KR20210079021A - Device and method for control ESS - Google Patents

Abstract

According to an embodiment of the present invention, an ESS comprises: a plurality of battery cells; a control unit which controls charging and discharging of the ESS; and a memory in which a power table and a resistance table are stored. The control unit comprises: an SOC calculating unit for calculating an SOC of each of the plurality of battery cells; a temperature measuring unit for measuring a temperature of the ESS; and a maximum input/output power setting unit that sets the maximum input/output power of the ESS. Therefore, the present invention stably controls the ESS by accurately calculating maximum input/output power.

Description

ESS control device and method {Device and method for control ESS}

The present invention relates to an apparatus and method for more stably controlling an ESS.

More specifically, it relates to an apparatus and method for stably controlling an ESS by more accurately calculating the maximum input/output power.

In general electric powered vehicles, plug-in hybrid vehicles, fuel cell vehicles, etc., a high-voltage battery is installed to drive electric power components, and discharge/charge is performed according to the driving/braking state of the vehicle, and the BMS controls the internal temperature and temperature of the high-voltage battery. It monitors the state of charge (SOC) in real time and controls the optimal use area and maximum input/output power through the controller.

The maximum input/output power is changed according to the internal temperature and SOC of the high voltage battery.

Conventionally, the maximum input/output power was set according to the temperature and the average SOC. Since the average SOC value is used to calculate the maximum input/output power, cells having a lower SOC than the average are used (discharged) to a relatively lower range in the discharge state. , in the charged state, a cell having a higher SOC than the average is used (charged) up to a higher range, so there is a problem in that the life of the cell is shortened.

Accordingly, the present invention relates to an apparatus and method for stably controlling an ESS by more accurately calculating the maximum input/output power.

Korean Patent Publication No. 10-2018-0047179 A

The present invention provides an apparatus and method for stably controlling an ESS by more accurately calculating the maximum input/output power.

The ESS according to an embodiment of the present invention is configured to include a plurality of battery cells, a controller for controlling the charging and discharging of the ESS, and a memory in which a power table and a resistance table are stored, and the controller includes a plurality of battery cells for each of the plurality of battery cells. It may be configured to include an SOC calculation unit for calculating SOC, a temperature measurement unit for measuring the temperature of the ESS, and a maximum input/output power setting unit for setting the maximum input/output power of the ESS.

The maximum input/output power setting unit may include: a first maximum input/output power detector configured to detect a first maximum input/output power based on the power table; a second maximum input/output power detection unit configured to detect a second maximum input/output power based on the resistance table; It may be configured to include a third maximum input/output power detector for detecting a third maximum input/output power based on the first maximum input/output power and the second maximum input/output power, and a correction unit for correcting the third maximum input/output power.

The first maximum input/output power detection unit and the second maximum input/output power detection unit detect the first maximum input/output power and the second maximum input/output power based on the minimum SOC and the average temperature when the ESS is discharging, and when the ESS is charging, The first maximum input/output power and the second maximum input/output power may be detected based on the maximum SOC and the average temperature.

The third maximum input/output power detection unit may detect a smaller value of the first maximum input/output power and the second maximum input/output power as the third maximum input/output power.

The compensator detects a battery cell having a maximum voltage from among the plurality of battery cells, and when the voltage of the battery cell having the detected maximum voltage is equal to or greater than a predetermined reference voltage value, adjusts the third maximum input/output power by a predetermined value. It is possible to correct the third maximum input/output power by decreasing it.

The method of setting the maximum input/output power of the ESS according to an embodiment of the present invention includes the ESS state measurement step of measuring the state of the ESS, the maximum input/output power calculation step of calculating the maximum input/output power of the ESS based on the measured ESS state and a maximum input/output power setting step of setting the calculated maximum input/output power to the maximum input/output power of the ESS.

The ESS state measurement step may include an ESS temperature measurement step of measuring the temperature of the ESS, and an SOC measurement step of measuring the SOC of each of a plurality of battery cells constituting the ESS.

The calculating of the maximum input/output power may include a first maximum input/output power detection step of detecting a first maximum input/output power based on a power table, a second maximum input/output power detection step of detecting a second maximum input/output power based on a resistance table, a third maximum input/output power detection step of detecting a third maximum input/output power based on the detected first maximum input/output power and the second maximum input/output power; and a correction step of correcting the third maximum input/output power. have.

In the first maximum input/output power detection step and the second maximum input/output power detection step, when the ESS is discharging, the first maximum input/output power and the second maximum input/output power are detected based on the minimum SOC and the average temperature, and the ESS is being charged. case, the first maximum input/output power and the second maximum input/output power may be detected based on the maximum SOC and the average temperature.

In the detecting of the third maximum input/output power, a smaller value of the first maximum input/output power and the second maximum input/output power may be detected as the third maximum input/output power.

The correction step may include detecting a battery cell having a maximum voltage from among the plurality of battery cells, and setting the third maximum input/output power to a predetermined value when the voltage of the battery cell having the detected maximum voltage is equal to or greater than a predetermined reference voltage value. The third maximum input/output power may be corrected by decreasing by the amount.

The present invention can more accurately calculate the maximum input/output power.

In addition, the present invention can stably control the ESS by more accurately calculating the maximum input/output power.

1 is a view showing an ESS according to an embodiment of the present invention.
2 is a flowchart illustrating a method of setting the maximum input/output power of the ESS according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily carry out the present invention. However, the present invention may be embodied in various different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Terms including an ordinal number, such as first, second, etc., may be used to describe various elements, but the elements are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

Throughout the specification, when a part is said to be “connected” to another part, it includes not only the case where it is “directly connected” but also the case where it is “electrically connected” with another element interposed therebetween. . Also, when a part "includes" a certain component, it means that other components may be further included, rather than excluding other components, unless otherwise stated. As used throughout this specification, the term “step for” or “step for” does not mean “step for”.

The terms used in the present invention have been selected as currently widely used general terms as possible while considering the functions in the present invention, but these may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like. In addition, in specific cases, there are also terms arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

1. ESS according to an embodiment of the present invention.

As described above in the background art, the ESS 10 sets the maximum input/output power. Conventionally, the maximum input/output power is set to the average temperature and the average SOC value of the battery cells, so battery cells having a low SOC are relatively more It discharges a lot, and the life of the battery cell is shortened.

Accordingly, the ESS 10 according to an embodiment of the present invention attempts to solve the conventional problem by more accurately calculating the maximum input/output power.

1 is a diagram showing the configuration of an ESS 10 according to an embodiment of the present invention.

Hereinafter, the ESS 10 according to an embodiment of the present invention will be described with reference to FIG. 1 .

The ESS 10 according to an embodiment of the present invention includes a plurality of battery cells 100 , a controller 300 for controlling charging and discharging of the ESS 10 , and a memory 200 in which a power table and a resistance table are stored. may be included.

1) memory (200)

According to the present invention, the power table 210 and the resistance table 220 are stored in the memory.

1-1) Power table (210)

The power table is a look-up table prepared to detect the maximum input/output power of the ESS according to temperature and SOC as is well known in the prior art.

In other words, the power table 210 is a table storing the maximum input/output power of the ESS according to temperature and SOC.

1-2) resistance table (220)

The resistance table is a lookup table in which the extracted resistance values in the OCV state are stored.

The resistance values stored in the resistance table may be used to calculate a voltage polarization that occurs in a situation where actual charging and discharging occurs.

Specifically, the conventional power table is manufactured based on OCV, and when the maximum input/output power is detected, the first maximum input/output power that does not consider the voltage polarization according to the charging/discharging state is detected.

That is, when the ESS is charging, a voltage polarization in the (+) direction occurs, so that the actual ESS voltage is a higher voltage than the OCV state. In the case of discharging, a voltage polarization in the (-) direction occurs and the actual ESS The voltage of is a state that is smaller than the OCV state, and the first maximum input/output power based on the conventional power table is different from the actual one.

Therefore, in order to detect the maximum input/output power corresponding to the actual state of the ESS, voltage polarization must be reflected.

Accordingly, in the present invention, it is possible to more accurately calculate the second value input/output power by reflecting the voltage polarization generated during actual charging and discharging based on the resistance table.

In the present invention, voltage polarization is calculated using a resistance table to detect the maximum input/output power corresponding to the actual state of the ESS, and the maximum current value is recalculated based on the maximum current value to detect the second maximum input/output power. .

In other words, in the present invention, by calculating the second maximum input/output power reflecting the voltage polarization based on the resistance table, the maximum input/output power corresponding to the actual state of the ESS is set rather than the first maximum input/output power based on the conventional power table. can

The second maximum input/output power calculated in this way may be a value smaller than the first maximum input/output power during charging, and may be a value greater than the first maximum input/output power during discharging.

2) control unit 300

The control unit 300 includes an SOC calculation unit 310 for calculating the SOC of each of the plurality of battery cells 100 , a temperature measurement unit 320 for measuring the temperature of the ESS, and maximum input/output power for setting the maximum input/output power of the ESS It is configured to include a setting unit 330 .

2-1) SOC calculator 310

The SOC calculator 310 may calculate the SOC of each of the plurality of battery cells 100 by using various well-known SOC calculation techniques, such as a cumulative integration method and an OCV-based SOC calculation method.

The calculated SOC of each of the plurality of battery cells 100 is transmitted to the maximum input/output power setting unit 330 .

2-2) Temperature measuring unit 320

The temperature measuring unit 320 measures the temperature of each of the battery cells, and transmits the measured temperature of each of the battery cells to the maximum input/output power setting unit 330 .

2-3) Maximum input/output power setting unit (330)

The maximum input/output power setting unit 330 includes a first maximum input/output power detection unit 331 that detects a first maximum input/output power based on the power table 210, reflecting voltage polarization based on the resistance table 220 A second maximum input/output power detection unit 332 for detecting a second maximum input/output power, a third maximum input/output power detection unit 333 for detecting a third maximum input/output power based on the first maximum input/output power and the second maximum input/output power and a correction unit 334 for correcting the third maximum input/output power.

2-3-1) First maximum input/output power detection unit 331

The first maximum input/output power detection unit 331 and the second maximum input/output power detection unit 332 detect the first maximum input/output power in the power table 210 based on the minimum SOC and the average temperature when the ESS is discharging, and , when the ESS is being charged, the first maximum input/output power may be detected from the power table 210 based on the maximum SOC and the average temperature.

In other words, the first maximum input/output power detection unit 331 detects the first maximum input/output power using the same power table 210 as in the prior art, but detects the first maximum input/output power based on the maximum SOC during charging, During discharge, the first maximum input/output power is detected based on the minimum SOC.

For example, if the ESS is discharging, when discharging is performed by setting the maximum input/output power based on the average SOC, the battery cells with the SOC lower than the average SOC are relatively more than the battery cells with the SOC higher than the average SOC. Since it discharges a lot, there is a high possibility that a battery cell having an SOC lower than the average SOC is damaged.

In other words, since a battery cell having an SOC lower than the average is discharged in the same way as a battery cell having an average SOC, the battery cell having an SOC lower than the average is inevitably damaged.

In order to solve this problem, in the present invention, by setting the maximum input/output power based on the lowest SOC during discharging, it is possible to prevent the battery cell having the lowest SOC from being overdischarged.

On the other hand, when the ESS is being charged and discharge is performed by setting the maximum input/output power based on the average SOC, the battery cells with the SOC higher than the average SOC are charged relatively more than the battery cells with the SOC lower than the average SOC. Therefore, there is a high possibility that a battery cell having an SOC higher than the average SOC is damaged.

In other words, since a battery cell having a higher-than-average SOC is charged in the same manner as a battery cell having an average SOC, the battery cell having a higher-than-average SOC is inevitably damaged.

In order to solve this problem, in the present invention, by setting the maximum input/output power based on the highest SOC during charging, it is possible to prevent the battery cell having the highest SOC from being overcharged.

2-3-2) second maximum input/output power detection unit 332

The second maximum input/output power detection unit 332 calculates the second maximum input/output power to which the voltage polarization is reflected based on the resistance table 220. For example, the second maximum input/output power detection unit 332 may include the Based on the resistance table 220 , the second maximum input/output power may be detected by reflecting the voltage polarization generated during actual charging/discharging.

Specifically, when the ESS is charging, a voltage polarization in the (+) direction occurs, so that the actual voltage of the ESS is a higher voltage than the OCV state. The voltage of the ESS is a state that is smaller than the OCV state, and the first maximum input/output power based on the conventional power table is different from the actual one.

Therefore, in order to detect the maximum input/output power corresponding to the actual state of the ESS, voltage polarization must be reflected.

Accordingly, in the present invention, the second value input/output power can be more accurately calculated by reflecting the voltage polarization generated during actual charging and discharging based on the resistance table.

In other words, by calculating the second maximum input/output power reflecting the voltage polarization based on the resistance table, it is possible to calculate the maximum input/output power corresponding to the actual state of the ESS rather than the first maximum input/output power based on the conventional power table. .

2-3-3) Third maximum input/output power detection unit (333)

The third maximum input/output power detection unit 333 detects a maximum input/output power having a lower value among the first maximum input/output power and the second maximum input/output power calculated by the above-described method.

This is to prevent damage to the battery cells as much as possible by setting the maximum input/output power as small as possible.

2-3-4) Correction unit (334)

The correction unit 334 corrects the third maximum input/output power based on the maximum voltage of the battery cell.

Specifically, a battery cell having the maximum voltage is detected, and when the voltage of the battery cell having the maximum voltage is equal to or greater than a predetermined reference voltage value, the third maximum input/output power is corrected by decreasing the third maximum input/output power by a predetermined value. do.

For example, the predetermined reference voltage value may be the voltage value of the battery cell when the SOC is 100%. In this correction, an error may occur in the process of calculating the SOC of the battery cells. it is for

In other words, by setting the maximum input/output power as low as possible, damage to the battery cells can be prevented as much as possible.

2. A method of setting the maximum input/output power of the ESS according to an embodiment of the present invention.

2 is a flowchart illustrating a method of setting the maximum input/output power of the ESS according to an embodiment of the present invention.

Hereinafter, a method of setting the maximum input/output power of the ESS according to an embodiment of the present invention will be described with reference to FIG. 2 .

The method for setting the maximum input/output power of the ESS according to an embodiment of the present invention includes the ESS state measurement step of measuring the state of the ESS, the maximum input/output power calculation step of calculating the maximum input/output power of the ESS based on the measured ESS state, and the It may be configured to include a maximum input/output power setting step of setting the calculated maximum input/output power to the maximum input/output power of the ESS.

1) ESS status measurement step

The ESS state measurement step may include an ESS temperature measurement step (S100) of measuring the temperature of the ESS and an SOC measurement step (S200) of measuring the SOC of each of a plurality of battery cells constituting the ESS.

2) Maximum input/output power calculation step

The step of calculating the maximum input/output power includes a first maximum input/output power detection step (S300) of detecting a first maximum input/output power based on a power table, and a second maximum input/output power of detecting a second maximum input/output power based on a resistance table The detection step (S400), the third maximum input/output power detection step (S500) of detecting a third maximum input/output power based on the detected first maximum input/output power and the second maximum input/output power (S500), and correcting the third maximum input/output power It may be configured to include a correction step (S600).

2-1) First maximum input/output power detection step (S300)

The first maximum input/output power detection step S300 is a process of detecting the first maximum input/output power of the ESS using the power table.

Specifically, the power table is a look-up table prepared based on the battery cells in the OCV state. On the other hand, the first maximum input/output power detection step S300 is performed based on the minimum SOC and the average temperature when the ESS is being discharged. 1 The maximum input/output power may be detected, and when the ESS is being charged, the first maximum input/output power may be detected based on the maximum SOC and the average temperature.

2-2) 2nd maximum input/output power detection step (S400)

The second maximum input/output power detection step S400 is a process of detecting the second maximum input/output power to which the voltage polarization is reflected using the resistance table.

The resistance table is a look-up table in which resistance values in the OCV state are stored to reflect polarization in a situation where actual charging and discharging occur.

For example, in the detecting of the second maximum input/output power, the second maximum input/output power may be detected by reflecting the voltage polarization generated during actual charging/discharging based on the resistance table.

Specifically, when the ESS is charging, a voltage polarization in the (+) direction occurs, so that the actual voltage of the ESS is a higher voltage than the OCV state. The voltage of the ESS is a state that is smaller than the OCV state, and the first maximum input/output power based on the conventional power table is different from the actual one.

Therefore, in order to detect the maximum input/output power corresponding to the actual state of the ESS, voltage polarization must be reflected.

Accordingly, the second maximum input/output power detection step of the present invention is a process of calculating the voltage polarization using a resistance table to detect the maximum input/output power corresponding to the actual state of the ESS, and reflecting this in the detection of the second maximum input/output power is calculated as

In other words, by calculating the second maximum input/output power reflecting the voltage polarization based on the resistance table, it is possible to detect the maximum input/output power corresponding to the actual state of the ESS rather than the first maximum input/output power based on the conventional power table. .

2-3) 3rd maximum input/output power detection step (S500)

In the third maximum input/output power detection step ( S500 ), a smaller value of the first maximum input/output power and the second maximum input/output power may be detected as the third maximum input/output power.

For example, if the ESS is discharging, when discharging is performed by setting the maximum input/output power based on the average SOC, the battery cells with the SOC lower than the average SOC are relatively more than the battery cells with the SOC higher than the average SOC. Since it discharges a lot, there is a high possibility that a battery cell having an SOC lower than the average SOC is damaged.

In other words, since a battery cell having an SOC lower than the average is discharged in the same manner as a battery cell having an average SOC, the battery cell having an SOC lower than the average is inevitably damaged.

In order to solve this problem, in the present invention, by setting the maximum input/output power based on the lowest SOC during discharging, it is possible to prevent the battery cell having the lowest SOC from being overdischarged.

On the other hand, when the ESS is being charged and discharge is performed by setting the maximum input/output power based on the average SOC, the battery cells with the SOC higher than the average SOC are charged relatively more than the battery cells with the SOC lower than the average SOC. Therefore, there is a high possibility that a battery cell having an SOC higher than the average SOC is damaged.

In other words, since a battery cell having a higher-than-average SOC is charged in the same manner as a battery cell having an average SOC, the battery cell having a higher-than-average SOC is inevitably damaged.

In order to solve this problem, in the present invention, by setting the maximum input/output power based on the highest SOC during charging, it is possible to prevent the battery cell having the highest SOC from being overcharged.

2-4) Calibration step (S600)

In the correction step ( S600 ), the third maximum input/output power is corrected based on the voltage.

Specifically, a battery cell having the maximum voltage is detected, and when the voltage of the battery cell having the maximum voltage is equal to or greater than a predetermined reference voltage value, the third maximum input/output power is corrected by decreasing the third maximum input/output power by a predetermined value. do.

For example, the predetermined reference voltage value may be the voltage value of the battery cell when the SOC is 100%.

This correction is to correct an error occurring in the process of calculating the SOC of the battery cells.

In other words, by setting the maximum input/output power as low as possible, damage to the battery cells can be prevented as much as possible.

On the other hand, when the maximum input/output power is calculated through the above-described steps, this value is set as the maximum input/output power of the ESS, and the ESS is controlled based on this value.

On the other hand, although the technical idea of the present invention has been described in detail according to the above embodiments, it should be noted that the above embodiments are for description and not for limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical spirit of the present invention.

10: energy storage system (ESS)
100: battery cell
200 : memory
210: power table
220: resistance table
300: control unit
310: SOC calculation unit
320: temperature measuring unit
330: maximum input/output power setting unit
331: first maximum input/output power detection unit
332: second maximum input/output power detection unit
333: third maximum input/output power detection unit
334: correction unit

Claims (11)

In the ESS consisting of a plurality of battery cells,
The ESS is
a control unit that controls charging and discharging of the ESS; and
a memory in which a power table and a resistance table are stored;
It consists of
The control unit is
an SOC calculator for calculating an SOC of each of the plurality of battery cells;
a temperature measuring unit that measures the temperature of the ESS; and
a maximum input/output power setting unit that sets the maximum input/output power of the ESS;
ESS, characterized in that it comprises a.
The method according to claim 1,
The maximum input/output power setting unit,
a first maximum input/output power detector configured to detect a first maximum input/output power based on the power table;
a second maximum input/output power detection unit configured to detect a second maximum input/output power based on the resistance table;
a third maximum input/output power detector configured to detect a third maximum input/output power based on the first maximum input/output power and the second maximum input/output power; and
a correction unit for correcting the third maximum input/output power;
ESS, characterized in that it comprises a.
3. The method according to claim 2,
The first maximum input/output power detection unit and the second maximum input/output power detection unit
When the ESS is being discharged, the first maximum input/output power and the second maximum input/output power are detected based on the minimum SOC and the average temperature,
ESS characterized in that when the ESS is being charged, the first maximum input/output power and the second maximum input/output power are detected based on the maximum SOC and the average temperature.
3. The method according to claim 2,
The third maximum input/output power detection unit,
ESS characterized in that the smaller value of the first maximum input/output power and the second maximum input/output power is detected as the third maximum input/output power.
3. The method according to claim 2,
The correction unit,
A battery cell having the maximum voltage is detected from among the plurality of battery cells, and when the voltage of the battery cell having the detected maximum voltage is equal to or greater than a predetermined reference voltage value, the third maximum input/output power is reduced by a predetermined value, ESS, characterized in that for correcting the third maximum input/output power.
In the method of setting the maximum input/output power of the ESS,
ESS state measurement step of measuring the state of the ESS;
a maximum input/output power calculation step of calculating the maximum input/output power of the ESS based on the measured ESS state; and
a maximum input/output power setting step of setting the calculated maximum input/output power to the maximum input/output power of the ESS;
A method of setting the maximum input/output power of the ESS, characterized in that it comprises a.
7. The method of claim 6,
The ESS state measurement step is,
ESS temperature measurement step of measuring the temperature of the ESS;
SOC measuring step of measuring the SOC of each of the plurality of battery cells constituting the ESS;
A method of setting the maximum input/output power of the ESS, characterized in that it comprises a.
7. The method of claim 6,
The step of calculating the maximum input/output power,
a first maximum input/output power detection step of detecting a first maximum input/output power based on the power table;
a second maximum input/output power detection step of detecting a second maximum input/output power based on the resistance table;
a third maximum input/output power detection step of detecting a third maximum input/output power based on the detected first maximum input/output power and second maximum input/output power; and
a correction step of correcting the third maximum input/output power;
A method of setting the maximum input/output power of the ESS, characterized in that it comprises a.
9. The method of claim 8,
The first maximum input/output power detection step and the second maximum input/output power detection step include
When the ESS is being discharged, the first maximum input/output power and the second maximum input/output power are detected based on the minimum SOC and the average temperature,
When the ESS is being charged, the method for setting the maximum input/output power of the ESS, characterized in that the first maximum input/output power and the second maximum input/output power are detected based on the maximum SOC and the average temperature.
9. The method of claim 8,
The third maximum input/output power detection step includes:
The maximum input/output power setting method of the ESS, characterized in that detecting a smaller value of the first maximum input/output power and the second maximum input/output power as the third maximum input/output power.
9. The method of claim 8,
The correction step is
A battery cell having the maximum voltage is detected from among the plurality of battery cells, and when the voltage of the battery cell having the detected maximum voltage is equal to or greater than a predetermined reference voltage value, the third maximum input/output power is reduced by a predetermined value, A method of setting the maximum input/output power of the ESS, characterized in that the third maximum input/output power is corrected.

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