KR102291134B1 - Method for operating energy storage system - Google Patents

Abstract

The present invention relates to an energy storage system (ESS) operating method, and more specifically, energy for determining whether to operate a battery module during discharge based on a voltage region occupying the most frequency among regions to which the voltage value of each battery module belongs It relates to a method of operating a storage system (ESS).

Description

ESS operation method {METHOD FOR OPERATING ENERGY STORAGE SYSTEM}

The present invention relates to an energy storage system (ESS) operating method, and more specifically, energy for determining whether to operate a battery module during discharge based on a voltage region occupying the most frequency among regions to which the voltage value of each battery module belongs It relates to a method of operating a storage system (ESS).

With the development of industry, the demand for electricity is increasing, and the gap in electricity consumption between day and night, season, and day is gradually deepening. Recently, for this reason, many technologies for reducing the peak load by utilizing the surplus power of the system have been rapidly developed.

A representative of these technologies is an Energy Storage System (ESS) that stores surplus power of the system in a battery or supplies insufficient power of the system from the battery.

In addition, the ESS is formed by being provided with a plurality of battery modules, and a general battery module configures a battery management system (hereinafter referred to as BMS) therein to efficiently control charging/discharging of the battery module.

In addition, in the ESS, a plurality of battery modules are connected in parallel to supply stable power, and it is possible to freely add or disconnect battery modules.

1 is a flowchart of a conventional operating method of an energy storage device (ESS) in which battery modules are connected in parallel.

Referring to FIG. 1 , each battery module first receives voltage data of all battery modules (voltage value reception step), and calculates a maximum voltage value based on the received voltage data (maximum voltage calculation step).

Thereafter, the discharge switch of the battery module having the calculated maximum voltage value is turned on to perform discharge (discharge switch-on step).

However, when discharging is performed in a situation in which a voltage difference between modules occurs due to various causes such as expansion of a new battery module or self-diagnosis and failure in a previously operated battery module, not only damage to the battery module performing discharging but furthermore There is a problem that discharge cannot be performed in the ESS.

This is because, when the number of battery modules having the maximum voltage value is less than a predetermined number, overcurrent may occur in the operated battery module, and if a problem occurs before the battery module having the maximum voltage value is driven, it is impossible to perform overall discharge.

Therefore, it is required to develop a technology capable of performing discharging by securing the maximum number of battery modules performing discharging when discharging is performed.

US 2015-0081731 A

The present invention provides an energy storage device (ESS) operating method for stably discharging when discharging is performed.

An energy storage device (ESS) operating method according to an embodiment of the present invention is a method of operating an energy storage device (ESS) composed of a plurality of battery modules when discharging, voltage value data of each of the plurality of battery modules different from each other a voltage value receiving step of receiving Each of the battery modules compares the voltage region set in the maximum voltage region setting step with its own module voltage to determine whether discharging is allowed or not, and each of the plurality of battery modules is based on the result determined in the discharging determination step. and a discharge switch control step of on/off controlling the discharge switch according to the configuration.

The voltage value receiving step is performed by each battery module at the same predetermined receiving cycle.

The state information of the battery module collected in the state information collecting step includes a voltage value and a current value.

The highest voltage region setting step includes a voltage value sorting step of arranging the voltage values of other battery modules received in the voltage value receiving step in a descending order, the largest voltage value among the voltage values of the battery modules sorted in the voltage value sorting step A voltage value comparison step of comparing the reference voltage value and the comparison voltage value by setting in descending order as the voltage value and the comparison voltage value, and when the difference between the voltage values compared in the voltage value comparison step is within a predetermined range, the module of the corresponding voltage region A comparison voltage value setting step of adding the number and setting the voltage value of the battery module of the next comparison order as a comparison voltage value, the number of modules in the corresponding voltage region added in the comparison voltage value setting step and the number of modules of the previous comparison order After setting the maximum voltage value in the maximum voltage setting step and the maximum voltage setting step of setting the reference voltage value of the larger number of modules as the maximum voltage value in the corresponding voltage region, the reference voltage value in the voltage value comparison step and the and a comparison determination step of determining whether to compare the voltage values of the next comparison order by comparing the order of each comparison sequence of the comparison voltage values in the comparison voltage value setting step with the number of pre-stored battery modules.

When the difference between the voltage values compared in the voltage value comparison step exceeds a predetermined range, the voltage value of the battery module in the next comparison sequence is set as the comparison voltage value.

In the step of setting the comparative voltage value, the number of modules in the corresponding voltage region is counted according to the reference voltage value.

In the comparison whether determining step, the comparison voltage value determining whether to perform the comparison of the next comparison voltage value by comparing the order value of the comparison voltage value of the next comparison order in the comparison voltage value setting step with the total number of battery modules If the order value of the comparison voltage value exceeds the total number of battery modules in the step and the step of determining whether to perform the comparison voltage value, the order value of the reference voltage value of the voltage value comparison step and the total number of battery modules are compared to the next reference voltage and a step of determining whether to perform a reference voltage value for determining whether to perform a value comparison, and if the order value of the comparison voltage value in the step of determining whether to perform the comparison voltage value is less than or equal to the total number of battery modules, the voltage value comparison step carry out

A battery module according to an embodiment of the present invention is a battery module constituting an energy storage device (ESS) in which a plurality of battery modules are connected in parallel, through a communication unit that communicates with other battery modules to receive voltage value data, and the communication unit A storage unit for storing the received voltage value data of all battery modules, a most voltage region setting unit for setting a voltage region occupying the most frequency among regions to which the voltage value of each battery module stored in the storage unit belongs, the most voltage region A discharge allowable determination unit that compares the voltage range set in the setting unit with its own module voltage to determine whether discharge is permitted, and a discharge switch control unit that turns on/off the discharge switch according to the result determined by the discharge permit determination unit is comprised of

In the communication unit, a reception cycle for receiving voltage value data is set to the same reception cycle as that of the entire battery module.

The maximum voltage region setting unit, a voltage value sorting unit for arranging the voltage values of all the battery modules stored in the storage unit in descending order, and a voltage value and A voltage value comparison unit that compares a reference voltage value and a comparison voltage value by setting the comparison voltage value in descending order, and if the difference between the voltage values compared in the voltage value comparison unit is within a predetermined range, the number of modules in the corresponding voltage region is added, , a comparison voltage value setting unit that sets the voltage value of the battery module in the next comparison order as a comparison voltage value, and sets the maximum voltage among the voltage region based on the number of modules in the voltage region added in the comparison voltage value setting unit comparing the order of each comparison sequence of the reference voltage value in the maximum voltage setting unit and the voltage value comparison unit and the comparison voltage value in the comparison voltage value setting unit with the number of stored battery modules to compare the voltage value of the next comparison order and a comparison determination unit for determining whether to compare.

The comparison voltage value setting unit stores the added number of modules in the corresponding voltage region in the storage unit.

The comparison determination unit may include a comparison voltage value determination unit configured to compare the order value of the next comparison voltage value in the comparison voltage value setting unit with the total number of battery modules to determine whether to perform the comparison of the next comparison voltage value; When the comparison voltage value determination unit determines that the order value of the comparison voltage value exceeds the total number of battery modules, the next reference voltage value by comparing the order value of the reference voltage value of the voltage value comparison unit with the total number of battery modules Battery module, characterized in that it comprises a reference voltage value to determine whether or not to perform the comparison of

An energy storage device (ESS) according to an embodiment of the present invention is configured to include a battery module.

A plurality of battery modules are connected in parallel.

An energy storage system (ESS) operating method according to an embodiment of the present invention provides stable discharge by selecting a battery module to be discharged based on a voltage region occupying the most frequency among regions to which the voltage value of each battery module belongs. can be done

1 is a flowchart of a conventional operating method of an energy storage device (ESS) in which battery modules are connected in parallel;
2 is a flowchart of an energy storage system (ESS) operating method according to an embodiment of the present invention.
3 is a flowchart of a setting step of a maximum voltage region in an energy storage system (ESS) operating method according to an embodiment of the present invention.
4 is a flowchart of a comparison determination step in an energy storage system (ESS) operating method according to an embodiment of the present invention.
5 is a block diagram of a battery module according to an embodiment of the present invention.
6 is a schematic diagram of an energy storage system (ESS) according to an embodiment of the present invention.
7 is a block diagram of a maximum voltage region setting unit in a battery module according to an embodiment of the present invention.
8 is a block diagram of a comparison determination unit in a battery module according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the contents described in the accompanying drawings. However, the present invention is not limited or limited by the embodiments. Only the embodiments are provided to complete the disclosure of the present invention, and to fully inform those of ordinary skill in the art of the scope of the present invention.

Also, 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 identifying 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.

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 a specific case, there is a term 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.

<Example 1>

Next, an energy storage system (ESS) operating method according to an embodiment of the present invention will be described.

The energy storage system (ESS) operating method of the present invention sets a voltage region that occupies the most frequency among regions to which the voltage value of each battery module belongs, and discharges by comparing the highest voltage value and the voltage value of each battery module in the voltage region Allow the battery module to be used for selection.

2 is a flowchart of an energy storage system (ESS) operating method according to an embodiment of the present invention.

Referring to FIG. 2 , in the method of operating an energy storage system (ESS) according to an embodiment of the present invention, each of a plurality of battery modules receives voltage value data of another battery module (voltage value receiving step: S200), and a plurality of Each of the battery modules sets a voltage region occupying the most frequency among regions to which the received voltage value of each battery module belongs (most voltage region setting step: S300).

In addition, each of the plurality of battery modules compares the voltage region set in the maximum voltage region setting step (S220) with its own module voltage to determine whether to allow discharging (discharge permission determination step: S400), and according to the determined result The on/off control of the discharge switch (discharge switch control step: S500).

Each step of the energy storage system (ESS) operating method will be described in more detail below.

The voltage value receiving step ( S200 ) is a step of receiving voltage value data of each battery module, and is performed individually by all battery modules.

Since the present invention selects and operates a battery module to be discharged before discharging, in order for the discharging battery module to perform discharging at the same time, a predetermined reception period for receiving voltage values from all battery modules is the same. It should have a period value.

In addition, a status check step of checking the status of the battery; is configured to additionally include, so that the voltage value information of the battery module in which off-control by diagnosis has occurred due to an abnormal state occurring in the battery module can be deleted. This is because the corresponding battery module cannot perform discharging, so the voltage value of the corresponding battery module is unnecessary to set the voltage range.

In addition, the most voltage region setting step (S300) is a step of setting a voltage region that occupies the most frequency among regions to which the voltage value of each battery module received in the voltage value receiving step (S200) belongs. It is set so that power can be supplied from the battery module so that even when an abnormal state occurs in a small number of battery modules, the output voltage value per battery module does not become higher than a predetermined overcurrent reference value so that power can be supplied stably.

In addition, the step of setting the maximum voltage region ( S300 ) will be described in more detail with reference to FIG. 3 .

3 is a flowchart of a setting step of a maximum voltage region in an energy storage device (ESS) overcurrent protection method according to an embodiment of the present invention.

3, the voltage values of other battery modules received in the voltage value receiving step (S200) are arranged in a descending order (voltage value sorting step: S310), and the largest voltage value among the voltage values of the sorted battery modules The voltage value and the comparison voltage value are set in descending order to compare the reference voltage value and the comparison voltage value (voltage value comparison step: S320).

When the difference between the voltage values compared in the voltage value comparison step (S320) is within a predetermined range, the number of modules in the corresponding voltage region is added, and the voltage value of the battery module in the next comparison order is set as the comparison voltage value (compared Voltage value setting step: S330), compares the number of modules in the added voltage region with the number of modules in the previous comparison order, and sets the reference voltage value of the larger number of modules as the maximum voltage value in the voltage region (maximum voltage setting step) : S340).

After the maximum voltage value is set in the maximum voltage setting step (S340), the reference voltage value in the voltage value comparison step (S320) and the order of each comparison sequence of the comparison voltage value in the comparison voltage value setting step are stored in the battery It is compared with the number of modules to determine whether to compare voltage values in the next comparison sequence (comparison determination step: S350).

If each step of the maximum voltage region setting step (S320) is described in more detail, the voltage value sorting step (S310) is to sort the voltage values of other battery modules received in the voltage value receiving step (S200) in descending order. is a step

For example, if the voltage of the battery module in the ESS is 4V, 7.2V, 5.5V, 6.5V, 5.3V, and 5.8V, respectively, the comparison order of No. 1 is 7.2V, the order of comparison No. 2 is 6.5V, 3 The comparison order of No. 4 is 5.8V, the comparison order of No. 4 is 5.5V, the comparison order of No. 5 is 5.3V, and the comparison order of No. 6 is 4V.

In addition, the voltage value comparison step ( S320 ) sets the largest voltage value among the voltage values of the battery modules arranged in the voltage value alignment step ( S310 ) in descending order as the reference voltage value and the comparison voltage value, and the reference voltage value and the comparison voltage This step compares values.

The method of comparing the reference voltage value and the comparison voltage value compares whether a difference between the reference voltage value and the comparison voltage value is within a predetermined range.

For example, if the voltage of the battery module in the ESS is 4V, 7.2V, 5.5V, 6.5V, 5.3V, and 5.8V, respectively, the first reference voltage value is set to 7.2V, followed by 6.5V, 5.8V , 5.5V, 5.3V, and 4V are sequentially set.

In addition, the first comparison voltage value is also set to 7.2V, followed by 6.5V, 5.8V, 5.5V, 5.3V, and 4V in order.

After that, when performing the first comparison, the 7.2V reference voltage value and the 7.2V comparison voltage value are compared, which checks whether the voltage difference between the reference voltage value and the comparison voltage value is within a predetermined range.

Here, the voltage difference between the reference voltage value and the comparison voltage value is set to 0.5V as an example, so that the maximum voltage range that does not affect the discharge can be set.

In addition, in the comparison voltage value setting step (S330), if the difference between the voltage values compared in the voltage value comparison step (S320) is within a predetermined range, the number of modules in the corresponding voltage region is added, and the battery module of the next comparison order Set the voltage value of , as the comparison voltage value.

In addition, when the difference between the voltage values compared in the voltage value comparison step (S320) exceeds a predetermined range, the number of modules in the corresponding voltage region is not added, and the voltage value of the battery module in the next comparison order is used as the comparison voltage value. set

In addition, the number of modules in the corresponding voltage region is counted according to the reference voltage value, and when the voltage difference between the reference voltage value and the comparison voltage value is within a predetermined range, the number of battery modules is added to the region to which the voltage value of each battery module belongs. It is possible to select the voltage region that occupies the most frequency.

For example, if the voltage of the battery module in the ESS is 4V, 7.2V, 5.5V, 6.5V, 5.3V, and 5.8V, respectively, when performing the first comparison, the first comparison voltage value is set to 7.2V, and the first When the comparison is finished, the second comparison voltage is set to 5.8V to prepare for the second comparison.

In addition, the maximum voltage setting step (S340) compares the number of modules in the corresponding voltage region added in the comparison voltage value setting step (S330) with the number of modules in the previous comparison order, and sets the reference voltage value of the larger number of modules to the corresponding voltage. As a step of setting the maximum voltage value among the regions, the previous maximum voltage value is updated only when the number of modules in the corresponding voltage region added in the comparison voltage value setting step S330 is greater than the number of modules in the previous comparison order.

If the first comparison is performed, the number of modules is not compared because there is no number of modules in the previous comparison order, and 1, the first number of modules, is set.

In addition, the maximum voltage value set here is set as a discharge allowable reference value in the discharging permit determination step (S400).

In addition, the comparison determination step (S350) is after the maximum voltage value is set in the maximum voltage setting step (S340), the reference voltage value in the voltage value comparison step (S320) and the comparison voltage value setting step (S330) A step of determining whether to compare the voltage values of the next comparison sequence by comparing the sequence number of each comparison sequence of the comparison voltage values with the number of previously stored battery modules, which will be described in detail with reference to FIG. 4 .

4 is a flowchart of a comparison determination step in an energy storage system (ESS) operating method according to an embodiment of the present invention.

Referring to FIG. 4 , the comparison determination step ( S350 ) is performed by comparing the order value of the comparison voltage value of the next comparison order in the comparison voltage value setting step ( S330 ) with the total number of battery modules to compare the next comparison voltage value. It is determined whether to perform (the comparison voltage value determination step: S351), and when the sequence value of the next comparison voltage value exceeds the total number of battery modules, the sequence value of the reference voltage value of the voltage value comparison step (S320) and It is determined whether the comparison of the next reference voltage value is performed by comparing the total number of battery modules (reference voltage value determination step: S352).

In addition, if the order value of the comparison voltage value is less than or equal to the total number of battery modules in the determining whether to perform the comparison voltage value ( S351 ), the reference voltage value is continuously used as the existing value, and the comparison voltage value is the comparison voltage of the next comparison order The voltage value comparison step (S320) is performed using the value.

In addition, if the order value of the reference voltage value is less than the total number of battery modules in the step of determining whether to perform the reference voltage value ( S352 ), the reference voltage value sets the reference voltage value of the next comparison order, and the comparison voltage value is the first comparison By setting the voltage value, the comparison of the reference voltage value in the following order can be performed.

In addition, if the order value of the reference voltage value is the same as the total number of battery modules in the step of determining whether to perform the reference voltage value ( S352 ), the voltage values of all the battery modules are already compared and among the regions to which the voltage values of all the battery modules belong Since the voltage region occupying the most frequency has been calculated, the discharging permit determination step (S400) is performed.

For example, if the ordinal value of the comparison voltage value in the next comparison sequence is 1, the ordinal value of the current reference voltage value is 5, and the total number of usable battery modules is 8, the comparison of the fifth reference voltage value is already is performed, so the comparison of the sixth reference voltage value is performed.

In addition, when the order value of the comparison voltage value is 4, the voltage value comparison step S320 is performed using the fourth comparison voltage value.

In addition, when the order value of the reference voltage value is 8, the comparison of the voltage values of all battery modules is finished, and thus the discharging permit determination step (S400) is performed.

In addition, the discharging permit determination step (S400) is a step of determining whether discharging is permitted by comparing each of the plurality of battery modules with the voltage region set in the maximum voltage region setting step (S300) and its own module voltage. Strictly speaking, it is a step of comparing the maximum voltage value set in the maximum voltage setting step (S340) with the own module voltage value.

In addition, the discharging switch-off control step (S500) controls the discharging switch on/off according to the result determined in the discharging or not determining step (S400), so its module voltage value is within the maximum voltage value and is included in the voltage range When it does, it controls its own discharge switch on.

More specifically, when its own module voltage value is less than or equal to the maximum voltage value, it is classified as an on-controllable battery module, and when it is included in the voltage range, the discharge switch is turned on.

Then, it is also possible to control the discharge by receiving only the voltage value of the periodically on-controllable battery module.

<Example 2>

Next, a battery module according to an embodiment of the present invention will be described.

The battery module of the present invention performs stable discharge by determining whether to discharge by setting a voltage region occupying the most frequency among regions to which the voltage value of each battery module of an energy storage device (ESS) connected in parallel with a plurality of battery modules in parallel can do.

5 is a block diagram of a battery module according to an embodiment of the present invention.

Referring to FIG. 5 , the battery module 100 according to an embodiment of the present invention communicates with other battery modules to receive voltage value data, and the communication unit 110 receives voltage values of all battery modules received through the communication unit 110 . The storage unit 120 for storing data; The discharge switch is turned on/off according to the result determined by the discharging permit determination unit 140 and the discharging discharging determination unit 140 that compare the voltage region set in the unit 130 with the own module voltage to determine whether discharge is permitted. It is configured to include a discharge switch control unit 150 that controls off.

In addition, the overall configuration of the energy storage system (ESS) will be described in detail with reference to FIG. 6 .

6 is a schematic diagram of an energy storage system (ESS) according to an embodiment of the present invention.

Referring to FIG. 6 , in the energy storage device (ESS), a plurality of battery modules 100 are connected in parallel, and since a separate central control device for controlling the plurality of battery modules is not configured, each battery module 100 ) individually determines whether to discharge for ESS operation.

In addition, due to the parallel configuration, an error occurs in the battery module located in the middle order, so that it does not affect other battery modules even if it is turned off or communication is poor.

Meanwhile, each configuration of the battery module 100 will be described in more detail below.

The communication unit 110 communicates with another battery module to receive voltage value data, and also transmits its own voltage value data to another battery module through the communication unit 110 .

In addition, the communication unit 110 is set to receive the voltage value data receiving period is the same as that of the entire battery module.

In addition, the storage unit 120 stores the voltage value data of the entire battery module received through the communication unit 110, which can be used by using the memory in the BMS in the battery module or by additionally configuring the memory separately. .

In addition, the storage unit 120 pre-stores the number of connected battery modules so that it can be used when determining whether discharging is permitted.

In addition, the maximum voltage region setting unit 130 sets a voltage region occupying the most frequency among regions to which the voltage value of each battery module stored in the storage unit 120 belongs to determine whether or not discharging is performed.

In addition, each configuration of the maximum voltage region setting unit 130 will be described in detail below with reference to FIG. 7 .

7 is a block diagram of a maximum voltage region setting unit in a battery module according to an embodiment of the present invention.

Referring to FIG. 7 , the maximum voltage region setting unit 130 includes a voltage value aligning unit 131 and a voltage value aligning unit 131 for arranging voltage values of all battery modules stored in the storage unit 120 in descending order. In the voltage value comparison unit 132, the voltage value comparison unit 132, which compares the reference voltage value and the comparison voltage value by setting the largest voltage value among the voltage values of the battery module sorted in descending order to the voltage value and the comparison voltage value. When the difference between the compared voltage values is within a predetermined range, the comparison voltage value setting unit 133 that adds the number of modules in the corresponding voltage region and sets the voltage value of the battery module in the next comparison order as the comparison voltage value, the comparison voltage Reference voltage value and comparison in the maximum voltage setting unit 134 and the voltage value comparator 132 that set the maximum voltage in the voltage region based on the number of modules in the corresponding voltage region added by the value setting unit 133 and a comparison determination unit 135 that compares the number of each comparison sequence of voltage values with the number of previously stored battery modules to determine whether to compare voltage values in the next comparison sequence.

More specifically, the voltage value sorting unit 131 sorts the voltage values of all the battery modules stored in the storage unit in a descending order, and numbers the voltage values according to each order so that they can be easily identified.

In addition, the voltage value comparison unit 132 sets the largest voltage value among the voltage values of the battery modules arranged by the voltage value alignment unit 131 as the voltage value and the comparison voltage value in descending order, and sets the reference voltage value and the comparison voltage value. compare

More strictly, it is compared whether the difference between the reference voltage value and the comparison voltage value is within a predetermined range.

In addition, when the difference between the voltage values compared by the voltage value comparison unit 132 is within a predetermined range, the comparison voltage value setting unit 133 adds the number of modules in the corresponding voltage region, and the battery module of the next comparison order Set the voltage value of , as the comparison voltage value.

In addition, when the difference between the voltage values compared by the voltage value comparison unit 132 exceeds a predetermined range, the comparison voltage value setting unit 133 does not add the number of modules in the corresponding voltage region, and Set the voltage value of the battery module as the comparison voltage value.

The number of modules in the corresponding voltage region is counted according to the reference voltage value, and when the number of battery modules is added according to the comparison result of the voltage value comparator 132, it occupies the highest frequency among regions to which the voltage value of each battery module belongs. Allows selection of voltage range.

In addition, the added number of modules of the corresponding voltage region is stored in the storage unit 120 to be used by the maximum voltage setting unit 134 .

Also, the maximum voltage setting unit 134 sets the maximum voltage in the corresponding voltage region based on the number of modules in the corresponding voltage region added by the comparison voltage value setting unit 133 .

In addition, it updates the previous maximum voltage value only when the number of modules in the corresponding voltage region added by the comparison voltage value setting unit 133 is greater than the number of modules in the previous comparison order.

If the first comparison is performed, the number of modules is not compared because there is no number of modules in the previous comparison order, and 1, the first number of modules, is stored.

In addition, the comparison determination unit 135 pre-stores the order of each comparison of the reference voltage value in the voltage value comparison unit 132 and the comparison voltage value in the comparison voltage value setting unit 133 to the previously stored battery module It is compared with the number of values to determine whether to compare the voltage values in the next comparison sequence.

In addition, each configuration of the comparison determination unit 135 will be described in detail below with reference to FIG. 8 .

8 is a block diagram of a comparison determination unit in a battery module according to an embodiment of the present invention.

Referring to FIG. 8 , the comparison determination unit 135 determines the order value of the next comparison voltage value in the comparison voltage value setting unit 133 and the total number of battery modules pre-stored in the storage unit 120 . In the comparison voltage value execution determination unit 135_1 to determine whether to perform the comparison of the next comparison voltage value by comparison and the comparison voltage value execution determination unit 135_1, the order value of the comparison voltage values exceeds the total number of battery modules a reference voltage value for determining whether to perform the comparison of the next reference voltage value by comparing the order value of the reference voltage value of the voltage value comparison unit 132 with the total number of battery modules pre-stored in the storage unit 120 when it is determined that It is configured to include a performance determination unit (135_2).

In addition, if the comparison voltage value execution determination unit 135_1 compares that the order value of the comparison voltage value is equal to or less than the total number of battery modules, the reference voltage value is not changed, and the voltage value comparison unit 132 sets the comparison voltage The comparison signal is transmitted to the voltage value comparison unit 132 so that the comparison voltage values of the next comparison sequence set by the value setting unit 133 can be compared.

In addition, when the order value of the reference voltage value in the reference voltage value execution determination unit 135_2 is less than the total number of battery modules, the reference voltage value sets the reference voltage value of the next comparison order, and the comparison voltage value is the first comparison The voltage value is set so that the voltage value comparison unit 132 compares the reference voltage values in the following order. Here, the comparison voltage value is a value preset by the comparison voltage value setting unit 133 . Therefore, the comparison determination unit 135 changes only the reference voltage value according to the comparison order.

In addition, if the order value of the reference voltage value is the same as the total number of battery modules in the reference voltage value execution determination unit 135_2 , the voltage values of all battery modules are already compared and among the regions to which the voltage values of all battery modules belong Since the voltage region occupying the most frequency has been calculated, a determination execution signal is transmitted to the discharging permit determination unit 140 .

In addition, the discharge permit determination unit 140 compares the voltage area set by the maximum voltage area setting unit 130 with its own module voltage to determine whether discharge is permitted.

More precisely, the maximum voltage value set by the maximum voltage setting unit 134 is compared with its own module voltage value to determine whether discharge is permitted.

The discharging permit determination unit 140, when its module voltage value is less than or equal to the maximum voltage value set by the maximum voltage setting unit 134, classifies it as an ON-controllable battery module, and enters the voltage region including the maximum voltage value. If its own module voltage value belongs to it, it is determined as a discharge-allowable battery module.

In addition, the discharge switch control unit 150 controls the discharge switch on/off according to the result determined by the discharge permit determination unit 140 .

Accordingly, when the discharge permit determination unit 140 determines that the battery module is a discharge allowable battery module, the discharge switch control unit 150 turns on the discharge switch.

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, a person of ordinary skill in the art of the present invention will be able to various embodiments within the description of the claims described.

100: battery module
110: communication department
120: storage
130: most voltage range setting unit
131: voltage value alignment unit
132: voltage value comparison unit
133: comparison voltage value setting unit
134: maximum voltage setting unit
135: comparison determination unit
135_1: comparison voltage value execution determination unit
135_2: reference voltage value execution determination unit
140: discharging permit determination unit
150: discharge switch control unit

Claims (13)

In the method of operating an energy storage device (ESS) composed of a plurality of battery modules when discharging,
a voltage value receiving step in which each of the plurality of battery modules receives voltage value data of a different battery module;
a maximum voltage region setting step of each of the plurality of battery modules setting a voltage region occupying the most frequency among regions to which the voltage value of each battery module received in the voltage value receiving step belongs;
a discharging permit determination step of determining whether discharging is permitted by comparing each of the plurality of battery modules with the voltage area set in the maximum voltage area setting step with its own module voltage; and
a discharging switch control step of controlling each of the plurality of battery modules to turn on/off the discharging switch according to the result determined in the discharging permit determination step;
An energy storage system (ESS) operating method, characterized in that it comprises a.
The method according to claim 1,
The voltage value receiving step is an energy storage device (ESS) operating method, characterized in that each battery module is performed at the same predetermined receiving cycle. The method according to claim 1,
The step of setting the maximum voltage range,
a voltage value sorting step of arranging voltage values of other battery modules received in the voltage value receiving step in a descending order;
a voltage value comparison step of comparing the reference voltage value and the comparison voltage value by setting the largest voltage value among the voltage values of the battery modules arranged in the voltage value alignment step in descending order as the voltage value and the comparison voltage value;
When the difference between the voltage values compared in the voltage value comparison step is within a predetermined range, a comparison voltage value setting step of adding the number of modules in the corresponding voltage region and setting the voltage value of the battery module in the next comparison order as the comparison voltage value ;
a maximum voltage setting step of comparing the number of modules in the corresponding voltage region added in the comparison voltage value setting step with the number of modules in the previous comparison order to set the reference voltage value of the larger number of modules as the maximum voltage value in the corresponding voltage region; and
After setting the maximum voltage value in the maximum voltage setting step, the order of each comparison sequence of the reference voltage value in the voltage value comparison step and the comparison voltage value in the comparison voltage value setting step is compared with the number of previously stored battery modules. a comparison determination step of determining whether to compare voltage values in the next comparison order;
An energy storage system (ESS) operating method, characterized in that it comprises a.
4. The method according to claim 3,
When the difference between the voltage values compared in the voltage value comparison step exceeds a predetermined range, the energy storage system (ESS) operating method, characterized in that the voltage value of the battery module in the next comparison order is set as the comparison voltage value.
4. The method according to claim 3,
The energy storage device (ESS) operating method, characterized in that the number of modules in the voltage region in the step of setting the comparative voltage value is counted according to the reference voltage value.
4. The method according to claim 3,
The comparison determination step is,
a comparison voltage value determination step of determining whether to perform comparison of the next comparison voltage value by comparing the sequence value of the comparison voltage value of the next comparison sequence in the comparison voltage value setting step with the total number of battery modules; and
When the order value of the comparison voltage value exceeds the total number of battery modules in the step of determining whether to perform the comparison voltage value, the order value of the reference voltage value in the voltage value comparison step is compared with the total number of battery modules to obtain the next reference voltage value. determining whether to perform a reference voltage value for determining whether to perform comparison; consists of,
When the order value of the comparison voltage value is less than or equal to the total number of battery modules in the step of determining whether to perform the comparison voltage value, the voltage value comparison step is performed.
In the battery module constituting an energy storage system (ESS) in which a plurality of battery modules are connected in parallel,
a communication unit communicating with another battery module to receive voltage value data;
a storage unit for storing voltage value data of all battery modules received through the communication unit;
a maximum voltage region setting unit for setting a voltage region occupying the most frequency among regions to which the voltage value of each battery module stored in the storage unit belongs;
a discharging permit determination unit for determining whether discharging is permitted by comparing the voltage area set by the maximum voltage area setting unit with its own module voltage; and
a discharge switch control unit configured to turn on/off the discharge switch according to a result determined by the discharge permit determination unit;
A battery module comprising a.
8. The method of claim 7,
The communication unit, battery module, characterized in that the receiving period for receiving the voltage value data is set to the same receiving period as the entire battery module.
8. The method of claim 7,
The maximum voltage region setting unit,
a voltage value sorting unit for arranging voltage values of all battery modules stored in the storage unit in descending order;
a voltage value comparator for comparing a reference voltage value and a comparison voltage value by setting the largest voltage value among the voltage values of the battery module sorted by the voltage value alignment unit as a voltage value and a comparison voltage value in descending order;
When the difference between the voltage values compared by the voltage value comparison unit is within a predetermined range, the comparison voltage value setting unit adds the number of modules in the corresponding voltage region and sets the voltage value of the battery module in the next comparison order as the comparison voltage value ;
a maximum voltage setting unit configured to set a maximum voltage in the corresponding voltage region based on the number of modules in the corresponding voltage region added by the comparison voltage value setting unit; and
Comparison for determining whether to compare voltage values in the next comparison order by comparing the reference voltage value in the voltage value comparison unit and the order of each comparison order of the comparison voltage value in the comparison voltage value setting unit with the number of pre-stored battery modules whether or not judgment unit;
A battery module comprising a.
10. The method of claim 9,
The comparison voltage value setting unit is configured to store the added number of modules in the corresponding voltage region in the storage unit.
10. The method of claim 9,
The comparison determination unit,
a comparison voltage value determination unit that compares an order value of a next comparison voltage value in the comparison voltage value setting unit with the total number of battery modules to determine whether to perform a comparison of a next comparison voltage value; and
When the comparison voltage value determination unit determines that the order value of the comparison voltage value exceeds the total number of battery modules, the next reference voltage value by comparing the order value of the reference voltage value of the voltage value comparison unit with the total number of battery modules a determination unit whether to perform a reference voltage value for determining whether to perform a comparison;
A battery module comprising a.
An energy storage system (ESS) comprising the battery module of any one of claims 7 to 11.
An energy storage device (ESS), characterized in that the battery module of any one of claims 7 to 11 is configured by connecting in parallel.

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