KR20200059966A - Apparatus and method for low-voltage battery rack management - Google Patents

Abstract

According to an embodiment of the present invention, provided is an energy storage system in which two or more battery racks are formed to be connected in parallel to a parallel line and which is configured to comprise a battery section controller (BSC) determining whether the two or more battery racks are connected to the parallel line. Each of the two or more battery racks includes a rack battery management system controlling a plurality of battery modules, and a switch connecting the battery rack to the parallel line. The BSC can determine whether each of the battery racks is connected to the parallel line based on a power limitation value of each of the two or more battery racks.

Description

ESS Apparatus and method for low-voltage battery rack management}

The present invention relates to an apparatus and method for managing a battery rack having a low voltage in the ESS.

Recently, due to exhaustion of fossil energy and environmental pollution caused by the use of fossil energy, interest in electric products that can be driven using a secondary battery has increased. Accordingly, technology development for mobile devices, electric vehicles (EVs), hybrid vehicles (HVs), energy storage systems (ESSs), and uninterruptible power supplies (UPS), etc. As demand and demand increase, the demand for secondary battery batteries as an energy source is rapidly increasing.

These secondary battery batteries have attracted attention as a new energy source for eco-friendliness and energy efficiency enhancement, in that they not only generate by-products due to the use of energy, as well as a primary advantage that can dramatically reduce the use of fossil energy.

In particular, secondary battery batteries used in electric vehicles, hybrid vehicles, energy storage systems, and uninterruptible power supplies are configured by connecting a plurality of battery racks including a plurality of battery modules to charge or discharge high-power and large-capacity power. As described above, in order to prevent overdischarge of the battery racks, the battery racks connected to the plurality of batteries were set with the power limit value of the ESS based on the battery rack having the lowest power limit value.

However, when setting the power limit of the ESS based on the battery rack having the lowest power limit value as described above, the other battery rack has a sufficient power limit value, but the power limit value of the entire ESS system is lowered, so the efficiency of the ESS is lowered. There was a falling issue.

As a conventional technique for solving this problem, there is Korean Patent Application Publication No. KR 2015-0098555 A.

In the prior art, there has been a technology that selects abnormally operating battery racks through individual battery rack breakage prevention devices connected to the battery racks and individually blocks them to use the entire battery for a longer time.

However, in the prior art, there was a disadvantage in that a section in which the entire power limit value of the ESS instantaneously bounces at the moment of breaking the abnormal battery rack.

Therefore, the present invention proposes an apparatus and method for stably controlling the total power limit value of the ESS when a battery rack having a low voltage occurs.

Korean Patent Publication KR 2015-0098555A

The present invention provides an apparatus and method for stably controlling the ESS total power limit value when a battery rack having a low voltage occurs.

One energy storage system formed by connecting two or more battery racks to a parallel line according to an embodiment of the present invention includes a battery section controller (BSC) for determining whether to connect to the parallel line for each of the two or more battery racks Can be configured.

Each of the two or more battery racks may include a plurality of battery modules, a rack battery management system (RBMS) controlling the plurality of battery modules, and a switch connecting a battery rack to the parallel line.

The BSC may determine whether to connect to a parallel line for each of the battery racks, based on the power limit value of each of the two or more battery racks.

The BSC is a first system power limit value, which is a system limit value calculated by excluding a battery rack having the lowest power limit value among the two or more battery racks, and a second system that is a system limit value calculated for both of the two or more battery racks. The system may include a system power limit value calculation unit for calculating the power limit value, and a comparison unit for comparing the first and second system power limit values calculated by the system power limit value calculation unit.

As a result of comparing the first and second system power limit values in the comparison unit, when the first system power limit value is greater than or equal to the second system power limit value, the battery having the lowest power limit value among the two or more battery racks The switch-off command can be sent to the rack.

A method of controlling a low-voltage battery rack in an ESS in which two or more battery racks are connected in parallel according to another embodiment of the present invention includes calculating individual power limits of the racks in the RMBS, and calculating the power limits in the BSC. A step of receiving an individual rack power limit value receiving a power limit value calculated by each of the two or more battery racks, and determining whether to connect a battery rack having the lowest power limit value among the received individual rack power limit values to a parallel line. The minimum power limit value may be configured to include determining whether to connect the battery rack.

The step of determining whether the lowest power limit value is connected to the battery rack is calculated by calculating a first system power limit value that calculates a system power limit value as the remaining individual rack power limit values excluding the lowest power limit value among the received individual rack power limit values. Step, a second system power limit value calculating step of calculating the system power limit value as a whole of the received individual rack power limit values, and comparing the first and second system power limit values comparing the first and second system power limit values And determining whether to connect the battery rack having the lowest power limit value according to the comparison result of the first and second system power limit value comparison steps.

In the calculating of the first system power limit value, when all the remaining individual rack power limit values except the lowest power limit value among the individual rack power limit values are the same, the lowest power limit value among the individual rack power limit values is excluded. The first system power limit value may be calculated by multiplying the number of battery racks having the remaining individual rack power limit values excluding the lowest power limit value among the remaining individual rack power limit values and the lowest power limit value among the individual rack power limit values.

If the individual rack power limit values are different from each other except the lowest power limit value among the individual rack power limit values, the second lowest power limit value among the individual rack power limit values and the lowest power limit among the individual rack power limit values The first system power limit value may be calculated by multiplying the number of battery racks having individual rack power limit values excluding the values.

In the determining whether the battery rack is connected, when the first system power limit value is greater than or equal to the second system power limit value, the battery rack having the lowest power limit value among the plurality of battery racks may be disconnected. have.

When the first system power limit value is smaller than the second system power limit value, the current battery rack connection state may be maintained.

The present invention can stably control the total power limit value of the ESS when a battery rack having a low voltage occurs.

1 is a view showing an ESS in which two or more battery racks according to an embodiment of the present invention are connected to a parallel line.
2 is a view showing that 10 battery racks constitute one ESS.
3 is a graph comparing the power limit value of the ESS according to an embodiment of the present invention with the prior art and other prior art.
4 is a flowchart illustrating a low voltage battery rack control 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 so that those skilled in the art to which the present invention pertains may easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are attached to similar parts throughout the specification.

Terms including ordinal numbers such as first and second may be used to describe various components, but the components are not limited by the terms. The terms are used only for the purpose of distinguishing one component from other components. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component. Terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Throughout the specification, when a part is “connected” to another part, this includes not only “directly connected” but also “electrically connected” with another element in between. . Also, when a part “includes” a certain component, it means that it may further include other components, not to exclude other components, unless otherwise stated. The term “~ (steps)” or “steps of” as used in the present specification does not mean “steps for”.

The terminology used in the present invention has been selected, while considering the functions in the present invention, general terms that are currently widely used are selected, but this may vary according to the intention or precedent of a person skilled in the art or the appearance of a new technology. In addition, in certain cases, some terms are arbitrarily selected by the applicant, and in this case, their meanings will be described in detail in the description of the applicable invention. Therefore, the terms used in the present invention should be defined based on the meanings of the terms and the contents of the present invention, not simply the names of the terms.

One. Energy storage system (ESS) according to an embodiment of the present invention

In the ESS 10 according to an embodiment of the present invention, two or more battery racks 100 are connected to a parallel line as shown in FIG. 1.

Meanwhile, each of the two or more battery racks 100 connected in parallel has a plurality of battery modules 110, a rack battery mangemant system (RBMS) 120 controlling the plurality of battery modules 110, and a battery rack in parallel lines. It may be configured to include a switch 130 to connect.

The plurality of battery modules 110 may be connected in series or parallel depending on the specification of the battery rack.

Meanwhile, the ESS 10 includes a battery section controller (BSC) 200, and the BSC 200 is connected to the parallel line 500 for each of the battery racks 100 connected to the parallel line. By determining whether or not, a connection determination for each battery rack 100 may be transmitted to the RBMS 120.

Specifically, the BSC 200 includes both the first system power limit value and the two or more battery racks, which are system limit values calculated, except for the battery rack having the lowest power limit value among the two or more battery racks 100. Comparison comparing the first and second system power limit values calculated by the system power limit value calculation unit 210 and the system power limit value calculation unit 210 for calculating a second system power limit value, which is a system limit value calculated by including It may be configured to include a portion 220.

For example, the battery rack having the lowest power limit value is a battery rack having a lower power limit value than other battery racks because the battery rack is defective, or the deterioration degree of the battery rack is high, so that it is faster than other battery racks. It may be a battery rack that generates low voltage.

On the other hand, in the system power limit value calculating unit 210, by multiplying the number of battery racks used to calculate the system power limit value by the power limit value of the lowest battery racks used to calculate the system power limit value. The system power limit value can be calculated. For example, when calculating the system power limit value for 10 battery racks, when the lowest power limit value of each of the 10 battery racks is 50KW, regardless of the power limit values of the remaining battery racks , The system power limit value can be calculated as 50KW X 10 = 50KW.

Meanwhile, when the first and second system power limit values are compared by the comparison unit 220, when the first system power limit value is greater than or equal to the second system power limit value, the lowest power among the plurality of battery racks The switch 130 off command may be transmitted to the battery rack 100 having a limit value.

Hereinafter, the difference between the present invention and the prior art will be described with specific examples.

Hereinafter, an ESS composed of 10 battery racks will be described, but is not limited thereto.

2 is a view showing that 10 battery racks constitute one ESS.

Hereinafter, each of the ten battery racks will be described as first to tenth battery racks.

Each of the first to ninth battery racks has a power limit value of 220 KW, and the tenth battery rack has a power limit value of 205 KW.

The power limit value of the entire ESS configured as described above is calculated by multiplying the lowest power limit value and the number of battery racks.

That is, the power limit value of the entire ESS is 205KW X 10, which is 2050KW.

Meanwhile, as the tenth battery rack continues to discharge, the power limit value decreases to 185KW.

On the other hand, when the power limit value of the fifth battery rack is lowered to 185KW, in the case of the prior art, the power limit value of the entire ESS is calculated as 185KW X 10, where 1850KW is the power limit value of the entire ESS.

Since the power limit value of the entire ESS is calculated by continuously multiplying the lowest power limit value and the number of battery racks constituting the ESS in the manner described above, the power of the entire ESS at the moment when the power limit value of the tenth battery becomes 0. The limit value was zero.

On the other hand, when the power limit value of the entire ESS becomes 0, the ESS can stop the discharge by determining that the ESS is completely discharged.

Meanwhile, even if the power limit value of the tenth battery rack is 0, sufficient power limits remain in the first to ninth battery racks having higher power limit values than the tenth battery rack.

In other words, the first to ninth battery racks can continue to discharge more, but since the power limit value of the tenth battery rack is 0, the power limit value of the entire ESS is calculated as 0, so no further discharge is performed. Power remains.

As another conventional technique for supplementing this, there was a technique of disconnecting the tenth battery rack when the power limit value of the tenth battery rack becomes 0, and operating the ESS with only the remaining first to ninth battery racks.

Although this prior art can use the ESS more efficiently, if the tenth battery rack is shorted when the tenth battery rack becomes 0, the power limit value of the ESS instantly bounces when the tenth battery rack is shorted. Occurred.

For example, when the power limit value of the tenth battery rack is 0, the power limit value of each of the first to ninth battery racks may be 20KW.

On the other hand, immediately before the power limit value of the tenth battery rack becomes 0, the power limit value of the entire ESS has a value close to 0. When the tenth battery rack is disconnected, the power limit value of the entire ESS is 1 to 1 Since the ESS power limit value is calculated only for the ninth battery racks, it can jump to 20KW X 9 = 180KW.

As such, if the power limit value of the entire ESS pops up, there is a high possibility that a problem occurs in the system connected to the ESS.

In order to solve this problem, in the present invention, the power limit value of the entire ESS calculated excluding the tenth battery rack, that is, the power limit value (first system power limit value) calculated by the first to ninth battery racks is If it is greater than or equal to the power limit value (second system power limit value) of the entire ESS calculated including all of the first to tenth battery racks, the tenth battery rack may be disconnected.

Specifically, as the tenth battery rack continues to discharge, the power limit value decreases to 185KW, and when the first to ninth battery racks decrease to 210KW, the entire ESS including all of the first to tenth battery racks The power limit value is calculated as 185KW X 10, which is 1850KW.

Meanwhile, the power limit value calculated by only the first to ninth battery racks excluding the tenth battery rack is 210KW X 9 = 1890KW.

That is, the second system power limit value calculated excluding the tenth battery rack is greater than the first system power limit value.

Therefore, from the overall ESS point of view, it may be efficient to disconnect the tenth battery rack and use only the first to ninth battery racks.

On the other hand, Figure 3 is a graph comparing the power limit value of the ESS according to an embodiment of the present invention with prior art and other prior art.

In the ESS connected by only the first to ninth battery racks according to an embodiment of the present invention, since the first to ninth battery racks have the same power limit value, the power limit value calculated by the first to ninth battery racks is 0 It can decrease linearly until.

Accordingly, it can be seen that in the prior art, the power limit value linearly decreases, but only a small amount of power can be used, and the other conventional technology has a similar capacity to use power, but the power limit value bounces instantaneously.

That is, the ESS can be efficiently used using more power than the prior art, and the ESS can be used more stably and statically by preventing the instantaneous power limit value from splashing in other prior art.

2. Low voltage battery rack control method according to an embodiment of the present invention.

4 is a flowchart illustrating a low voltage battery rack control method according to an embodiment of the present invention.

Hereinafter, a low voltage battery rack control method according to an embodiment of the present invention will be described with reference to FIG. 4.

The low voltage battery rack control method according to an embodiment of the present invention relates to a method for controlling a low voltage battery rack in an ESS in which two or more battery racks are connected in parallel.

Specifically, the low-voltage battery rack control method according to an embodiment of the present invention, the individual rack power limit value calculating step of calculating the power limit value of the battery rack in RMBS, the power limit value calculated in each of the two or more battery racks in the BSC Receiving the individual rack power limit value receiving step, the minimum power limit value determining whether to connect the battery rack having the lowest power limit value among the received individual rack power limit value to the parallel line determining whether to connect the battery rack It can be configured to include.

For example, the battery rack having the lowest power limit value (lowest power limit value) is a battery rack having a lower power limit value than other battery racks because the battery rack is defective, or the deterioration degree of the battery rack is high. , It may be a battery rack that generates a low voltage faster than other battery racks.

On the other hand, the step of determining whether the minimum power limit value is connected to the battery rack is the first system power limit for calculating the system power limit value with the remaining individual rack power limit values excluding the lowest power limit value among the received individual rack power limit values. A value calculation step, a second system power limit value calculation step of calculating a system power limit value as a whole of the received individual rack power limit values, and a first and second system power limit value comparing the first and second system power limit values The comparison step and the first and second system power limit value comparison step may include a battery rack connection determination step of determining whether to connect the battery rack having the lowest power limit value according to the comparison result.

On the other hand, in the step of calculating the first system power limit value, if all of the remaining individual rack power limit values except the lowest power limit value among the individual rack power limit values are the same, the lowest power limit value among the individual rack power limit values The first system power limit value may be calculated by multiplying the number of individual rack power limit values excluding and the number of battery racks having the remaining individual rack power limit values excluding the lowest power limit value among the individual rack power limit values.

On the other hand, if the remaining individual rack power limit values other than the lowest power limit value among the individual rack power limit values are different, the second lowest power limit value of the individual rack power limit values and the lowest of the individual rack power limit values. The first system power limit value may be calculated by multiplying the number of battery racks having individual rack power limit values excluding the power limit value.

Meanwhile, in the determining whether the battery rack is connected, when the first system power limit value is greater than or equal to the second system power limit value, connection of the battery rack having the lowest power limit value among the plurality of battery racks is performed. I can quit.

Meanwhile, when the first system power limit value is smaller than the second system power limit value, the current battery rack connection state may be maintained.

In other words, when the first system power limit value is reversed, the second system power limit value can be disconnected from the battery rack having the lowest power limit value.

Meanwhile, the above-described individual rack power limit value calculating step, individual rack power limit value receiving step, and minimum power limit value battery rack connection determination step may be repeatedly performed at predetermined periodic intervals.

On the other hand, although the technical spirit of the present invention has been described in detail according to the above embodiment, it should be noted that the above embodiment is for the purpose of explanation and not for the 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: ESS
100: battery rack
110: a plurality of battery modules
120: RBMS
130: switch
200: BSC
210: system power limit value calculator
220: comparator
500: parallel line

Claims (9)

In one energy storage system formed by two or more battery racks are connected in parallel to each other on a parallel line,
The energy storage system,
And a battery section controller (BSC) for determining whether to connect to the parallel line for each of the two or more battery racks,
Each of the two or more battery racks
A plurality of battery modules;
RBMS (Rack Battery Mangemant system) for controlling the plurality of battery modules; And
A switch connecting a battery rack to the parallel line;
It comprises,
The BSC,
And determining whether to connect to a parallel line for each of the battery racks, based on a power limit value of each of the two or more battery racks.
The method according to claim 1,
The BSC,
Calculating a first system power limit value, which is a system limit value calculated by excluding a battery rack having the lowest power limit value among the two or more battery racks, and a second system power limit value, which is a system limit value calculated for both of the two or more battery racks A system power limit value calculator;
And a comparator comparing the first and second system power limit values calculated by the system power limit value calculator.
The method according to claim 1,
The BSC,
As a result of comparing the first and second system power limit values in the comparison unit, when the first system power limit value is greater than or equal to the second system power limit value, a battery having the lowest power limit value among the two or more battery racks Battery system, characterized in that for transmitting the switch off command to the rack.
A method for controlling a low voltage battery rack in an ESS in which two or more battery racks are connected in parallel,
An individual rack power limit value calculating step of calculating the power limit value of the battery rack in the RMBS;
An individual rack power limit value receiving step of receiving power limit values calculated in each of the two or more battery racks in the BSC;
Determining whether to connect a battery rack having the lowest power limit value among the received individual rack power limit values to a parallel line;
Method of controlling a low-voltage battery rack of the ESS, characterized in that comprises a.
The method according to claim 4,
The minimum power limit value determining whether the battery rack is connected,
A first system power limit value calculating step of calculating a system power limit value with the remaining individual rack power limit values excluding the lowest power limit value among the received individual rack power limit values;
A second system power limit value calculating step of calculating a system power limit value as a whole of the received individual rack power limit values;
A first and second system power limit value comparison step of comparing the first and second system power limit values; And
A battery rack connection determining step of determining whether to connect the battery rack having the lowest power limit value according to the comparison result of the first and second system power limit value comparison steps;
Method of controlling a low-voltage battery rack of the ESS, characterized in that comprises a.
The method according to claim 5,
When all of the individual rack power limit values are the same except for the lowest power limit value among the individual rack power limit values,
The step of calculating the first system power limit value is
First by multiplying the number of battery racks having the remaining individual rack power limit values excluding the lowest power limit value from the remaining individual rack power limit values excluding the lowest power limit value from the individual rack power limit values. ESS low voltage battery rack control method, characterized in that for calculating the system power limit value.
The method according to claim 5,
When the individual rack power limit values other than the lowest power limit value among the individual rack power limit values are different,
The first system power limit value calculation step,
The first system power limit value is calculated by multiplying the number of battery racks having the remaining individual rack power limit values except for the second lowest power limit value among the individual rack power limit values and the lowest power limit value among the individual rack power limit values. ;
ESS low voltage battery rack control method characterized in that.
The method according to claim 5,
The determining whether the battery rack is connected,
When the first system power limit value is greater than or equal to the second system power limit value, disconnect the battery rack having the lowest power limit value among the plurality of battery racks,
If the first system power limit value is less than the second system power limit value, the low voltage battery rack control method of the ESS, characterized in that to maintain the current battery rack connection.
The method according to claim 4,
The step of calculating the individual rack power limit value, the step of receiving the individual rack power limit value, and the step of determining whether the battery rack is connected to the lowest power limit value are repeatedly performed at predetermined intervals.

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