JP6813289B2 - Steam temperature controller, steam temperature control method, and power generation system - Google Patents

Description

Embodiments of the present invention relate to steam temperature control devices, steam temperature control methods, and power generation systems.

As the temperature of gas turbine exhaust gas in a combined cycle thermal power generation system rises and the temperature changes steeply, it tends to be difficult to control the temperature in the exhaust heat recovery boiler. As a countermeasure, there is a method of predicting the steam temperature at the outlet of the superheater installed in the exhaust heat recovery boiler and controlling the cooler provided between the superheaters based on this predicted value.

Japanese Unexamined Patent Publication No. 2016-057026

However, the method of predicting the steam temperature at the outlet of the superheater and controlling the cooler based on this predicted value requires a lot of cost in calculating the predicted value in the control device, and within a single calculation cycle. The prediction calculation may not be completed. In order to avoid this, it is necessary to reduce operations other than prediction operations in the control device or introduce a higher-performance control device.

An object to be solved by the present invention is to provide a steam temperature control device, a steam temperature control method, and a power generation system capable of appropriately controlling the steam temperature in a superheater installed in an exhaust heat recovery boiler. Is.

According to one embodiment, the steam temperature control device is upstream of the superheater so that the measured value of the outlet steam temperature of the superheater installed in the boiler that generates steam matches the outlet steam temperature set value. The feedback control unit that calculates the first indication value regarding the flow rate of water supplied to the heater that cools the steam that is installed on the side and cools the steam that is supplied to the superheater, and the outlet steam temperature fluctuates. It has a feed forward control unit that calculates a second instruction value related to the flow rate of the water supplied to the heater, and an adder that adds the first instruction value and the second instruction value. , the flow rate of the exhaust gas passing through the super heater, the flow rate of the steam supplied to the superheater, and an inlet steam temperature of the superheater is included, the feedforward control unit, the superheater on the basis of the factors It has a superheater characteristic calculation unit that calculates an inlet steam temperature set value with respect to the inlet steam temperature, and a heater characteristic calculation unit that calculates the second indicated value based on the inlet steam temperature set value.

According to the present invention, the steam temperature in the superheater installed in the exhaust heat recovery boiler can be appropriately controlled.

The schematic diagram which shows the structural example of the power generation system in 1st Embodiment. The figure which shows the basic configuration example of the control device of the outlet steam temperature of the exhaust heat recovery boiler of the power generation system in 1st Embodiment. The flowchart which shows an example of the procedure for obtaining the set value of the inlet steam temperature of the 2nd superheater, which is determined by the heat exchange amount of the power generation system in 1st Embodiment. The figure which shows an example of the timing chart for obtaining the set value of the inlet steam temperature of the 2nd superheater determined by the amount of heat exchange of the power generation system in 1st Embodiment. The figure which shows the specific configuration example of the control device of the outlet steam temperature of the exhaust heat recovery boiler of the power generation system in 1st Embodiment. The figure which shows an example of the change in the time direction when the exhaust gas temperature changes in the power generation system in 1st Embodiment. The figure which shows the specific configuration example of the control device of the outlet steam temperature of the exhaust heat recovery boiler of the power generation system in 2nd Embodiment. The figure which shows an example of the change in the time direction when the exhaust gas temperature changes in the power generation system in 2nd Embodiment.

Hereinafter, embodiments will be described with reference to the drawings.
(First Embodiment)
FIG. 1 is a schematic diagram showing a configuration example of a power generation system according to the first embodiment. The power generation system of FIG. 1 is a combined cycle type thermal power generation system based on an exhaust heat recovery method.

The power generation system of FIG. 1 includes a gas turbine 1, a compressor 2, a first generator 3, an exhaust gas pipe 4, an exhaust heat recovery boiler 5, a drum 11, a descending pipe 12, and an evaporator 13. The first steam pipe 14, the first superheater 15, the heater 16, the second steam pipe 17, the second superheater 18, the heater valve 19, the control device 20, and the main steam pipe 21. A main steam valve 22, a bypass pipe 23, a bypass valve 24, a steam turbine 25, and a second generator 26 are provided. The control device 20 is an example of a steam temperature control device.

The power generation system of FIG. 1 further includes a flow meter 31 _F and a thermometer 31 _T provided on the exhaust gas pipe 4, a pressure gauge 32 _P provided on the drum 11, and a temperature provided on the first steam pipe 14. A total of 33 _T , a thermometer 34 _T provided on the second steam pipe 17, a flow meter 35 _F , a thermometer 35 _T , and a pressure gauge 35 _P provided on the main steam pipe 21, and a steam turbine 25. A rotation speed measuring instrument 36 for the second generator 26 and an electric output measuring instrument 37 for the second generator 26 are provided.

In the power generation system of FIG. 1, the gas turbine 1 is rotated by the air compressed by the compressor 2, and the first generator 3 generates power by utilizing this rotation. The exhaust gas discharged from the gas turbine 1 is sent to the exhaust heat recovery boiler 5 via the exhaust gas pipe 4. The exhaust heat sent to the exhaust heat recovery boiler 5 is used in the order of the second superheater 18, the first superheater 15, and the evaporator 13 installed in the exhaust heat recovery boiler 5, and the exhaust heat recovery boiler 5 is used. It is discharged from 5.

On the other hand, the water in the drum 11 is sent to the evaporator 13 in the exhaust heat recovery boiler 5 via the descending pipe 12, and is heated by the heat of the exhaust gas in the evaporator 13 to become saturated steam. This steam is sent to the first superheater 15 in the exhaust heat recovery boiler 5 via the first steam pipe 14, is superheated by the first superheater 15, and then is cooled by the cooler 16. The steam cooled by the cooler 16 is sent to the second superheater 18 in the exhaust heat recovery boiler 5 via the second steam pipe 17, and is reheated by the second superheater 18. The control device 20 adjusts the opening degree of the cooler valve 19 for supplying water for steam cooling to the warmer 16, and adjusts the amount of steam cooling in the warmer 16. 2 The outlet steam temperature of the superheater 18 can be controlled to a set value.

The steam (main steam) superheated by the second superheater 18 is sent to the steam turbine 25 via the main steam pipe 21. In the power generation system of FIG. 1, the steam turbine 25 is rotated by the main steam, and the second generator 26 generates power using this rotation. The bypass pipe 23 branches from the main steam pipe 21 upstream of the steam turbine 25. The main steam flow rate of the main steam pipe 21 is controlled to a target value by adjusting the opening degree of the main steam valve 22 on the main steam pipe 21 by the control device 20. Further, the inlet steam pressure of the steam turbine 25 is controlled to a target value by adjusting the opening degree of the bypass valve 24 on the bypass pipe 23 by the control device 20.

The control device 20 controls the rotation speed of the steam turbine 25 by adjusting the main steam flow rate of the main steam pipe 21, thereby controlling the electric output of the second generator 26. The rotation speed of the steam turbine 25 is measured by the rotation speed measuring instrument 36, and the electric output of the second generator 26 is measured by the electric output measuring instrument 37.

Further, the second superheater 18 of the present embodiment is composed of a plurality of heat exchangers. Each of these heat exchangers exchanges heat between steam and exhaust gas. As a result, heat is transferred from the exhaust gas to the steam, which heats the steam and cools the exhaust gas.

Therefore, the outlet exhaust gas temperature of the second superheater 18 seen from the gas turbine 1 (the temperature of the exhaust gas at the outlet of the exhaust gas of the second superheater 18) is the inlet exhaust gas temperature of the second superheater 18 seen from the gas turbine 1. 2 The temperature of the exhaust gas at the inlet of the exhaust gas of the superheater 18) is lower than that of the exhaust gas. The inlet exhaust gas temperature of the second superheater 18 is measured by a thermometer 31 _T on the exhaust gas pipe 4. Further, the outlet exhaust gas temperature of the second superheater 18 is determined by heat exchange between the steam and the exhaust gas in the second superheater 18. Incidentally, the exhaust gas flow rate in the second superheater 18 is measured by the flow meter 31 _F on exhaust pipe 4.

On the other hand, the outlet steam temperature of the second superheater 18 seen from the warmer 16 (the temperature of the steam at the steam outlet of the second superheater 18) is the inlet steam temperature of the second superheater 18 seen from the warmer 16. It rises above (the temperature of the steam at the inlet of the steam of the second superheater 18). The inlet steam temperature of the second superheater 18 is measured by a thermometer 34 _T on the second steam pipe 17. The outlet steam temperature of the second superheater 18 is measured by a thermometer 35 _T on the main steam pipe 21. The outlet steam temperature of the second superheater 18 is determined by heat exchange between the steam and the exhaust gas in the second superheater 18. The steam flow rate in the second superheater 18 is measured by a flow meter 35 _F on the main steam pipe 21.

The outlet steam temperature of the second superheater 18 needs to be controlled to a predetermined temperature or lower in order to protect the metal parts of the respective heat exchangers and the like. On the other hand, the higher the outlet steam temperature of the second superheater 18, the higher the power generation efficiency of the second generator 26. Therefore, it is desirable that the outlet steam temperature of the second superheater 18 is maintained at a constant value at a high temperature.

The cooler 16 cools the vapor by adding liquid phase water to the vapor. The power generation system of the present embodiment controls the outlet steam temperature of the second superheater 18 by balancing the temperature decrease of the steam by the heater 16 and the temperature rise of the steam by the second superheater 18. The thermometer 34 _T on the second steam pipe 17 measures the temperature of the steam after being cooled by the cooler 16 and before being heated by the second superheater 18.

The outlet steam temperature of the second superheater 18 is controlled by adjusting the cooling amount of steam in the cooler 16. Further, the cooling amount of the steam in the heater 16 is controlled by the amount of water added to the steam in the heater 16. Therefore, the outlet steam temperature of the second superheater 18 can be controlled by adjusting the opening degree of the heater valve 19 provided in the pipe for supplying water to the heater 16. That is, the opening degree of the warmer valve 19 is determined based on the flow rate of the water supplied to the warmer 16, and takes a value related to the flow rate of the water supplied to the warmer 16.

When the opening degree of the warmer valve 19 increases, the flow rate (spray flow rate) of water added to the steam by the warmer 16 increases, and the outlet steam temperature of the second superheater 18 decreases. On the other hand, when the opening degree of the warmer valve 19 decreases, the flow rate of water added to the steam by the warmer 16 decreases, and the outlet steam temperature of the second superheater 18 rises.

The control device 20 outputs an opening command including a command value Z for the opening of the heater valve 19. This opening degree command is supplied to the cooler valve 19, and as a result, the opening degree of the warmer valve 19 is adjusted to the command value Z.

Next, the relationship between the control method and the control target in the power generation system of the present embodiment will be described. The control device 20 has a steam temperature control function and a steam pressure control function for controlling the steam temperature and the main steam pressure at the outlet of the exhaust heat recovery boiler 5 so as to be set values. Further, the control device 20 controls the opening degree of the main steam valve 22 so that the electric output of the second generator 26, which is usually called the MW (megawatt) output, becomes a set value. The main steam flow rate is determined by the controlled opening degree of the main steam valve 22, and the rotation speed of the steam turbine 25 and the electric output of the second generator 26 are determined.

The main steam pressure at the inlet of the steam turbine 25 is controlled to a set value by the steam pressure control function of the control device 20. The control device 20 outputs an opening command value to a bypass valve 24 different from the main steam valve 22, so that the steam flow rate in the bypass valve 24 is adjusted and the main steam pressure at the inlet of the steam turbine 25 is controlled. Will be done.

FIG. 2 is a diagram showing a basic configuration example of a control device for the outlet steam temperature of the exhaust heat recovery boiler of the power generation system according to the first embodiment. The meanings of the symbols used in FIG. 2 are as follows.

C1 (s): Feedback characteristics G1 (s): First plant characteristics C2 (s): Feedforward characteristics G2 (s): Second plant characteristics SV: Set value (related to the outlet steam temperature of the exhaust heat recovery boiler 5) Control setting value)
PV: Process value including disturbance (measured value related to outlet steam temperature of exhaust heat recovery boiler 5)
u: Operation amount (spray valve opening (opening of warmer valve 19))
y: Process value excluding disturbance (outlet steam temperature of exhaust heat recovery boiler 5)
y2: Disturbance process value (disturbance of the outlet steam temperature of the exhaust heat recovery boiler 5)
d: Disturbance (change in exhaust gas temperature, change in exhaust gas flow rate, change in steam flow rate, etc.)
The contents shown in parentheses in the explanation of the meanings of the above symbols show specific examples in the case of outlet steam temperature control of the exhaust heat recovery boiler 5.

First, consider the case where the disturbance d does not occur. Here, the disturbance d is a change in the exhaust gas temperature, the exhaust gas flow rate, the steam flow rate, and the like, which causes the outlet steam temperature to fluctuate.
The first plant characteristic G1 (s) is a process that does not include disturbance from the spray valve opening degree, which is the operation amount u, when the exhaust gas temperature change, the exhaust gas flow rate change, the steam flow rate change, etc., which are disturbance d, do not occur. The dynamic characteristics up to the outlet steam temperature of the exhaust heat recovery boiler 5 having a value y are shown.
Since the disturbance d has not occurred, the process value y2 of the disturbance is 0, and the process value PV including the disturbance (measured value regarding the outlet steam temperature of the exhaust heat recovery boiler 5) is the same as the process value y not including the disturbance. is there.
If there is a difference between the process value PV (measured value related to the outlet steam temperature of the exhaust heat recovery boiler 5) including disturbance and the set value SV, the input of the feedback characteristic C1 (s) changes and the spray is the operation amount u. When the valve opening changes and the feedback characteristic C1 (s) is appropriately set, the process value PV including the disturbance matches the set value SV after a certain period of time.

Next, consider the case where the disturbance d is generated. The second plant characteristic G2 (s) is the effect of the disturbance d on the process value PV (measured value relating to the outlet steam temperature of the exhaust heat recovery boiler 5) including the disturbance.
When the disturbance d occurs, the process value PV (measured value related to the outlet steam temperature of the exhaust heat recovery boiler 5) including the disturbance fluctuates under the influence of the second plant characteristic G2 (s).

Here, it is assumed that the disturbance d, which is the input of the second plant characteristic G2 (s), can be measured and the feedforward characteristic C2 (s) shown by the dotted line in FIG. 2 exists.
For G1 (s), C2 (s), and G2 (s) shown in FIG. 2, if the feedforward characteristic C2 (s) can be determined so that G1 (s) C2 (s) = G2 (s). , (1) The change of (disturbance process value) y2 determined by the disturbance d, and (2) the change of the process value y not including the disturbance d caused by the change of the operation amount u due to the feedforward characteristic C2 (s). Are the same, and the process value PV including disturbance does not fluctuate.

An example of the setting method of the feedforward characteristic C2 (s) will be described.
The feedforward characteristic C2 (s) is an exhaust gas temperature change, an exhaust gas flow rate change, a steam flow rate change, or the like. These affect the outlet steam temperature of the exhaust heat recovery boiler 5 in the second superheater 18 shown in FIG. Therefore, the feedforward characteristic C2 (s) may be set in accordance with the second superheater 18 shown in FIG.

As an example of the feedforward characteristic C2 (s), the equation (1) of heat exchange based on the logarithmic mean temperature difference simulating the static characteristic of disturbance is shown. This formula (1) is a formula for calculating the heat exchange amount Q based on the logarithmic mean temperature difference dT.

Q = h × dT ... Equation (1)
dT = {(TH_out −TL_out) − (TH_in −TL_in)} / log ((TH_out −TL_out) / (TH_in −TL_in))
h: Heat transfer coefficient (W / m ² K)
TH_out: Outlet exhaust gas temperature (° C) in the second superheater 18
TH_in: Inlet exhaust gas temperature (° C) in the second superheater 18
TL_in: Inlet steam temperature (° C) in the second superheater 18
TL_out: Outlet steam temperature (° C) in the second superheater 18
In the same formula, the outlet exhaust gas temperature in the second superheater 18 and the outlet steam temperature in the second superheater 18 are determined by the amount of heat exchange. The amount of heat exchange varies depending on the outlet exhaust gas temperature of the second superheater 18 and the outlet steam temperature of the second superheater 18. Therefore, it is necessary to determine the heat exchange amount, the outlet exhaust gas temperature of the second superheater 18, and the outlet steam temperature of the second superheater 18 so as to satisfy both of them. Therefore, it is necessary to repeatedly calculate the amount of heat exchange.

Among the feedforward characteristics, the modeling of heat exchange in the second superheater 18 shown in FIG. 1 has been described above. The amount calculated by the model described above is the heat exchange amount Q.
A method of calculating the set value of the inlet steam temperature of the second superheater 18 from the heat exchange amount Q is shown. The set value of the inlet steam temperature is a value for controlling the measured value of the outlet steam temperature so as to match the set value of the outlet steam temperature.
The basis of the calculation method of this set value is the temperature at which the temperature is lowered by the amount corresponding to the heat exchange amount Q from the set value of the outlet steam temperature of the second superheater 18, and the inlet steam temperature of the second superheater 18. It is a method to set the value of. This equation is shown in the following equations (2-1) and (2-2). Hereinafter, the equations (2-1) and (2-2) may be collectively referred to as the equation (2).

Tin_set ＝ Tout_set−ΔT… Equation (2-1)
ΔT = Q / Fs / Cs ... Equation (2-2)
Q: Heat exchange amount (kW)
Fs: Steam flow rate (kg / sec)
Cs: Specific heat of steam (kJ / kg ・ K)
ΔT: Temperature rise in the second superheater 18 (° C.)
Tin_set: Set value (° C) of the inlet steam temperature of the second superheater 18.
Tout_set: Set value (° C) of the outlet steam temperature of the second superheater 18.
Equation (2) shows how the set value Tin_set of the inlet steam temperature of the second superheater 18 is determined by the heat exchange amount Q. However, as shown in the equation (1), the heat exchange amount Q changes depending on the inlet steam temperature of the second superheater 18. The inlet steam temperature of the second superheater 18 is determined by the set value Tin_set of the inlet steam temperature of the second superheater 18.
Therefore, since the heat exchange amount Q changes depending on the set value Tin_set of the inlet steam temperature of the second superheater 18 calculated by the equation (2), the inlet steam of the second superheater 18 is repeatedly used. It is necessary to repeatedly calculate the temperature setting value Tin_set.

After all, in order to obtain the heat exchange amount Q, a convergence calculation is performed by repeating the above calculation according to the equation (1), and further, the set value Tin_set of the inlet steam temperature of the second superheater 18 determined by the heat exchange amount Q is expressed by the equation ( It is necessary to repeat the convergence calculation according to 2). That is, in order to finally obtain the set value Tin_set of the inlet steam temperature of the second superheater 18, it is necessary to perform a double repetitive calculation in addition to the repetitive calculation for obtaining the heat exchange amount Q. Therefore, a lot of calculation costs are required, and in some cases, the calculation may not be completed within one calculation cycle of the control device 20.

By the way, the cycle of change of the outlet steam temperature of the second superheater 18 is sufficiently slower than one calculation cycle (for example, 200 milliseconds) of a general control device. Therefore, in order to control the outlet steam temperature of the second superheater 18, it is not necessary for the control device 20 to finish the convergence calculation of the set value Tin_set of the inlet steam temperature of the second superheater 18 within the one calculation cycle. , This convergence calculation may be performed over a plurality of calculation cycles of the control device. That is, in the present embodiment, of the double iterative calculation (convergence calculation) for obtaining the above heat exchange amount Q and the set value Tin_set of the inlet steam temperature of the second superheater 18, the inlet of the second superheater 18 Iterative calculation (convergence calculation) for obtaining the set value Tin_set of steam temperature is configured to be performed over a plurality of calculation cycles of the control device.

As an example, the control device 20 performs a repetitive calculation for obtaining the heat exchange amount Q for each calculation cycle of the control device 20, and sets the inlet steam temperature of the second superheater 18 determined by the heat exchange amount Q. The iterative calculation for obtaining the value Tin_set is performed over a plurality of calculation cycles of the control device 20. As a result, it is possible to reduce the calculation cost per calculation cycle of the control device 20, so that the calculation for controlling the outlet steam temperature is not completed within one calculation cycle of the control device 20. Can be avoided.

The above calculation will be described. FIG. 3 is a flowchart showing an example of a procedure for obtaining a set value of the inlet steam temperature of the second superheater, which is determined by the amount of heat exchange in the power generation system according to the first embodiment.
First, the control device 20 sets the initial heat exchange amount according to the following equation (3) (S301).
Q = h (Tout_set−Tin)… Equation (3)
Next, the control device 20 calculates the set value of the inlet steam temperature of the second superheater 18 using the equation (2). That is, the control device 20 calculates the temperature rise in the second superheater 18 according to the equation (2-2) (S302), and further calculates the inlet steam temperature in the second superheater 18 according to the equation (2-1). Calculate (S303). As described above, since the heat exchange amount Q changes depending on the inlet steam temperature of the second superheater 18, it is necessary to repeatedly calculate (converge calculation) for the inlet steam temperature of the second superheater 18 calculated at this time. However, the control device 20 uses the inlet steam temperature of the second superheater 18 calculated at this time as the inlet steam temperature set value Tin_set of the second superheater 18 for steam temperature control in the second superheater 18. (S304).
The control device 20 determines whether or not the steam temperature control has been completed (S305). When the control ends, for example, when the stop signal of the plant to be controlled is received (Yes in S305), the control device 20 ends the calculation. If the control is not completed (No in S305), the control device 20 converges and calculates the heat exchange amount Q under the input condition by the iterative calculation of the equation (1) (S306). After that, the control device 20 recalculates the temperature rise in the second superheater 18 (S306 → S302). At this time, in the steps of S302 and S303, the set value Tin_set of the inlet steam temperature of the second superheater 18 is repeatedly calculated by the equation (2) (the equation (2-1) and the equation (2-2)), and the S304 The value of the inlet steam temperature set value Tin_set of the second superheater 18 output in the step and used for steam temperature control in the second superheater 18 is changed (corrected). In this way, with respect to the set value Tin_set of the inlet steam temperature of the second heater 18, the set value of the inlet steam temperature is executed while performing the convergence calculation which is the iterative calculation over the plurality of calculation cycles of the control device 20. Until the Tin_set converges, the provisional inlet steam temperature set value at the inlet of the second superheater 18 before the convergence calculation is completed is used for steam temperature control in the second superheater 18.

Further, the order in which the above S301 to S304 and 306 occur will be described. FIG. 4 is a diagram showing an example of a timing chart for obtaining a set value of the inlet steam temperature of the second superheater, which is determined by the amount of heat exchange of the power generation system according to the first embodiment.
The control device 20 sets the initial exchange heat amount before the calculation cycle a is started (S301). The control device 20 performs the processes of S301 to S303 in the calculation cycle a. Here, the control device 20 uses the calculation result in S303 to perform the processing of S306 in the next calculation cycle shown as the calculation cycle b in FIG.
After all, the control device 20 controls the steam temperature using the set value Tin_set of the inlet steam temperature of the second superheater 18 calculated in each calculation cycle, while controlling the inlet steam temperature of the second superheater 18 used. While using the set value Tin_set, the set value Tin_set of the inlet steam temperature of the second superheater is calculated again in the next calculation cycle. In this way, the set value Tin_set of the inlet steam temperature of the second superheater 18 is repeatedly calculated over a plurality of calculation cycles of the control device 20, and finally the set value Tin_set of the inlet steam temperature of the second superheater 18 converges. Then, the inlet steam temperature of the second superheater 18 is controlled to a set value.

It should be noted that each calculation cycle may be a constant cycle or an indefinite cycle. In FIGS. 3 and 4, an example in which the set value Tin_set of the inlet steam temperature of the second superheater 18 is calculated only once in each calculation cycle a, b, ..., N is shown, but each calculation cycle a, At least one of b, ..., N may be configured so that the set value Tin_set of the inlet steam temperature of the second superheater 18 is repeatedly calculated a plurality of times. In this case, the number of repetitive operations in each operation period a, b, ..., N may be given in advance, for example, the repetitive operation is performed twice in the operation cycles a and b. Alternatively, a plurality of residual threshold values used for the convergence test of the iterative calculation are set, and the residual threshold values used for the convergence test are given so as to advance the calculation cycles a, b, ..., N of the control device 20. May be good. Further, by combining these, for example, one operation is performed in the first operation cycle a, one repetitive operation is performed in the next operation cycle b, a total of two operations are performed, and the result of the repetitive operation is obtained in the next operation cycle c. Iterative calculation until the residual falls below the first residual threshold, which is relatively large, and after the next calculation cycle d, iterative calculation until the residual falls below the second residual threshold, which is smaller than the first residual threshold. May be set to be performed respectively.

In this configuration, for example, in the first calculation cycle (calculation cycle a in FIG. 4), the set value Tin_set of the inlet steam temperature of the second superheater 18 output in the step of S304 and used for steam temperature control. Is a provisional value that includes a relatively large residual value with respect to the convergence value after the iterative calculation has converged, but as described above, the cycle of change in the outlet steam temperature of the second superheater 18 is general. The set value Tin_set of the inlet steam temperature of the second superheater 18 is repeatedly calculated over a plurality of calculation cycles of the control device 20 and is finally calculated, which is sufficiently slower than the calculation cycle (for example, 200 milliseconds) of the control device. It becomes a convergence value with a small residual. Therefore, there is no problem even if the control device 20 requires a plurality of cycles to calculate the set value of the inlet steam temperature of the second superheater 18. As described above, according to the present embodiment, the calculation in each calculation cycle of the control device 20 can be surely completed, and the increase in the calculation cost can be suppressed.

Based on the above, a specific configuration of the outlet steam temperature control device 20 of the exhaust heat recovery boiler 5 whose basic configuration is shown in FIG. 2 is shown. FIG. 5 is a diagram showing a specific configuration example of a control device for the outlet steam temperature of the exhaust heat recovery boiler of the power generation system according to the first embodiment.

The feedback characteristic shown as C1 (s) in FIG. 2 corresponds to the PID calculation unit 506 shown in FIG. 5, and constitutes a feedback control unit. The feedforward characteristics shown as C2 (s) in FIG. 2 are the steam specific heat calculation unit 501, the superheater characteristic calculation unit 502, the calculation unit 503, the heater characteristic calculation unit 504, and the spray valve characteristic calculation unit shown in FIG. Corresponding to 505, these constitute a feedforward control unit.

Each of the above parts 501 to 505, which corresponds to C2 (s) shown in FIG. 2, will be described. The inputs corresponding to the disturbance d are (1) the measured value F of the inlet exhaust gas flow rate of the second superheater 18 (the flow rate of the exhaust gas passing through the second superheater 18), and (2) the inlet exhaust gas of the second superheater 18. Measured temperature Ti, (3) Measured value f of the outlet steam flow rate of the second superheater 18 (flow rate of steam passing through the second superheater 18), (4) Of the inlet steam temperature of the second superheater 18. There are seven items: measured value ti, (5) outlet steam pressure Po of the second superheater 18, (6) spray water temperature t1, and (7) spray water pressure p1.
The steam specific heat calculation unit 501 calculates the specific heat based on the measured value po of the outlet steam pressure of the second superheater 18 and the measured value ti of the inlet steam temperature of the superheater.
The superheater characteristic calculation unit 502 calculates the set value tiS (Tin_set in FIGS. 3 and 4) of the inlet steam temperature of the second superheater 18 based on the equations (1) and (2).
However, regarding the heat exchange amount Q of the formulas (1) and (2), the superheater characteristic calculation unit 502 may perform the above-mentioned (1) measured values F of the inlet exhaust gas flow rate of the second superheater 18 and (2) second. Calculated based on the measured value Ti of the inlet exhaust gas temperature of the superheater 18, (3) the measured value f of the outlet steam flow rate of the second superheater 18, and (4) the measured value ti of the inlet steam temperature of the second superheater 18. ..

The calculation unit 503 performs a calculation for delaying the output of the set value tiS of the inlet steam temperature of the second superheater 18, which is the output of the superheater characteristic calculation unit 502, for only one calculation cycle of the control device 20. Therefore, the calculation unit 503 shifts the output of the superheater characteristic calculation unit 502 by one calculation cycle and uses it as the input of the superheater characteristic calculation unit 502 again. That is, the calculation unit 503 superheats the set value tiS (Tin_set in FIGS. 3 and 4) of the inlet steam temperature of the second superheater 18 calculated by the superheater characteristic calculation unit 502 before one calculation cycle of the control device 20. It is input again to the instrument characteristic calculation unit 502.
Further, the calculation unit 503 does not delay the output of the set value tiS of the inlet steam temperature of the second superheater for only one calculation cycle of the control device 20 as described above, but if it is before the previous cycle of the calculation cycle. , The output of the set value tiS of the inlet steam temperature of the second superheater may be delayed only during two or more calculation cycles of the control device 20.

The cooler characteristic calculation unit 504 calculates the required spray flow rate based on the set value tiS of the inlet steam temperature of the second superheater, the spray water temperature t1, and the spray water pressure p1.
The spray valve characteristic calculation unit 505 is a spray valve opening which is a second instruction value regarding the flow rate of the water supplied to the warmer 16 based on the spray flow rate calculated by the warmer characteristic calculation unit 504 and the spray water pressure p1. Calculate the degree indication value (feed forward minutes). The spray valve opening instruction value indicates an instruction value of the flow rate of water added to steam by the heater 16. Based on this indicated value, the control device 20 adjusts the opening degree of the heater valve 19 for supplying water for steam cooling to the heater 16, and the amount of steam cooled by the steam cooler 16. To adjust.

Further, the PID calculation unit 506, which corresponds to C1 (s) shown in FIG. 1, has a set value toS of the outlet steam temperature of the second superheater 18 and a measured value to of the outlet steam temperature of the second superheater 18. The PID calculation with TL_out) as an input is performed, and the result of this calculation is output as a spray valve opening instruction value (feedback portion) which is a first instruction value regarding the flow rate of water supplied to the superheater 16.

The control device 20 includes an adder that adds the spray valve opening degree indicated value (feedback portion), which is the first indicated value, to the spray valve opening degree indicated value (feedforward portion), which is the second indicated value. The added value is output as the operation amount u for G1 (s) shown in FIG.
After all, the control device 20 calculates the spray valve opening degree instruction value (operation amount u) with the disturbance d as an input. With this manipulated variable u, it is possible to control the measured value of the outlet steam temperature so as to match the set value of the outlet steam temperature.

As described above, in the first embodiment, in view of the fact that the calculation in the control device 20 for controlling the outlet steam temperature of the second superheater 18 does not end within a single calculation cycle, the second superheater 18 The calculation for controlling the outlet steam temperature can be completed within a plurality of cycles of the control device 20. As a result, the measured value of the outlet steam temperature can be controlled so as to match the set value of the outlet steam temperature, so that the steam temperature in the superheater installed in the exhaust heat recovery boiler can be appropriately controlled. ..

(Second Embodiment)
Next, the second embodiment will be described. Regarding the second embodiment, the same contents as those described in the first embodiment will be omitted.
In the first embodiment, for G1 (s), C2 (s), and G2 (s) shown in FIG. 2, C2 (s) is set so that G1 (s) C2 (s) = G2 (s). It was explained that if it can be determined, y2 determined by the disturbance and the change of y generated by the change of u due to C2 (s) become the same, and the PV does not fluctuate.
Therefore, in the first embodiment, a method using a logarithmic mean temperature difference for setting the feedforward characteristic C2 (s) is shown. However, in the setting of the feedforward characteristic C2 (s) based on this logarithmic mean temperature difference, only the static characteristic was simulated. Therefore, in the steady-state value, although it can be expected that G1 (s) C2 (s) (the product of G1 (s) and C2 (s)) and G2 (s) are almost the same, the disturbance suddenly changed. I couldn't handle the case.

An example of control when the disturbance suddenly changes in this way will be described. FIG. 6 is a diagram showing an example of a change in the time direction when the exhaust gas temperature changes in the power generation system according to the first embodiment. In FIG. 6, (a) the measured value Ti of the inlet exhaust gas temperature of the second superheater 18, (b) the measured value F of the inlet exhaust gas flow rate of the second superheater 18, and (c) the outlet steam temperature of the second superheater. The measured value to, (d) the measured value f of the outlet steam flow rate of the second superheater 18, and (e) the spray flow rate f1 of the warmer 16 are shown.

When the measured value Ti ((a) of FIG. 6) of the inlet exhaust gas temperature of the second superheater 18 changes as a disturbance, the control device 20 sets the spray flow rate f1 of the cooler 16 ((e) of FIG. 6). Control. When the disturbance suddenly changes as described above, the spray flow rate f1 suddenly increases. Due to the metallic heat capacity of the second superheater 18, there is a delay before the measured value to of the outlet steam temperature of the second superheater 18 rises.

On the other hand, when the spray flow rate f1 suddenly increases, the measured value to of the outlet steam temperature of the second superheater 18 may decrease at a timing earlier than the measured value to of the outlet steam temperature rises. In this case, as shown in FIG. 6C, the measured value to of the outlet steam temperature of the second superheater 18 is temporarily reduced. In this case, the feedback control works to reduce the spray flow rate f1 of the cooler 16. As a result, the measured value to of the outlet steam temperature of the second superheater 18 starts to rise, and the feedback control works again to meet the set value.

As described above, in the setting of C2 (s) based on the logarithmic mean temperature difference shown in the first embodiment, only the static characteristics are simulated and G1 (s) C2 (s) = G2 (s). Since C2 (s) is defined as described above, a deviation occurs due to the fluctuation when the disturbance suddenly changes.

FIG. 7 is a diagram showing a specific configuration example of a control device for the outlet steam temperature of the exhaust heat recovery boiler of the power generation system according to the second embodiment.
In the second embodiment, the calculation unit 503 that delays the output only during one calculation cycle of the control device 20 in the first embodiment is changed to the first-order delay calculation unit 603. That is, in the second embodiment, the superheater characteristic calculation unit 502 is obtained by processing the time-series data of the set value tiS (Tin_set in FIGS. 3 and 4) of the inlet steam temperature of the second superheater 18 by the first-order delay. Used as an input for. In this case, each calculation cycle is a constant cycle.

Further, not limited to the first-order delay, the time-series data of the set value of the inlet steam temperature of the second superheater 18 is used as the input of the superheater characteristic calculation unit 502, for example, the data processed by the third-order or higher-order delay. It may be.

The effect in the second embodiment will be described. FIG. 8 is a diagram showing an example of a change in the time direction when the exhaust gas temperature changes in the power generation system according to the second embodiment. Similar to FIG. 6, in FIG. 8, (a) the measured value Ti of the inlet exhaust gas temperature of the second superheater 18, (b) the measured value F of the inlet exhaust gas flow rate of the second superheater 18, and (c) the second superheater. The measured value to of the outlet steam temperature of the device, (d) the measured value f of the outlet steam flow rate of the second superheater 18, and (e) the spray flow rate f1 of the warmer 16 are shown.

As shown in FIG. 8E, in the second embodiment, the change in the spray flow rate f1 of the heater 16 is mitigated as compared with the first embodiment. As a result, C2 so that G1 (s) C2 (s) = G2 (s) in consideration of not only the static characteristics of the factor that fluctuates the outlet steam temperature but also the dynamic characteristics of the factor that fluctuates the outlet steam temperature. (S) can be defined.

As described above, in the second embodiment, it is possible to improve the influence of the deviation that occurs when the disturbance suddenly changes when the first embodiment is implemented.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

Further, the method realized by the control device 20 of each embodiment is, for example, a magnetic disk (floppy (registered trademark) disk, hard disk, etc.), an optical disk (as a program (software means) that can be executed by a computer (computer)). It can be stored in a recording medium such as a CD-ROM, DVD, MO, etc., or a semiconductor memory (ROM, RAM, flash memory, etc.), or transmitted and distributed by a communication medium. The program stored on the medium side also includes a setting program for configuring the software means (including not only the execution program but also the table and the data structure) to be executed by the computer in the computer. A computer that realizes this device reads a program recorded on a recording medium, constructs software means by a setting program in some cases, and executes the above-mentioned processing by controlling the operation by the software means. The recording medium referred to in the present specification is not limited to distribution, and includes a storage medium such as a magnetic disk or a semiconductor memory provided in a device connected inside a computer or via a network.

1 ... Gas turbine, 2 ... Compressor, 3 ... 1st generator, 4 ... Exhaust pipe, 5 ... Exhaust heat recovery boiler, 11 ... Drum, 12 ... Down pipe, 13 ... Evaporator, 14 ... 1st steam pipe, 15 ... 1st superheater, 16 ... warmer, 17 ... second steam pipe, 18 ... 2nd superheater, 19 ... warmer valve, 20 ... control device, 21 ... main steam pipe, 22 ... main steam valve , 23 ... Bypass piping, 24 ... Bypass valve, 25 ... Steam turbine, 26 ... Second generator, 31 _F , 35 _F ... Flow meter, 31 _T , 33 _T , 34 _T , 35 _T ... Thermometer, 32 _P , 35 _P ... Pressure gauge, 36 ... Rotation speed measuring instrument, 37 ... Electric output measuring instrument, 501 ... Steam specific heat calculation unit, 502 ... Superheater characteristic calculation unit, 503 ... Calculation unit, 504 ... Heater characteristic calculation unit, 505 ... Spray valve characteristic calculation unit, 506 ... PID calculation unit, 603 ... Primary delay calculation unit.

Claims (6)

The steam installed on the upstream side of the superheater and supplied to the superheater so that the measured value of the outlet steam temperature of the superheater installed in the boiler that generates steam matches the outlet steam temperature set value. A feedback control unit that calculates the first indication value regarding the flow rate of water supplied to the cooler to be cooled,
A feedforward control unit that calculates a second instruction value regarding the flow rate of the water supplied to the incubator based on a factor that causes the outlet steam temperature to fluctuate, and the first instruction value and the second instruction value are added. Equipped with an adder to
The factor, the flow rate of the exhaust gas passing through the super heater, the flow rate of the steam supplied to the superheater, and an inlet steam temperature of the superheater is included,
The feedforward control unit
A superheater characteristic calculation unit that calculates an inlet steam temperature set value related to the inlet steam temperature of the superheater based on the above factors.
A steam temperature control device including a heater characteristic calculation unit that calculates the second indicated value based on the inlet steam temperature set value. The superheater characteristic calculation unit
It is configured so that the iterative calculation of the heat exchange amount in the superheater and the iterative calculation of the inlet steam temperature set value can be executed, respectively.
The first aspect of claim 1, wherein the iterative calculation of the heat exchange amount is executed for each calculation cycle, and the iterative calculation of the inlet steam temperature set value is executed for a plurality of times of the calculation cycle. Steam temperature controller. The steam temperature control device according to claim 1 or 2, wherein the superheater characteristic calculation unit calculates the inlet steam temperature set value based on the static characteristic of the factor. The steam temperature control device according to claim 3, wherein the superheater characteristic calculation unit calculates an inlet steam temperature set value based on the static characteristic and the dynamic characteristic of the factor. The steam installed on the upstream side of the superheater and supplied to the superheater so that the measured value of the outlet steam temperature of the superheater installed in the boiler that generates steam matches the outlet steam temperature set value. Calculate the first indication for the flow rate of water supplied to the cooler to cool,
The second indicated value regarding the flow rate of the water supplied to the incubator is calculated based on the factor that the outlet steam temperature fluctuates.
The first indicated value and the second indicated value are added to adjust the flow rate of the water supplied to the heater.
The factor, the flow rate of the exhaust gas passing through the super heater, the flow rate of the steam supplied to the superheater, and an inlet steam temperature of the superheater is included,
To calculate the second indicated value
To calculate the inlet steam temperature set value for the inlet steam temperature of the superheater based on the above factors,
A steam temperature control method including calculating the second indicated value based on the inlet steam temperature set value. A boiler including a superheater and a heater arranged on the upstream side of the superheater to cool the steam supplied to the superheater.
A steam turbine driven by the steam from the superheater of the boiler, and
A steam temperature control device for controlling the steam temperature of the steam for driving the steam turbine is provided.
The steam temperature control device is
A feedback control unit that calculates a first indicated value regarding the flow rate of water supplied to the cooler so that the measured value of the outlet steam temperature of the superheater matches the outlet steam temperature set value.
A feedforward control unit that calculates a second instruction value regarding the flow rate of the water supplied to the incubator based on a factor that causes the outlet steam temperature to fluctuate.
An adder that adds the first indicated value and the second indicated value is provided.
The factor, the flow rate of the exhaust gas passing through the super heater, the flow rate of the steam supplied to the superheater, and an inlet steam temperature of the superheater is included,
The feedforward control unit
A superheater characteristic calculation unit that calculates an inlet steam temperature set value related to the inlet steam temperature of the superheater based on the above factors.
A power generation system including a heater characteristic calculation unit that calculates the second indicated value based on the inlet steam temperature set value.