JP4905835B2 - Load control device for thermal power plant - Google Patents

Description

  The present invention relates to a load control device for a thermal power plant using coal, heavy oil or the like as fuel.

As schematically shown in FIG. 1, a thermal power plant using coal, heavy oil or the like as a fuel includes a boiler, a governor, a steam turbine, a generator, etc., generates steam by the boiler, and rotates the steam turbine to generate power. To do.
In order to change the power generation output in response to a load change of electric power, the steam flow flowing to the steam turbine is changed by the governor, and the amount of generated steam is changed by changing the fuel flow rate and the water supply amount.

  Conventionally, thermal power plants have mainly aimed at stable power supply, and demand for responsiveness to load changes has been small. Therefore, conventional load control of a thermal power plant is mainly performed in consideration of durability of the plant equipment, and control for maintaining the steam pressure and the steam temperature within a certain range.

However, in recent years, in response to fluctuations in power demand, even thermal power plants are required to respond to load changes.
Thus, various proposals have been made as means for improving the responsiveness of a thermal power plant (for example, Patent Documents 1 and 2).
Patent document 3 is a prior art related to the present invention.

The “power plant control apparatus” of Patent Document 1 aims to reduce an increase in operating costs due to power transmission output surplus or shortage due to a delay in response of the power plant to a power transmission output command or power transmission output pattern from a central power station.
Therefore, in the present invention, as shown in FIG. 16, the power plant control device 51 calculates the deviation between the power transmission output command from the central power station 59 or the power transmission output pattern 60 and the power transmission output signal 61 from the power transmission output detector 58. To do. The deviation signal 62 is integrated by the calculator 54, and the input device 53 corrects the power transmission output command or the power transmission output pattern 60 based on the integration result. The proportional calculator 52 calculates the deviation between the power transmission output command or power transmission output pattern 60 and the power transmission output signal 61 to create a generator output command signal 55 and control the power plant 50.

FIG. 2 is a control block diagram schematically showing the control of Patent Document 1. As shown in FIG. As shown in this figure, as means for improving the response characteristics of a thermal power plant, Patent Literature 1 uses only feedback control that does not use a controlled object model.
However, as a feature of feedback control, control is performed after a control result (a power generation amount in a thermal power plant) is obtained, so that it is insufficient as a response improvement means for a thermal power plant mainly composed of a response delay.

The “steam turbine load control device” of Patent Document 2 aims to stabilize the control characteristics of the steam turbine load control device and improve the responsiveness.
Therefore, in the present invention, as shown in FIG. 17, in a load control device for a power generation steam turbine having an electric governor, a digital setting system 73 for calculating a command value determined from a target load and a load change rate, and the command value A subtractor 74 that obtains a control deviation signal by comparing the output of the generator 5, and a function generation that obtains an opening setting signal for controlling the opening of the steam control valve and the intercept valve according to the control deviation signal And a lead / lag compensator 76 for compensating the response delay of the medium / low pressure turbine due to the reheater or the moisture separator / heater.

FIG. 3 is a control block diagram schematically showing the control of Patent Document 2. As shown in this figure, Patent Document 2 advances and compensates for the deviation (compensates the response delay by advancing the phase), but this method is not sufficient for a thermal power plant having a large response delay.
Further, it is possible to improve the responsiveness by increasing the feedback gain, but there is a possibility of overshoot or divergence.

An object of the “control device for an internal combustion engine” of Patent Document 3 is to make it possible to share the parameters of the actual torque response time for various applications for controlling the internal combustion engine.
Therefore, in the present invention, as shown in FIG. 18, the final target torque is set by the application selection means 81 from among the target torques set by the ISC, cruise control, traction control, AT-ECU, ABS-ECU, etc. The actuator command value (target throttle opening) corresponding to the target torque is selected and output from the output control means 82 to the engine 80, and the intake air amount is controlled so that the output torque of the engine 80 matches the target torque. . The output control means 82 converts the target torque into a target intake air amount, and compensates the target intake air amount by a response delay compensation means (an inverse model of the intake system model and an inverse model of the throttle model). It determines the throttle opening.

  FIG. 4 is a control block diagram schematically showing the control of Patent Document 3. As shown in FIG. The control of Patent Document 3 is a two-degree-of-freedom control, and after identifying an intake system model and a throttle model of an internal combustion engine, the inverse model is used for control design.

JP 2005-110382 A, “Power Plant Control Device” JP-A-7-224610, “Load Control Device for Steam Turbine” JP 2006-70701 A, “Control Device for Internal Combustion Engine”

  Since a thermal power plant generates electricity with a plurality of steam turbines having different characteristics and performs constant pressure control, constant temperature control, and the like, it is difficult to express the power generation response characteristic with a single transfer function. In addition, since the power generation response characteristics vary depending on external conditions such as fuel quality and temperature, it is impossible to always represent the same transfer function.

  A general control block diagram of the two-degree-of-freedom control applied in Patent Document 3 is shown in FIG. In this figure, P is a transfer function indicating the response characteristic of the controlled object, F is a transfer function specifying the target value response, and K is a transfer function specifying the feedback characteristic. In the two-degree-of-freedom control, feedforward control for improving the target value response and feedback control for reducing the influence of modeling error and disturbance can be realized independently, and high responsiveness can be realized.

  However, in the two-degree-of-freedom control, it is necessary to sufficiently identify the reverse response characteristic of the controlled object indicated by 1 / P in this figure, that is, the response characteristic of the controlled object. Therefore, there are many components such as the thermal power plant targeted by the present invention, and there is a problem that cannot be applied when it is difficult to model the control target.

  In addition, in the thermal power plant targeted by the present invention, it is necessary to keep the pressure and temperature of steam within a certain range from the durability of the plant equipment, and there is a problem that the existing control logic cannot be changed significantly. .

  The present invention has been developed to solve the above-described problems. That is, an object of the present invention is to provide a thermal power plant that can realize high responsiveness close to two-degree-of-freedom control without almost changing existing control logic and identifying response characteristics of a control target. It is to provide a load control device.

According to the present invention, there is provided a load control device for a thermal power plant that controls the power plant so as to output a power output B corresponding to the required power A,
A plant control device P for controlling the power plant so as to output a power output B corresponding to the target power C while performing constant pressure control or constant temperature control;
A frequency response improvement filter F1 that outputs a corrected required power A1 obtained by correcting the required power A;
A feedback circuit that adds the predetermined coefficient K to the difference dB = A−B between the required power A and the power output B to obtain a target power correction value D, and adds this to the corrected required power A1 to obtain the target power C; A thermal power plant load control device characterized by comprising:

  According to a preferred embodiment of the present invention, the corrected required power A1 multiplies the required power A by a predetermined gain G according to the change speed dA / dt of the required power A.

  The gain G is 1 when the change rate dA / dt of the required power A is smaller than a predetermined first threshold, rapidly increases when the change exceeds the first threshold, and is constant when the predetermined maximum value is reached. Is preferably set so as to gradually decrease when the change rate dA / dt of the required power A exceeds a predetermined second threshold.

  According to the configuration of the present invention, since the power plant is controlled so as to output the power output B corresponding to the target power C while performing constant pressure control or constant temperature control, the existing control logic is provided. The power generation response according to the above can be regarded as the determined response characteristic and can be applied as it is.

  In addition, a feedback circuit that integrates a predetermined coefficient K to the difference dB = A−B between the required power A and the power output B to obtain a target power correction value D, and adds this to the corrected required power A1 to obtain the target power C. Therefore, it is possible to realize feedback control that reduces the effects of modeling errors and disturbances.

  Furthermore, a frequency response improvement filter F1 that outputs a corrected required power A1 obtained by correcting the required power A is provided. Preferably, the corrected required power A1 is changed to the required power A according to the change speed dA / dt of the required power A. Since the predetermined gain G is multiplied, feedforward control that improves the target value response can be realized independently.

That is, the point of the present invention is that the filter F1 that improves the frequency corresponding to the load change of the power is used instead of using the inverse model of the controlled object.
With this configuration, feedforward control is performed, and response delay can be further improved.
In addition, since it is designed based on an assumed frequency of required load change, strict model identification is not required. Also, how much the gain is set depends on the degree of response improvement required, but can be arbitrarily set.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

FIG. 6 is a control block diagram showing a first embodiment of a load control device for a thermal power plant according to the present invention.
The load control device for a thermal power plant according to the present invention is a control device that controls the power plant so as to output a power output B corresponding to the required power A in response to the required power A.

  In this figure, the control device of the present invention includes a plant control device P, a frequency response improvement filter F1, and a feedback circuit 10.

  The plant control device P controls the power plant so as to output a power output B corresponding to the target power C while performing constant pressure control or constant temperature control. For this plant control device P, existing control logic for controlling the power plant can be used as it is.

  The frequency response improving filter F1 (hereinafter simply referred to as “filter”) outputs a corrected required power A1 obtained by correcting the required power A. The corrected required power A1 adds a predetermined gain G to the required power A according to the change speed dA / dt of the required power A.

  The feedback circuit 10 includes an extraction point 11, an addition point 12, an integration function 13, and an addition point 14, and corrects the target power by adding a predetermined coefficient K to the difference dB = A−B between the required power A and the power output B. A value D is set, and this is added to the correction required power A1 to obtain a target power C.

  In FIG. 6, the target value response function F is preferably added as a filter for removing high frequency components when the power load includes high frequency components. However, the required power A (hereinafter also referred to as “power load”) is a power transmission request pattern from the central power station, and does not include high-frequency components such as noise, and performs rate limit processing.

FIG. 7 is a diagram illustrating the frequency-gain characteristics of the filter F1.
In this figure, the gain G is 1 when the change speed dA / dt (frequency) of the required power A is smaller than a predetermined first threshold value a1, and increases rapidly when it exceeds the first threshold value a1. It is set to remain constant when it reaches the value G1 times, and gradually decreases when the change rate dA / dt of the required power A exceeds a predetermined second threshold value a2, as described above. (Load) does not include high frequency components such as noise and performs rate limit processing, etc., so the response characteristics shown by solid lines are basically sufficient, and the response characteristics shown by the dotted lines are only used when the power load contains high frequency components. Shall be set.
Note that the filter F1 is not limited to this configuration, and a frequency response improving filter shown in an example described later may be used.

FIG. 8 is a diagram illustrating a control example according to the present invention. In this example, it is assumed that a power load change simulating the power transmission request pattern (A) from the central power station is given to the thermal power generation simulation model.
(B) is a general control block diagram of the load control device. In this figure, FX is a control device, (1) when correction by target value shaping is not performed, (2) only feedback control, (3) feedback control with compensation for the deviation, and (4) according to the present invention. The power deviation of 2-degree-of-freedom control with feedforward control was measured.

FIG. 9 is a comparison diagram of power deviation according to the control example of FIG.
As can be seen from this figure, the feedback control gain used in the two-degree-of-freedom control is the same as the lead compensation in (3), so that the response delay is greatly improved by the feedforward control portion.

FIG. 10 is a control block diagram showing a second embodiment of the load control device according to the present invention.
In FIG. 10, the frequency response improving filter F1 includes a high-pass filter HF that passes only the high-frequency component of the required power A, and an addition point 15 for adding the passed high-frequency component to the required power A.
With this configuration, the part indicated by the dotted frame in the figure can be integrated as a preceding input circuit, and more practical control can be performed by adding limits and rate limits to avoid excessive responses. It becomes.
The control block diagram of FIG. 10 is equivalent to FIG. 6 and has the same function.

FIG. 11 is a control block diagram showing a third embodiment of the load control device according to the present invention.
This control block diagram is also equivalent to FIG. 6 and has the same function.

  Examples of the present invention will be described below.

The thermal power generation simulation model conventionally follows the power load requirement of 1% L / min and improves the response so that it can newly follow 3% L / min.
Here,% L is a unit indicating what percentage of the rated load. Furthermore, the amount of change in the power load request is 10% L.

It takes 600 seconds to change the 10% L output at 1% L / min and 200 seconds to change the 10% L output at 3% L / min.
Therefore, in order to realize such an improvement in responsiveness, the gain to the input change of 1% L / min · 600 seconds is close to 1 ×, and the gain to the input change of 3% L / min · 200 seconds is A high filter may be a frequency response improvement filter.

FIG. 12 is a Bode diagram of the frequency response improving filter. As a unit of gain, dB (decibel) is used.
For example, the Bode diagrams of the three transfer functions shown in Equation (1) to Equation (3) in Equation 1 differ only in the frequency components that respond as shown in this drawing.

FIG. 13 is a diagram illustrating responses to input changes in the three transfer functions.
The responses to input changes of 1% L / min · 600 seconds and 3% L / min · 200 seconds are very different as shown in this figure.
Also, it can be seen that F1b is appropriate among these three responses. This is because the gain up to 200 seconds (5 * 10 ⁻³ Hz) is high, and then the gain decreases toward 1 time (0 db).

  For the frequency response improving filter, the transfer function may be a second or higher order transfer function as shown in Equation (4).

FIG. 14 is a control block diagram showing a fourth embodiment of the load control device.
In order to avoid overshoot, upper and lower limit limits may be provided with the power load target value as shown in this figure as a limit value.

  FIG. 15 is an example of power output to which a power load target value obtained by adding a frequency response improving filter and a feedback gain of gain 1 is applied. By applying a power load target value obtained by adding a frequency response improvement filter and a feedback gain of gain 1, an improvement in power output can be expected as shown in FIG.

  According to the configuration of the present invention, since the power plant is controlled so as to output the power output B corresponding to the target power C while performing constant pressure control or constant temperature control, the existing control logic is provided. The power generation response according to the above can be regarded as the determined response characteristic and can be applied as it is.

  In addition, a feedback circuit that integrates a predetermined coefficient K to the difference dB = A−B between the required power A and the power output B to obtain a target power correction value D, and adds this to the corrected required power A1 to obtain the target power C. Therefore, it is possible to realize feedback control that reduces the effects of modeling errors and disturbances.

  Furthermore, a frequency response improvement filter F1 that outputs a corrected required power A1 obtained by correcting the required power A is provided. Preferably, the corrected required power A1 is changed to the required power A according to the change speed dA / dt of the required power A. Since the predetermined gain G is multiplied, feedforward control that improves the target value response can be realized independently.

That is, the point of the present invention is that the filter F1 that improves the frequency corresponding to the load change of the power is used instead of using the inverse model of the controlled object.
With this configuration, feedforward control is performed, and response delay can be further improved.
In addition, since it is designed based on an assumed frequency of required load change, strict model identification is not required. Also, how much the gain is set depends on the degree of response improvement required, but can be arbitrarily set.

  In addition, this invention is not limited to embodiment mentioned above, Of course, it can change variously in the range which does not deviate from the summary of this invention.

It is a schematic diagram of a thermal power plant. It is a control block diagram which shows typically the control of patent document 1. FIG. It is a control block diagram which shows typically the control of patent document 2. FIG. It is a control block diagram which shows typically control of patent documents 3. It is a general control block diagram of 2 degree-of-freedom control. It is a control block diagram which shows 1st Embodiment of the load control apparatus of the thermal power plant by this invention. It is a figure which shows the frequency-gain characteristic of filter F1. It is a figure which shows the example of control by this invention. It is a comparison figure of the electric power deviation by the example of control. It is a control block diagram which shows 2nd Embodiment of the load control apparatus by this invention. It is a control block diagram which shows 3rd Embodiment of the load control apparatus by this invention. It is a Bode diagram of a frequency response improvement filter. It is a figure which shows the response with respect to the input change in three transfer functions. It is a control block diagram which shows 4th Embodiment of a load control apparatus. It is an example of electric power output to which the electric power load target value which added the feedback gain of the frequency response improvement filter and the gain 1 is applied. 1 is a configuration diagram of a “power plant control apparatus” in Patent Document 1. FIG. 2 is a configuration diagram of a “steam turbine load control device” of Patent Document 2. FIG. 3 is a configuration diagram of “a control device for an internal combustion engine” in Patent Document 3. FIG.

Explanation of symbols

A required power, A1 corrected required power, dA / dt rate of change,
B power output, C target power, D target power correction value,
F target value response function, F1 frequency response improvement filter,
G gain, HF high-pass filter,
K factor, P plant controller,
10 Feedback circuit,
11 withdrawal points, 12 addition points,
13 integration function, 14 addition points,
15 addition points,

Claims (3)

A load control device for a thermal power plant that controls a power plant so as to output a power output B corresponding to the required power A,
A plant control device P for controlling the power plant so as to output a power output B corresponding to the target power C while performing constant pressure control or constant temperature control;
A frequency response improvement filter F1 that outputs a corrected required power A1 obtained by correcting the required power A;
A feedback circuit that adds the predetermined coefficient K to the difference dB = A−B between the required power A and the power output B to obtain a target power correction value D, and adds this to the corrected required power A1 to obtain the target power C; A load control apparatus for a thermal power plant, comprising:   The load control device for a thermal power plant according to claim 1, wherein the corrected required power A1 multiplies the required power A by a predetermined gain G according to a change speed dA / dt of the required power A.   The gain G is 1 when the change rate dA / dt of the required power A is smaller than a predetermined first threshold, increases rapidly when the change exceeds the first threshold, and remains constant when it reaches a predetermined maximum value. The load control device for a thermal power plant according to claim 2, wherein the load control device is set to gradually decrease when the change speed dA / dt of the required power A exceeds a predetermined second threshold value.

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