial installation. A battery having a relatively low degradation degree has a relatively large storage capacity, while a battery having a relatively high degradation degree has a small storage capacity. Batteries whose degeneracy is above the threshold are no longer usable due to degraded performance and need to be replaced.

On the other hand, when the battery system is composed of a plurality of battery packs, the degradation degree of each battery pack varies with time. Even if a battery pack having the same specifications, the electrochemical reactions occurring inside are not completely the same. Therefore, if the operating time of the battery system is prolonged, the deviation of the electrochemical reaction is accumulated, and the degradation between the battery packs becomes different. Also, in the case of operating the battery system, even when all the battery packs constituting the system are not used at the same time and only a part of the battery packs are used, degradation among the battery packs also becomes a cause of accelerating the variation.

When a degradation degree deviation occurs between a plurality of battery packs constituting a battery system, the overall performance of the battery system deteriorates and the life span is reduced. Particularly, a battery pack having a higher degree of degradation progresses more rapidly in performance, so that a battery pack with a high degree of degradation deteriorates the overall performance of the battery system. Therefore, in order to use the battery system for a long time safely, there is a need for a selective management method of the battery considering the degradation degree of the battery.

It is an object of the present invention to provide a battery management apparatus and a battery management method for controlling the use of a battery selectively in accordance with the degradation degree of the battery in a battery system.

It is another object of the present invention to provide a battery management apparatus and a battery management apparatus for connecting switches in units of individual batteries and comparing the degree of degradation measured for each individual battery unit so as to preferentially connect switches having a low degradation degree, Method.

According to an aspect of the present invention, there is provided a battery management apparatus for controlling grid connection in accordance with an order of degradation of a battery set unit, the battery management apparatus comprising: A switch for electrically connecting or disconnecting the battery aggregation unit to the system; A switch control unit for applying an on or off signal to the switch; A unit battery management unit for measuring a degradation state for each battery set unit to calculate a degradation degree; And a master battery management unit for receiving the degree of degradation from at least one or more unit battery management units and comparing the degree of degradation of each battery and controlling the switch control unit to first connect the battery set units in descending order of degeneration to the system, .

In the present invention, the battery aggregation unit includes a plurality of battery elements.

Here, the battery element may include: a battery cell that receives and stores external power and supplies stored power to the outside; A battery module corresponding to an assembly of a plurality of battery unit cells; A battery pack corresponding to a plurality of battery unit modules; A battery system corresponding to an aggregate of a plurality of battery packs; And a battery plant corresponding to an aggregate of a plurality of battery systems, or a combination thereof.

According to an aspect of the present invention, the unit battery management unit uses at least one of internal resistance, temperature, output voltage, open-circuit voltage, charging / discharging current, and storage capacity for each battery element constituting a battery aggregation unit And calculates the degeneration degree of the battery set unit.

Here, the unit battery management unit calculates an average value of degrees of degradation for each battery element as a degradation rate of the battery set unit.

Further, the unit battery management unit has a switch control function for applying an on or off signal to the switch, and receives a connection control signal output from the master battery management unit to apply on or off control of the switch.

Here, the battery management apparatus further includes a switch control unit for applying an on or off signal to the switch, and the switch control unit receives a connection control signal output from the master battery management unit and applies on or off control of the switch .

According to another aspect of the present invention, there is provided a method of managing a battery using a degeneration degree of a battery, the method comprising the steps of: (a) measuring a degradation state of a battery set unit corresponding to each unit battery management unit and calculating a degree of degradation; (b) receiving a degree of degradation from the at least one unit battery management unit by the master battery management unit; (c) comparing the degree of degradation received by the master battery management unit to determine a degree of degradation of the battery group unit; (d) the master battery management unit outputting a connection control signal of a corresponding battery aggregation unit in a predetermined order; And (e) a physical connection of a corresponding switch is switched to a connection by a connection control signal to preferentially connect the corresponding battery aggregation unit to the system.

According to the present invention, after degradation degree of each battery is compared, individual batteries are first connected to the system in order of decreasing degree of degradation, so that battery life can be extended and maintenance can be minimized, thereby enabling efficient operation of the battery.

The following drawings attached to this specification are illustrative of preferred embodiments of the present invention, and together with the detailed description of the invention to serve to further understand the technical spirit of the present invention, the present invention is a matter described in such drawings It should not be construed as limited to.
FIG. 1 is a diagram illustrating a technology model in which a battery management apparatus according to an exemplary embodiment of the present invention connects a battery having a low degree of degradation to a system with priority.
2 is a diagram illustrating an example of a battery set unit according to an embodiment of the present invention.
3 is a schematic circuit diagram of a battery management apparatus according to an embodiment of the present invention.
4 is a schematic internal structure diagram of a battery management apparatus according to another embodiment of the present invention.
5 is a schematic flowchart of a battery management method according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

<1. System configuration>

1 is an exemplary view of a technology model in which a battery management apparatus 1 according to an embodiment of the present invention connects a battery having a low degree of degradation to a system in priority.

The battery management apparatus 1 according to an embodiment of the present invention measures the degree of degradation of individual batteries. Assuming that the unit of the battery is a cell unit, it is assumed that battery cell 1 has the lowest degradation degree among the three battery cells 101, and degradation degree is low in the order of battery cell 3 and battery cell 2. Under the above assumption, the battery management apparatus 1 determines that the battery cell 1 has the best battery performance and the battery cell 2 has the worst performance after measuring the degradation degree of the three battery cells 101.

The battery management apparatus 1 preferentially connects the switch 14 of a battery having a low degradation degree when the battery cell 101 is selected according to the amount of power required for charging or discharging. That is, the battery management device 1 connects the battery cell 1 to the system in order of degradation, and sequentially connects the battery cell 3 and the battery cell 2 to the system according to the required amount of power. Here, the connection to the system means that the battery is used for charging or discharging.

Therefore, the frequency of use is reduced because the battery cell 2 is selected as the third battery cell 2 last in accordance with the amount of electric power. On the other hand, when the battery is used in an arbitrary order without considering the degree of degradation, since the battery cell 2 having a high degree of degradation can be selected as the first or second battery cell, the frequency of use can be relatively increased. When the frequency of use of the battery cell 2 is increased, the degree of degradation is accelerated and the replacing time is also increased accordingly. In addition, since the battery cell 2 has a small power capacity with a high degree of degradation, when it is preferentially selected, more batteries are required to meet the required amount of power. For example, when the required power amount is 4, the power capacity of the battery cell 1 is 5, the power capacity of the battery cell 2 is 3, and the power amount of the battery cell 3 is 4, the battery cell 1 or the battery cell 3 is selected first , Only one battery can be used because the required power amount 4 is satisfied. On the other hand, when the battery cell 2 is first selected, two batteries are required in accordance with the additional connection of the battery cell 1 or the battery cell 3 in order to satisfy the required power amount 5.

However, since the battery management apparatus 1 first uses the battery cell 1 having a large power capacity based on the degree of degradation, and then uses the batteries in the order of the battery cell 3 and the battery cell 2, a relatively small number of batteries It is possible to supply necessary amount of electric power. Further, since the use of the battery 2 having a high degree of degradation is excluded as much as possible, the replacement timing of the battery 2 can be delayed. As a result, it is possible to maximize the available battery resources while reducing the manpower and the cost of maintenance for battery replacement.

On the other hand, the degradation degree measured by the battery management device 1 can be defined as SOH (State of Health) of the battery. SOH is a parameter that quantitatively shows changes in the capacity characteristics of a battery due to the aging effect, and it shows how much the battery capacity has deteriorated. Therefore, a battery having a low degree of degradation has a high SOH value, so it is a battery that can be used for a long time. A battery having a high degree of degradation means a battery having a low SOH value. In addition, if the SOH is known, the battery can be replaced at an appropriate time, and the overcharge and over discharge of the battery can be prevented by controlling the charge / discharge capacity of the battery according to the duration of the battery.

As one example, since the change in the battery capacity characteristic is reflected in the change in the internal resistance of the battery, the SOH can be estimated by the internal resistance and temperature of the battery. That is, the capacity of the battery is measured by the internal resistance of the battery and the temperature by the charge / discharge test. A look-up table for SOH mapping is then obtained by relative quantification of the measured capacity based on the initial capacity of the battery. Then, the SOH of the battery can be estimated by measuring the internal resistance and temperature of the battery in an actual battery use environment and mapping the SOH corresponding to the internal resistance and the temperature from the lookup table.

However, what is most important in the above SOH estimation method is how accurately the internal resistance of the battery can be obtained. However, it is practically impossible to directly measure the internal resistance of the battery during charging / discharging of the battery. Therefore, the internal resistance of the battery is indirectly calculated by Ohm's law by measuring the voltage and charge / discharge current of the battery.

Other examples of SOH estimation methods include a full discharge test, a chemical test, and an ohm test. The full discharge test estimates the SOH by measuring the capacity of the battery cell by discharging the fully charged battery cell to the end. The chemical test estimates the SOH by measuring the substrate corrosion of lead acid batteries and the electrolyte concentration. Ohm test estimates SOH by measuring resistance, conductance and impedance.

As another example of the SOH estimation method, there is a method of estimating the SOH of the battery using SOC (State Of Charge) which is a parameter indicating the remaining capacity of the battery. This method estimates the SOC (State Of Charge) of the battery by integrating the charge / discharge current of the battery and estimates the SOH using the estimated SOC.

As another example of the SOH estimation method, there is a method of using the integrated current value by SOH obtained from the current integration experiment of the battery which knows the actual degradation degree in SOH estimation. In this method, the voltage and current of the battery are measured in a predetermined charging voltage range, and then the accumulated current of the SOH obtained from the ampere counting experiment of the battery, The value is stored in advance. The SOH value corresponding to the accumulated current value is mapped from the cumulative current value by the stored SOH (State Of Health) to calculate the accumulated current value by accumulating the stored current measurement value in the charging voltage section, .

In the present invention, various methods such as the internal resistance utilization method, the test utilization method, the SOC utilization method, and the integrated current value utilization method may be used in the method of calculating the degree of degradation, and the method is not limited to a specific method. Accordingly, it should be apparent to those skilled in the art that various modifications may be made to the method of measuring the degeneration degree of the battery.

2 is a diagram illustrating an example of a battery set unit according to an embodiment of the present invention.

According to the present invention, the battery can be divided into a battery set unit 100 constituting the inside of the battery. The battery set unit 100 is composed of a plurality of battery elements. The minimum unit of the battery element is the battery cell 101. Here, the battery cell is a unit cell including an anode, a cathode, and a separator, and is a minimum unit of electric power storage and supply. When a plurality of battery cells 101 are connected to each other to form an aggregate, they become units of the battery module 102. When a plurality of battery modules 102 are connected to each other to form an aggregate, the battery pack 103 becomes a battery pack. When a plurality of battery packs 103 are connected to each other to form an aggregate, the battery system 104 becomes a battery system. Individual battery aggregation units and any combination thereof constitute a battery assembly.

The battery system 104 corresponds to a large battery system 104 to which the present invention is applied and is a minimum unit that can be installed in a smart grid (micro grid) area. When the plurality of battery systems 104 are connected to each other, the battery 105 becomes a battery plant 105. Of course, the battery plant 105 is the power source that holds the largest capacity and voltage.

The battery management apparatus 1 according to the present invention includes a battery cell 101 corresponding to the battery element of the battery aggregation unit 100, a battery module 102, a battery pack 103, a battery system 104, (105), and a combination thereof, the degradation degree is compared for each lower battery unit, and the battery unit having a low degree of degradation is first connected to the system, thereby improving the efficiency of battery use and minimizing maintenance.

1, the connection unit of the battery is shown as the battery cell 101. However, the actual connection unit is not limited to the battery cell 101 but also the battery module 102, the battery pack 103, Battery system 104 and battery plant 105, or any combination thereof, as would be apparent to those skilled in the art.

3 is a schematic circuit diagram of a battery management device 1 according to an embodiment of the present invention.

The battery management apparatus 1 according to an exemplary embodiment of the present invention may include a unit battery manager 11 and a unit battery manager 11 that calculate a degree of degeneration of a battery assembly unit 100 including a plurality of battery cells 101. The first battery manager 12 and the master battery manager 12 which are connected to the system by comparing the deterioration degree of the received battery set unit 100 and preferentially connect the battery set unit 100 having a low degeneration degree to the grid are first connected. It is configured to include a switch 14 for electrically connecting the battery assembly unit 100 by the connection control signal of the battery assembly unit 100.

The unit battery management unit 11 is connected to each individual battery aggregation unit 100 to measure the degree of degradation of the battery aggregation unit 100. Then, the unit battery management unit 1 transmits the calculated degree of degradation to the master battery management unit 12.

Here, the unit battery management unit 11 calculates at least one of the measurement factors such as the internal resistance, the temperature, the output voltage, the open-circuit voltage, the charge / discharge current, and the storage capacity for each individual battery element constituting each battery aggregation unit 100 And the state of degeneration of the battery is calculated as the SOH value. Furthermore, the unit battery management unit 11 may calculate the average value of the degree of degradation measured from the plurality of battery elements constituting the battery aggregation unit 100 as the SOH value.

The master battery management unit 12 performs charging or discharging control for n (n &gt; = 1) battery aggregation units 100 according to the required power amount. The master battery management unit 12 receives degradation degrees of the individual battery aggregate units 100 from at least one or more unit battery management units 11. Then, the master battery management unit 12 compares the degrees of degeneration of the received battery cells and outputs a connection control signal of the battery set unit 100 in the order of decreasing degrees according to the amount of power required. Here, the connection control signal includes a control signal for connecting or disconnecting the switch 14. [

Therefore, the master battery management unit 12 preferentially uses the battery aggregation unit 100 having a low degradation degree. That is, the frequency of use decreases as the battery set unit 100 having a relatively high degree of degradation. Therefore, the degradation acceleration of the entire battery aggregation unit 100 is significantly lowered, and the battery life is naturally extended.

The switch 14 is provided for each battery pack unit 100 and performs connection and disconnection of the battery pack unit 100 by the output of the connection control signal. When the switch 14 is connected, the battery aggregate unit 100 is connected to the system and is in an in-use state.

Here, the switch 14 may receive the connection control signal through the unit battery management unit 11. [ That is, the switch 14 connects or disconnects the battery set unit 100 to the system by receiving the connection control signal output from the master battery management unit 12 as an ON or OFF signal through the unit battery management unit 11 .

The individual switch 14 can be any known switch means known to be capable of controlling the electrical connection of wiring such as a semiconductor switch or a mechanical relay switch.

4 is a schematic internal structure of a battery management device 1 according to another embodiment of the present invention.

The battery management apparatus 1 according to another embodiment of the present invention further includes a switch control unit 13 in the battery management apparatus 1 of FIG. The battery pack unit 100 of the battery management device 1 is assumed to be a battery rack 106 in which a plurality of battery cells 101 are connected to a battery tray.

The unit battery management unit 11 is connected to the individual battery rack 106 and calculates the degree of degradation of the individual battery rack 106. [ The unit battery management unit 11 transmits the calculated degree of degradation to the master battery management unit 12. The master battery management unit 12 compares the degree of degradation collected from each of the unit battery management units 11 to select the battery racks 106 in descending order of degree of degradation, And controls the connection of the corresponding switch 14 so that the switch 106 is used first.

Here, the switch control unit 13 receives a switch connection control signal of the battery set unit 100 connected first from the master battery management unit 12. The switch control unit 13 controls the switch 14 according to the connection control signal to preferentially connect the battery rack 106 to the system.

<2. Method composition>

The battery management method using the degree of degradation of the battery according to an embodiment of the present invention can be preferably realized by constructing the battery management apparatus 1 described above.

5 is a schematic flowchart of a battery management method according to an embodiment of the present invention.

First, the unit battery management unit 11 calculates the degeneration degree of the corresponding battery aggregate unit 100 (S11). The degree of degeneration is already described as an SOH value of the battery, in which the internal resistance and the storage capacity of the battery element constituting the battery aggregation unit 100 are used and various calculation methods can be applied.

When the degradation degree is calculated, the master battery management unit 12 receives degradation degrees of the individual battery aggregate units 100 from at least one unit battery management unit 11, thereby collecting degradation degrees of the batteries to be controlled as a whole S12).

After the individual degree of degradation is collected, the master battery management unit 12 compares the degree of degradation and aligns the identification information of the battery set unit 100 in order of decreasing degree of degradation (S13). Then, the order of connection of the battery set units 100 to be preferentially used is determined by the ordering.

When the order of degradation is determined, the master battery management unit 12 outputs a switch control signal to the unit battery management unit 11 to which the battery set unit 100 of the order is connected first (S14).

When the switch control signal is output, the unit battery management unit 11 connects the corresponding switch 14 to connect the battery aggregation unit 100 to the system (S15).

According to the present invention, after degradation degree is compared for each battery aggregation unit 100, the battery aggregation unit is first connected to the system in order of decreasing degree of degradation, thereby minimizing extension of battery life and maintenance, This is possible.

In the above-described embodiment, the term "part" is not used as a term meaning a hardware classification of the battery management device. Accordingly, a plurality of constituent parts may be integrated into one constituent part, and one constituent part may be divided into a plurality of constituent parts. Also, the constituent unit may mean a hardware constituent unit, but may mean a constituent unit of software. Therefore, it should be understood that the present invention is not particularly limited by the term "part ".

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It goes without saying that various modifications and variations are possible within the scope of equivalence of the scope.

1: Battery management device 11: Unit battery management section
12: master battery management unit 14: switch
100: Battery set unit

Claims (13)

A battery management apparatus for controlling system connection in priority order in accordance with a degeneration degree of a battery set unit,
A switch connected to the battery set unit to electrically connect or disconnect the battery set unit to the system;
A unit battery management unit for measuring a degradation state for each battery set unit to calculate a degradation degree; And
A master battery management unit for receiving the degree of degradation from at least one or more unit battery management units to compare the degree of degradation and for connecting the battery set units in descending order of degradation degree to the system first,
The battery management apparatus comprising: The method of claim 1,
Wherein the battery set unit includes a plurality of battery elements. The method of claim 2,
Wherein the battery element comprises:
A battery cell receiving and storing external power and supplying the stored power to the outside;
A battery module corresponding to an assembly of a plurality of battery unit cells;
A battery pack corresponding to a plurality of battery unit modules;
A battery system corresponding to an aggregate of a plurality of battery packs; And
Battery plant corresponding to a collection of plural battery systems
And the battery management apparatus according to any one of claims 1 to 3, 4. The method according to any one of claims 1 to 3,
The unit battery management unit includes:
Wherein the degree of degradation of the battery set unit is calculated using at least one of internal resistance, temperature, output voltage, open-circuit voltage, charge / discharge current, and storage capacity for each battery element constituting the battery set unit Management device. 5. The method of claim 4,
The unit battery management unit includes:
And calculates an average value of degrees of degradation for each of the battery elements as a degradation rate of the battery set unit. 3. The method according to claim 1 or 2,
The unit battery management unit includes:
And a switch control function for applying an on or off signal to the switch, and receives a connection control signal output from the master battery management unit to apply on or off control of the switch. 3. The method according to claim 1 or 2,
And a switch control unit for applying an on or off signal to the switch,
Wherein the switch control unit receives the connection control signal output from the master battery management unit and applies the ON or OFF control of the switch. A battery management method in which a battery management apparatus controls a system connection of a battery in priority order in accordance with an order of degradation of a battery set unit,
(a) measuring a degradation state of a battery set unit corresponding to each unit battery management unit and calculating a degree of degradation;
(b) receiving a degree of degradation from the at least one unit battery management unit by the master battery management unit;
(c) comparing the degree of degradation received by the master battery management unit to determine a degree of degradation of the battery group unit;
(d) the master battery management unit outputting a connection control signal of a corresponding battery aggregation unit in a predetermined order; And
(e) a physical connection of the corresponding switch is switched to connection by a connection control signal, and the corresponding battery aggregation unit is preferentially connected to the system
Battery management method comprising a. The method of claim 8,
Wherein the battery set unit includes a plurality of battery elements. The method of claim 9,
Wherein the battery element comprises:
A battery cell receiving and storing external power and supplying the stored power to the outside;
A battery module corresponding to an assembly of a plurality of battery unit cells;
A battery pack corresponding to a plurality of battery unit modules;
A battery system corresponding to an aggregate of a plurality of battery packs; And
Battery plant corresponding to a collection of plural battery systems
The battery management method comprising the steps of: 11. The method according to any one of claims 8 to 10,
The step (a)
Wherein the degree of degradation of the battery set unit is calculated using at least one of internal resistance, temperature, output voltage, open-circuit voltage, charge / discharge current, and storage capacity for each battery element constituting the battery set unit Battery management method. 12. The method of claim 11,
The step (a)
Wherein an average value of degrees of degradation for each battery element is calculated as a degradation rate of a battery set unit. 10. The method according to claim 8 or 9,
The step (e)
The unit battery management unit receiving a connection control signal output from the master battery management unit and applying control of on or off of the switch;
And a step of the switch control unit receiving a connection control signal output from the master battery management unit and applying on or off control of the switch.

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