KR100699352B1 - Electric power generating system for peak control and method thereof - Google Patents

Abstract

An electric power generating system for controlling power peak and a control method thereof are provided to effectively supply electric power to consumers, even when a power peak value exceeds a target value. An electric power generating system includes a power measuring unit(180), an emergency generator(350), at least one automatic switch(200-1,200-2), and a power control system(300). The power measuring unit measures power usage quantity of loads. The emergency generator generates electric power and supplies the power to the loads. The automatic switch connects a power line, which supplies power to the loads, to one of a power line of a power supply unit or a power line of the emergency generator. The power control system calculates power usage estimation values, compares the calculated value with a target value, and activates the emergency generator, when the calculated value exceeds the target value. Then, the power control system controls the automatic switch, so that the power from the emergency generator is supplied to the loads.

Description

Power generation system that performs power peak control and its control method {ELECTRIC POWER GENERATING SYSTEM FOR PEAK CONTROL AND METHOD THEREOF}

1 is a block diagram illustrating a general maximum demand power control system.

2 is a flowchart for explaining a control method of a general maximum demand power control system.

3 is a view for explaining a power supply system for constructing a general emergency generator.

4 is a flowchart for explaining a method for supplying power by a power supply system that is constructing an emergency generator.

5 is a block diagram illustrating a power generation system for performing power peak control by an emergency generator according to a preferred embodiment of the present invention.

6 is a view for explaining an embodiment of a power generation system for performing power peak control by an emergency generator according to the present invention.

7 is a flowchart illustrating a control method of a power generation system for performing power peak control by an emergency generator according to a preferred embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

100: power control means

110: current-limit fuse 120: instrument transformer

130: transformer 170: KEPCO meter

180: power meter 200: automatic transfer switch

300: power control system 350: emergency generator

400: breaker 700: load group

The present invention relates to a power generation system for performing power peak control by an emergency generator and a control method thereof.

The power supply system, which receives power from the power supplier (Korea Electric Power Corporation) and supplies it to the load side (power demander), is introduced by the peak demand system to eliminate power instability.

For this power peak system, the maximum demand electric power was developed.

The principle of the peak demand power controller works by first setting the target peak power of the power consumer, then predicting the power demand forecast every 15 minutes through the current trend of increasing power, and making the power demand forecast within the range not exceeding the target peak power. The loads of the two circuits are cut off to adjust the power used to be below the target power.

In addition, the maximum demand power controller has a built-in microprocessor to monitor the power load condition at all times, and if the load is expected to exceed the preset target peak power within 15 minutes, an alarm is generated and unnecessary load is generated. Cuts power up to 8 loads sequentially from (set load) to suppress the maximum demand power below the target power, and if the load drops, loads are loaded by the program input in advance.

1 is a block diagram illustrating a general maximum demand power control system.

Referring to FIG. 1, a current-limit fuse 11, a KEPCO meter 17, an instrument transformer 12, a transformer 13, and maximum demand power are located on a line supplied with power from a power supplier. A controller 18, a plurality of loads (power consumers) 16, a plurality of circuit breakers 15 connected to each of the plurality of loads, and a plurality of magnetic contactors 14 connected to receive power from each load It includes.

The plurality of loads 16 may correspond to a power device driven by being supplied with power, for example, an electronic device such as a television or an air conditioner, a manufacturing device of a control company, or a medical device of a hospital.

Each wiring breaker 15 has a function of earth leakage protection, overcurrent protection, overload protection, and phase loss protection, and protects each connected load.

Each magnetic contactor 14 connects the powered line and the loads 16 and functions as a switch to turn on / off the connection of the line and the loads 16 according to a control signal received from the outside.

The current-limiting fuse 11 generates a high arc resistance to forcibly limit the fault current to cut off the current, and cuts off the power system in the event of a short circuit to a high-voltage system line supplied with power from the power supplier. Protect.

The transformer 13 changes the alternating voltage or current value of the power provided by the power supplier using electromagnetic induction so that the loads 16 can be supplied. In other words, the transformer 13 is provided with the power used by the loads 16.

Instrument transformer 12 provides a change in the power supplied so that the KEPCO meter 17 can measure the power usage.

The KEPCO meter 17 measures the power consumption currently being used by the loads 16 based on the power changed in the instrument transformer 12.

In addition, the KEPCO meter 17 provides a power pulse signal according to the power usage to the maximum demand power controller 18.

The maximum demand power controller 18 checks the current power consumption from the power pulse signal received from the KEPCO meter 17 in a certain period (15 minute period), predicts the power demand prediction value, and compares it with a predetermined target power amount.

And, if the maximum demand power controller 18 is expected to exceed the target power amount, the maximum demand power controller 18 applies a control signal to the electronic contactor 14 connected to the loads 16 in the order that is already input, so that the load The power supplied to the 16 is cut off.

Thus, the peak demand power controller 18 controls the interruption of the power supplied to the load 16 so that the power usage does not exceed the target amount of power, thereby maintaining the power usage.

2 is a flowchart illustrating a control method of a general maximum demand power control system.

Referring to FIG. 2, the maximum demand power controller 18 determines the power usage every 15 minutes according to the power pulse signal received from the KEPCO meter 17 (S 10).

The maximum demand power controller 18 checks whether the identified power usage is greater than the first allowable value (target power amount) (S 11).

If the power demand is not greater than the first allowable value, the maximum demand power controller 18 checks whether or not the spare power is secured (S12). 16) to be supplied with power (S 13).

On the other hand, the maximum demand power controller 18 checks whether the power usage is greater than the first allowable value and greater than the second allowable value (target peak power amount) (S 14), so that the power consumption is greater than the second allowance or the first. If it is smaller than the allowable value but the spare power is not secured, the control signal is applied to the magnetic contactor 14 according to the previously set priority to cut off the power supplied to the load 16 (S 15).

In the power control method using the maximum demand power controller 18, when a power use contract is made between a power supplier and a power consumer, the consumer pays an unnecessary power fee by contracting a power capacity exceeding a required amount of power. May result.

On the other hand, the current power supply system is building an emergency power generation system in case of a significant loss of life or damage when a power failure occurs, such as a hospital.

3 is a view for explaining a power supply system for constructing a general emergency generator.

As shown in FIG. 3, the power supply system in which the emergency generator is constructed includes a current-limit fuse 11, an instrument transformer 12, a transformer 13, a plurality of circuit breakers 15, and a plurality of circuit breakers. Loads 16, emergency generator 35 and automatic transfer switch 36.

Components of the same reference numerals as those of FIG. 1 process the same functions, and thus the description thereof will be omitted.

The emergency generator 35 corresponds to a device that generates power based on its own fuel. When the power supplied from the power provider is interrupted and the supply is interrupted, the emergency generator 35 generates power by the emergency generator 35 to supply the load 16. do.

The automatic transfer switch 36 switches the line powered by the loads 16 from the emergency generator 35 to the power line powered by the emergency generator 35 when the power supplied from the power supplier is interrupted. Start the operation.

When the power transfer switch 36 starts to supply power again from the power supplier, the automatic transfer switch 36 switches the line from which the loads 16 are powered to the power line supplied from the power provider, Stop the drive.

That is, when the power supply is stopped from the power supplier, the automatic transfer switch 36 operates the emergency generator 35 to generate emergency power, and loads the line from which the loads 16 are powered by the emergency generator 35. Switch to the power line so that the loads 16 are powered even in the event of a power outage, and when power supply is resumed from the power supply, the emergency generator 35 switches the line of the loads 16 to the power supply line of the power provider. Suspend operation.

4 is a flowchart for explaining a method for supplying power by a power supply system that is constructing an emergency generator.

Referring to FIG. 4, when the automatic transfer switch 36 starts to supply power from the power supplier (S 20), the automatic transfer switch 36 checks whether the power supplied from the power supplier is stopped due to a problem such as a power failure (S 21). ,

The automatic transfer switch 36 checks whether the line of the current loads 16 is connected to the power line of the power provider if the power is not interrupted (S 22), and the emergency generator that is not the power line of the power provider. If connected to the power line of 35, the line of the load 16 is switched to the power line of the power supplier (S 23).

On the other hand, when the power supply is interrupted, the automatic transfer switch 36 operates the emergency generator 35 (S 24).

In addition, the automatic transfer switch 36 checks whether the emergency generator 35 is operated to supply emergency power (S 25), and when emergency power is supplied, the emergency generator 35 connects the lines of the loads 16 to the emergency generator 35. Switch to the power line of (S 26).

The loads 16 are driven by the power supplied from the emergency generator 35, not the power supplier (S 27).

In addition, when power is supplied again from the power supplier, the automatic transfer switch 36 switches the lines of the loads 15 to the power lines of the power provider and stops the operation of the emergency generator 35 (S 28).

The power supply system built with such an emergency generator is prepared only for a power failure situation in which power is not supplied from a power supplier.

Therefore, power consumers can always supply power to the loads 16 without paying a huge power usage fee due to the excessive amount of power, and the power supplier supplies only the necessary power to the power consumer. Therefore, a method for relieving the burden of power peaks should be sought.

Therefore, the present invention was devised to solve the necessity as described above, the power supplier to supply only the power (contracted power) necessary to the power consumer to relieve the burden of the power peak, the power consumer to use the amount of power supplied It is an object of the present invention to provide a power generation system and a method for performing power peak control by an emergency generator capable of continuously supplying power to a load even when exceeded.

In order to achieve the above object, a power generation system for performing power peak control by an emergency generator according to an aspect of the present invention includes a plurality of loads driven by consuming power supplied from a power supplier, and each load supplied from a power supplier. The power meter that measures the amount of power consumed by them for a certain period of time, the emergency generator that generates electricity to generate excess power and supplies it to each load, and the line where each load is supplied with power Power usage estimates are calculated from a plurality of automatic switching switches that switch to a power line and power usage measured by a power meter, and when the power usage prediction amount exceeds the target power amount, an emergency generator is started. To generate excess power, the line of the load powers the emergency generator The excess power by controlling the automatic transfer switch to be switched into the furnace includes a power control system to supply the load.

In the power control system according to the present invention, the load power amount for each load or load group for each load group in which a plurality of loads are clustered, selects a load or load group corresponding to the excess power amount exceeding the target power amount, and selects the selected load. Or by controlling the automatic transfer switch for switching the line of the load group, it characterized in that the excess power generated in the emergency generator is supplied to the selected load or load group.

In the power control system according to the present invention, if the predicted power usage does not exceed the target power in the state where the automatic transfer switch is switched to the power line of the emergency generator, the automatic transfer switch controls the automatic transfer switch so that the load line is the power supplier. Characterized in that the switch to the power line.

The power control system according to the present invention is characterized in that when the power supplied from the power supplier is stopped, the emergency generator is operated and each automatic transfer switch is switched to the power line of the emergency generator.

The power control system according to the present invention is characterized by generating an electric power corresponding to excess power by controlling the operation of the emergency generator.

The power control system according to the present invention includes power control means for operating an emergency generator to generate excess power when the power usage prediction amount exceeds a target power amount, and controlling the automatic transfer switch to supply excess power to the load; Located between the power line of the generator and each automatic transfer switch, it includes a number of breakers to protect the power line.

In the power generation system performing power peak control by the emergency generator according to the present invention, a transformer for supplying power to each load by varying the power supplied from the power supplier, and measuring the amount of power used by the power supplied from the power provider, The apparatus further includes a KEPCO meter that provides a power pulse signal for calculating power usage by the meter, and a plurality of breakers for protecting a power line of the power provider.

According to another aspect of the present invention, there is provided a power supply control method of a power supply control system using an emergency generator, the method comprising calculating a power usage amount for which power supplied from a power supplier is consumed for a predetermined time, and calculating a power usage prediction amount from the power usage amount Comparing with a predetermined target power amount, and if the power usage prediction amount exceeds the target power amount, starting the emergency generator, and the load power amount for each load group or load group clustered by a plurality of loads are calculated. Selecting a load or load group having a load power amount corresponding to an excess power amount in which the power usage prediction amount exceeds the target power amount, and switching a line of the selected load or load group to a power line of the emergency generator; It includes.

The step of switching to the power line of the emergency generator, the power control supply system includes a plurality of automatic transfer switch for switching the line of the load, the emergency generator by controlling the automatic transfer switch for switching the line of the selected load or load group It is characterized by switching to the power line.

In the control method of the power generation system to perform the power peak control by the emergency generator according to the present invention, when the power supplied from the power supplier is stopped, the emergency generator is operated, and each automatic transfer switch is switched to the power line of the emergency generator. It further comprises the step.

The step of operating the emergency generator according to the invention is characterized in that for controlling a power generation corresponding to the excess power for a predetermined time.

In the control method of the power generation system to perform the power peak control by the emergency generator according to the present invention, if the power usage prediction amount does not exceed the target power amount, the emergency generator operation is checked, and if it is in operation, the emergency generator is operated. Stopping and if the load line is switched to the power line of the emergency generator, converting the load line to the power line of the power supply.

Hereinafter, a power generation system for performing power peak control by an emergency generator according to the present invention and a method thereof will be described in detail with reference to the accompanying drawings.

5 is a block diagram illustrating a power generation system for performing power peak control by an emergency generator according to a preferred embodiment of the present invention.

Referring to FIG. 5, the power supply control system according to the present invention includes an instrument transformer 120, an electric power meter 170, a transformer 13, a power meter 180, an emergency generator 350, The power control system 300 and a plurality of load groups 700 are provided with a plurality of loads.

The transformer 130 supplies the plurality of load groups 700 by varying the AC voltage or the current value of the power provided from the power provider using electromagnetic induction.

Instrument transformer 120 is provided by changing the power supplied so that the KEPCO meter 17 can measure the power usage.

The KEPCO meter 170 measures the power consumption currently used by the load groups 700 based on the power changed in the instrument transformer 120, and provides a power pulse signal according to the power consumption to the power meter 180. do.

The power meter 180 checks the current power usage from the power pulse signal received from the KEPCO meter 170 at a predetermined cycle (15 minute cycle) and transmits (notifies) the power usage to the power usage system.

In the above and below, the power meter 180 may be used as it is, as well as the maximum demand power controller 18, which has been generally used in the related art, may be used as long as the power usage can be checked.

The power control system 300 predicts a power usage prediction value (power usage prediction amount) from the power usage received from the power meter 180.

When the power usage prediction amount is expected to exceed the target power amount already set, the power control system 300 activates the emergency generator 350 to output excess power from which the power usage prediction amount exceeds the target power amount from the emergency generator 350. Supply to load groups 700.

The emergency generator 350 is operated according to the control of the power control system (eg, uptime, power generation amount, etc.) to generate power to supply the excess power required to the load groups 700. That is, the emergency generator 350 generates its own power by the emergency generator 350 to supply the excess power required by the load groups 700.

Then, the load is divided into a plurality of load groups 700 according to the power consumption of the load that is already set or measured, and each automatic transfer switch 200 controls the line of each load group 700 to the control of the power control system 300. Accordingly, the power line of the power provider or the power line of the emergency generator 350 is switched.

That is, the power control system 300 calculates or predicts the excess power amount when the power usage prediction amount predicted from the power usage amount received from the power meter 180 exceeds the target power amount.

In addition, the power control system 300 operates the emergency generator 350 at a time when the power usage prediction amount is expected to exceed the target power amount.

The power control system 300 calculates the load power amount of each load or the load power amount of each load group 700, and controls the automatic transfer switch 200 located on the line of each load group 700 to control each load or load. Switch the preference of group 700.

For example, when the amount of excess power is estimated to be 100 watts (W) and the load power of the third load group 700-3 is 100 watts, the power control system 300 is an emergency generator. Operation 350 to generate 100 watts of excess power, switching the second automatic transfer switch 200-2 to convert the line of the third load group 700-3 to the power line of the emergency generator 350. do.

On the other hand, when the power usage prediction amount does not exceed the target power amount, the power control system 300 stops the operation of the emergency generator 350 and switches the second automatic transfer switch 200-2 to load the third load. The line of group 700-3 is switched to the power line of the power provider.

That is, the power control system 300 does not stop the supply due to a problem such as a power supply supplied by the power supplier, but operates the emergency generator 350 at a time when the power usage prediction amount is expected to exceed the target power amount. The excess power is supplied to the load so that the load can be reliably supplied.

On the other hand, the power control system 300 operates the emergency generator 350 at the time of the power failure to switch the line of the load to the power line of the emergency generator 350 so that it can be constantly supplied with power.

6 is a view for explaining an embodiment of the power generation system for performing power peak control by the emergency generator according to the present invention.

As shown in FIG. 6, a plurality of breakers 400-1 and 400-2 are installed on a power line supplied with power from a power supplier, and an instrument transformer 120 and a transformer 130 are installed.

The breakers 400-1 and 400-2 cut off power when electric power (electricity) is leaked on the power line to prevent safety accidents such as fire or electric shock.

And, the instrument transformer 120 transmits a power pulse signal to the KEPCO meter 170, the power meter 180 measures the power consumption from the power pulse signal received from the instrument transformer 120.

The power control system 300 includes power control means 100, which may be implemented as a control device such as a microprocessor, and a plurality of breakers 400-3 and 400-4.

The power meter 180 transmits the measured power consumption to the power control means 100 of the power control system 300, and the power control means 100 predicts the power usage prediction amount from the power usage.

The power control means 100 controls and operates the emergency generator 350 when the power usage prediction amount exceeds the target power amount.

At this time, the power control means 100 may operate the emergency generator 350 according to the excess power amount to control the amount of power generated.

Then, the power line of the emergency generator 350 is separated and connected to the automatic transfer switch (200-1, 200-2), respectively.

Each breaker 400-3, 400-4 of the power control system 300 protects the power line of the emergency generator 350.

The power control means 100 calculates the amount of load power of each individual load or load group 700.

Then, the power control means 100 selects a load or load group 700 having a load power amount corresponding to the excess power amount.

According to an example, when the amount of excess power is predicted to be 100 watts (W) and the load power of the third load group 700-3 is 100 watts, the power control means 100 is an emergency generator. Operation 350 to generate 100 watts of excess power, switching the second automatic transfer switch 200-2 to convert the line of the third load group 700-3 to the power line of the emergency generator 350. do.

On the other hand, when the power usage prediction amount does not exceed the target power amount, the power control system 300 stops the operation of the emergency generator 350 and switches the second automatic transfer switch 200-2 to load the third load. The line of group 700-3 is switched to the power line of the power provider.

7 is a flowchart illustrating a power supply control method using a generator according to a preferred embodiment of the present invention.

Referring to FIG. 7, when power is supplied from a power supplier, the power meter 180 determines the power usage every 15 minutes according to the power pulse signal received from the KEPCO meter 170 (S 100).

Then, the power meter 180 transmits the power usage to the power control system 300 and calculates the power usage prediction amount (S 110).

The power control system 300 compares the power usage prediction amount with a target power amount already set (S 120), and if the power usage prediction amount does not exceed the target power amount, the power control system 300 checks whether the emergency generator 350 is operating (S 130). .

If the emergency generator 350 is in operation, the power control system 300 stops the operation of the emergency generator 350 (S 140).

In addition, the power control system 300 checks the current state of the automatic transfer switch 200 to determine whether the line of the load group 700 is connected to the power line of the emergency generator 350.

If the line of the load group 700 is connected to the power line of the emergency generator 350, the power control system 300 controls the automatic transfer switch 200 to control the line of the load group 700 to the power line of the power provider. Switch to

On the other hand, when the power usage prediction amount exceeds the target power amount, the power control system 300 checks whether the emergency generator 350 is operating (S 150).

If the emergency generator 350 is not operating, the power control system 300 operates the emergency generator 350 (S 160).

At this time, the power control system 300 controls the operation of the emergency generator 350 according to the amount of excess power, and to generate the excess power corresponding to the excess power.

The power control system 300 calculates the load power amount of each individual load or the load power amount of each load group 700 (S 170).

The power control system 300 selects a load or a load group 700 having a load power amount corresponding to the excess power amount (S 180).

The power control system 300 controls the automatic transfer switch 200 for switching the lines of the selected load group 700 to switch the lines of the selected load group 700 to the power lines of the emergency generator 350 (S). 190).

According to one example, when the excess power amount is predicted to be 100 watts (W) and the load power amount of the third load group 700-3 is 100 watts, the power control system 300 is an emergency generator. Operation 350 to generate 100 watts of excess power, switching the second automatic transfer switch 200-2 to convert the line of the third load group 700-3 to the power line of the emergency generator 350. do.

On the other hand, when the power usage prediction amount does not exceed the target power amount, the power control system 300 stops the operation of the emergency generator 350 and switches the second automatic transfer switch 200-2 to load the third load. The line of the group 700-3 is switched to the power line of the power provider (S 200).

That is, the power control system 300 does not stop the supply due to a problem such as a power supply supplied by the power supplier, but operates the emergency generator 350 at a time when the power usage prediction amount is expected to exceed the target power amount. The excess power is supplied to the load so that the load can be reliably supplied.

On the other hand, the power control system 300 operates the emergency generator 350 at the time of a power failure to convert the line of the load to the power line of the emergency generator 350 so that it can be constantly and stably supplied power.

The above detailed description of the present invention has been described, for example, when a separate power supply control system operates an emergency generator to supply excess power to the loads, but the emergency generator self-predicts the excess power to provide an emergency. The same applies if the generator supplies excess power to the loads.

That is, the power control system 300 may be integrally provided with the emergency generator 350, and the power meter 180 may be integrally provided with the emergency generator 350.

5 and 6 show the state in which the power control system 300 is integrally provided in the emergency generator 350 to form the emergency power generation control system 500 in dotted lines. Of course, the power meter 180 may be included in the emergency power generation control system 500 according to the embodiment.

The above embodiments are only preferred embodiments of the present invention, and the technical idea of the present invention may be variously modified or adjusted by those skilled in the art. Such modifications and adjustments fall within the scope of the present invention if they use the technical idea of the present invention.

As described above, according to the present invention, the power supplier can supply only as much power as the power consumer needs (target power amount), and even if the power demand increases and the power peak value exceeds the target value, the additional power supply is not required. It is not necessary.

In addition, the power consumer can solve the unnecessary power usage problem by supplying the loads with excess power exceeded by the emergency generator even when the amount of power consumed by the loads exceeds the target power amount.

In addition, the power consumer can secure a stable power supply by being able to supply power to the loads by the power generated by the emergency generator in an emergency situation such as a power outage.

Claims (8)

In a system for powering and controlling a plurality of loads driven by power supplied from a power supplier: A power meter supplied from the power provider to measure power consumption consumed by the loads; An emergency generator generating power by self-generation and supplying power to the load; At least one automatic transfer switch for converting a line from which the load is powered to a power line of the power provider or a power line of the emergency generator; The power usage prediction amount is calculated from the power usage measured by the power meter, and when the power usage prediction amount exceeds the target power amount by comparing it with a preset target power amount, the emergency generator is operated to generate power and the line of the load A power control system for controlling the automatic transfer switch to be switched to a power line of the emergency generator so that the generated power of the emergency generator is supplied to the load; Power generation system for performing the power peak control by the emergency generator comprising a. The method of claim 1, wherein the power control system, The load power amount for each load or load group for which a plurality of loads are clustered is calculated, and the load or load group corresponding to the excess power in which the power usage prediction amount exceeds the target power amount is selected, and the selected load or Power generation system for performing the power peak control by the emergency generator, characterized in that for controlling the automatic transfer switch for switching the line of the load group, so that the generated power of the emergency generator is supplied to the selected load or load group. The method of claim 1, wherein the power control system, If the power transfer predicted amount does not exceed the target power amount when the line of the load is switched to the power line of the emergency generator, the automatic transfer switch controls the auto transfer switch so that the line of the load is connected to the power provider. A power generation system for performing power peak control by an emergency generator, characterized in that the switch to the power line. The method of claim 1, wherein the power control system, And controlling the operation of the emergency generator so that the power usage predicted amount generates power corresponding to excess power exceeding the target amount of power. The method of claim 1, wherein the power control system, Power control means for operating the emergency generator to generate power when the power usage prediction amount exceeds the target power amount, and controlling the automatic transfer switch to supply power of the emergency generator to the load; A circuit breaker positioned between the emergency generator and the automatic transfer switch to protect a power line of the emergency generator; Power generation system for performing the power peak control by the emergency generator, characterized in that comprises a. In the power supply control method of the power generation system to perform the power peak control by the emergency generator, Calculating the amount of power consumed by the power supplied from the power supplier; Calculating a power usage prediction amount from the power usage amount and comparing the power usage prediction amount with a preset target power amount; Starting an emergency generator when the power usage forecast amount exceeds the target power amount; Calculating a load power amount for each load group for which the load power amount for each load or the plurality of loads is clustered; Selecting a load or load group having a load power amount corresponding to the excess power amount in which the power usage prediction amount exceeds the target power amount; Switching a line of the selected load or load group to a power line of the emergency generator; Control method of the power generation system to perform the power peak control by the emergency generator comprising a. The method of claim 6, wherein the step of switching to the power line of the emergency generator, The power control supply system includes at least one automatic switching switch for switching the line of the load, and to control the automatic transfer switch for switching the line of the selected load or load group to switch to the power line of the emergency generator A control method of a power generation system for performing power peak control by an emergency generator, characterized in that. The method of claim 6, If the predicted amount of power usage does not exceed the target power amount, the emergency generator is checked for operation and the emergency generator is stopped when the emergency generator is in operation, and the line of the load is connected to the power line of the emergency generator. Switching a line of the load to a power line of the power provider if switched; The control method of the power generation system to perform the power peak control by the emergency generator characterized in that it further comprises.

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