KR20220083253A - An enhanced method for considering energy storage system as ancillary service resources in stochastic unit commitment - Google Patents

Abstract

A reserve power calculation method for the use of a net copper reserve power resource of an energy storage device according to an embodiment of the present invention comprises the steps of: generating a reference charge/discharge schedule of the energy storage device without considering uncertainty; generating a plurality of charge/discharge scenarios that may occur due to uncertainty in the reference charge schedule; and calculating a reserve power constraint of the generator start-stop plan based on the standard charging schedule and the charging/discharging schedules according to the plurality of charging/discharging scenarios.

Description

AN ENHANCED METHOD FOR CONSIDERING ENERGY STORAGE SYSTEM AS ANCILLARY SERVICE RESOURCES IN STOCHASTIC UNIT COMMITMENT

The present invention relates to a reserve power calculation method for pure copper reserve resource utilization of an energy storage device, and specifically, an energy storage device that can be utilized for a generator start-stop plan (Unit Commitment) by expressing uncertainty as a scenario using a probabilistic method. It relates to the method of calculating reserve power.

Since electricity is difficult to store unlike other energy sources, it has the characteristic that electricity must be consumed as well as produced.

Therefore, power generation companies must produce an amount of electricity equivalent to the expected demand, but the consumption of electricity is not always constant, but fluctuates by time, day, and season, so it is an important task to match the supply and demand of electricity. If there is a gap between the power supply and the power supply, the power supply becomes unbalanced and the quality of power (voltage and frequency) is adversely affected.

In order to solve these problems, the utilization of energy storage system (ESS) is gradually increasing. it means.

Such energy storage devices are expected to have enormous market potential as an effective means of establishing a stable and efficient energy supply and demand system, and are recently attracting attention at home and abroad as a new growth engine.

A characteristic of the current domestic electricity market is that the maximum power increase rate is rapidly increasing compared to the average load increase rate due to the change in the electricity consumption pattern of industrial consumers. Also, the overall load rate is gradually decreasing, while the seasonal and time-dependent load fluctuations tend to increase. have.

In such a situation, the use of energy storage systems is rapidly emerging as a way to actively respond to power peaks by leveling the electric load for each time period and effectively respond to large-scale blackout accidents for stable power supply and demand.

In addition, the need for energy storage devices is expected to further increase in consideration of the problem of lowering the power supply reserve and the change in output on the system due to the increase in the proportion of new and renewable energy introduced.

On the other hand, in the conventional case, the amount of net copper reserve power available based on the amount of energy stored in the energy storage device was calculated, and based on this, a generator start-stop plan was established.

However, in the case of an energy storage device, unlike a generator, it is not possible to increase the amount of power generation by adding fuel. More reserve power is allocated to the energy storage device than is actually usable.

In the end, less reserve power is allocated to the existing generator under the same reserve power standard, which has a problem in that it can lead to economic loss due to a decrease in the available reserve power and load cut-off in an actual accident situation.

On the other hand, the following prior art document discloses a technology related to an operating system of an energy storage device based on a real-time power system situation, but does not disclose the technical gist of the present invention.

Republic of Korea Patent Publication No. 10-1493785

The reserve power calculation method for the net copper reserve resource utilization of the energy storage device according to an embodiment of the present invention aims to solve the following problems in order to solve the above problems.

It is to provide a reserve power calculation method for the utilization of the net copper reserve resource of the energy storage device that can prevent the economic loss due to the reduction of the reserve power and load cut-off caused by allocating more reserve power than the actual usable capacity to the energy storage device.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those of ordinary skill in the art from the following description.

A reserve power calculation method for the use of a net copper reserve power resource of an energy storage device according to an embodiment of the present invention comprises the steps of: generating a reference charge/discharge schedule of the energy storage device without considering uncertainty; generating a plurality of charge/discharge scenarios that may occur due to uncertainty in the reference charge schedule; and calculating a reserve power constraint of the generator start-stop plan based on the standard charging schedule and the charging/discharging schedules according to the plurality of charging/discharging scenarios.

The charge/discharge scenario may include: a first scenario in which the amount of charge of the energy storage device is smaller than the amount of charge according to the reference charge/discharge schedule for a preset time determined based on a change amount of the charge/discharge schedule of the current time compared to the previous time; a second scenario in which the amount of charge of the energy storage device for a preset time is greater than the amount of charge according to the reference charge/discharge schedule; and a third scenario in which the amount of charge of the energy storage device is smaller than the amount of charge according to the reference charge/discharge schedule for a preset time and is decreased compared to the previous time.

It is preferable that the reserve power constraint of the generator start-up regular plan is the evaporative net copper reserve criterion and the reduced net copper reserve force criterion to be secured for each time period.

It is preferable that the evaporative net copper reserve capacity standard to be secured for each time period is calculated by the following Equation (1).

<Formula (1)>

는 시간대별 확보해야 할 증발 순동 예비력 기준,

는 시간대별 발전기를 통해 확보하는 증발 순동 예비력,

는 시간대별 각 시나리오 s에서 에너지 저장장치에서 충전하는 에너지,

는 시간대별 각 시나리오 s에서 에너지 저장장치에서 방전하는 에너지,

는 불확실성이 없는 기준 시나리오임.From here

is the standard of evaporative net copper reserve to be secured by time period,

is the evaporative net copper reserve power secured through the generator for each time period,

is the energy charged by the energy storage device in each scenario s over time,

is the energy discharged from the energy storage device in each scenario s over time,

is the baseline scenario without uncertainty.

It is preferable that the standard of net copper reserve power to be secured for each time period is calculated by the following Equation (2).

<Formula (2)>

는 시간대별 확보해야 할 감발 순동 예비력 기준,

는 시간대별 발전기를 통해 확보하는 감발 순동 예비력,

는 시간대별 각 시나리오 s에서 에너지 저장장치에서 충전하는 에너지,

는 시간대별 각 시나리오 s에서 에너지 저장장치에서 방전하는 에너지,

는 불확실성이 없는 기준 시나리오임.From here

is the standard of net copper reserve capacity to be secured by time period,

is the net copper reserve power secured through the generator for each time period,

is the energy charged by the energy storage device in each scenario s over time,

is the energy discharged from the energy storage device in each scenario s over time,

is the baseline scenario without uncertainty.

The reserve power calculation method for the net copper reserve resource utilization of the energy storage device according to an embodiment of the present invention establishes a generator start-stop plan based on the charge/discharge schedule of the energy storage device in consideration of uncertainty, thereby providing an appropriate amount of reserve power to the energy storage device. It can be expected to have the effect of reducing the expected cost and total planned cost due to load limiting and reducing the renewable energy output limit as well.

Effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those of ordinary skill in the art from the following description.

1 is a flowchart illustrating a method for calculating a reserve power for use of a net copper reserve resource resource of an energy storage device according to an embodiment of the present invention in time series.
FIG. 2 is a view for explaining a charge/discharge scenario that may occur due to uncertainty in a method for calculating a reserve power for a net copper reserve resource utilization of an energy storage device according to an embodiment of the present invention.
3 is a graph illustrating a reserve force allocated to an energy storage device by applying a conventional method.
4 is a graph showing the reserve power allocated to the energy storage device when the reserve power calculation method for the net copper reserve resource utilization of the energy storage device according to an embodiment of the present invention is applied.

A preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings, but the same or similar components are assigned the same reference numerals regardless of reference numerals, and redundant description thereof will be omitted.

In addition, in the description of the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, it should be noted that the accompanying drawings are only for easy understanding of the spirit of the present invention, and should not be construed as limiting the spirit of the present invention by the accompanying drawings.

Hereinafter, with reference to FIGS. 1 to 4, a method of calculating a reserve power for utilization of a net copper reserve resource of an energy storage device according to an embodiment of the present invention will be described.

As described above, when the reserve power of the energy storage device is calculated in consideration of only the state of charge of the energy storage device as in the related art, there is a problem in that more reserve power is allocated to the energy storage device than the actual usable capacity.

Therefore, in order to solve this problem, the reserve power calculation method for the net copper reserve resource utilization of the energy storage device according to an embodiment of the present invention does not first consider the uncertainty as shown in FIG. A step (S100) of generating (Reference) is performed.

Thereafter, a step (S200) of generating a plurality of charging/discharging scenarios that may occur due to uncertainty in the reference charging schedule is performed, wherein the charging/discharging scenarios are the charging/discharging scenarios of the current time (T) compared to the previous time (T-1). It is determined based on the amount of change in the schedule.

When this is described in more detail with reference to FIG. 2 , the current charged according to the standard charging/discharging schedule of the energy storage device without considering the uncertainty in the state of charge 100 of the energy storage device at the previous time point T-1 It is defined as a charging/discharging schedule based on the charging state 200 of the energy storage device at the time.

In the first scenario 310, it is assumed that the system load exceeds the reference charge/discharge schedule. At the current time T, charging is performed compared to the previous time T-1, but the amount of charge As a situation in which the reference charge amount is decreased, the reserve capacity of the first scenario 310 at the current time point T may be defined as the upward reserve capacity of (a).

The second scenario 320 assumes a situation in which the load of the system is small compared to the standard charge/discharge schedule or the output of renewable energy is higher than expected, that is, the charging amount is the standard at the current time point T compared to the previous time point T-1. As a situation in which the charging amount increases, the reserve capacity of the second scenario 320 at the current time point T may be defined as the downward reserve capacity of (b).

The third scenario 330 assumes a situation in which the charge rate at the current time point T is reduced compared to the charge rate at the previous time point T-1, that is, a discharge situation, which may result in a significant increase in system load or regeneration. As a situation that may occur when the power output of energy is lower than expected, the reserve capacity of the third scenario 330 at the current time point T may be defined as the upward reserve capacity of (c).

Thereafter, the step (S300) of calculating the reserve power constraint of the generator start-stop plan is performed based on the standard charging schedule and the charging/discharging schedule according to the plurality of charging/discharging scenarios.

Here, the reserve power constraint of the generator start-up regular plan can be calculated based on the evaporative net copper reserve power standard and the reduced net copper reserve power standard to be secured for each time period.

That is, the reserve power constraint conditions of the generator start-stop plan are modified and applied, including the definition of the new reserve power of the energy storage device.

<Formula (1)>

는 시간대별 확보해야 할 증발 순동 예비력 기준,

는 시간대별 발전기를 통해 확보하는 증발 순동 예비력,

는 시간대별 각 시나리오 s에서 에너지 저장장치에서 충전하는 에너지,

는 시간대별 각 시나리오 s에서 에너지 저장장치에서 방전하는 에너지,

는 불확실성이 없는 기준 시나리오임.From here

is the standard of evaporative net copper reserve to be secured by time period,

is the evaporative net copper reserve power secured through the generator for each time period,

is the energy charged by the energy storage device in each scenario s over time,

is the energy discharged from the energy storage device in each scenario s over time,

is the baseline scenario without uncertainty.

In addition, the standard of net copper reserve power to be secured for each time period can be expressed as in Equation (2) below.

<Formula (2)>

는 시간대별 확보해야 할 감발 순동 예비력 기준,

는 시간대별 발전기를 통해 확보하는 감발 순동 예비력,

는 시간대별 각 시나리오 s에서 에너지 저장장치에서 충전하는 에너지,

는 시간대별 각 시나리오 s에서 에너지 저장장치에서 방전하는 에너지,

는 불확실성이 없는 기준 시나리오임.From here

is the standard of net copper reserve capacity to be secured by time period,

is the net copper reserve power secured through the generator for each time period,

is the energy charged by the energy storage device in each scenario s over time,

is the energy discharged from the energy storage device in each scenario s over time,

is the baseline scenario without uncertainty.

As described above, by performing a stochastic unit commitment plan including a scenario in consideration of uncertainty, the reserve power of the generator and the energy storage device is allocated for each time period.

The energy storage device to which the reserve power allocated to the energy storage device by applying the conventional method shown in FIG. 3 and the reserve power calculation method for the utilization of the net copper reserve power resource of the energy storage device according to an embodiment of the present invention shown in FIG. 4 is applied Comparing the reserve power allocated to , it can be seen that FIG. 4 allocates less reserve power to the energy storage device compared to FIG. 3 .

That is, when the reserve power calculation method for the net copper reserve resource utilization of the energy storage device according to an embodiment of the present invention is applied, the power system can be operated more stably without allocating excessive reserve power to the energy storage device. .

In addition, since load shedding does not occur when the reserve power calculation method for the net copper reserve resource utilization of the energy storage device according to an embodiment of the present invention is applied, the expected cost caused thereby is reduced as shown in Table 1 below. can

division the old way proposed method Power generation cost [$] 324,405.7 325,445.8 load limiting cost [$] 15,072.7 0 Total cost [$] 339,478.4 325,445.8

Furthermore, when applying the reserve power calculation method for the net copper reserve resource utilization of the energy storage device according to an embodiment of the present invention, the renewable energy remaining due to the excessive reserve power allocation of the energy storage device is additionally allocated to the start-up stop power generation plan By doing so, it is also possible to reduce the renewable energy output restriction, which can be confirmed in Table 2 below, which shows the renewable energy output restriction of the conventional method and the method of the present invention.

hour the old way the present invention Case 1 Case 2 19:00 0 28.6 MW 0 23 o'clock 17.4 MW 0 0 24 hours 33.5 MW 0 0

The embodiments described in this specification and the accompanying drawings are merely illustrative of some of the technical ideas included in the present invention. Therefore, since the embodiments disclosed in the present specification are for explanation rather than limitation of the technical spirit of the present invention, it is obvious that the scope of the technical spirit of the present invention is not limited by these embodiments. Modifications and specific embodiments that can be easily inferred by a person of ordinary skill in the art within the scope of the technical idea included in the specification and drawings of the present invention are included in the scope of the present invention. will have to be interpreted.

Claims (5)

generating a reference charge/discharge schedule of the energy storage device without considering uncertainty;
generating a plurality of charging/discharging scenarios that may occur due to uncertainty in the reference charging schedule; and
calculating a reserve power constraint of a generator start-stop plan based on the standard charging schedule and a charging/discharging schedule according to the plurality of charging/discharging scenarios;
Reserve power calculation method for the utilization of net copper reserve power resources of the energy storage device, including.
The method according to claim 1, The charge/discharge scenario,
It is determined based on the amount of change in the charge/discharge schedule of the current time compared to the previous time,
a first scenario in which the amount of charge of the energy storage device from the previous time point to the present time point is smaller than the charge amount according to the reference charge/discharge schedule;
a second scenario in which the amount of charge of the energy storage device from the previous time point to the current time point is greater than the charge amount according to the reference charge/discharge schedule; and
a third scenario in which the charge amount of the energy storage device from the previous time point to the present time point is smaller than the charge amount according to the reference charge/discharge schedule and is decreased compared to the previous time point;
Reserve power calculation method for the utilization of net copper reserve power resources of the energy storage device, including.
The method according to claim 1,
The reserve power constraint condition of the generator start-up regular plan is the reserve power calculation method for the utilization of the net copper reserve resource of the energy storage device, which is the standard of the evaporation net copper reserve power to be secured for each time period and the net copper reserve power standard.
4. The method according to claim 3,
The evaporative net copper reserve standard to be secured for each time period is a reserve capacity calculation method for the use of the net copper reserve capacity resource of the energy storage device calculated by the following Equation (1).
<Formula (1)>

From here

is the standard of evaporative net copper reserve to be secured by time period,

is the evaporative net copper reserve power secured through the generator for each time period,

is the energy charged by the energy storage device in each scenario s over time,

is the energy discharged from the energy storage device in each scenario s over time,

is the baseline scenario without uncertainty.
4. The method according to claim 3,
The standard of the net copper reserve to be secured for each time period is the reserve capacity calculation method for the use of the net copper reserve resource of the energy storage device calculated by the following Equation (2).
<Formula (2)>

From here

is the standard of net copper reserve capacity to be secured by time period,

is the net copper reserve power secured through the generator for each time period,

is the energy charged by the energy storage device in each scenario s over time,

is the energy discharged from the energy storage device in each scenario s over time,

is the baseline scenario without uncertainty.

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