KR20180114739A - Method for managing Energy Storage System - Google Patents

Abstract

The present invention relates to a method for managing an energy storage system. More specifically, the present invention relates to a method for managing an energy storage system which transmits a charging/discharging command value or a corrected command value to each energy storage system according to SOC state information or the amount of charging/discharging power of each energy storage system. According to an embodiment of the present invention, the method for managing an energy storage system comprises the steps of: receiving SOC state information from one or more energy storage systems; transmitting a charging/discharging command value to the one or more energy storage systems according to the received SOC state information; comparing the charging/discharging command value with the amount of charging/discharging power of the one or more energy storage systems; and transmitting a corrected command value correcting the charging/discharging value according to the comparison result to the one or more energy storage systems.

Description

[0001] METHOD FOR MANAGING ENERGY STORAGE [0002]

The present invention relates to an energy storage device management method, and more particularly, to an energy storage device management method for transmitting a charge / discharge command value or a correction command value to an energy storage device in accordance with SOC status information or charge / .

An energy storage system (ESS) is a device that stores power supplied from a power grid (GRID) or supplies stored power to a power grid (GRID). Such an energy storage device is used in various fields due to its advantage of a high output control speed.

In order to improve the stability of the system operation, a plurality of energy storage devices are managed by a single energy management system (EMS). In other words, the power management system controls the operating states of a plurality of energy storage devices to charge or discharge power.

1 is a view showing a state in which a plurality of energy storage devices 20 are managed according to a conventional method. Hereinafter, a process of charging or discharging electric power to or from the energy storage device 20 according to a conventional energy storage device management method will be described in detail with reference to FIG.

Referring to FIG. 1, a plurality of energy storage devices (ESS 1 to ESS N, 20) are managed by one power management system 10. Each energy storage device 20 performs a charging or discharging operation in accordance with the charging / discharging command value received from the power management system 10.

Such a power management system 10 is located in the control room, and the power control device 11 and the plurality of energy storage devices 20 are located in the field. More specifically, the site is the location where actual power transfer occurs under the control of the grid operator operating the power management system 10, and the control room is connected to the plurality of energy storage devices 20 via the power management system 10 Control position.

Generally, the control room and the site can be physically separated, and the system operator located in the control room controls the individual energy storage device 20 located in the field. The power control device 11 shown in FIG. 1 performs a role of relaying the charge / discharge command value generated in the power management system 10 to each energy storage device 20.

Further, the power control device 11 receives the state information of the energy storage device 20 and transfers it to the power management system 10. More specifically, the power control device 11 receives status information on whether or not the energy storage device 20 is abnormal, a battery abnormality, and a communication status abnormality, and transmits the status information to the power management system 10.

The conventional power management system 10 transmits a charge / discharge command value to each energy storage device 20 according to the setting of the system operator. Thereafter, the power management system 10 acquires the output value of each energy storage device 20. [ Here, the output value includes the actual charge amount of each energy storage device 20. [

The power management system 10 quantifies the performance score of how much the output value of each energy storage device 20 follows the charge / discharge command value. The higher the performance score, the higher the reliability of the energy storage device 20 is. Such a performance score is calculated as the difference between the charge / discharge command value and the actual charge / discharge amount of the energy storage device 20 becomes smaller.

The conventional power management system 10 transmits the charge / discharge command value without considering the battery charge amount of each energy storage device 20. [ Accordingly, the energy storage device which can not perform the charge / discharge operation according to the battery charge amount can not perform the charge / discharge operation even if it receives the charge / discharge command value.

For example, an energy storage device that can not perform a charging operation any more because the battery charging amount exceeds a certain reference amount can not perform the charging operation even if the charging instruction value is received. Further, since the battery charge amount is less than the predetermined reference amount, the energy storage device which can not perform further discharge operation can not perform the discharge operation even if it receives the discharge instruction value.

Accordingly, according to the conventional energy storage device management method, the energy storage device which can not perform the charge / discharge operation can not follow the charge / discharge command value. Therefore, regardless of the performance or efficiency of the energy storage device, .

In addition, it is impossible to efficiently control the frequency of the power system by continuously transmitting the charge / discharge command value to the energy storage device which can not perform the charging / discharging operation, thereby lowering the accuracy of the system operation.

The present invention can improve the performance score of the energy storage device by transmitting a charge / discharge command value or a correction command value to the energy storage device according to the SOC status information or the charge / discharge power amount of the energy storage device, Discharge command value to be compensated for an amount of power that fails to follow the charge / discharge command value.

In addition, the present invention determines whether the energy storage device can perform a charge-discharge operation based on SOC state information, thereby preventing a charge / discharge command value from being transmitted to an energy storage device that can not perform a charge / discharge operation It is an object of the present invention to provide an energy storage device management method capable of preventing the performance score of the energy storage device from being lowered.

It is another object of the present invention to provide an energy storage device management method capable of improving the accuracy of a system operation by generating a correction command value by correcting a charge / discharge command value so that a charge / discharge power amount follows a charge / discharge command value do.

In addition, the present invention sets the penalty charge for the correction command value so that the system operator can be financially compensated for the power loss caused by the low efficiency of the energy storage device, And to provide a method of managing an energy storage device that is continuously managed.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention which are not mentioned can be understood by the following description and more clearly understood by the embodiments of the present invention. It will also be readily apparent that the objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.

According to an aspect of the present invention, there is provided an energy storage device management method comprising: receiving SOC status information from at least one energy storage device; Discharge command value; comparing the charge / discharge command value with a charge / discharge power amount of the one or more energy storage devices; and comparing the correction command value, which is the charge / discharge command value, To the storage device.

According to the present invention, the charging / discharging command value or the correction command value is transmitted to the energy storage device according to the SOC status information or the charge / discharge power amount of the energy storage device, thereby improving the performance score of the energy storage device And the system operator can be financially compensated for the amount of power that does not follow the charge / discharge command value.

According to the present invention, it is possible to prevent the charging / discharging command value from being transmitted to the energy storage device which can not perform the charging / discharging operation by determining whether the energy storage device can perform the charging / discharging operation based on the SOC state information So that the performance score of the energy storage device can be prevented from being lowered.

In addition, according to the present invention, it is possible to improve the accuracy of the system operation by generating the correction command value by correcting the charge / discharge command value so that the charge / discharge power amount follows the charge / discharge command value.

In addition, according to the present invention, by setting a penalty charge for the correction command value, it is possible to allow the system operator to financially compensate for the power loss caused by the low efficiency of the energy storage device, To be managed continuously.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows a view of managing a plurality of energy storage devices according to a conventional method; Fig.
2 is a flowchart illustrating an energy storage device management method according to an embodiment of the present invention;
FIG. 3 illustrates a view of managing a plurality of energy storage devices in accordance with the present invention. FIG.
4 is a flowchart showing a process of generating a correction command value according to an embodiment of the present invention;

The above and other objects, features, and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings, which are not intended to limit the scope of the present invention. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to denote the same or similar elements.

The present invention relates to a method for managing an energy storage system (ESS) that stores power supplied from a power system or supplies stored power to a power system. The energy storage device management method of the present invention can be performed by an energy management system (EMS, 100).

The power system (GRID) means a system in which a power plant, a substation, a transmission and distribution line, and a load are integrated to generate and utilize electric power. For example, a power system may include industrial facilities such as factories from a general household using electrical power, and may include thermal power, wind power, solar power, nuclear power plants, and the like that produce electricity.

Accordingly, the energy storage device can store (charge) the electric power produced by the power plant or the like in the battery, and when the electric power supplied to the load is insufficient, the electric power stored in the battery can be transmitted (discharged) to the load.

In other words, the energy storage device can perform the charge / discharge operation according to the charge / discharge command value of the power management system 100 that monitors the power system. The present invention relates to a method of managing an energy storage device by transmitting a charge / discharge command value or a correction command value to an energy storage device capable of charging / discharging operations.

2 is a flowchart illustrating an energy storage device management method according to an embodiment of the present invention. Referring to FIG. 2, an energy storage device management method according to an exemplary embodiment of the present invention includes receiving SOC state information of each energy storage device (S210), and calculating a charge / discharge command value (Step S220).

The method of managing an energy storage device of the present invention may further include comparing a charge / discharge command value with a charge / discharge power amount of the energy storage device (S230), and transmitting a correction command value to the energy storage device .

The method of managing the energy storage device shown in FIG. 2 is according to one embodiment, and the order and the sequence of constituent elements are not limited to the embodiment shown in FIG. 2, , Changed or deleted.

FIG. 3 is a diagram illustrating a method of managing a plurality of energy storage devices (ESS 1 to ESS N) according to the present invention, and FIG. 4 illustrates a process of generating a correction command value according to an embodiment of the present invention It is a flowchart. Hereinafter, steps S210 to S240 described above with reference to Figs. 2 to 4 will be described in detail.

Referring to FIG. 3, as described above, the energy storage device management method of the present invention can be performed by an energy management system (EMS) 100. The power management system 100 may be a system operated by a grid operator and may include a power exchange that charges or compensates an electric utility for electricity while regulating the supply and demand of the power.

Such a power management system 100 may be located in the control room, and the power control apparatus 110 and the plurality of energy storage devices may be located in the field. More specifically, the site is a location where actual movement of power occurs under the control of the system operator, and the control room is a location for controlling the energy storage device of the electric company through the power management system 100.

Generally, the control room and the site can be physically separated, and the system operator located in the control room can control the individual energy storage devices of the electric utility located in the field. Meanwhile, the power control apparatus 110 shown in FIG. 3 may serve as a relay for transferring the charge / discharge command value generated in the power management system 100 to each energy storage device.

Also, the power control apparatus 110 may receive the status information of the energy storage device and transmit the status information to the power management system 100. More specifically, the power control apparatus 110 receives status information on the operating state (charging state or discharging state) of the energy storage device, abnormality state, battery abnormality state, and communication state abnormality and sends the state information to the power management system 100 .

Referring to Figures 2 and 3, the power management system 100 of the present invention may receive SOC status information from one or more energy storage devices (S210). Here, the SOC state information may include a State Of Charge (SOC) of the battery.

More specifically, in the present invention, each energy storage device may include a battery management device for managing the battery and the battery. The battery management device is a device equipped with software for managing status information of a battery, and may be, for example, a battery management system (BMS).

The battery management device can measure the state of charge (SOC) of the battery and transmit it to the power management system 100. Alternatively, the energy storage device may receive a charge amount of the battery from the battery management device, and may transmit the charge amount of the received battery to the power management system 100. [ To this end, the energy storage device or the battery management device may include a communication module for performing data communication with the power management system 100. The power management system 100 may monitor the received battery charge amount.

Referring again to FIG. 2, the power management system 100 according to an exemplary embodiment of the present invention may transmit a charge / discharge command value to one or more energy storage devices according to received SOC state information (S220).

Here, the charge / discharge command value includes a charge command value and a discharge command value. The charge command value and the discharge command value may include information on the total energy storage managed by the power management system 100 or the amount of power that each energy storage device should charge and discharge.

Accordingly, the power management system 100 can transmit the charge command value to the energy storage device having a low battery charge amount based on the SOC state information. On the other hand, the power management system 100 can transmit the discharge command value to the energy storage device having a large battery charge amount based on the SOC state information.

Referring to FIG. 3, the energy storage device receiving the charging command value may receive the amount of power corresponding to the charging command value from the power system (GRID) and store the amount of power in the battery. On the other hand, the energy storage device receiving the discharge command value can discharge the electric power corresponding to the discharge command value from the electric power stored in the battery to the electric power system (GRID).

However, the energy storage device can preset the minimum charge amount and the maximum charge amount in order to maintain high efficiency of battery charge / discharge. For example, the minimum charge amount may be set to 10% of the maximum amount of energy that the energy storage device can charge. In addition, the maximum charge amount can be set to 90% of the maximum amount of energy that the energy storage device can charge.

Accordingly, the energy storage device with the battery charge amount of 90% or more does not perform the charge operation, and the energy storage device with the battery charge amount of less than 10% may not perform the discharge operation.

The power management system 100 of the present invention can check the battery charge amount of each energy storage device based on the received SOC state information and transmit the charge / discharge command value to the energy storage device capable of performing the battery charge / discharge operation have.

More specifically, the power management system 100 according to an embodiment of the present invention can determine whether one or more energy storage devices can perform charge / discharge operations based on the received SOC state information.

The power management system 100 can check whether the battery charge amount of each energy storage device exceeds the maximum charge amount based on the received SOC state information. In addition, the power management system 100 can determine whether the battery charge amount of each energy storage device is less than the minimum charge amount based on the received SOC state information.

The power management system 100 may determine that the energy storage device can perform the charging operation if the battery charging amount of the energy storage device is less than the maximum charging amount. Also, the power management system 100 may determine that the energy storage device can perform the discharging operation when the battery charging amount of the energy storage device exceeds the minimum charging amount.

Referring to FIG. 4, the power management system 100 according to an embodiment of the present invention can perform charge / discharge operations of one or more energy storage devices when the battery charge amount included in the SOC status information is within a preset range (S410).

The predetermined range may be set differently corresponding to the charging operation and the discharging operation, respectively. More specifically, the predetermined range for the charging operation may be in a range below the maximum charging amount described above.

In other words, the range of the battery charge amount at which the energy storage device is judged to be capable of performing the charging operation can be set in a range from 0% to 90% of the maximum amount of the energy storage device can charge.

Further, the predetermined range for the discharging operation may be a range exceeding the above-described minimum charging amount. In other words, the range of the battery charge amount at which the energy storage device is judged to be capable of performing the discharging operation can be set in a range of 10% to 100% of the maximum amount of the energy storage device can charge.

The power management system 100 compares the battery charge amount based on the received SOC state information with the preset range and determines that the energy storage device can perform the charge / discharge operation when the battery charge amount is within a predetermined range .

Meanwhile, the SOC state information of the present invention may include information on whether or not the energy storage device can perform a charge / discharge operation. More specifically, each energy storage device can compare its battery charge amount with the above-described minimum charge amount, maximum charge amount, or preset range to determine whether the charge operation or the discharge operation can be performed.

If it is determined that the charge / discharge operation is to be performed, the energy storage device may transmit the determination result to the power management system 100 by including the determination result in the SOC state information. Accordingly, the power management system 100 can immediately determine whether or not the energy storage device can perform the charge / discharge operation based on the SOC state information.

As described above, the present invention determines whether or not the energy storage device can perform the charge / discharge operation based on the SOC state information, thereby transmitting the charge / discharge command value to the energy storage device that can not perform the charge / discharge operation The performance score of the energy storage device can be prevented from deteriorating.

Referring again to FIG. 2, the power management system 100 according to an exemplary embodiment of the present invention transmits a charge / discharge command value to one or more energy storage devices when it is determined that one or more energy storage devices can perform charge / (S220).

More specifically, the power management system 100 can transmit the charge / discharge command value only to the energy storage device determined to be capable of performing a charge / discharge operation among a plurality of energy storage devices.

Alternatively, the power management system 100 may send a charge / discharge command to all energy storage devices. In this case, it is possible to transmit the charge / discharge command value to the energy storage device determined to be unable to perform the charge / discharge operation. In other words, the energy storage device determined to be unable to perform the charge / discharge operation may not perform the charge / discharge operation even if it receives the charge / discharge instruction value.

As described above, the energy storage device that receives the charging command value can receive the amount of power corresponding to the charging command value from the power system and store it in the battery. On the other hand, the energy storage device receiving the discharge command value can discharge the electric power corresponding to the discharge command value among the electric power stored in the battery to the electric power system.

Referring again to FIG. 2, the power management system 100 according to an exemplary embodiment of the present invention may compare a charge / discharge command value with a charge / discharge power amount of one or more energy storage devices (S230).

The charge / discharge power may be the amount of power actually charged or discharged by the energy storage device depending on the charge / discharge command value. The power management system 100 can monitor the charge / discharge power amount of the energy storage device and compare the charge / discharge power amount with the charge / discharge command value.

More specifically, the charge / discharge command value may differ from the charge amount of the actual energy storage device due to the reduced efficiency due to the performance degradation of the energy storage device. In other words, an error may occur in the charge / discharge command value and the actual charge / discharge power amount.

The power management system 100 can calculate the difference between the charge / discharge command value and the charge / discharge power amount. In general, the energy storage device can not completely follow the charge / discharge command value due to the physical limit, so the charge / discharge command value is larger than the charge / discharge power amount. Accordingly, the difference between the charge / discharge command value and the charge / discharge power amount may be a value obtained by subtracting the charge / discharge power amount from the charge / discharge command value.

The power management system 100 according to an embodiment of the present invention can determine whether the charge / discharge command value is corrected based on the difference between the charge / discharge command value and the charge / discharge power amount. 4, the power management system 100 may determine whether the charge / discharge command value is corrected by comparing the difference between the charge / discharge command value and the charge / discharge power value with a preset value (S420).

When the difference between the charge / discharge command value and the charge / discharge power amount exceeds a predetermined value, the power system can determine that the charge / discharge command value needs to be corrected. On the other hand, if the difference between the charge / discharge command value and the charge / discharge power amount is less than a predetermined value, the power system can judge that the charge / discharge command value does not need to be corrected.

For example, in FIG. 3, the charging command value received at ESS 1 and ESS 2 may be 2 [MW] and the preset value may be 0.2 [MW]. At this time, the amount of electric power charged in ESS 1 may be 1.7 [MW] and the amount of electric power charged in ESS 2 may be 1.9 [MW].

The difference between the charge / discharge command value and the charge / discharge power amount in ESS 1 exceeds 0.3 [MW] and exceeds 0.2 [MW]. Therefore, the power management system 100 determines that the charge command value transmitted to the ESS 1 needs to be corrected .

On the other hand, since the difference value between the charge / discharge command value and the charge / discharge power amount in ESS 2 does not exceed 0.2 [MW] in 0.1 [MW], the power management system 100 can not correct the charge command value transmitted to the ESS 2 It can be judged that it is not necessary.

In other words, the preset value can be set according to the efficiency required for each energy storage device. For example, if the efficiency required by the system operator is 90% efficiency, the preset value may be set to a value obtained by subtracting 90% from the charge / discharge command value at the charge / discharge command value.

인 0.1[MW]로 설정될 수 있다. 이에 따라, 충방전 지령값과 충방전 전력량의 차이값이 0.1[MW]를 초과하면 충방전 지령값에 보정이 필요할 수 있고, 0.1[MW]를 초과하지 않으면 충방전 지령값에 보정이 필요하지 않을 수 있다.In other words, if the charge / discharge command value is 1 [MW], the preset value

0.1 [MW]. Accordingly, if the difference between the charge / discharge command value and the charge / discharge power amount exceeds 0.1 [MW], the charge / discharge command value may need to be corrected. If the difference value does not exceed 0.1 [MW], the charge / .

Referring to FIG. 2 again, the power management system 100 according to an embodiment of the present invention stores a correction command value, which is a charge / discharge command value corrected based on a comparison result between a charge / discharge command value and a charge / To the device (S240).

4, the power management system 100 according to an embodiment of the present invention can generate a correction command value by correcting the charge / discharge command value so that the charge / discharge power amount follows the charge / discharge command value (S430).

As described above, an error may occur in charge / discharge command value and charge / discharge power amount. Accordingly, the power management system 100 can generate the correction command value so that the charge / discharge power amount of the energy storage device follows the existing charge / discharge command value.

The correction command value can be calculated by multiplying the charge / discharge command value by a correction coefficient. Where the correction factor may be the reciprocal of the energy storage efficiency. More specifically, in FIG. 3, if the charge command value received at ESS 1 is 2 [MW] and the amount of power actually charged to ESS 1 is 1.7 [MW], the efficiency of ESS 1 is 85% with 1.7 / 2.

At this time, the correction coefficient may be 2 / 1.7, which is the reciprocal of the efficiency of ESS 1. Accordingly, the power management system 100 can generate a correction command value of 2.353 [MW], which is obtained by multiplying the existing charge command value 2 [MW] by the correction coefficient.

In another example, when the discharge command value received at ESS 3 in FIG. 3 is 1 [MW] and the amount of power actually discharged by ESS 3 is 0.7 [MW], it is determined that the discharge command value for ESS 3 needs to be corrected .

Since the efficiency of ESS 3 is 70%, which is 0.7 / 1, the correction factor can be 1 / 0.7, which is the reciprocal of the efficiency of ESS 3. Accordingly, the power management system 100 can generate the correction command value at 1.429 [MW] which is the original discharge command value 1 [MW] multiplied by the correction coefficient.

The power management system 100 of the present invention can transmit the generated correction command value to one or more energy storage devices and the energy storage device that receives the correction command value can perform the charge and discharge operations according to the correction command value .

In the above example, ESS 1 can perform the charging operation in accordance with the correction command value of 2.353 [MW]. More specifically, since the efficiency of ESS 1 is 85%, the actual charging power amount of ESS 1 according to the correction command value may be 2 [MW].

Also, in the above example, ESS 3 can perform the discharge operation according to the correction command value of 1.429 [MW]. More specifically, since the efficiency of ESS 3 is 70%, the actual discharge power amount of ESS 1 according to the correction command value may be 1 [MW].

In other words, the power management system 100 transmits a correction command value that corrects the existing charge / discharge command value to the energy storage device so that each energy storage device charges or discharges the amount of power corresponding to the existing charge / discharge command value can do.

As described above, the present invention can improve the accuracy of the system operation by generating the correction command value by correcting the charge / discharge command value so that the charge / discharge power amount follows the charge / discharge command value.

More specifically, the charge / discharge command value means the charge / discharge power amount of the power intended by the system operator operating the power management system 100. However, depending on the efficiency of the energy storage device, the actual charge / discharge power may be different from the charge / discharge power intended by the system operator.

At this time, by generating the correction command value and making the actual charge / discharge power amount of the energy storage device equal to the charge / discharge power amount intended by the system operator, according to the present invention, it is possible to perform accurate system operation reflecting the intention of the system operator.

The power management system 100 according to an embodiment of the present invention can set an electricity rate for a charge / discharge command value. As described above, the power management system 100 may be a power exchange.

Accordingly, a system operator operating a KPX can charge electric utilities operating an energy storage device in the field or compensate electric utilities for electric utilities. In other words, the user operating the power management system 100 located in the control room in FIG. 3 may be different from the user operating the power control device 110 and the plurality of energy storage devices located in the field.

The electric charge may be set in accordance with the charge / discharge command value. In other words, the electric charge may be set corresponding to the charge / discharge command value transmitted from the power management system 100, rather than being set corresponding to the amount of electric power actually charged or discharged by the energy storage device.

More specifically, the electricity bill may include an electricity bill set corresponding to the charge command value and an electricity bill set corresponding to the discharge command value. Accordingly, when the energy storage device charges the battery with the power supplied from the power system according to the charging command value, the system operator can charge the electric company with the electric charge corresponding to the charging command value.

On the other hand, when the energy storage device discharges the power stored in the battery to the power system according to the discharge command value, the system operator can compensate the electric charge corresponding to the discharge command value to the electric utility.

The electricity rate corresponding to the charging command value and the electricity rate corresponding to the discharge command value can be set to the electricity rate corresponding to the unit electric power amount and can be set to different rates.

Electricity companies operating a number of energy storage devices may be paid or reimbursed for electricity charges based on the daily charge, discharge rate, or monthly charge accumulated charge.

The power management system 100 according to an exemplary embodiment of the present invention may set a penalty charge for the correction command value. The compensation command value may be larger than the charge / discharge command value. In other words, since the correction command value is generated when the actual charge / discharge power amount of the energy storage device does not sufficiently follow the charge / discharge command value, the correction command value is generated to be larger than the charge / discharge command value.

The above-mentioned electric charge can be set for the portion corresponding to the charge / discharge command value in the correction command value. However, the addition charge or reduction charge may be set for the portion added from the existing charge / discharge command value. At this time, the addition charge may be larger than the above-mentioned electric charge, and the reduction charge may be smaller than the above-mentioned electric charge.

For example, if the energy storage device does not charge enough power according to the charge command value, the power management system 100 may send a correction command value to the energy storage device. Since the correction command value is generated only when the efficiency of the energy storage device is low, the system operator can impose an add charge on the added portion from the existing charge command value to the electric utility.

In other words, the penalty charge imposed on the electric utility that has received the correction command value may be a charge for the electricity charge for the existing charge command value plus an add charge for the portion added from the existing charge command value.

More specifically, when the existing charge command value transmitted to the ESS 1 shown in FIG. 3 is 2 [MW] and the efficiency of the ESS 1 is 85%, the correction command value is generated as 2.353 [MW] as described above . At this time, the penalty charge imposed on the electric operator for ESS 1 may be the sum of the electric charge for 2 [MW] plus the add charge for 0.353 [MW].

In another example, if the energy storage device does not discharge enough power according to the discharge command value, the power management system 100 may send a correction command value to the energy storage device. Since the correction command value is generated only when the efficiency of the energy storage device is low, the system operator can compensate the electric utilities for the subtraction charge on the added portion from the existing discharge command value.

In other words, the penalty charge compensated for by the electric utility receiving the correction command value may be a rate obtained by adding the subtraction rate for the portion added from the existing discharge command value to the electric charge for the existing discharge command value.

More specifically, when the existing discharge command value transmitted to the ESS 3 shown in FIG. 3 is 1 [MW] and the efficiency of the ESS 3 is 70%, the correction command value is generated as 1.429 [MW] as described above . At this time, the penalty charge for which the electric utility is compensated for ESS 3 may be the charge for the electric charge for 1 [MW] plus the subtraction charge for 0.429 [MW].

The addition charge and the reduction charge described above can be set in advance through a contract between the system operator operating the power management system 100 of the present invention and the electric power provider operating the energy storage device of the present invention.

As described above, the present invention sets the penalty charge for the correction command value, thereby allowing the system operator to financially compensate for the power loss caused by the low efficiency of the energy storage device, To manage the performance of the system continuously.

In summary, the present invention can improve a performance score of an energy storage device by transmitting a charge / discharge command value or a correction command value to an energy storage device according to SOC state information or charge / discharge power amount of the energy storage device , So that the system operator can be financially compensated for the amount of power that does not follow the charge / discharge command value.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, But the present invention is not limited thereto.

Claims (8)

Receiving SOC state information from the one or more energy storage devices;
Transmitting a charge / discharge command value to the one or more energy storage devices according to the received SOC state information;
Comparing the charge / discharge command value with a charge / discharge power amount of the at least one energy storage device; And
And transmitting to the at least one energy storage device a correction command value obtained by correcting the charge / discharge command value according to the comparison result
How to manage energy storage devices.
The method according to claim 1,
The charge / discharge power amount
Wherein the at least one energy storage device is charged or discharged according to the charge / discharge command value.
The method according to claim 1,
The step of transmitting the charge / discharge command value to the at least one energy storage device according to the received SOC state information
Determining whether the one or more energy storage devices can perform a charge / discharge operation based on the received SOC state information; And
And transmitting a charge and discharge command value to the at least one energy storage device when it is determined that the at least one energy storage device can perform a charge and discharge operation.
The method of claim 3,
Wherein the step of determining whether the one or more energy storage devices can perform a charge and discharge operation based on the received SOC state information
And determining that the at least one energy storage device can perform a charge / discharge operation when the battery charge amount included in the SOC state information is within a preset range.
The method according to claim 1,
Wherein the step of comparing the charge / discharge command value with the charge / discharge power amount of the at least one energy storage device
And determining whether the charge / discharge command value needs to be corrected based on a difference between the charge / discharge command value and the charge / discharge power amount.
The method according to claim 1,
Wherein the step of transmitting the correction command value corrected for the charge / discharge command value to the at least one energy storage device in accordance with the comparison result
Generating a correction command value by correcting the charge / discharge command value so that the charge / discharge power amount follows the charge / discharge command value; And
And transmitting the generated correction command value to the one or more energy storage devices.
The method according to claim 1,
And setting an electricity charge for the charge / discharge command value.
The method according to claim 1,
And setting a penalty charge for the correction command value.

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