JP5571456B2 - Control method for power generation control device - Google Patents

Description

The present invention relates to a power generation control apparatus using simultaneous power amount control for determining an output command of a generator so as to be a generator transmission power amount equal to a power amount specified at regular time intervals in a power system. It relates to a control method.

Electricity liberalization has been achieved due to deregulation, and there is an increasing number of power producers and suppliers (hereinafter referred to as PPS) of specific scales that newly build private power generation facilities and use the power company's power transmission network to buy and sell power It was.
The PPS needs to transmit electric power required by the contracted consumer, and generally contracts with a power amount per fixed time. If this amount of electricity is not observed, the contract may be breached and a penalty may be incurred.

Since it is difficult to control the generator output to match the power amount when the power amount fluctuates every certain time, the power contract with PPS is not a sales contract when the power amount fluctuates Or, it is common to make a contract on the assumption that the amount of electric power is not changed.
Against this background, the transmission power amount is matched with the contracted power amount by changing the generator output according to the fluctuating power amount so that power trading can be performed even when the power amount fluctuates every certain time ( There is a demand for a method for controlling the amount of electric power that can be simultaneously applied (Patent Documents 1 and 2).

Japanese Patent No. 3806029 JP 2004-104949 A

However, in the simultaneous equal amount control methods in Patent Documents 1 and 2, it may take a long time for the power supply command power amount to coincide with the generator transmission power amount.
Further, when the generator output is changed in order to match the power supply command power amount and the generator transmission power amount, an extra output increase command and output decrease command may be output.
In addition, this has a problem that the generator life is shortened.

  Therefore, the present invention solves such problems, the purpose of which is to make the generator transmission power amount coincident even when the power amount per fixed time given from the power supply command system fluctuates, Moreover, it is to shorten the generator output fluctuation time, reduce the load on the generator, and extend the generator life.

In order to solve the above-described problems and achieve the object of the present invention, the present invention is configured as follows.
That is, the control method of the power generation control device according to the present invention includes a power supply command input unit that receives a power amount of a power supply command every predetermined unit time, a transmission power input unit that receives current transmission power, and a plurality of generators A generator output command output unit for transmitting a generator output command to the power supply control device, and supplying power by dividing the power amount per unit time input to the power supply command input unit by unit time Command power, using error integrated power integrated error power that is the difference between the current power transmission power received by the transmission power input unit and the power supply command power as the adjustment power of the power supply command power , Furthermore, a rate limiter for setting an upper limit of the electric energy is provided, and the sum of the error integrated power and the error power is limited by the rate limiter so that it can be applied to generators having different power generation efficiency. , Characterized by using a regulated power after the is the output of the rate limiter limiting the supply-demand output command obtained by adding to the feed command power, as the output command value of the plurality of generators.

  With this configuration, the power supply command power amount matches the generator transmission power amount within a fixed time. Moreover, the generator output fluctuation time is shortened.

  ADVANTAGE OF THE INVENTION According to this invention, even when the electric energy for every fixed time given from an electric power feeding command system fluctuates, generator electric power transmission electric energy can be united. In addition, the generator output fluctuation time is shortened, the load on the generator is reduced, and the generator life is increased.

It is a block diagram which shows the logic outline | summary of the electric energy simultaneous amount control method of the electric power error integration system used with the control method of the electric power generation control apparatus of this invention. 1 is a configuration diagram of a power control system of a power plant to which a power error integration type simultaneous power amount control method of a power error integration method used in a control method of a power generation control device of the present invention is applied. It is a characteristic view which shows the various electric power control methods including the electric energy simultaneous same amount control method of the electric power error integration system used with the control method of the electric power generation control apparatus of this invention.

(First embodiment)
Embodiments of the present invention will now be described. FIG. 1 is a block diagram showing a logic outline of a power amount simultaneous and same amount control method of the power error integration method used in the control method of the power generation control device of this embodiment.
However, in describing the logic outline of the power error integration type simultaneous power amount control method of the power error integration method used in the control method of the power generation control device of this embodiment of FIG. 1, a power plant to which this embodiment of FIG. 2 is applied. It is easier to understand the technical background of this power control system. Therefore, an outline of the configuration of the power control system of the power plant in FIG. 2 will be described first, and then the present embodiment in FIG. 1 will be described.

<Power plant power control system>
The best mode for carrying out the present invention is application to a power control system of a power plant. FIG. 2 shows the configuration of a power control system of a power plant having n generators to which the power error integration type simultaneous power amount control method of the power error integration method used in the control method of the power generation control device is applied .
In FIG. 2, a command for the amount of electric power (characteristic diagram 201) that fluctuates every certain time is sent from the power supply command system 21 to the overall load control device 22. The integrated load control device 22 has each load of n generators 241 to 24n from n load control devices (No. 1 load control devices 231 to n load control devices 23n) having a generator output control function. Information on (No. 1 actual load to No. n actual load) is obtained.

Then, compared with the command related to the electric energy of the power supply command system 21, “simultaneous same amount control” and “load distribution control” described later are performed, and n load control devices (No. 1 load control device 231 to No. n load) are performed. Each load command (No. 1 load command to No. n load command) is output to the control device 23n).
Each of the n load control devices (No. 1 load control device 231 to n load control device 23n) issues a load command to each of the n generators (No. 1 generator 241 to n generator 24n), Operate each generator. Note that each of the n generators (No. 1 generator 241 to No. n generator 24n) transmits information on each actual load according to the voltage and current of the generator, and the n load control devices (No. 1 load control devices 231 to 231). The n-th load control device 23n) grasps each.

  As described above, “simultaneous same amount” is a control for generating the same amount of power as the command related to the power amount of the power supply command system 21 and generating the same amount of power as the power supply command in a short time almost simultaneously with the command. Control "and" load distribution control "that performs load distribution according to the capacity and state of each generator.

<Control logic applied to the same amount of power control using the power error integration method>
FIG. 1 shows an outline of a control logic applied to simultaneous power amount control of the power error integration method used in the control method of the power generation control device of this embodiment.
In FIG. 1, an interior surrounded by a broken line 11 is a power generation control function block 11 showing the function of the power generation control device in a block diagram. The inside surrounded by the broken line 12 is the simultaneous and same amount adjusting unit 12.

  The power supply command system power amount (Pt) 101 that changes from the power supply command system SYS at regular intervals is received by the division block A1 provided in the power generation control function block 11. In addition, since FIG. 1 represents the function of the power generation control device as a block diagram, the device itself is not illustrated. However, the power supply command input unit (not shown) that receives the power amount of the power supply command as a device is roughly equivalent to the functional block in FIG. 1 for the power supply command system power amount (Pt) 101 or a division block having an input terminal. A1.

The division block A1 is provided with a clock source for inputting t as a reference time or generating t as a reference time in the division block A1. In the division block A1, the power supply command system power amount Pt, which changes every predetermined time, is divided by the time t to obtain a power supply command power W1t (1 formula).
Note that dividing the power supply command system power amount Pt by the time t to obtain the power supply command power W1t also means converting the power amount into power.
In addition, the reference time t is generally in units of minutes (several minutes to several tens of minutes).

W1t = Pt / t (1 formula)

The transmission power detection block A2 detects the current transmission power. FIG. 1 shows a function for detecting transmission power as a transmission power detection block A2, and a device for detecting transmission power, wiring for transmission, and the like are not shown.
In addition, a transmission power input unit (not shown) that receives current transmission power as an apparatus roughly corresponds to the function block of FIG. 1 having a current transmission output (power) (W2t, W10t) 102 or a detection function. Transmission power detection (block) A2.

The difference between the power supply command power W1t and the current transmission output (power) W2t received from the transmission power detection (block) A2 is subtracted by the subtraction block A3, and the obtained output value is set as the error power W3t (Equation 2). .
This grasps the divergence between the power supply command power W1t reflecting the command of the power supply command system and the current power transmission output (power) W2t.

W3t = W1t−W2t (2 formulas)

The adjusted power (before limitation) W5t calculated in the integration block A5 is held for one timing (t) in the holding block A5 ′ (DLY: Delay). This held one is designated as W5t-1. This relationship is expressed as shown in (Formula 3).
It should be noted that this is because the difference between the power supply command power W1t reflecting the command of the power supply command system and the current power transmission output (power) W2t is accumulated not only at the current time but also at the past time. This is because (DLY: Delay) data held at one timing (t) is used as information on past transmission power in order to reflect this.

W5t-1 = DLY (W5t) (3 formulas)

An error adjustment power W4t is obtained by adding the error power W3t and the adjustment power (before restriction) W5t-1 calculated one timing before in the addition block A4 (Equation 4).
This is the sum of the deviation from the current power transmission output W2t and the accumulation at the past time point.

W4t = W3t + W5t-1 (4 formulas)

An error integrated power W5t is obtained by integrating the error adjustment power W4t in the integration block A5, and this becomes the adjustment power (before limit) W5t (Equation 5).
This is to accumulate (integrate) errors (deviation) in order to perform power adjustment in a short time (simultaneously) and accurately (same amount).
The integration here is performed in an analog manner, and is generally performed in seconds.

W5t = ∫W4t · dt (5 formulas)

The power obtained by limiting the adjusted power (before limit) W5t by the power limit block A6 becomes the adjusted power W6t (formula 6).
The power limit block A6 is realized by a rate limiter. The adjusted power (before limitation) W5t may be output as an unrealistic value exceeding the total of the actual capacities of the plurality of generators (GEN1 to GENn) in calculation. Realistic power control is realized by setting the upper limit of power or the limit of change amount by the power limit block A6.
Note that, when the limit is provided by the power limit block A6, the limited difference remains, but this is gradually eliminated by the calculation after the next unit time (t).

W6t = Lim (W5t) (6 formulas)

A value obtained by adding the adjustment power W6t and the power supply command power W1t in the addition block A7 is a simultaneous same amount output command W7t (expression 7).
As the adjustment power W6t adjusts the difference between the power supply command power W1t and the current power transmission output (power) W2t, the adjustment power W6t is added to the power supply command power W1t.

W7t = W1t + W6t (7 formulas)

Simultaneous output control command W7t is output by generator output command distribution block A8, and generator output command W8t is output to a plurality of generators, and generators GEN1 to GENn are controlled according to the output to realize simultaneous control of the same amount. . As described above, the generators may be expressed as generators GEN1 to GENn, and the outputs of the generators may be expressed as generator outputs GEN1 to GENn.
Further, a generator output command distribution block A8 is roughly equivalent to a function block of FIG. 1 as a generator output command output unit (not shown) as a device.
Then, the generated power of all the generators is set as a generator output W8t ′ (Equation 8).
Note that there may be a slight difference between the generator output command W8t and the generator output W8t ′ obtained by adding the actual generated power of all the generators.

W8t ′ = GEN1 + GEN2 +... + GENn (Expression 8)

In the subtraction block A10, a value obtained by subtracting the in-house power W9t detected from the in-house power detection (block) A9 from the generator output W8t ′ is the current transmission output W10t (Equation 9).
This is to subtract the in-house power W9t corresponding to the amount of power (including the loss) used inside the power plant by the power generated by the plurality of generators GEN1 to GENn of the power plant.

W10t = W8t′−W9t (9 formulas)

This power transmission output W10t is equal to the power transmission output W2t used in the simultaneous power amount control (equation 10).

W2t = W10t (10 formulas)

  In the present invention, by adding the adjusted power W6t to the power supply command power W1t as the simultaneous same amount output command W7t, the power output command system power amount Pt (and power P) is satisfied, and then the generator output command Simultaneously and simultaneously controlling the amount of electric power that makes W8t constant quickly is realized.

<Output power control characteristics>
Next, control characteristics in the case of using the same amount of electric power at the same time will be described.
FIG. 3 is a characteristic diagram showing various power control methods including a power error integration type simultaneous power amount control method of the power error integration method used in the control method of the power generation control device of the present invention.
FIG. 3 (c) shows the output power control characteristics obtained by applying the power error integration type simultaneous power amount control of the power error integration method used in the control method of the power generation control device of this embodiment (the present invention) to the power control system. is there. Note that the title of FIG. 3C is “simultaneous power error integration type simultaneous amount control of the present invention” for simplification.
When an output command is given as a rectangular wave from the power supply command system indicated by the broken line in FIG. 3C, the generator power transmission output having the waveform indicated by the solid line is obtained. In order to respond steeply at the rise and fall of the rectangular wave output command, the generator power transmission output responds while vibrating, and finally coincides with the output command.

At this time, a triangular portion constituted by a broken line and a solid line corresponds to a deficiency of the generator power transmission output with respect to the output command. Further, the triangular portion formed by the solid line of the generator power transmission output beyond the rectangular wave output command corresponds to the surplus of the generator power transmission output with respect to the output command. These deficiencies and surpluses are controlled to be equal.
Thus, even when a load command is given by a rectangular wave from the power supply command system, the amount of power can be easily controlled, and the generator output can be made constant at an early stage.

As a reference diagram, FIG. 3A is a characteristic diagram in the case of “control only by the error between the generator output command value and the generator power transmission output”.
Generally, a specified power amount is given as a load command by a rectangular wave every n minutes from the power supply command system. However, since the generator is limited by the load following characteristics due to mechanical limitations, the generated power is a rectangular wave. Instead, power is generated at a constant rate of change. For this reason, the transmitted power follows with a constant rate of change until reaching the load command value, and even if the rectangular wave load command is given as it is, the generated power in a certain time as shown in FIG. The amount cannot be controlled to a specified value.
In this method, the amount of power indicated by the triangle in the broken line part of FIG. 3A is insufficient or excessive, and there is no guarantee that the total amount of power becomes the value determined by the contract.

Further, as a reference diagram, FIG. 3B is a characteristic diagram in the case of “known simultaneous equal amount control”.
In this method, simultaneous equal amount control is performed, and control that satisfies the amount of power specified by the power supply command system is performed.
However, in the known simultaneous and same amount control, the generator output constantly fluctuates, and it is difficult to control the amount of power, and it may take a long time for the power supply command power amount and the generator transmitted power amount to coincide.
Further, when the generator output is changed in order to match the power supply command power amount with the generator transmission power amount, an extra output increase command and output decrease command may be output. For this reason, the control method shortens the generator life.

As described above, in the present embodiment, the output voltage control as shown in FIG. 3C is performed by applying the power error integration type simultaneous power amount control of the power error integration method used in the control method of the power generation control device to the power control system. Even when a load command is given as a rectangular wave from the power supply command system, the amount of power can be easily controlled and the generator output can be made constant at an early stage.
Therefore, the power supply command power amount and the generator transmission power amount coincide with each other within a predetermined time shorter than in the past.
Further, since no extra output increase command or output decrease command is output when the generator output is varied, the generator life is prevented from being shortened.

<Further effects of this embodiment>
As described above, in the present embodiment, the amount of electric power that fluctuates every predetermined time is adjusted by appropriately adjusting the generator output using the power error integration method simultaneous equal amount control in the control method of the power generation control device of the present invention. By matching, it is possible to supply the amount of power contracted as PPS.

  In addition, even when the amount of electric power given by the power supply command system fluctuates, it is possible to track the power transmission amount of the generator to match, so that it is also possible to trade power that is not currently sold or traded I can do it.

  Further, even when the amount of electric power given by the power supply command system for every fixed time fluctuates, it is possible to make the electric power transmitted by the generator consistent, so the range of contracts in terms of electric energy is expanded.

Further, by using the power error integration type simultaneous equal amount control method of this embodiment, the generator output fluctuation time is shortened, and unnecessary output increase command and output decrease command at the time of power amount adjustment are solved or reduced.
In addition, since the generator output fluctuation time becomes short, the burden on the generator is reduced, and the generator life can be extended.

  Moreover, since this embodiment is realizable by changing the logic of the generator output command part of a generator, it can be applied to the existing power generation equipment. Therefore, it is possible to change the power generation facility that is contract-operated with a certain amount of power or the like to a contracted operation in which the amount of power fluctuates.

DESCRIPTION OF SYMBOLS 11 Electric power generation control functional block 12 Simultaneous same amount adjustment part 101, Pt Feeding command system electric energy (feeding command input part)
102, W2t, W10t Current transmission power (transmission power input unit)
103, W8t Generator output command after distribution A1 Division block A2 Transmission power detection block A3, A10 Subtraction block A4, A7 Addition block A5 Integration block A5 'Holding block A6 Power limit block A8 Generator output command distribution block (generator output) Command output part)
A9 In-house power detection block GEN1-GENn Output of generator (1-n), generator (1-n)
SYS Power supply command system block W1t Power supply command power W3t Error power W4t Error adjustment power W5t Adjustment power before adjustment, adjustment power, error integration power W5t-1 Adjustment power before 1 timing, adjustment power W6t Adjustment power after limitation W7t Simultaneously Quantity output command W8t 'Generator output W9t In-house power

Claims (2)

A power supply command input unit that receives the power amount of the power supply command every predetermined unit time, a transmission power input unit that receives current transmission power, and a generator output command output that transmits a generator output command to a plurality of generators A control method of a power generation control device comprising:
By dividing the amount of power per unit time input to the power supply command input unit by unit time, power supply command power is obtained, and the current power transmission power and the power supply command power received by the power transmission power input unit The error integrated power obtained by integrating the error power that is the difference between the power supply command power is used as the adjustment power of the power supply command power ,
Furthermore, it has a rate limiter that sets the upper limit of the electric energy,
The rate limiter limits the power that is the sum of the error integral power and the error power so that it can be applied to generators with different power generation efficiency,
A control method for a power generation control device , wherein a simultaneous same amount output command obtained by adding regulated power, which is an output of the rate limiter, to the power supply command power is used as an output command value of the plurality of generators . In the control method of the power generation control device according to claim 1 ,
Control of a power generation control device, wherein a power supply command power amount that changes every predetermined unit time given from the power supply command system to the power supply command input unit and a power transmission power amount of a generator are matched within a predetermined time Method.

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