KR20220094159A - Control device and control method - Google Patents

Abstract

The present invention relates to a control apparatus and a control method. The control apparatus lets a thermal power plant provided with a turbine bypass valve for regulating an amount of steam bypassing a steam turbine driven by the steam from a boiler be a control target. The control apparatus controls the boiler based on a boiler input command value, while controlling the turbine bypass valve based on a turbine bypass valve opening command value. The turbine bypass valve opening command value is generated based on an AFC signal in an AFC compatible mode of the thermal power plant. The boiler input command value is generated by adding a bias value with a positive sign to a base input value based on a load command value for a thermal power plant in the AFC compatible mode. The control apparatus of the present invention comprises: a turbine bypass valve opening command value generating unit; a turbine bypass valve controlling unit; a boiler input command value generating unit; and a boiler controlling unit.

Description

CONTROL DEVICE AND CONTROL METHOD

The present disclosure relates to a control device and a control method.

This application claims priority based on Japanese Patent Application No. 2020-219036 for which it applied to the Japan Patent Office on December 28, 2020, and uses the content here.

BACKGROUND OF THE INVENTION A thermal power plant is known in which steam generated from a boiler (steam generator) is used to drive a steam turbine. In thermal power plants of this kind, for the line for supplying steam from the boiler to the steam turbine, there is often a turbine bypass valve above the bypass line configured to bypass the steam turbine. A turbine bypass valve is typically used in order to suppress a rise in vapor pressure by contributing to reduction of a start time by opening degree controlled before start of a steam turbine, or by opening operation when the vapor pressure in a steam turbine rises excessively.

However, as such a thermal power plant, an electric company operating a thermal power plant for generating power using the output of a steam turbine transmits the voltage and frequency of the generated power to the power system that is the power supply destination based on the Electricity Business Act. It is an obligation to try to maintain each of the values at a predetermined value for each. The electric power company responded by controlling the boiler output based on the load command value provided from the central power supply center or AFC (Automatic Frequency Control) signal corresponding to the relatively fast frequency change according to the supply and demand condition in the power system.

However, for example, in a thermal power plant using a boiler with low responsiveness, such as a coal boiler, it is difficult to obtain good followability to a component corresponding to a relatively fast frequency change such as an AFC signal. With respect to such a conventional subject, for example, in Patent Document 1, when an AFC signal is received while maintaining the above-described turbine bypass valve in a fully closed state during normal operation, the AFC signal is added to the load command value. While generating the obtained boiler input command value, it is proposed to improve the followability|trackability with respect to an AFC signal by performing opening degree control of the turbine bypass valve proportional to an AFC signal.

Japanese Patent Laid-Open No. 59-145309

In Patent Document 1, when the AFC signal is received, the boiler input command value is generated by adding the AFC signal to the load command value. Therefore, while the AFC signal is positive, the boiler input command greater than the load command value is is obtained On the other hand, when the AFC signal is negative, it becomes a boiler input signal smaller than the load command value, and since the adjustment margin for controlling the opening degree of the turbine bypass valve corresponding to the AFC signal is small, the large amount of the AFC signal It becomes difficult to respond to change. Further, in Patent Document 1, the boiler input signal is obtained by adding the AFC signal to the load command value. However, as described above, there is a time lag to a considerable extent until the boiler input signal is reflected in the amount of steam from the actual boiler, and the AFC There exists a possibility that cooperation of the turbine bypass valve whose opening degree is controlled in proportion to a signal cannot be made favorable.

At least one embodiment of the present invention has been made in view of the above circumstances, and an object of the present invention is to provide a control device and a control method capable of contributing to frequency maintenance of an electric power system by having good followability to an AFC signal.

In order to solve the above problem, the control device according to at least one embodiment of the present invention includes:

A control device for a thermal power plant comprising a boiler, a steam turbine driven by steam from the boiler, and a turbine bypass valve for regulating the amount of steam bypassing the steam turbine,

a turbine bypass valve opening degree command value generating unit for generating a turbine bypass valve opening degree command value of the turbine bypass valve based on an AFC signal in the AFC corresponding mode of the thermal power plant;

a turbine bypass valve control unit for controlling the turbine bypass valve based on the turbine bypass valve opening degree command value;

a boiler input command value generating unit for generating a boiler input command value by adding a positive bias value to a base input value based on a load command value for the thermal power plant in the AFC corresponding mode;

a boiler control unit for controlling the boiler based on the boiler input command value;

be prepared

In order to solve the above problem, the control method according to at least one embodiment of the present invention includes:

A control method of a thermal power plant comprising a boiler, a steam turbine driven by steam from the boiler, and a turbine bypass valve for regulating the amount of steam bypassing the steam turbine,

generating a boiler input command value by adding a positive bias value to a base input value based on a load command value for the thermal power plant in the AFC-compatible mode of the thermal power plant;

controlling the boiler based on the boiler input command value;

a step of generating a turbine bypass valve opening degree command value of the turbine bypass valve based on an AFC signal in the AFC-compatible mode;

a step of controlling the turbine bypass valve based on the turbine bypass valve opening degree command value;

be prepared

According to at least one embodiment of the present invention, it is possible to provide a control device and a control method capable of contributing to frequency maintenance of an electric power system by having good followability to an AFC signal.

1 is a schematic configuration diagram of a thermal power plant according to an embodiment.
FIG. 2 is a block diagram showing an internal configuration of the control device of FIG. 1 .
3 is a control logic diagram of the turbine bypass valve opening command value generator of FIG. 2 .
FIG. 4 is an example of a function included in the function calculator of FIG. 3 .
5 is a control logic diagram of the boiler input command value generator of FIG. 2 .
FIG. 6 is an example of a bias value obtained by the function calculator of FIG. 5 .
7 is a control logic diagram of the main steam valve opening command value generator of FIG. 2 .
Fig. 8 is a timing chart showing time changes of various signals in the control device of Fig. 2;
9 is a graph showing the adjustment margin of the plant at the load command value.
10 is an overall configuration diagram of a thermal power plant according to another embodiment.
It is a part of the control logic diagram of the turbine bypass valve opening degree command value generation part with which the control apparatus of FIG. 10 is equipped.
12 is a graph illustrating a relationship between a differential pressure and a gain in the function calculator of FIG. 11 .

Hereinafter, some embodiments of the present disclosure will be described with reference to the accompanying drawings. However, the dimensions, materials, shapes, relative arrangements, and the like of components described as embodiments or shown in the drawings are not intended to limit the scope of the present disclosure thereto, but are merely illustrative examples.

For example, expressions indicating a relative or absolute arrangement such as “in a certain direction”, “along a certain direction”, “parallel”, “orthogonal”, “center”, “concentric” or “coaxial” are strictly In addition to indicating the arrangement as shown in Figs.

For example, expressions indicating that things are in an equivalent state, such as "same", "equal" and "homogeneous", not only indicate a strictly equivalent state, but also have tolerances or differences to the extent that the same function is obtained. It is supposed to indicate the state as well.

For example, expressions representing shapes such as a square shape or a cylindrical shape not only represent shapes such as a square shape or a cylindrical shape in a geometrically strict sense, but also include irregularities and chamfers within the range where the same effect is obtained. It is assumed that the shape to be shown is also shown.

On the other hand, expressions such as "have", "have", "have", "include", or "have" one component are not exclusive expressions except for the presence of other components.

In the following embodiment, the thermal power plant 1 is taken as an example and demonstrated as the thermal power plant which is the control object of the control apparatus which concerns on at least one Embodiment of this invention. 1 is a schematic configuration diagram of a thermal power plant 1 according to an embodiment.

A thermal power plant 1 includes a boiler 2 , a steam turbine 4 , and a condenser 12 . In this embodiment, the thermal power plant 1 is exemplified as the steam turbine 4 in which the high-pressure side turbine 4A and the low-pressure side turbine 4B are exemplified. However, the thermal power plant 1 is A single steam turbine 4 may be provided, and three or more steam turbines 4 may be provided.

The boiler 2 is a steam generator capable of generating superheated steam by exchanging heat generated by burning pulverized fuel with feed water or steam. The boiler 2 is a coal combustion (pulverized coal combustion) boiler which uses pulverized coal which pulverized coal (carbon-containing solid fuel) as pulverized fuel, for example, and burns this pulverized fuel with a burner.

In addition, although a coal-fired boiler is illustrated as the boiler 2 in this embodiment, the boiler 2 is a PC (Petroleum Coke) fuel, petroleum residue etc. which generate|occur|produce at the time of biomass fuel or petroleum refining as a fuel. of solid fuel may be used. In addition, the boiler 2 is not limited to solid fuel as a fuel, Petroleum, such as heavy oil, light oil, and heavy oil, and liquid fuels, such as factory waste liquid, can also be used, Furthermore, as a fuel, gaseous fuel (natural gas, by-product gas) etc.) can also be used. In addition, the boiler 2 may be a mixed combustion boiler used combining these fuels.

Steam (superheated steam) produced in the boiler 2 is supplied to the steam turbine 4 via a main steam line 6 . In this embodiment, steam from the boiler 2 drives 4 A of high-pressure-side turbines by first being supplied to 4 A of high-pressure-side turbines provided upstream. The main steam line 6 connects between the boiler 2 and the high-pressure side turbine 4A. The main steam line 6 is provided with a main steam valve 8 . The main steam valve 8 controls the opening degree by the control device 100 so that the amount of steam supplied from the boiler 2 to the steam turbine 4 is variable.

The steam which has completed work in the high-pressure side turbine 4A is supplied to the low-pressure side turbine 4B provided on the downstream side through the steam line 10 to drive the low-pressure side turbine 4B. The steam line 10 connects between the high-pressure side turbine 4A and the low-pressure side turbine 4B. The steam which has completed the operation|work with the low pressure side turbine 4B is discharged|emitted to the condenser 12, and condensate is produced|generated.

Also, a bypass line 14 connecting the condenser 12 with an upstream side of the main steam line 6 from the main steam valve 8 is provided. The bypass line 14 is provided with a turbine bypass valve 16 , and by adjusting the opening degree of the turbine bypass valve 16 , a part of the steam flowing through the main steam line 6 is transferred to the steam turbine 4 . By bypassing the , discharge to the condenser 12 is possible.

The output shafts of the high pressure side turbine 4A and the low pressure side turbine 4B are respectively connected to the rotating shaft of a generator which is not shown in figure. The generator generates electricity by driving it with power from these steam turbines 4 . Electric power generated by the generator is supplied to an electric power system (for example, a commercial system) through a power transmission line (not shown).

In addition, the high-pressure side turbine 4A and the low-pressure side turbine 4B have an output shaft in common with each other, and the output shaft may be connected to a common generator, and as a generator, the output shaft of the high-pressure side turbine 4A is connected. You may provide the 2nd generator to which the 1st generator and the output shaft of the low-pressure side turbine 4B are connected.

The control device 100 is a control unit of the thermal power plant 1, and includes, for example, a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and a computer-readable storage medium. Consists of. The serial processing for realizing various functions is stored in a storage medium or the like in the form of a program as an example, and the CPU reads the program into a RAM or the like and executes information processing and arithmetic processing, so that various functions are implemented. come true Also, the program may be applied in the form of being installed in advance in a ROM or other storage medium, provided in a state stored in a computer-readable storage medium, or delivered through a communication means by wire or wireless, etc. . The computer-readable storage medium is a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like.

FIG. 2 is a block diagram illustrating an internal configuration of the control device 100 of FIG. 1 . The control device 100 includes a turbine bypass valve opening command value generation unit 110 , a turbine bypass valve control unit 140 , a boiler input command value generation unit 142 , a boiler control unit 160 , A main steam valve opening degree command value generation unit 162 and a main steam valve control unit 174 are provided. The turbine bypass valve opening degree command value generation part 110 creates opening degree command value Stb of the turbine bypass valve 16, and the turbine bypass valve control part 140 is a turbine based on the said opening degree command value Stb. The degree of opening of the bypass valve 16 is controlled. The boiler input command value generation unit 142 generates a boiler input command value BID, and the boiler control unit 160 controls the boiler 2 based on the boiler input command value BID. The main steam valve opening degree command value generating unit 162 generates a main steam valve opening degree command value Jd for controlling the opening degree of the main steam valve 8 , and the main steam valve control unit 174 is the main steam valve The main steam valve 8 is controlled based on the opening degree command value Jd.

Next, each configuration of the control device 100 shown in FIG. 2 will be described in detail. 3 is a control logic diagram of the turbine bypass valve opening command value generation unit 110 of FIG. 2 . The turbine bypass valve opening degree command value generation part 110 is a structure for producing|generating the turbine bypass valve opening degree command value Stb of the turbine bypass valve 16, The 1st opening degree command value calculation part 112 , is configured to include a second opening degree command value calculation unit 120 and a third opening degree command value calculation unit 130 .

In the first opening command value calculation unit 112 , in the subtractor 114 , the differential pressure ΔPs between the detected value Ps of the main steam pressure in the main steam line 6 and the target main steam pressure Pst is calculated, and the PI controller By (116), the 1st opening degree command value Stb1 corresponding to the said differential pressure (DELTA)Ps is calculated|required. The target main steam pressure Pst is calculated by adding a predetermined bias value Psb to the main steam pressure set value Pss which is a reference value in the adder 118 . The bias value Psb is a parameter added to the main steam pressure set value Pss in order to set it as a threshold value for judging an abnormal rise of the main steam pressure Ps, and in this embodiment, "0 MPa" or "1.0 MPa" by the switch SW1 ' is selectively switchable. The 1st opening degree command value Stb1 computed in this way, when the main steam pressure Ps in the main steam line 6 rises abnormally, the opening degree command value for performing the opening degree control of the turbine bypass valve 16. function as

The 2nd opening degree command value calculation part 120 is for calculating 2nd opening degree command value Stb2 which is opening degree command value Stb for performing opening degree control of the turbine bypass valve 16 at the time of a start is the composition In the 2nd opening degree command value calculation part 120, the detection value Ps of the steam pressure (main steam pressure) in the main steam line 6 is input into the function calculator 122, and, by the turbine bypass valve suitable at the time of starting. It is calculated so that the opening degree control of (16) is implemented.

The above-mentioned 1st opening degree command value calculation part 112 and the 2nd opening degree command value calculation part 120 are connected via switch SW2. The switch SW2 is switchable based on whether the operation mode is the startup mode. Specifically, when the operation mode is in the starting mode, the switch SW2 selects the second opening command value calculation unit 120, and when the operation mode is not the starting mode, the first opening command value calculation unit ( 112) is selected.

The 3rd opening degree command value calculation part 130 is a structure for calculating 3rd opening degree command value Stb3, and it is comprised including the base opening degree calculation part 132 and the bias opening degree calculation part 134. . The third opening command value Stb3 is the bias opening degree Stb3bias calculated by the bias opening calculation unit 134 with respect to the base opening degree Stb3base calculated by the base opening calculation unit 132 in the adder 136 . It is obtained by adding

The base opening degree calculation part 132 calculates the base opening degree Stb3base of the turbine bypass valve 16 based on the load command value L. The load command value L is provided from, for example, a central power supply command center, and the base opening degree calculation unit 132 converts it into a steam flow rate Qs in the function calculator 138 . The subtractor 140 calculates the difference ΔQs between the steam flow rate Qs calculated by the function calculator 138 and the detected value Qsj of the steam flow rate at the outlet of the first bypass line. The difference ΔQs is input to the PI controller 142 to obtain a corresponding base opening Stb3base. In addition, a hold circuit 144 is provided on the output side of the PI controller 142, and is configured such that a constant base opening Stb1 is maintained in the AFC compatible mode (while receiving the AFC signal).

The bias opening degree calculation unit 134 calculates the bias opening degree Stb3bias based on the AFC signal. In the bias opening calculation unit 134 , the AFC signal is input to the function calculator 146 to be converted into the bias opening Stb3bias. FIG. 4 is an example of a function included in the function calculator 146 of FIG. 3 . In Fig. 4, the function is prescribed such that the bias opening Stb3bias monotonically decreases as the AFC signal increases (in addition, in the range above the preset upper limit and below the lower limit of the AFC signal, the bias opening Stb3bias is constant. prescribed).

A switch SW3 is provided on the output side of the function calculator 146 . The switch SW3 can switch between the calculation result of the function calculator 146 as the bias opening Stb3bias or the preset default value "0%" as the bias opening degree Stb3bias, based on whether or not the AFC signal is inputted in the AFC compatible mode. That is, in the AFC-compatible mode, the calculation result of the function calculator 146 is used as the bias opening Stb3bias, and in other operation modes, the bias opening Stb3bias becomes zero.

The base opening degree Stb3base and the bias opening degree Stb3bias calculated in this way are added to each other in the adder 136 . A switch SW4 is provided on the output side of the adder 136, and based on whether or not the AFC signal is inputted in the AFC compatible mode, the third opening degree command value Stb3 is the calculation result of the adder 136, or a preset default value " 0%" can be switched. That is, in the AFC-compatible mode, the calculation result of the adder 136 is used as the third opening degree command value Stb3, and in other operation modes, the third opening degree command value Stb3 becomes zero.

And in the turbine bypass valve opening degree command value generation part 110, it is comprised so that the larger one of the outputs from switches SW2 and SW4 may be selected as opening degree command value Stb by high value selector HS. Opening degree command value Stb is input to the turbine bypass valve control part 140 (refer FIG. 2), and is used for opening degree control of the turbine bypass valve 16. As shown in FIG.

The turbine bypass valve control part 140 controls the turbine bypass valve 16 based on the turbine bypass valve opening degree command value Stb calculated in this way, and at the time of operation of a series of thermal power plant 1 In the AFC response mode, good response to the AFC signal can be obtained while accurately avoiding the shortening of the start-up time or the abnormal rise of the main steam pressure. That is, control of the turbine bypass valve 16 suitable at the time of starting is performed by outputting 2nd opening degree command value Stb2 as turbine bypass valve opening degree command value Stb at the time of starting. Moreover, in the normal case where the AFC signal is not received, since the bias opening Stb3bias based on the AFC signal is zero, the turbine bypass valve 16 is controlled based on the third opening command value Stb3 which is the base opening Stb3base. while controlling the turbine bypass valve 16 based on the 1st opening degree command value Stb1, when the main steam pressure Ps abnormally rises by becoming more than the main steam pressure set value Pst, the abnormal rise of the main steam pressure Ps is suppressed. can do. And in the AFC correspondence mode which receives an AFC signal, the turbine bypass valve 16 is controlled based on 3rd opening degree command value Stb3 to which the bias opening degree Stb3bias based on an AFC signal was added with respect to base opening degree Stb3base. Thereby, even when there is a time lag until the boiler input signal is reflected in the amount of steam as in the case of a coal-fired boiler as the boiler 2 by this, by controlling the opening degree of the turbine bypass valve 16 based on the AFC signal, AFC Good followability to a signal can be obtained. Moreover, in the case of AFC correspondence mode, the adjustment margin of the turbine bypass valve 16 is acquired irrespective of the magnitude|size of the load command value L by generating boiler input command value BID as mentioned later.

5 is a control logic diagram of the boiler input command value generator 142 of FIG. 2 . In the boiler input command value generating unit 142 , first, the load command value L is input to the change rate limiter 144 . In the rate of change limiter 144, the rate of change of the load command value L, which varies from moment to moment, is limited so as to be less than or equal to a predetermined value, and is output as the first command value D1. A second command value D2 (MWD) is obtained by adding the frequency control signal Df to the first command value D1 by the adder 146 . The frequency control signal Df contributes to stabilization of the electric power system by adding a load corresponding to a change in the system frequency to the first command value D1 (generator output command). In Fig. 5, the result of limiting the rate of change by inputting the system frequency to the function calculator 147, calculating the load corresponding to the system frequency, and inputting the output to the rate limiter 149 is the frequency control signal Df is added to the first command value D1.

In the circuit of Fig. 5, the frequency control signal Df is added to the first command value D1, while the AFC signal is not added. This increases the boiler input command value BID by adding a bias value Dbias to be described later, so that the turbine bypass valve 16 is maintained at an appropriate opening degree so as to respond to the increase or decrease in the turbine intake flow rate, so the boiler input by adding the AFC signal This is because there is no need to increase or decrease the command value BID.

Subsequently, the main steam pressure control signal Ds is further added to the second command value D2 output from the adder 146 to become the third command value D3 by the adder 148 . The main steam pressure control signal Ds is the target main steam pressure Pst calculated by inputting the second command value D2 to the function calculator 152 in the subtractor 150 and the main steam pressure in the main steam line 6 . The pressure difference ΔPs of the detected value Ps is calculated, and the pressure difference ΔPs is input to the PI controller 154 to obtain it.

Further, in the adder 156 , the bias value Dbias is added to the third command value D3 that is a base value based on the load command value L for the thermal power plant 1 , whereby the boiler input command value BID is generated. The bias value Dbias can be switched by the switch SW6. In the AFC-compatible mode, a positive value obtained by the function calculator 158 is selected, and in other operation modes, "0%" is selected.

Here, FIG. 6 is an example of the bias value Dbias obtained by the function calculator 158 of FIG. 5 . In the example of FIG. 6 , the bias value Dbias does not depend on the load command value L in the range where the load command value L (second command value D2) input to the boiler input command value generator 142 is equal to or less than a predetermined value. set approximately constant. The value is set, for example, corresponding to the maximum reduction value with respect to the reference value of the AFC signal. Thereby, in AFC-compatible mode, even when the load command value L changes, since a fixed bypass value does not change, the adjustment margin of the turbine bypass valve 16 is securable in a wide load range. That is, even when the AFC signal is negative in the AFC mode, by adding the bias value Dbias, which is a constant value having a positive sign, to generate the boiler input command value BID, the load command value L regardless of whether the AFC signal is positive or negative. A larger boiler output can be ensured, and followability can be improved by opening degree control of the turbine bypass valve 16 corresponding to an AFC signal.

In addition, the bias value Dbias is set so that, in the range where the load command value L is larger than a predetermined value, it may decrease as it approaches the upper limit value (100%) of the load command value L. In the example shown in Fig. 6, in the range of the load command value L from 95% to the upper limit value (100%), the bias value Dias is set to monotonically decrease as the load command value L increases.

The boiler input command value BID calculated in this way is input to the boiler control unit 160 (refer to FIG. 2 ). The boiler control unit 160 controls the boiler 2 based on the boiler input command value BID.

Subsequently, FIG. 7 is a control logic diagram of the main steam valve opening degree command value generation unit 162 of FIG. 2 . In the main steam valve opening degree command value generation unit 162 , the AFC signal is converted into the fourth command value D4 by the function calculator 164 . The switch SW7 inputs the change rate limiter 166 by selecting the fourth command value D4 in the AFC-compatible mode, and adds the result to the first command value D1 (refer to FIG. 5) in the adder 168. Thus, the fifth command value D5 is obtained. By adding the output signal from the change rate limiter 166 to the first command value D1 in this way, the fluctuation range of the main steam pressure during operation of the turbine bypass valve 16 can be reduced, and An improvement in the responsiveness of the generator output can be expected. As for the fifth command value D5, the deviation ΔP of the output detection value P of the generator (not shown) connected to the steam turbine 4 in the subtractor 170 is calculated, and the main corresponding to the deviation ΔP in the PI controller 172 . A steam valve opening degree command value Jd is generated.

Moreover, in another operation mode, the switch SW7 selects "0%" which is a default value, and the 5th command value D5 becomes the 1st command value D1 itself.

In this way, the main steam valve opening degree command value Jd generated by the main steam valve opening degree command value generation unit 162 is provided to the main steam valve control unit 174 . The main steam valve control unit 174 controls the opening degree of the main steam valve 8 based on the main steam valve opening degree command value Jd. Thereby, the opening degree of the main steam valve 8 is controlled cooperatively with the opening degree of the turbine bypass valve 16 taking the AFC signal into account similarly based on the main steam valve opening degree command value Jd in consideration of the AFC signal, It is possible to improve the followability to the AFC signal.

Then, the control content of the thermal power plant 1 by the control apparatus 100 which has the said structure is demonstrated. FIG. 8 is a timing chart showing time changes of various signals in the control device 100 of FIG. 2 . In FIG. 8 , in the initial state in which the control device 100 controls the thermal power plant 1 in the normal mode, after the time t0, the AFC signal is received and the transition to the AFC-compatible mode is performed, (a ) AFC signal, (b) Load command value L, (c) Fifth command value D5, (d) Second command value D2, (e) Third command value D3, (f) Boiler input command value BID, (g) ) main steam valve opening command value Jd, (h) turbine bypass valve opening degree command value Stb, (i) generator output P, (j) main steam pressure deviation ΔPs (=detected value of main steam pressure Ps - target main The time change of the vapor pressure Pst) is shown respectively.

(a) An AFC signal generally has a complex waveform centered on a reference value (0%), but in this embodiment, an AFC signal that changes stepwise with the passage of time is exemplified in order to make the explanation easy to understand. (Specifically, (a) the AFC signal is "+3%" at time t0 to t1, "+5%" at time t1 to t2, and "+1%" at time t2 to t3 step by step fluctuates). In addition, in order to explain the responsiveness to (a) AFC signal in an easy-to-understand manner, the (b) load command value L received by the control device 100 from a central power supply command center or the like was set to be constant (50%).

(c) The fifth command value D5 is calculated by inputting the fourth command value D4 based on the AFC signal to the change rate limiter 166 by selecting the function calculator 164 side in the switch SW7 in the AFC compatible mode The value is obtained by adding the first command value D1 in the adder 168 . Accordingly, the fifth command value D5 has a waveform to which the (a) AFC signal, which changes with time, is added to the constant (50%) (b) load command value L.

(d) The second command value D2 is obtained by adding the frequency control signal Df by the adder 146 to (b) the load command value L whose change rate is limited by the change rate limiter 144 . In the present embodiment, the frequency control signal Df is set to zero, and (b) the second command value D2 having a constant value (50%) similar to the load command value L is disclosed.

(e) The third command value D3 is obtained by adding the main steam pressure control signal Ds in the adder 148 to (d) the second command value D2, and has a constant value (50%) of (d)th By adding the main steam pressure control signal Ds which fluctuates with time with respect to 2 command value D2, the behavior which fluctuates centering on the 2nd command value D2 is shown.

(f) The boiler input command value BID is obtained by adding the bias value Dbias in the adder 156 to the (e) third command value D3. In the AFC-compatible mode, a constant value (5%) set by the function calculator 158 is added as the bias value Dbias. In addition, a constant value is added to the boiler input command value BID at the timing at which the AFC mode is set (before the time t0 when the AFC signal is input). After the boiler load has been increased to a certain value, the AFC signal is input. Thereby, (f) boiler input command value BID has shown the behavior which fluctuates centering on the value to which the bias value Dbias (5%) was added with respect to 2nd command value D2 (50%). Here, the setting of the AFC mode may be set automatically by determining the time in advance in addition to being determined and set by the operator.

(g) The main steam valve opening degree command value Jd is calculated based on the deviation ΔP between (c) the fifth command value D5 and (i) the generator output P in the PI controller 172, and is to the boiler input command value BID The temporal change in which the trend of the first command value D1 is reflected with respect to the corresponding waveform is shown.

(h) The turbine bypass valve opening degree command value Stb is obtained by adding the bias opening degree Stb3bias based on the (a) AFC signal to the constant base opening degree Stb3base after the time t0 when the AFC signal is input. In (a), a step-by-step time change corresponding to the AFC signal is shown.

(i) Generator output P has shown the increase/decrease tendency corresponding to (a) AFC signal, although it fluctuates with time. This has shown that the power generation control of the thermal power plant 1 is performed so that it may respond to an AFC signal, and favorable followability with respect to an AFC signal is acquired.

(j) the main steam pressure deviation ΔPs is the differential pressure between the steam pressure Ps in the main steam line 6 and the target main steam pressure Pst, as described above, and fluctuates in time in response to the load of the high-pressure side turbine 4A, have. The main vapor pressure deviation ΔPs fluctuates in time and increases or decreases in response to the AFC signal.

9 is a graph showing the load adjustment margin of the plant at the load command value L; In FIG. 9 , as a comparative example, the load adjustment margin of the boiler input command value BID when the bias value Dbias is fixed to 0% is shown by a broken line in order to compare the effect of the bias value Dbias for easy understanding. According to this comparative example, since the boiler input command value BID with the bias value Dbias set to 0% has only an adjustment margin according to the load command value L as described above with reference to FIG. 5, the load command value L is As it is lowered, the load regulation margin is decreasing. On the other hand, in this embodiment, since a constant value having a positive sign is added as the bias value Dbias to obtain the boiler input command value BID, as shown by the solid line in FIG. Regardless of the magnitude of the load command value L, a constant load adjustment margin is obtained up to the low load side.

In the comparative example, the turbine bypass valve 16 is not opened and closed, but the load is adjusted by increasing or decreasing the boiler input command value BID. As shown by the broken line in Fig. 9, the load adjustment margin in the low load band becomes narrower than in the high load band. In contrast, in the present embodiment, by adding and fixing the bias value Dbias to the boiler input command value BID, and then opening and closing the turbine bypass valve 16, the load adjustment margin up to the low load band is equal to that of the high load band can keep That is, compared with the comparative example, the load adjustment margin in the low load band can be expanded. This is achieved by increasing the boiler input command value BID by the addition of the bias value Dbias, increasing the evaporation amount in advance and using the evaporation amount as a buffer for the load adjustment margin. In other words, it can be said that the operation control is "priority in load adjustment margin". With such control, even when the boiler 2 is operated in a load band lower than 100% load, it is possible to cope with the problem of securing the load adjustment force accompanying an increase in renewable energy or the like.

Subsequently, the control apparatus 100' which makes the thermal power plant 1' which concerns on another embodiment a control object is demonstrated. 10 is an overall configuration diagram of a thermal power plant 1 ′ according to another embodiment. In this embodiment, in addition to the 1st bypass line 14 corresponding to the bypass line 14 of the embodiment shown in FIG. 1, the 2nd bypass line 15 is provided. A first bypass line 14 communicates upstream and downstream of the main steam line 6 , and the first bypass line 14 is provided with a first turbine bypass valve 16 . The opening degree of the first turbine bypass valve 16 is controllable by the control device 100 ′, and depending on the opening degree, a portion of the steam flowing through the main steam line 6 is transferred to the first bypass line ( 14), the high-pressure side turbine 4A can be bypassed and supplied to the steam line 10 .

In addition, a second bypass line 15 is provided between the condenser 12 and the upstream side of the low-pressure side turbine 4B of the steam line 10 . The second bypass line 15 is provided with a second turbine bypass valve 17 . The opening degree of the second turbine bypass valve 17 is controllable by the control device 100 , and according to the opening degree, a part of the steam flowing through the steam line 10 and the second bypass line 15 are controlled. It is possible to supply the condenser 12 by bypassing the low-pressure side turbine 4B through this.

The control apparatus 100' has a structure (refer FIG. 2) common to the control apparatus 100 which concerns on the above-mentioned embodiment. The turbine bypass valve opening degree command value generation part 110 of the control apparatus 100' creates turbine bypass valve opening degree command value Stb corresponding to the 1st turbine bypass valve 16. As shown in FIG.

The opening degree of the second turbine bypass valve 17 is set to adjust the reheat steam pressure (inlet pressure of the low-pressure side turbine 4B) to a specified value when the thermal power plant 1' is started or during normal operation. is properly controlled for In addition, typically, the opening degree target value of the 2nd turbine bypass valve 17 differs in the time of starting of the thermal power plant 1' and the time of normal operation, and is set suitably, respectively.

FIG. 11 is a part of a control logic diagram of the turbine bypass valve opening degree command value generation unit 110 ′ included in the control device 100 ′ of FIG. 10 . Although the turbine bypass valve opening degree command value generation part 110' has the control logic fundamentally common to FIG. 3, in FIG. Only the figure calculation part 134' and the bias opening degree correcting part 200 are shown (in addition, another structure of the turbine bypass valve opening degree command value generation part 110' is the turbine bypass shown in FIG. Since it is the same as the valve opening command value generating unit 110, it is omitted in FIG. 11).

The bias opening degree correction|amendment part 200 correct|amends the bias opening degree Stb3bias based on the load of 4 A of high-pressure side turbines. In the present embodiment, the bias opening correction unit 200 is a parameter for evaluating the load of the high-pressure side turbine 4A, the main steam pressure Ps in the main steam line 6 and the steam line 10 . The differential pressure ΔP' of the vapor pressure Pse is calculated by the subtractor 202, and the differential pressure ΔP' is input to the function calculator 204, thereby calculating the gain G for correcting the bias opening Stb3bias.

12 is a graph showing the relationship between the differential pressure ΔP' and the gain G in the function calculator 204 of FIG. 11 . In this example, it is prescribed that the gain G monotonically decreases as the differential pressure ΔP' for evaluating the load on the high-pressure side turbine 4A increases. The gain G calculated in this way is multiplied by the output of the function calculator 146 based on the AFC signal in the correction unit 206 to be used for correcting the bias opening Stb3bias.

The influence of the bias value Stb3bias with respect to 3rd opening degree command value Stb3 becomes small so that the low load side, but in this embodiment, with respect to the bias opening degree Stb3bias contained in 3rd opening degree command value Stb3 in this way, the high-pressure side turbine 4A ), set the gain G, which increases as the load decreases. Thereby, also in the low load side, the effect of the bias value Stb3bias in 3rd opening degree command value Stb3 can be acquired effectively, and the followability with respect to an AFC signal favorable in a wide load range can be acquired.

As described above, according to the above embodiments, it is possible to provide a control device and a control method capable of maintaining a power generation frequency with good followability to an AFC signal.

The contents described in each of the above embodiments are grasped as follows, for example.

(1) A control device according to an aspect,

A boiler (for example, the boiler 2 of the above embodiment), a steam turbine driven by steam from the boiler (for example, the steam turbine 4 of the above embodiment), and bypassing the steam turbine Control of a thermal power plant (eg, thermal power plant 1, 1' of the above embodiment) provided with a turbine bypass valve (eg, turbine bypass valve 16 of the above embodiment) for regulating the amount of steam A device (for example, the control devices 100 and 100' of the above embodiment),

In the AFC correspondence mode of the thermal power plant, generating a turbine bypass valve opening degree command value (for example, the turbine bypass valve opening degree command value Stb of the above embodiment) of the turbine bypass valve based on an AFC signal A turbine bypass valve opening degree command value generation unit (for example, the turbine bypass valve opening degree command value generation unit 110 of the above embodiment) for

A turbine bypass valve control unit (for example, the turbine bypass valve control unit 140 of the embodiment) for controlling the turbine bypass valve based on the turbine bypass valve opening degree command value;

In the AFC-compatible mode, with respect to a base input value (for example, the second command value D2 of the embodiment) based on the load command value for the thermal power plant (for example, the load command value L of the embodiment) A boiler input command value generating unit (eg, a boiler input command value BID of the above embodiment) for generating a boiler input command value (eg, the boiler input command value BID of the above embodiment) by adding a positive bias value (eg, the bias value Dbias of the above embodiment) For example, the boiler input command value generation unit 142 of the above embodiment),

and a boiler control unit (eg, the boiler control unit 160 of the above embodiment) for controlling the boiler based on the boiler input command value.

According to the aspect of said (1), in the AFC correspondence mode, favorable followability is acquired with respect to an AFC signal by controlling the opening degree of a turbine bypass valve based on the opening degree command value generate|occur|produced based on the AFC signal. On the other hand, the boiler input command value is generated by adding a positive bias value to the base input value based on the load command value. Thereby, when a turbine bypass valve is controlled by the opening degree command value based on an AFC signal, irrespective of the positive or negative sign of an AFC signal, the opening degree adjustment margin of a turbine bypass valve is securable.

(2) In another aspect, in the aspect of said (1),

The bias value is constant regardless of the load command value in the range where the load command value is equal to or less than a predetermined value.

According to the aspect of said (2), when generating a boiler input command value, the bias value added with respect to a base input value is set constant irrespective of a load command value. Thereby, also when a load command value changes, since a bypass value does not change, in a wide load range, the adjustment margin of a turbine bypass valve is securable.

(3) In another aspect, in the aspect of said (2),

The bias value is set corresponding to a maximum reduction value with respect to the reference value of the AFC signal.

According to the aspect of said (3), a constant bias value is set corresponding to the maximum reduction value with respect to the reference value of an AFC signal irrespective of a load command value. Thereby, with respect to the AFC signal which changes every moment, the adjustment margin of a turbine bypass valve can always be ensured and favorable followability with respect to an AFC signal is acquired.

(4) In another aspect, in any one of the aspects (1) to (3) above,

The said opening command value generation|occurrence|production part is based on the said AFC signal to the base opening degree of the said turbine bias valve (for example, base opening degree Stb3base of the said embodiment) at the time of transition to the said AFC correspondence mode. By adding (for example, bias opening degree Stb3bias of the said embodiment), it is comprised so that the said opening degree command value may be produced|generated.

According to the aspect of said (4), the opening degree control value of a turbine bias valve is produced|generated by adding a bias opening degree with respect to a base opening degree. The base opening degree maintains the opening degree of the turbine bias valve when the thermal power plant shifts from the normal mode to the AFC signal correspondence mode, and is generated by adding a bias value based on an AFC signal that changes every moment thereto. By performing opening degree control of a turbine bypass valve based on such an opening degree control value, the favorable followability with respect to an AFC signal is acquired.

(5) In another aspect, in the aspect of said (4),

The said base opening degree is an intermediate opening degree between a fully open state and a fully closed state.

According to the aspect of said (5), in AFC-compatible mode, the base opening used as the reference|standard of opening degree control of a turbine bypass valve is set to an intermediate opening degree. Thereby, when changing the opening degree of a turbine bypass valve based on an AFC signal, the adjustment margin of a turbine bypass valve is ensured regardless of the sign of an AFC signal, and favorable followability with respect to an AFC signal can be acquired.

(6) In another aspect, in any one of said (1) to (5),

The thermal power plant further comprises a main steam valve (for example, the main steam valve 8 of the above embodiment) for regulating the amount of main steam supplied from the boiler to the steam turbine;

The control device is

A steam valve opening degree command value generation unit (for example, the main steam valve opening degree command value Jd of the above embodiment) for generating a steam valve opening degree command value (for example, the main steam valve opening degree command value Jd of the above embodiment) based on the AFC signal a steam valve opening degree command value generating unit 162);

a main steam valve control unit (for example, the main steam valve control unit 174 of the above embodiment) for controlling the main steam valve based on the steam valve opening degree command value;

have more

According to the aspect of (6) above, the opening degree of the main steam valve is controlled based on the main steam valve opening degree command value generated based on the AFC signal. Thereby, the main steam valve can improve followability to an AFC signal by operating cooperatively with the turbine bypass valve whose opening degree is similarly controlled based on an AFC signal.

(7) In another aspect, in any one of said (1) to (6),

A bias opening degree correction part (for example, the bias opening degree correction part 200 of the said embodiment) for correcting the said bias opening degree based on the load of the said steam turbine is further provided.

According to the aspect of said (7), the followability|trackability with respect to the AFC signal by a bias opening degree can be improved in a steam turbine wide load range by correct|amending a bias opening degree based on the load of a steam turbine.

(8) In another aspect, in the aspect of said (7),

The bias opening correction unit corrects the bias opening so that the correction amount increases as the load decreases.

According to the aspect of said (8), the correction amount of a bias opening degree is set so that it may become large as the load of a steam turbine becomes small. Thereby, even on the low load side where the effect by the bias opening tends to become relatively small, the followability to the AFC signal by the bias opening can be effectively improved.

(9) In another aspect, in the aspect of said (7) or (8),

The said bias opening degree correction part is a differential pressure (for example, the said embodiment) of the supply vapor pressure of the said steam turbine (for example, the main steam pressure Ps of the said embodiment), and an exhaust vapor pressure (for example, the turbine exhaust pressure Pse of the said embodiment) The load is calculated based on the differential pressure ΔP') of the form.

According to the aspect of said (9), the load of a steam turbine can be evaluated appropriately, without adding a new sensor etc. by the differential pressure of the steam pressure supplied to a steam turbine, and the steam pressure discharged|emitted from a steam turbine.

(10) In another aspect, in any one of the aspects (1) to (9) above,

The said turbine bypass valve is provided in the bypass line which communicates the upstream and downstream of the said steam turbine.

According to the aspect of said (10), by providing a turbine bypass valve in the bypass line which communicates the upstream and downstream of a steam turbine, for example, by adjusting the opening degree at the time of starting a thermal power plant, the downstream of a steam turbine By supplying steam to the side, various components (reheaters, etc.) on the downstream side of the steam turbine can be suitably protected.

(11) In another aspect, in any one of (1) to (9) above,

The said turbine bypass valve is provided in the bypass line which communicates with the condenser provided in the upstream of the said steam turbine, and the downstream of the said steam turbine.

According to the aspect of said (11), when a turbine bypass valve is controlled by the opening degree command value based on an AFC signal by simpler control, irrespective of the positive or negative sign of an AFC signal, the turbine bypass valve An opening adjustment margin can be secured (for example, the bias opening correction part in (9) above can be made unnecessary).

(12) A control method according to an aspect,

A boiler (for example, the boiler 2 of the above embodiment), a steam turbine driven by steam from the boiler (for example, the steam turbine 4 of the above embodiment), and bypassing the steam turbine Control method of a thermal power plant (for example, thermal power plant 1, 1' of the said embodiment) provided with the turbine bypass valve (for example, the turbine bypass valve 16 of the said embodiment) for regulating the amount of steam is,

In the AFC-compatible mode of the thermal power plant, a base input value (eg, the second command value D2 of the embodiment) based on the load command value for the thermal power plant (eg, the load command value L of the embodiment) ) by adding a positive bias value (for example, the bias value Dbias of the above embodiment) to a boiler input command value (for example, the boiler input command value BID of the above embodiment);

controlling the boiler based on the boiler input command value;

In the AFC-compatible mode, a step of generating a turbine bypass valve opening degree command value (for example, the turbine bypass valve opening degree command value Stb of the above embodiment) of the turbine bypass valve based on an AFC signal;

a step of controlling the turbine bypass valve based on the turbine bypass valve opening degree command value;

be prepared

According to the aspect of said (12), in the AFC correspondence mode, favorable followability|trackability is acquired with respect to an AFC signal by controlling the opening degree of a turbine bypass valve based on the opening degree command value generate|occur|produced based on the AFC signal. On the other hand, the boiler input command value is generated by adding a positive bias value to the base input value based on the load command value. Thereby, when a turbine bypass valve is controlled by the opening degree command value based on an AFC signal, irrespective of the positive or negative sign of an AFC signal, the opening degree adjustment margin of a turbine bypass valve is securable.

(13) In another aspect, in the aspect of said (12),

After the boiler is controlled by the boiler input command value so that the load of the boiler increases more than the load command value, the turbine bypass valve is controlled based on the opening degree command value.

According to the aspect of said (13), after the opening degree adjustment margin of a turbine bypass valve is ensured when the load of a boiler increases more than the said load command value, opening degree control of a turbine bypass valve is implemented. Thereby, when opening degree control of a turbine bypass valve is performed based on an AFC signal, opening degree adjustment corresponding to an AFC signal can be performed irrespective of the positive or negative of an AFC signal, and favorable followability with respect to an AFC signal is acquired. .

1: Thermal power plant
2: Boiler
4: steam turbine
4A: high pressure side turbine
4B: low pressure side turbine
6: main steam line
8: main steam valve
10: steam line
12: Revenge
14: bypass line (first bypass line)
15: second bypass line
16: turbine bypass valve (first turbine bypass valve)
17: second turbine bypass valve
100: control device
110: turbine bypass valve opening command value generation unit
112: first opening degree command value calculation unit
120: second opening degree command value calculation unit
130: third opening degree command value calculation unit
132: base opening degree calculation unit
134: bias opening degree calculation unit
140: turbine bypass valve control
142: boiler input command value generation unit
144: hold circuit
160: boiler control unit
162: main steam valve opening degree command value generation unit
174: main steam valve control
200: bias opening correction unit
206: correction unit

Claims (13)

A control device for a thermal power plant comprising a boiler, a steam turbine driven by steam from the boiler, and a turbine bypass valve for regulating the amount of steam bypassing the steam turbine,
a turbine bypass valve opening degree command value generation unit for generating a turbine bypass valve opening degree command value of the turbine bypass valve based on an AFC signal in the AFC corresponding mode of the thermal power plant;
a turbine bypass valve control unit configured to control the turbine bypass valve based on the turbine bypass valve opening degree command value;
A boiler input command value generating unit for generating a boiler input command value by adding a positive bias value to a base input value based on a load command value for the thermal power plant in the AFC corresponding mode;
a boiler control unit for controlling the boiler based on the boiler input command value;
provided, a control device. According to claim 1,
The control device wherein the bias value is constant regardless of the load command value in a range where the load command value is equal to or less than a predetermined value. 3. The method of claim 2,
and the bias value is set corresponding to a maximum reduction value with respect to a reference value of the AFC signal. 4. The method according to any one of claims 1 to 3,
The said turbine bypass valve opening degree command value generation|generation part adds the bias opening degree based on the said AFC signal to the base opening degree of the said turbine bias valve at the time of transition to the said AFC correspondence mode, The said turbine bypass valve A control device configured to generate an opening command value. 5. The method of claim 4,
The base opening degree is an intermediate opening degree between a fully open state and a fully closed state. 4. The method according to any one of claims 1 to 3,
The thermal power plant further comprises a main steam valve for regulating the amount of main steam supplied from the boiler to the steam turbine,
The control device is
a main steam valve opening command value generating unit for generating a main steam valve opening degree command value based on the AFC signal;
a main steam valve control unit for controlling the main steam valve based on the main steam valve opening degree command value;
Further provided, a control device. 4. The method according to any one of claims 1 to 3,
The control apparatus further comprising a bias opening correction part for correcting the bias opening degree based on the load of the said steam turbine. 8. The method of claim 7,
and the bias opening correction unit corrects the bias opening so that the correction amount increases as the load decreases. 8. The method of claim 7,
The said bias opening degree correction part calculates|requires the said load based on the differential pressure of the supply vapor pressure of the said steam turbine, and exhaust vapor pressure. 4. The method according to any one of claims 1 to 3,
The said turbine bypass valve is provided in the bypass line which communicates the upstream and downstream of the said steam turbine, The control apparatus. 4. The method according to any one of claims 1 to 3,
The said turbine bypass valve is provided in the bypass line which communicates the condenser provided in the upstream of the said steam turbine, and the downstream of the said steam turbine. A control method of a thermal power plant comprising a boiler, a steam turbine driven by steam from the boiler, and a turbine bypass valve for regulating the amount of steam bypassing the steam turbine,
generating a boiler input command value by adding a positive bias value to a base input value based on a load command value for the thermal power plant in the AFC-compatible mode of the thermal power plant;
controlling the boiler based on the boiler input command value;
a step of generating a turbine bypass valve opening degree command value of the turbine bypass valve based on an AFC signal in the AFC corresponding mode;
a step of controlling the turbine bypass valve based on the turbine bypass valve opening degree command value;
provided, a control method. 13. The method of claim 12,
After the boiler is controlled by the boiler input command value so that the load of the boiler increases more than the load command value, the turbine bypass valve is controlled based on the turbine bypass valve opening degree command value.

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