KR102169772B1 - Device for Controlling Battery of Energy Storage Equipment - Google Patents

Abstract

Provided is a battery control device of an energy storage facility. The battery control device of an energy storage facility that is connected to a power network to control a battery provided in the energy storage facility for supplying power to a customer can comprise: a discharge capacity setting module that divides the total available discharge capacity of the battery into a peak cut control discharge capacity and a schedule control discharge capacity; a peak cut control module that peak-cut controls the amount of discharge of the battery according to the peak cut control discharge capacity so that the power consumption of the customer does not exceed preset maximum power consumption; a schedule control module that schedule controls the amount of discharge of the battery to be discharged to the schedule control discharge capacity preset for each time slot; and a residual discharge capacity carry forward module that carries forward a residual discharge capacity remained after being used for peak cut control from the peak cut control discharge capacity allocated to a specific time zone to the next time slot right after the specific time slot, and adds the same to the schedule control discharge capacity controlled by the schedule control module.

Description

TECHNICAL FIELD The device for controlling battery of energy storage equipment TECHNICAL FIELD

The present invention relates to a battery control device of an energy storage facility, and more specifically, to a battery control device of an energy storage facility capable of improving the battery utilization rate of the energy storage facility.

In recent years, as the supply of renewable energy increases and the demand for a smart grid increases, the importance of energy storage devices in the next generation power grid is gradually increasing. Energy storage devices are mainly used for connecting renewable energy and energy management in buildings and factories.

In the case of an energy storage device for energy management in buildings and factories, the battery is charged during the late night time when the power rate is low and the electricity charged in the battery is discharged during the day when the power rate is high. In the case of energy storage devices for energy management, by reducing the peak value of the power consumption during the day, while benefiting from the difference between the low cost of electricity in the late night and the high cost of the day in the week, the size of the contracted power is kept low. It also has the effect of lowering the overall electricity bill.

Conventional energy storage devices for energy management analyze the past load pattern and discharge with a set amount of power according to the time period, and set the maximum value of power consumption and discharge so that the power consumption does not exceed the set maximum value (P _max ). It is operated in a peak-cut control method that controls the amount of power generated.

Users want to maximize profits by increasing the battery utilization rate of the energy storage device, but each control method has its drawbacks.

In the case of the schedule control method, when power consumption greater than the general load pattern occurs, the contract power cannot be kept low due to the occurrence of a high power peak. In addition, in the case of the peak cut control method, the use rate of the battery is lowered, resulting in a problem of reducing profits.

Accordingly, in order to increase the profits of users who operate energy storage devices for energy management in buildings and factories, a control method capable of maximizing battery utilization while limiting power peaks is required.

One technical problem to be solved by the present invention is to provide a battery control device for an energy storage facility capable of improving the battery utilization rate of the energy storage facility.

Another technical problem to be solved by the present invention is to provide a battery control device for an energy storage facility capable of improving the profits of a user who operates an energy storage facility for energy management of buildings and factories.

The technical problem to be solved by the present invention is not limited to the above.

In order to solve the above technical problem, the present invention provides a battery control device for an energy storage facility.

According to an embodiment, a battery control device of an energy storage facility is a battery control device that controls a battery provided in an energy storage facility that is connected to a power grid and supplies power to a customer, and peaks the total available discharge capacity of the battery. A discharge capacity setting module divided into a discharge capacity for cut control and a discharge capacity for schedule control; A peak cut control module configured to peak cut control the amount of discharge of the battery according to the peak cut control discharge capacity so that the power consumption of the customer does not exceed a preset maximum power consumption; A schedule control module configured to schedule a discharge amount of the battery to be discharged to the schedule control discharge capacity preset for each time period; And the discharge capacity for schedule control controlled by the schedule control module by carrying over the remaining discharge capacity used for the peak cut control to the next time set consecutively with the specific time period among the discharge capacity for peak cut control allocated to a specific time period. It may include a residual discharge capacity carryover module that adds up to.

According to an embodiment, a power consumption pattern analysis module may be further included, and the power consumption pattern analysis module may analyze a past power consumption pattern of a customer equipped with the energy storage facility.

According to an embodiment, the discharge capacity setting module may set a division ratio between the peak cut control discharge capacity and the schedule control discharge capacity according to the power consumption pattern of the customer analyzed by the power consumption pattern analysis module. .

According to an embodiment, further comprising a peak cut discharge capacity distribution module and a schedule discharge capacity distribution module, wherein the peak cut discharge capacity distribution module distributes the peak cut control discharge capacity set by the discharge capacity setting module for each time period, , The schedule discharge capacity distribution module may distribute the schedule control discharge capacity set by the discharge capacity setting module for each time period.

According to an embodiment, the discharge capacity setting module sets the peak cut control discharge capacity to be greater than the schedule control discharge capacity when the customer's power consumption is wide among the customer's power consumption patterns. When the fluctuation width of the power consumption of is relatively narrow, the peak cut control discharge capacity may be set to be less than the schedule control discharge capacity.

According to an embodiment, the schedule control module schedules the amount of discharge of the battery so that the battery is discharged to the preset discharge capacity in proportion to time, or the preset discharge capacity with a constant discharge amount over a specific time period. Until the battery is discharged, the amount of discharge of the battery may be controlled by a schedule.

According to an embodiment, the schedule control module includes the remaining discharge capacity used for peak cut control in a previous time period, carried forward by the residual discharge capacity carryover module, and the schedule control discharge allocated for schedule control in the current time period. The amount of discharge of the battery may be scheduled to be controlled so that the battery is discharged with the summed discharge capacity.

According to an embodiment of the present invention, a battery control device for controlling a battery provided in an energy storage facility that is connected to a power grid and supplies power to a customer, wherein the total available discharge capacity of the battery is peak-cut control discharge capacity and schedule control. A discharge capacity setting module divided by discharge capacity; A peak cut control module configured to peak cut control the amount of discharge of the battery according to the peak cut control discharge capacity so that the power consumption of the customer does not exceed a preset maximum power consumption; A schedule control module configured to schedule a discharge amount of the battery to be discharged to the schedule control discharge capacity preset for each time period; And the discharge capacity for schedule control controlled by the schedule control module by carrying over the remaining discharge capacity used for the peak cut control to the next time set consecutively with the specific time period among the discharge capacity for peak cut control allocated to a specific time period. It may include a residual discharge capacity carryover module that adds up to.

Accordingly, a battery control device of an energy storage facility capable of improving the battery utilization rate of the energy storage facility may be provided.

In addition, according to an embodiment of the present invention, by combining the advantages of a schedule control method that increases battery utilization and a peak cut control method that can lower contract power by keeping the power peak low, energy storage facilities for building and factory energy management A battery control device of an energy storage facility may be provided that can improve the profit of the user who operates the device.

1 is a schematic diagram of a power grid including an energy storage facility according to an embodiment of the present invention.
2 is a block diagram illustrating a battery control device of an energy storage facility according to an embodiment of the present invention.
3 is a block diagram illustrating a discharge capacity setting module in a battery control device of an energy storage facility according to an embodiment of the present invention.
4 is a reference diagram showing the available battery capacity divided into a peak cut control discharge capacity and a schedule control discharge capacity by a discharge capacity setting module in the battery control device of an energy storage facility according to an embodiment of the present invention.
5 is a block diagram illustrating a battery control device of an energy storage facility according to an embodiment of the present invention, which further includes a power consumption pattern analysis module, a peak cut discharge capacity distribution module, and a schedule discharge capacity distribution module. .
6 is a block diagram illustrating a power consumption pattern analysis module in a battery control device of an energy storage facility according to an embodiment of the present invention.
7 is a graph showing peak cut discharge capacity and schedule discharge capacity for each time period distributed by a peak cut discharge capacity distribution module and a schedule discharge capacity distribution module in the battery control device of an energy storage facility according to an embodiment of the present invention. .
8 is a graph showing a form in which residual discharge capacity is carried over and summed over time by a residual discharge capacity carryover module in the battery control device of an energy storage facility according to an embodiment of the present invention.
9 is a flowchart illustrating a battery control method of an energy storage facility according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the technical idea of the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content may be thorough and complete, and the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

In the present specification, when a component is referred to as being on another component, it means that it may be formed directly on the other component or that a third component may be interposed between them. In addition, in the drawings, the shape and size are exaggerated for effective description of technical content.

In addition, in various embodiments of the present specification, terms such as first, second, and third are used to describe various components, but these components should not be limited by these terms. These terms are only used to distinguish one component from another component. Accordingly, what is referred to as a first component in one embodiment may be referred to as a second component in another embodiment. Each embodiment described and illustrated herein also includes its complementary embodiment. In addition, in the present specification,'and/or' is used to mean including at least one of the elements listed before and after.

In the specification, expressions in the singular include plural expressions unless the context clearly indicates otherwise. In addition, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, elements, or a combination of the features described in the specification, and one or more other features, numbers, steps, and configurations It is not to be understood as excluding the possibility of the presence or addition of elements or combinations thereof. In addition, in the present specification, "connection" is used to include both indirectly connecting a plurality of constituent elements and direct connecting.

Further, in the following description of the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

1 to 8 are views for explaining a battery control device of an energy storage facility according to an embodiment of the present invention.

As shown in FIG. 1, the battery control device 100 according to an embodiment of the present invention is provided in the energy storage facility 30.

Here, the energy storage facility 30 is a facility that is connected to the power grid 10, for example, a power plant or a transmission tower that supplies power, and supplies power to the consumer 20 side. The customer 20 may mean a subject that consumes power. Household or industrial facilities may be the subject of power consumption, and specific requirements such as required amount of power and voltage may vary according to the type and time of each consumer.

The energy storage facility 30 may include a battery B. The battery B may be provided as a secondary battery capable of charging and discharging, and may be formed of, for example, lithium ions and sodium sulfate.

The energy storage facility 30 charges the battery B by receiving electricity from the power grid 10 during the late-night time when the power rate is low, and discharges the battery B during the day time when the power rate is high, so as to receive power. It can be supplied to the (20) side. In addition, the energy storage facility 30 supplies electricity to the customer 20 during a period in which the demand for power increases rapidly, such as in the summer, and the demand for power fluctuates severely, so that the electricity is supplied to the customer 20 through the power grid 10. It can be controlled to lower the peak value of the amount of power directly supplied.

That is, the energy storage facility 30 may be defined as a storage facility that stores excessively produced power in a power plant and transmits it to the customer 20 when the power is temporarily insufficient.

The battery control device 100 according to an embodiment of the present invention includes the battery B provided in the energy storage facility 30 connected to the power grid 10 to supply power to the customer 20 as described above. It is a device that controls the discharge capacity.

As shown in FIG. 2, the battery control device 100 according to an embodiment of the present invention includes a discharge capacity setting module 110, a peak cut control module 120, a schedule control module 130, and a residual discharge capacity carryover. It may be formed including the module 140.

The discharge capacity setting module 110 may divide the total available discharge capacity of the battery B into a discharge capacity for peak cut control and a discharge capacity for schedule control.

As shown in FIG. 3, the discharge capacity setting module 110 may include a communication unit 111, an operation unit 112, and a database 113.

The communication unit 111 communicates with a communication module (not shown) mounted on the battery B. The communication unit 111 may receive information on the available discharge capacity of the battery B from a communication module (not shown). In this case, the information on the available discharge capacity of the battery B transmitted from the communication module (not shown) may be the maximum amount of charge of the battery B charged through the power grid 10.

The operation unit 112 divides the total available discharge capacity of the battery B delivered from the communication unit 111 into a peak cut control discharge capacity and a schedule control discharge capacity.

In this case, as shown in FIG. 4, the operation unit 112 may calculate a division ratio between the peak cut control discharge capacity and the schedule control discharge capacity according to the power consumption pattern of the customer 20. For example, when the electric power demand or the electric power consumption fluctuates severely, such as in the summer season (left graph of Fig. 4), that is, if the power consumption fluctuation range on the customer side is wide, the ratio of the peak cut control discharge capacity Can be set larger than the ratio of the discharge capacity for schedule control. In addition, when the power demand or the power consumption fluctuates relatively less, such as in spring or autumn (the right graph in Fig. 4), in other words, when the power consumption fluctuation range on the customer side is relatively narrow, the schedule control discharge The ratio of the capacity can be set larger than the ratio of the discharge capacity for peak cut control.

As another example, the operation unit 112 may set the peak cut control discharge capacity to be greater than the schedule control discharge capacity in a section in which the power consumption of the customer 20 side of the power consumption pattern of the customer 20 exceeds a preset maximum power consumption. . In addition, the operation unit 112 may set the peak cut control discharge capacity to be less than the schedule control discharge capacity in a section in which the power consumption of the customer 20 does not exceed a preset maximum power consumption. Through this, the utilization rate of the battery B may be improved.

In this way, based on the power consumption pattern for each period of the customer 20, the information on the peak cut control discharge capacity and the schedule control discharge capacity for the total available discharge capacity of the battery B, set by the operation unit 112, is provided by the communication unit. It is transmitted to the peak cut control module 120 and the schedule control module 130 through 111, respectively.

The database 113 stores information on the peak cut control discharge capacity and the schedule control discharge capacity with respect to the total available discharge capacity of the battery B, set by the operation unit 112.

Meanwhile, as shown in FIG. 5, the battery control apparatus 100 according to an embodiment of the present invention may further include a power consumption pattern analysis module 150.

The power consumption pattern analysis module 150 analyzes the past power consumption pattern of the customer 20 equipped with the energy storage facility 30 and provides it to the discharge capacity setting module 110. Accordingly, the discharge capacity setting module 110, more specifically, the calculation unit 112 of the discharge capacity setting module 110, is based on the power consumption pattern of the customer 20 analyzed by the power consumption pattern analysis module 150. , It determines or calculates the division ratio between the peak cut control discharge capacity and the schedule control discharge capacity with respect to the total available discharge capacity of the battery B.

As shown in FIG. 6, the power consumption pattern analysis module 150 that provides the power consumption pattern of the customer 20 to the discharge capacity setting module 110 includes a receiver 151, a pattern analysis unit 152, and an output unit. (153) may be included.

The receiving unit 151 communicates with a communication module (not shown) installed on the side of the customer 20 to receive a power consumption pattern on the side of the customer 20. In this case, the receiving unit 151 may receive information on the power usage of the customer 20 from a communication module (not shown) installed on the customer 20 side for each time period. In this case, the information on the power usage of the customer 20 side received by the receiving unit 151 may be stored in a separate database.

The pattern analysis unit 152 calculates the power consumption pattern of the customer 20 by time, day, month, year, and for a specific period, based on the information on the power use of the customer 20 received by the receiving unit 151. Can be analyzed. For example, the pattern analysis unit 152 may use the customer 20's yearly and previous year's power consumption change, the maximum and minimum power consumption period or time of the year, etc. Patterned power consumption information can be generated by analyzing monthly and daily power consumption trends.

The output unit 153, according to the analyzed power consumption pattern of the customer 20, the discharge capacity setting module 110 to the ratio of the peak cut control discharge capacity to the total available capacity of the battery B and the schedule control discharge In order to set the ratio of the capacity, the power consumption pattern of the customer 20 side generated by the pattern analysis unit 1520 is output to the discharge capacity setting module 110.

Again, referring to FIG. 5, the battery control apparatus 100 according to an embodiment of the present invention may further include a peak cut discharge capacity distribution module 160.

As shown in FIG. 7, the peak cut discharge capacity distribution module 160 may distribute the peak cut control discharge capacity set by the discharge capacity setting module 110 for each time period. For example, the peak-cut discharge capacity allocation module 160 in total T ₀ to time T is set to _7, it is possible to set the maximum discharge capacity in the time T ₁ -T _{2 pk1} P, T ₂ -T ₃ times The maximum dischargeable capacity can be set as P _pk2 in, and the maximum dischargeable capacity can be set as P _pk3 in the T ₃ -T ₄ time zone. In addition, the distribution peak-cut discharge capacity module 160 may set the maximum discharge capacity at a time T ₄ -T _{5 pk4} P, can be set up to the discharge capacity at the time T ₅ -T ₆ to P _pk5. That is, the peak cut discharge capacity distribution module 160 may divide the entire peak cut control discharge capacity set by the discharge capacity setting module 110 into P _pk1 to P _pk5 for each time period.

Here, the peak cut discharge capacity distribution module 160 calculates the maximum dischargeable capacity for each time period based on the power consumption pattern for each time period of the customer 20 analyzed through the power consumption pattern analysis module 150. Likewise, it may be set differently from each other, that is, corresponding to the power consumption pattern for each time period of the customer 20 side.

In this way, information on the maximum dischargeable capacity for peak cut control set for each time zone by the peak cut discharge capacity distribution module 160 is transmitted to the peak cut control module 120 to provide information on the power supplied to the customer 20 side. Can be used for peak cut control.

Referring again to FIG. 5, the battery control apparatus 100 according to an embodiment of the present invention may further include a schedule discharge capacity distribution module 170.

Referring to FIG. 7, the schedule discharge capacity distribution module 170 may distribute the schedule control discharge capacity set by the discharge capacity setting module 110 for each time period. For example, the schedule discharge capacity distribution module 170 may set the total discharge capacity to P _sc0 in the T ₀ -T ₁ time zone, and the total discharge capacity in the T ₁ -T ₂ time zone in the time zone set as T ₀ to T ₇ . The discharge capacity can be set to P _sc1 , and the total discharge capacity can be set to P _sc2 in the T ₂ -T ₃ time period. In addition, the schedule discharge capacity distribution module 170 may set the total discharge capacity to P _sc3 in the T ₃ -T ₄ time period, and set the total discharge capacity to P _sc4 in the T ₄ -T ₅ time period, and T _5- at time T ₆ can be set to the total discharge capacity as P _sc5. In addition, the schedule control discharge capacity distribution module 170 may set the total discharge capacity to P _sc6 in the time period T ₆ -T ₇ .

Here, the schedule discharge capacity distribution module 170 calculates the total discharge capacity for each time period as described above, based on the power consumption pattern for each time of the customer 20 analyzed through the power consumption pattern analysis module 150. It can be set differently, that is, corresponding to the power consumption pattern for each time period of the customer 20 side.

In this way, information on the total discharge capacity for schedule control set for each time zone by the schedule discharge capacity distribution module 170 is transmitted to the schedule control module 130 to be used for schedule control of the power supplied to the customer 20. I can.

Referring back to FIG. 1, the peak cut control module 120 is divided by the discharge capacity setting module 110, and the battery according to the peak cut control discharge capacity distributed by time slot by the peak cut discharge capacity distribution module 160 The amount of discharge in (B) is controlled by peak cut. Through this, the peak cut control module 120 may control the power consumption of the customer 20 so as not to exceed a preset maximum power consumption. To this end, the peak cut control module 120 discharges the battery B under the maximum dischargeable capacity distributed by the peak cut discharge capacity distribution module 160 by time, so that the power consumption of the customer 20 is preset. Peak cut control is possible so as not to exceed the maximum power consumption.

That is, as shown in FIG. 7, the peak cut control module 120 discharges the battery B below the maximum dischargeable capacity P _pk1 in the T ₁ -T ₂ time period, thereby discharging the power consumption of the customer 20 side. Peak cut control is possible so as not to exceed the preset maximum power consumption in the T ₁ -T ₂ time period, and the battery (B) is discharged to less than P _pk2 , the maximum dischargeable capacity in the T ₂ -T ₃ time period, The peak cut control is possible so that the power consumption of the) side does not exceed the maximum power consumption set in the T ₂ -T ₃ time zone, and the battery (B) is discharged to P _pk3 or less, the maximum dischargeable capacity in the T ₃ -T ₄ time zone. Thus, it is possible to control the peak cut so that the power consumption of the customer 20 does not exceed the maximum power consumption preset in the T ₃ -T ₄ time period.

In addition, the peak-cut control module 120 is T ₄ -T ₅ times the maximum dischargeable capacity, the power consumption of the suyongga 20 side T ₄ -T ₅ times by discharging the battery (B) below the P _pk4 in Peak cut control is possible so as not to exceed the preset maximum power consumption, and by discharging the battery (B) below the maximum dischargeable capacity P _pk5 in the T ₅ -T ₆ time period, the power consumption of the customer (20) is T ₅ -T You can control the peak cut so that it does not exceed the maximum power consumption set in the ₆ time zone.

Here, when the power supplied through the power grid 10 is maintained below the preset maximum power consumption during peak cut control by the peak cut control module 120, the battery B is discharged to the maximum dischargeable capacity for each time period. May not be performed, and thus, residual discharge capacity may be generated. In an embodiment of the present invention, by carrying over and discharging such residual discharge capacity to the next time period, the utilization rate of the battery B is improved, which will be described in more detail below.

Referring back to FIG. 1, the schedule control module 130 schedule controls the amount of discharge of the battery B so that the battery B is discharged with a preset discharge capacity for each time period. Specifically, the schedule control module 130 is divided by the discharge capacity setting module 110, and the battery B is discharged with the schedule control discharge capacity distributed by the schedule discharge capacity distribution module 170 for each time period. The amount of discharge in (B) can be controlled by schedule.

That is, as shown in FIG. 7, the schedule control module 130 can perform a schedule control for discharging the battery B with the total discharge capacity P _sc0 in the T ₀ -T ₁ time zone, and the T ₁ -T ₂ time zone You can control the schedule of discharging the battery (B) with the total discharge capacity P _sc1 and schedule control to discharge the battery (B) with the total discharge capacity P _sc2 in the time period T ₂ -T ₃ . In addition, the schedule control module 130 can control the schedule to discharge the battery (B) with the total discharge capacity P _sc3 in the time period T ₃ -T ₄ , and the total discharge capacity P _sc4 in the time period T ₄ -T ₅ Schedule control for discharging (B) can be performed, and schedule control for discharging the battery (B) with total discharge capacity P _sc5 in the T ₅ -T ₆ time period. In addition, the schedule control module 130 may _perform a schedule control for discharging the battery B with a total discharge capacity P _sc6 in the time period T ₆ -T ₇ .

Meanwhile, in an embodiment of the present invention, the schedule control module 130 may schedule control the amount of discharge of the battery B so that the battery B is discharged to a preset total discharge capacity in proportion to the time in a specific time period. have.

For example, the schedule control module 130 schedules the amount of discharge of the battery B so that the amount of discharge of the battery B increases in proportion to the time in the T ₀ -T ₁ time period, until the total discharge capacity P _sc0 Battery (B) can be discharged. In addition, the schedule control module 130 discharges the battery B with the total discharge capacity P _sc6 in the time period T ₆ -T ₇ , The amount of discharge of the battery B may be controlled in a schedule so that the amount of discharge of the battery B decreases in proportion to time.

On the other hand, the schedule control module 130 may schedule control the amount of discharge of the battery B so that the battery B is discharged to a predetermined total discharge capacity with a constant amount of discharge in all sections of a specific time period. For example, the schedule control module 130 may discharge the battery B up to the total discharge capacity P _sc1 while discharging the battery B in a certain amount in the T ₁ -T ₂ time period, and T ₂ -T _{In the 3} time zone, it is possible to discharge the battery (B) up to the total discharge capacity P _sc2 while discharging the battery (B) in a certain amount. In the T ₃ -T ₄ time zone, the battery (B) is discharged in a certain amount Battery (B) can be discharged up to the discharge capacity P _sc3 . In addition, the schedule control module 130 can discharge the battery B up to the total discharge capacity P _sc4 while discharging the battery B in a certain amount in the T ₄ -T ₅ time zone, and T ₅ -T ₆ time zones In, while discharging the battery B in a certain amount, the battery B may be discharged to the total discharge capacity P _sc5 .

Here, the schedule control module 130 according to an embodiment of the present invention discharges the battery B to a discharge capacity that is a sum of the total discharge capacity set in the corresponding time period and the peak cut control discharge capacity carried over from the previous time period. The discharge amount of B) is controlled by schedule, which will be described in more detail below.

Referring back to FIG. 1, the residual discharge capacity carryover module 140 determines the remaining discharge capacity used during peak cut control through the peak cut control module 120 among the discharge capacity for peak cut control allocated to a specific time period. It is carried over to the next time set consecutively. In this way, the residual discharge capacity carried over by the residual discharge capacity carryover module 140 to the next time period may be added to the schedule control discharge capacity controlled by the schedule control module 130. Accordingly, the total discharge capacity in a corresponding time period controlled by the schedule control module 130 may be increased.

Referring to FIG. 8, since the peak cut control module 120 discharges the battery B under the peak cut control discharge capacity in order to maintain the power supplied from the power grid 10 below a preset maximum power consumption, the power grid ( If the power supplied from 10) is maintained below the preset maximum power consumption, some or all of the maximum dischargeable capacity distributed in a specific time period may not be discharged.

For example, T ₁ -T ₂ at the time, and the peak-cut by the control module 120, the discharge sikyeotdamyeon the P battery (B) by P _{pk_u1 pk1} of maximum discharge capacity, discharge of the battery (B) from the T ₂ The available capacity remains as much as P _{pk_r1} (=P _pk1 -P _{pk_u1} ). In this way, the available discharge capacity P _{pk_r1} remaining in the T ₁ -T ₂ time zone may be carried over by the residual discharge capacity carryover module 140 to the next time T ₂ -T ₃ time zone. T ₂ -T, and the discharge peak-cut control February ₃ times capacity P _{pk_r1} is summed at the scheduled control the total discharge capacity P _sc2 allocated to the time T ₂ -T _3, and therefore, the schedule control module 130 is T ₂ In the -T ₃ time zone, the total discharge capacity P _{pk_r1} +P _sc2 can be used to control the schedule for discharging the battery B.

Also, in T ₂ -T ₃ times, the discharge of the peak-cut control module sikyeotdamyeon discharge the battery (B) by, P _{pk_u2} of the maximum dischargeable capacity of P _pk2 by 120, a battery (B) from the T ₃ capacity Remains as much as P _{pk_r2} (=P _pk2 -P _{pk_u2} ). In this way, the available discharge capacity P _{pk_r2} remaining in the T ₂ -T ₃ time zone may be carried over by the residual discharge capacity carryover module 140 to the next time period T ₃ -T ₄ . T ₃ -T and the discharge peak-cut control February ₄ times capacity _{pk_r2} P sums for a scheduled control of the total discharge capacity P _sc3 allocated to the time T ₃ -T _4, and therefore, the schedule control module 130 is T ₃ In the -T ₄ time zone, the total discharge capacity P _{pk_r2} +P _sc3 can be used to control the schedule of discharging the battery B.

Subsequently, in the T ₃ -T ₄ time zone, if the battery B is discharged by P _{pk_u3} among the maximum dischargeable capacity P _pk3 by the peak cut control module 120, the battery B can be discharged at T ₄ . The capacity remains as much as P _{pk_r3} (=P _pk3 -P _{pk_u3} ). In this way, the available discharge capacity P _{pk_r3} remaining in the T ₃ -T ₄ time zone may be carried over by the residual discharge capacity transfer module 140 to the next time T ₄ -T ₅ time zone. T ₄ -T ₅ and can discharge the peak-cut control February time capacity P _{pk_r3} is summed at the scheduled control the total discharge capacity P _sc4 partitioned T ₄ -T ₅ times, whereby the scheduling control module 130 is T ₄ In the -T ₅ time zone, the total discharge capacity P _{pk_r3} +P _sc4 can be used to control the schedule of discharging the battery B.

In addition, T ₄ sikyeotdamyeon discharge of discharge of the battery P (B) P by _{pk_u4} of _pk4, maximum discharge capacity by at -T ₅ times, the peak-cut control module 120, a battery (B) at T ₅ capacity Remains as much as P _{pk_r4} (=P _pk4 -P _{pk_u4} ). In this way, the dischargeable capacity P _{pk_r4} left in the T ₄ -T ₅ time zone may be carried over by the residual discharge capacity carryover module 140 to the next time T ₅ -T ₆ time zone. T ₅ -T ₆ are possible and the discharge peak-cut control February time capacity P _{pk_r4} is summed at the scheduled control the total discharge capacity P _sc5 allocated to the time T ₅ -T _6, whereby the scheduling control module 130 T ₅ In the -T ₆ time zone, the total discharge capacity P _{pk_r4} +P _sc5 can be used to control the schedule of discharging the battery B.

And T ₅ -T ₆ in time, the peak-cut by the control module 120, the discharge sikyeotdamyeon the P battery (B) by P _{pk_u5 pk5} of maximum discharge capacity, the dischargeable capacity of the battery (B) at T ₆ is It remains as much as P _{pk_r5} (=P _pk5 -P _{pk_u5} ). In this way, the available discharge capacity P _{pk_r5} left in the T ₅ -T ₆ time zone may be carried over by the residual discharge capacity carryover module 140 to the next time T ₆ -T ₇ time zone. T ₆ -T is the peak-cut discharge control February ₇ times capacity P _{pk_r5} sums to the total discharge capacity P _sc6 control the distribution schedule to the time T ₆ -T _7, whereby the scheduling control module 130 T ₆ In the -T ₇ time zone, the total discharge capacity P _{pk_r5} +P _sc6 can be used to control the schedule of discharging the battery B.

As described above, the battery control apparatus 100 according to an embodiment of the present invention maintains a schedule control method that increases the utilization rate of the battery B and a maximum power consumption peak through the residual discharge capacity carryover module 140. It combines the advantages of the peakcut control method, which can lower contract power. Through this, the battery control device 100 can effectively use the battery B while responding to the peak cut, and as a result, it is more economical to the user who operates the energy storage facility 30 for energy management in buildings and factories. It can provide benefits.

Hereinafter, a battery control method of an energy storage facility according to an embodiment of the present invention will be described with reference to FIG. 9. At this time, reference numerals of each component refer to FIGS. 1 to 8.

9 is a flowchart illustrating a battery control method of an energy storage facility according to an embodiment of the present invention.

Referring to FIG. 9, the battery control method of an energy storage facility according to an embodiment of the present invention includes a discharge capacity setting step (S110), a discharge capacity distribution step by time slot (S120), a peak cut control step (S130), and A discharge capacity carryover step (S140) and a schedule control step (S150) may be included.

First, the discharge capacity setting step (S110) is a step of dividing the total available discharge capacity into a discharge capacity for peak cut control and a discharge capacity for schedule control.

In the discharge capacity setting step (S110), a division ratio of the peak cut control discharge capacity and the schedule control discharge capacity may be calculated according to the power consumption pattern of the customer 20 side. For example, in the discharge capacity setting step (S110), when the power demand fluctuation is severe or in the section in which the power consumption of the customer 20 exceeds a preset maximum power consumption among the power consumption patterns of the customer 20, the peak cut The ratio of the control discharge capacity can be set larger than the ratio of the schedule control discharge capacity. In addition, in the discharge capacity setting step (S110), the ratio of the discharge capacity for schedule control is adjusted for peak-cut control when the power demand fluctuation is relatively modest or in the section in which the power consumption of the customer 20 does not exceed a preset maximum power consumption. It can be set larger than the ratio of the discharge capacity.

Next, the discharge capacity distribution step for each time slot (S120) is a step of distributing each discharge capacity divided into a peak cut control discharge capacity and a schedule control discharge capacity by time through the discharge capacity setting step S110.

In the step of distributing the discharge capacity for each time period (S120), the set discharge capacity for controlling the peak cut may be distributed for each time period. For example, in the step of distributing the discharge capacity by time slot (S120), a maximum dischargeable capacity used for peak cut control may be set for each time period set in a predetermined time period. In addition, in the step of distributing the discharge capacity for each time period (S120), a total discharge capacity used for the schedule control may be set for each time period set in a predetermined time period.

Next, the peak cut control step (S130) is a step of controlling the discharge amount of the battery B according to the peak cut control discharge capacity so that the power consumption of the customer 20 does not exceed a preset maximum power consumption. . In the peak cut control step (S130), the battery B is discharged under the maximum dischargeable capacity distributed by time period among the discharge capacity for peak cut control, so that the power supplied from the power grid 10 to the customer 20 is stored in the corresponding time period. Peak cut control is possible so as not to exceed the set maximum power consumption.

At this time, when the power supplied through the power grid 10 during peak cut control is maintained below the preset maximum power consumption, the battery B may not be discharged up to the maximum dischargeable capacity for each time period. Accordingly, each Residual discharge capacity may be generated for each time period.

Next, the residual discharge capacity carryover step (S140) is a step of transferring the remaining residual discharge capacity used during the peak cut control among the discharge capacities for peak cut control allocated to a specific time period to a next time set consecutively with the specific time period.

Here, in the peak cut control step (S130), the battery B is discharged under the peak cut control discharge capacity in order to keep the power supplied from the power grid 10 below a preset maximum power consumption, so the power grid 10 supplies it. When the power is maintained below the preset maximum power consumption, some or all of the maximum dischargeable capacity distributed for peak cut control may not be discharged in all or part of the time period.

Accordingly, in the residual discharge capacity carryover step (S140), in order to increase the utilization rate of the battery B, when some or all of the maximum dischargeable capacity distributed for peak cut control in the entire or partial time period remains without being discharged, the peak The remaining discharge capacity used during the peak cut control through the cut control step S130 may be carried over to the next time period, and may be added to the discharge capacity for schedule control in the next time period.

Finally, the schedule control step (S150) is a step of controlling the amount of discharge of the battery B so that the battery B is discharged with a preset discharge capacity for schedule control for each time period. In this case, in the schedule control step S150, a schedule may be controlled so that the battery B is discharged to a preset total discharge capacity in proportion to the time in a specific time period. In addition, in the schedule control step (S150), the schedule may be controlled so that the battery B is discharged to a predetermined total discharge capacity with a constant discharge amount in all sections of a specific time period.

On the other hand, in the schedule control step (S150) according to an embodiment of the present invention, the peak cut control discharge capacity carried over by the residual discharge capacity carryover module 140 and the schedule control discharge capacity distributed in the corresponding time period in all or part of the time period. The amount of discharge of the battery B may be controlled in a schedule so that the battery B is discharged with the summed total discharge capacity.

As described above, the battery control method of an energy storage facility according to an embodiment of the present invention includes a schedule control method that increases the utilization rate of the battery B and a peak cut control method that can lower contract power by keeping the maximum power consumption peak low. By combining the advantages and controlling the discharge amount of the battery (B), it is possible to use the battery (B) as much as possible while effectively responding to the peak cut, that is, to increase the utilization rate of the battery (B), and as a result, energy management in buildings and factories It is possible to provide more economic benefits to the user who operates the energy storage facility 30.

In the above, the present invention has been described in detail using preferred embodiments, but the scope of the present invention is not limited to specific embodiments, and should be interpreted by the appended claims. In addition, those who have acquired ordinary knowledge in this technical field should understand that many modifications and variations can be made without departing from the scope of the present invention.

100; Battery control device
110; Discharge capacity setting module
120; Peak cut control module
130; Schedule control module
140; Residual discharge capacity carryover module
150; Power consumption pattern analysis module
160; Peak cut discharge capacity distribution module
170; Schedule discharge capacity distribution module
10; Power grid
20; Customer
30; Energy storage equipment

Claims (7)

A battery control device that controls a battery provided in an energy storage facility connected to a power grid and supplying power to a customer,
A discharge capacity setting module that divides the total usable discharge capacity of the battery into a discharge capacity for peak cut control and a discharge capacity for schedule control;
A peak cut control module configured to peak cut control the amount of discharge of the battery according to the peak cut control discharge capacity so that the power consumption of the customer does not exceed a preset maximum power consumption;
A schedule control module configured to schedule a discharge amount of the battery to be discharged to the schedule control discharge capacity preset for each time period; And
Among the discharge capacity for peak cut control allocated to a specific time period, the remaining discharge capacity used for the peak cut control is carried over to the next time period set in succession with the specific time period to the discharge capacity for schedule control controlled by the schedule control module. Including; a residual discharge capacity carrying module to sum up;
The schedule control module schedules control the amount of discharge of the battery to discharge the battery to the preset discharge capacity in proportion to time, or discharges the battery to the preset discharge capacity at a constant discharge amount in the entire period of a specific time period. A battery control device of an energy storage facility that schedules the amount of discharge of the battery.
The method of claim 1,
Further comprising a power consumption pattern analysis module,
The power consumption pattern analysis module is a battery control device of an energy storage facility to analyze a past power consumption pattern of the customer equipped with the energy storage facility.
The method of claim 2,
The discharge capacity setting module is a battery control device of an energy storage facility that sets a division ratio between the peak cut control discharge capacity and the schedule control discharge capacity according to the power consumption pattern of the customer analyzed by the power consumption pattern analysis module. .
The method of claim 1,
Further comprising a peak cut discharge capacity distribution module and a schedule discharge capacity distribution module,
The peak cut discharge capacity distribution module distributes the peak cut control discharge capacity set by the discharge capacity setting module for each time period,
The schedule discharge capacity distribution module distributes the schedule control discharge capacity set by the discharge capacity setting module for each time period.
The method of claim 1,
The discharge capacity setting module is a battery control device of an energy storage facility configured to set the peak cut control discharge capacity based on the schedule control discharge capacity according to a variation width of the power consumption side of the customer among the power consumption patterns of the customer.
delete The method of claim 1,
The schedule control module,
The battery is discharged by the sum of the remaining discharge capacity used for peak cut control in the previous time zone and the discharge capacity for schedule control allocated for schedule control in the current time zone carried over by the residual discharge capacity carryover module. A battery control device of an energy storage facility for controlling the amount of discharge of the battery as possible.

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