JP4117517B2 - Coal gasification combined power plant and its operation control device. - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
In the operation of a coal gasification combined power plant, the present invention mainly controls operation control of the power recovery unit that suppresses the change rate of the operation end in the power recovery unit that has relatively slow load following performance and that has relatively easy load following performance. The present invention relates to operation control technology that improves load following performance in the entire plant.
[0002]
[Prior art]
In the conventional coal gasification combined power plant, in order to follow the plant load command value, the so-called gas turbine initiative that adjusts the amount of coal supplied to the gasifier and the amount of oxidizer supplied based on the gas turbine output Load control methods have been mainly proposed.
[0003]
Further, in JP-A-7-332022, a part of the refined gas from the gasifier is always bypassed to the exhaust heat recovery boiler and burned in the boiler, whereby the superheater in the exhaust heat recovery boiler is disclosed. A technique is disclosed that increases the steam turbine output by increasing the inlet temperature, and at the same time eliminates the need for a superheater in the heat recovery section provided in the gasification furnace.
[0004]
[Problems to be solved by the invention]
In the gas turbine initiative load control, there is a problem that a long time is required from when coal is introduced into the gasification furnace until it is converted into purified gas and reaches the gas turbine combustor, and the response is not sufficient. In addition, there is a problem in that the gas pressure and the pressure in the gasifier also fluctuate by operating the gas turbine fuel flow rate adjustment valve before increasing the amount of purified gas from the gasifier during load following. Furthermore, in the technique disclosed in the publication, when the load command value to the plant greatly fluctuates, fluctuations in the amount of coal and the amount of oxidizer supplied to the gasifier also increase. The problem is that it is difficult to adjust the supply amount so that a part of the refined gas is always sent to the exhaust heat recovery boiler bypassing the gas turbine combustor, and the gas turbine output is reduced. ,was there.
[0005]
A first problem of the present invention is a coal gasification combined power plant, The purpose is to reduce the time delay of control when the load fluctuates. The second problem of the present invention is that Stabilization of gas pressure during load fluctuations The purpose is to suppress a reduction in gas turbine output.
[0006]
[Means for Solving the Problems]
In order to solve the first problem, in a coal gasification combined power plant, a gas turbine bypass pipe that is branched from a fuel gas pipe and includes a gas turbine bypass valve capable of adjusting a flow rate, and a gas turbine bypass pipe are ventilated. Purified gas combustion device for combusting purified gas to be combusted, and combustion gas conduit for connecting the combustion gas outlet side of the purified gas combustion device and the exhaust gas inlet side of the exhaust heat recovery device A control device for controlling the opening degree of the gas turbine bypass valve, and the control device is configured to control a deviation between the output of the steam turbine and an output command value of the steam turbine that is varied according to plant load fluctuations. Control the opening of the gas turbine bypass valve to zero .
[0007]
Furthermore, in order to solve the second problem, the gasification equipment for generating steam using the heat generated while gasifying the coal to generate the crude gas, and the gasification equipment connected to the gasification equipment are arranged. A gas purification facility that removes unnecessary substances from the crude gas to obtain a purified gas, a gas turbine that is connected to the gas purification facility by a fuel gas pipe, and that uses the purified gas as fuel, and a gas turbine that is connected to the gas turbine The exhaust heat recovery device that generates steam using the exhaust gas discharged from the gas turbine and the steam generated by the gasification facility and the exhaust heat recovery device and supplied via the main steam valve A steam turbine as a source, and a steam bypass pipe connecting a pipe for guiding the steam generated by the gasification facility and the exhaust heat recovery device to the steam turbine to a condenser of the steam turbine via a flow control valve; , A purified gas combustion device that is connected to a purified gas outlet side of a purification facility through a valve and combusts the purified gas, and a combustion gas outlet side of the purified gas combustion device communicates with an exhaust gas inlet side of the exhaust heat recovery device An operation control device for controlling the operation of a coal gasification combined power plant comprising a pipeline based on the plant load command value, wherein the plant load command value is converted into a gas turbine load command value and a steam turbine load command value. Load command distributing means for distributing, and fuel flow adjusting opening adjusting means for adjusting the fuel flow adjusting opening of the gas turbine so that the difference between the actual output of the gas turbine and the gas turbine load instruction value is zero And a fuel flow adjustment opening adjusting means for adjusting a fuel flow adjustment opening of the gas turbine so that a difference between an actual output of the gas turbine and the gas turbine load command value is zero, and the steam turbine A first main steam valve opening signal for adjusting a main steam valve opening of the steam turbine so that a difference between an actual output and the steam turbine load command value is zero; an inlet main steam pressure of the steam turbine; and a plant By selecting a low value of the second main steam valve opening signal that adjusts the main steam valve opening of the steam turbine so that the difference from the inlet main steam pressure setting value having the load command value as an argument is 0 The difference between the main steam valve opening adjusting means for adjusting the main steam valve opening, and the actual pressure of the crude gas at the crude gas outlet of the gasification facility and the crude gas outlet pressure set value using the plant load command value as an argument A signal that adjusts the amount of coal supplied to the gasification facility so as to be zero, and an output signal of the fuel flow control valve adjustment means, and the second main steam valve opening signal A signal generated on the basis of adjusting the amount of coal supplied to the gasification facility, The difference between the supply coal amount adjusting means for adjusting the amount of coal supplied to the gasification facility from the actual supply oxidant amount to the gasification facility and the oxidant supply amount setting value using the plant load command value as an argument Oxidant supply amount adjusting means for adjusting the oxidant supply valve opening so as to make the value 0, and when the crude gas actual pressure is larger than the crude gas outlet pressure set value, the purified gas is supplied from the gas purification facility. A purified gas bypass amount adjusting means for increasing the purified gas bypass amount led to the combustion device and decreasing the purified gas bypass amount when the actual crude gas pressure is smaller than the crude gas outlet pressure set value; When the main steam pressure is larger than the inlet main steam pressure set value, the opening degree of the flow rate adjusting valve disposed in the steam bypass pipe that directly vents the steam from the exhaust heat recovery device to the steam turbine condenser is set. Increase Providing a steam bypass flow rate adjustment means.
[0008]
Furthermore, when the main steam pressure falls below a predetermined pressure, an opening degree regulating means for making the main steam valve opening degree constant may be added to the main steam valve opening degree adjusting means.
[0009]
In addition, an opening degree regulating means for outputting a signal for making the main steam valve opening degree constant is provided, and in the case of operation for improving load following performance, the opening degree of the main steam valve is determined by the output of the main steam valve opening degree adjusting means. When performing control and operating at maximum power generation efficiency, there may be provided switching means for controlling the opening degree of the main steam valve by the output of the opening degree regulating means.
[0010]
The refined gas bypass amount adjusting means is preferably configured to increase or decrease the purified gas bypass amount when the difference between the crude gas actual pressure and the crude gas outlet pressure set value exceeds a preset allowable value. .
[0011]
The steam bypass flow rate adjustment means is configured to increase the opening of a flow rate adjustment valve interposed in a steam bypass pipe when the inlet main steam pressure is larger than an allowable value than an inlet main steam pressure set value. It is desirable to do.
[0012]
The purified gas bypass amount adjusting means adjusts the purified gas bypass amount so that the difference between the steam turbine load command value and the actual output of the steam turbine is zero when the load fluctuates. It is desirable to add means.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIG. The illustrated plant includes a gasification facility part that gasifies coal, a gas purification part that purifies gas generated in the gasification facility part, a power generation part that extracts power from the purified gas, and a power generation part. And a control means (not shown).
[0014]
The gasification equipment part is connected to the gasification furnace 7, the heat recovery boiler 8 provided in connection with the gasification furnace 7, and equipped with a heat transfer tube (heat exchanger), and the outlet side and the inlet side of the heat transfer tube The steam separator 14 arranged in this manner, the bunker 6 for supplying the coal to the gasification furnace 7 via the pipeline 72 having the coal supply valve 21 interposed therebetween, and the coal supply amount installed in the pipeline 72 A coal supply amount detector 26 for detecting the oxidant, an oxidant supply source (not shown) for supplying the oxidant to the gasification furnace 7 via a pipe line 73 provided with an oxidant supply valve 22, and the pipe line 73. An oxidant supply amount detector 27 for detecting an oxidant supply amount, and a water supply pump 15 interposed in a conduit 74 connecting the inlet side of the lower end of the heat transfer tube and the steam separator 14, A conduit 66 that communicates the bottom of the heat recovery boiler 8 and the top of the gasification furnace 7, and a portion near the heat recovery boiler connection portion of the conduit 66 It is configured to include the generated gas outlet pressure detector 28 for detecting the outlet pressure of the installation has been generated crude gas.
[0015]
The gas purification part is connected to the gas purification facility 9 arranged on the pipe 66 and connected to the side thereof, and is connected to the gas outlet side of the gas purification facility 9. The pressure adjustment valve 16 and the flow rate adjustment valve are sequentially arranged from the upstream side. 17 is connected to a purified gas supply pipe 67 which is a fuel gas pipe interposed 17 and a purified gas supply pipe 67 upstream of the pressure regulating valve 16 by a gas turbine bypass pipe 23 having a gas turbine bypass valve 24 interposed therebetween. And a purified gas combustion device 25.
[0016]
The power generation portion includes a combustor 3 installed in connection with the purified gas supply pipe 67, a gas turbine 4 installed in connection with the combustor 3, and a gas turbine generator driven by the gas turbine 4. 12, a compressor 2 that is also driven by a gas turbine 4 to supply compressed air to the combustor 3, an inlet guide vane 1 that is disposed on the air inlet side of the compressor 2 to control the amount of intake air, and a gas A gas turbine output detector 30 that is installed on the output shaft of the turbine 4 and detects the output, and an exhaust gas pipe 4 connected to the exhaust side of the gas turbine 4 is connected to a heating side fluid flow path inlet (that is, an exhaust gas inlet). The heat recovery device 10, the steam turbine 5 connected to the heated fluid flow path outlet side (that is, the steam outlet side) of the exhaust heat recovery device 10 by the steam pipe 69, and the recovery unit connected to the steam outlet side of the steam turbine 5 Water vessel 11 and steam turbine 5 A generator 13 coupled to the output shaft and driven, a steam turbine output detector 31 attached to the output shaft for detecting output, a main steam valve 18 interposed in the steam pipe 69, and main steam A main steam pressure detector 29 that is attached to the steam pipe 69 between the valve 18 and the exhaust heat recovery device 10 to detect the steam pressure, and a steam pipe 59 between the main steam valve 18 and the main steam pressure detector 29. A steam bypass pipe 70 communicating with the condenser 11 via a bypass valve 19 whose flow rate can be adjusted, a condenser discharge side of the condenser 11 and a heated fluid input side of the exhaust heat recovery device 10 (that is, water supply input) And a water supply pump 20 that is interposed in the water supply pipe 71 and feeds the condensate of the condenser 11 to the exhaust heat recovery device 10.
[0017]
The exhaust heat recovery device 10 includes an economizer, an evaporator, and a superheater. The economizer entrance side constitutes the heated fluid entrance side, and the superheater exit side constitutes the heated fluid flow path exit side. The outlet side of the economizer is connected to an air / water drum (not shown), and the outlet side and the inlet side of the evaporator are also connected to the air / water drum. The superheater entrance side is also connected to the steam-water drum. The upper part (gas phase part) of the steam separator 14 is connected to the superheater entrance side by a steam pipe 75. In other words, the water supplied to the water supply pipe 71 by the water supply pump 20 is guided to the air / water drum through the economizer, and is evaporated while circulating between the air / water drum and the evaporator. The steam accumulated in the steam drum is combined with the steam from the steam pipe 75 and flows into the superheater, and flows out to the steam pipe 69 through the superheater.
[0018]
A combustion gas outlet side of the purified gas combustion device 25 is connected to the exhaust pipe 68 by a combustion gas pipe 76. The heated fluid outlet side of the exhaust heat recovery apparatus 10 is open to the atmosphere. A water supply line (not shown) is connected to the pipe line 74 from a water supply pipe 71, and another water supply line (not shown) is connected to supply makeup water.
[0019]
Next, the operation of the combined coal gasification combined cycle plant will be described. The flow rate of the oxidant is adjusted by the oxidant supply valve 22 and supplied to the gasification furnace 7. The gasifier 7 combusts fine coal supplied from the bunker 6 through the coal supply valve 21 with the oxidant, and recovers the generated high-temperature and high-pressure generated gas containing hydrogen, carbon monoxide, and carbon dioxide. Supply to boiler 8. The heat recovery boiler 8 includes a heat transfer tube (that is, a heat exchanger) through which feed water flows. The heat exchanger is heated by the high-temperature and high-pressure generated gas to generate steam, and the generated steam is Supply to water separator 14. The steam from which moisture has been separated by the steam separator 14 is sent to the exhaust heat recovery device 10 through the steam pipe 75, and the separated moisture is circulated to the heat exchanger by the feed water pump 15.
[0020]
On the other hand, the product gas cooled by releasing heat is supplied to the gas purification equipment 9 through the pipe 66. The gas purification equipment 9 removes unnecessary substances contained in the product gas to obtain purified gas, and sends this purified gas to the purified gas supply pipe 67. The gas turbine bypass valve 24 is closed in the normal operation state. The purified gas whose pressure is adjusted by the pressure adjusting valve 16 interposed in the purified gas supply pipe 67 is supplied to the combustor 3 after the flow rate is adjusted by the flow rate adjusting valve 17. The air flows into the compressor 2 while the flow rate is adjusted by the inlet guide vanes 1, is compressed by the compressor 2, becomes high-pressure air, and is supplied to the combustor 3.
[0021]
The combustor 3 burns the purified gas supplied from the gas purification facility with the high-pressure air supplied from the compressor 2 and supplies the generated high-temperature gas to the turbine 4. The high-temperature gas supplied to the turbine 4 is recovered in power by the turbine 4, and after being generated by the connected gas turbine generator 12, is discharged as exhaust gas to the atmosphere through the exhaust heat recovery device 10. The exhaust heat recovery apparatus 10 constitutes a heat exchanger including a heating side fluid channel (exhaust gas channel) and a heated fluid channel (economizer, evaporator, superheater), and flows through the heating side fluid channel. Steam supplied by the heat of the exhaust gas is supplied from the water supply pipe 71 and flows through an economizer and an evaporator to generate steam. The generated steam merges with the steam supplied from the steam separator 14 via the steam pipe 75 and flows into the superheater. After passing through the superheater, the steam is guided to the steam pipe 69. The steam guided to the steam pipe 69 is supplied to the steam turbine 5 after the flow rate is adjusted by the main steam valve 18. The steam supplied to the steam turbine 5 is recovered in power by the steam turbine 5 and is generated by the connected steam turbine generator 13. The steam after power recovery is condensed in the condenser 11 and supplied to the exhaust heat recovery device 10 by the feed water pump 20, and a part of the heat recovery boiler 8 passes through the pipe line 74 and the feed water pump 15. To be supplied.
Next, an operation method for each of the above-described element devices according to the plant operation state will be described.
[0022]
When increasing the plant load, first, the amount of coal supplied from the bunker 6 is increased by the coal supply valve 21, and the amount of gas generated in the gasifier 7 is increased. Next, the amount of water supplied to the heat recovery boiler 8 is increased by the water supply pump 15 to increase the amount of steam generated in the steam separator 14. The increased amount of steam is supplied to the superheater of the exhaust heat recovery apparatus 10 via the steam pipe 75 and increases in the amount of steam that merges with the steam generated in the exhaust heat recovery apparatus 10, and at the same time, the main steam valve 18 Is increased, and the amount of recovered power in the steam turbine 5 is increased. After the composition of the gas generated from the gasifier 7 is stabilized, the amount of purified gas supplied to the combustor 3 is increased by the flow rate adjusting valve 17 and at the same time by adjusting the opening of the main steam valve 18, Follow the load command to the plant. As described above, when the plant load increases, first, the amount of steam supplied to the steam turbine is increased, and after the composition of the gas generated from the gasification furnace 7 is stabilized, the amount of purified gas supplied to the combustor 3 is increased. This operation suppresses fluctuations in the gas pressure and the pressure in the gasifier when the plant load increases. Moreover, the load follow-up time as a plant can be shortened by performing the load change of a steam turbine ahead of the load change of a gas turbine.
[0023]
When the plant load is lowered, first, the amount of coal supplied from the bunker 6 is reduced, and at the same time, the opening degree of the main steam valve 18 is lowered and the bypass valve 19 is opened. Next, the amount of water supplied to the heat recovery boiler 8 is decreased by the water supply pump 15. After the amount of gas generated from the gasifier 7 is stabilized, the flow regulating valve 17 is closed to reduce the opening, and the bypass valve 19 is fully closed while adjusting the opening of the main steam valve 18. By following the above, the load command to the plant is made to follow. By performing load follow-up at the time of plant load drop by the above operation, fluctuations in gas pressure and in-furnace pressure of the gasifier are suppressed.
[0024]
When the generated steam pressure in the exhaust heat recovery apparatus 10 is lower than a predetermined pressure, the main steam valve 18 is fully opened and the bypass valve 19 is fully closed. Next, simultaneously with opening the gas turbine bypass valve 24, the operation of the purified gas combustion device 25 is started. In addition to the exhaust gas from the turbine 4, high-temperature gas generated in the purified gas combustion device 25 is supplied to the exhaust heat recovery device 10, thereby increasing the generated steam pressure in the exhaust heat recovery device 10 to a predetermined value. At this time, when the total output of the turbine 4 and the steam turbine 5 is lower than the plant load command value, the supplied coal amount of the bunker 6 is increased, and in the opposite case, it is decreased. By the above operation, the generated steam pressure in the exhaust heat recovery apparatus 10 is adjusted.
[0025]
Next, an operation method when a combustion abnormality occurs in the combustor 3 will be described in the case of runback and trip.
[0026]
The basic operation at the time of gas turbine runback is the same as that at the time of plant load drop described above. Two types of operation change rate and width at each operation end are set in advance for normal operation and runback, and a function of switching simultaneously with the generation of the runback signal is provided.
[0027]
When the gas turbine trips, first, the pressure regulating valve 16 is fully closed, and at the same time, the gas turbine bypass valve 24 is opened to start the operation of the purified gas combustion device 25. Next, the flow regulating valve 17 is closed to bring the gas turbine into a starting state. Further, the main steam valve 18 is fully opened and the bypass valve 19 is fully closed. At the same time, the water supply amount of the water supply pump 20 is increased, and as a result, the output of the steam turbine 5 is maintained at the maximum output and the recovery of the gas turbine operation is waited. At the time when the gas turbine is restored to a predetermined load (when the sum of the gas turbine output and the steam turbine output matches the commanded output), the gas turbine bypass valve 24 is closed to reduce the opening degree. The operation of increasing the opening degree of the flow regulating valve 17 is performed. Next, the main steam valve 18 is closed to reduce the opening, and while adjusting the opening of the bypass valve 19, the output of the gas turbine is increased to follow the load command to the plant. By performing the operation at the time of abnormal combustion in the combustor 3 by the above operation, it is possible to suppress fluctuations in the gas pressure and the in-furnace pressure of the gasifier when restarting from the gas turbine trip.
[0028]
Next, a control apparatus suitable for performing the above-described operations will be described with reference to FIG. The illustrated control system diagram shows a plant load command value (MWD), a coal supply amount detector 26, an oxidant supply amount detector 27, a generated gas outlet pressure detector 28, a main steam pressure detector 29, and a gas turbine output. Using the outputs of the detector 30 and the steam turbine output detector 31 as inputs, the flow rate adjusting valve 17, the main steam valve 18, the bypass valve 19, the coal supply valve 21, the oxidant supply valve 22, and the gas turbine bypass valve 24 A control system to be controlled is shown.
[0029]
A gas turbine output setting device 32, a steam turbine output setting device 37, and function setting devices 46, 53, 62 are connected in parallel to each other to a signal line through which a load command value (MWD) to the plant flows. Subtractors 33, 38, 47, 54, and 63 are connected to the output side of the setting device.
[0030]
A subtracter 33 is arranged by connecting a negative input to the output side of the gas turbine output setting device 32, and an output of the gas turbine output detector 30 is connected to a positive input of the subtractor 33. A PI controller 34 is connected to the output side of the subtracter 33, and one input terminal of the adder 35 is connected to the output side of the PI controller 34. Further, a function setter 36 is connected to the output side of the gas turbine output setter 32, and the output of the function setter 36 is connected to the other input terminal of the adder 35. The output of the adder 35 becomes an opening degree signal of the flow rate adjusting valve 17.
[0031]
A subtractor 38 is arranged by connecting a positive input to the output side of the steam turbine output setting device 37, and an output of the steam turbine output detector 31 is connected to a negative input of the subtractor 38. A PI controller 39 and a PI controller 45 are connected in parallel to the output side of the subtractor 38, and one input terminal of the adder 40 is connected to the output side of the PI controller 39. Further, a function setting unit 41 is connected to the output side of the steam turbine output setting unit 37, and the output of the function setting unit 41 is connected to the other input terminal of the adder 40. The output side of the adder 40 is connected to one input side of the low value selector 42, and the output side of the low value selector 42 selects one of the two inputs and outputs one of the switches 43. Connected to the input side. The other input side of the switch 43 is connected to the output side of a constant setter 44 that is an opening degree restricting means. The output of the switch 43 is an opening signal of the main steam valve 18. Note that the switch 43 operates to output the input from the low value selector 42 in the load following mode.
[0032]
A subtractor 47 is arranged by connecting a + side input to the output side of the function setter 46, and an output side of the generated gas outlet pressure detector 28 is connected to a − side input of the subtractor 47. A PI controller 48 is connected to the output side of the subtractor 47, and one input terminal of the adder 49 is connected to the output side of the PI controller 48. The other input of the adder 49 is connected to the output of the adder 35. A dead band setting device 50 is connected to the output side of the subtractor 47, and a function setting device 51 is connected to the output side of the dead band setting device 50. The output side of the function setting device 51 is connected to one input side of a switch 52 that selects and outputs one of the two inputs. The other input side of the switch 52 is connected to the output side of the PI controller 45 connected to the output side of the subtractor 38. The output of the switch 52 becomes an opening signal of the gas turbine bypass valve 24. Note that the switch 52 operates to output an input from the PI controller 45 during gas turbine bypass load control.
[0033]
A subtractor 54 is arranged by connecting the input + side to the output side of the function setter 53, and the output side of the main steam pressure detector 29 is connected to the − side input of the subtractor 54. Dead zone setting devices 55 and 55A are connected to the output side of the subtractor 54, a PI controller 56 is connected to the output side of the dead zone setting device 55, and a PI controller 61 is connected to the output side of the dead zone setting device 55A. Yes.
[0034]
A function setting unit 57 is connected to the output side of the PI controller 56, and the output side of the function setting unit 57 is connected to one of the inputs of the adder 58. The output of the adder 49 is connected to the other input of the adder 58, and the output side of the adder 58 is connected to the + side input of the subtractor 59. The output of the coal supply amount detector 26 is connected to the minus side input of the subtractor 59, and the output of the subtractor 59 is input to the PI controller 60. The output of the PI controller 60 becomes the opening signal of the coal supply valve 21. The output of the PI controller 56 is also connected to the other input of the low value selector 42.
[0035]
The output of the PI controller 61 becomes an opening degree signal of the bypass valve 19.
[0036]
A subtracter 63 is arranged with the input + side connected to the output side of the function setter 62, and the output side of the oxidant supply amount detector 27 is connected to the − side input of the subtractor 63. A PI controller 64 is connected to the output side of the subtracter 63, and an adder 65 is connected to one of the inputs connected to the output side of the PI controller 64. The other input of the adder 65 is connected to the output of the PI controller 60, and the output of the adder 65 becomes an opening signal of the oxidant supply valve 22.
[0037]
Hereinafter, control for controlling the flow rate adjustment valve 17, the main steam valve 18, the bypass valve 19, the coal supply valve 21, the oxidant supply valve 22, and the gas turbine bypass valve 24 by the control system having the above configuration will be described.
[0038]
The load command value (MWD) to the plant is obtained by the gas turbine output setter 32 and the steam turbine output setter 37 constituting the load command distribution means, respectively, for the gas turbine output (gas turbine output command value) and the steam turbine output. Is converted into a command value (steam turbine output command value). The subtractor 33 calculates the difference between the gas turbine output from the gas turbine output detector 30 and the output of the gas turbine output setting unit 32 and transmits the obtained deviation to the PI controller 34. The PI controller 34 performs a PI calculation based on the input deviation, generates a signal for controlling the opening degree of the flow rate adjustment valve 17 so that the deviation becomes zero, and outputs the calculation result to the adder 35. The output of the gas turbine output setting device 32 is simultaneously input to the function setting device 36, and the function setting device 36 calculates a correction value of the opening degree signal based on the gas turbine output command value. The output of the PI controller 34 and the output of the function setting unit 36 are added by an adder 35 and output as an opening signal of the flow rate adjusting valve 17 that adjusts the flow rate of the gas turbine fuel (purified gas). The subtractor 33, the adder 35, the function setter 36, and the PI controller 34 constitute a fuel flow control valve opening adjustment means.
[0039]
The gas turbine output setting units 32 and 37 set the steam turbine output change rate to be larger than the gas turbine output change rate when a load fluctuation command is input. Further, the steam turbine output setting device 37 sets the flow rate adjustment valve 17 to be fully closed when the gas turbine operation state is tripped. By the above process, the gas turbine load change rate at the time of load fluctuation can be suppressed, and the gasification furnace 7 outlet pressure fluctuation can be suppressed.
[0040]
On the other hand, the subtractor 38 to which the output (steam turbine output command value) of the steam turbine output setting unit 37 is input is the difference between the output of the steam turbine output setting unit 37 and the steam turbine output from the steam turbine output detector 31. And the obtained deviation is transmitted to the PI controller 39. The PI controller 39 performs a PI calculation based on the input deviation, generates a signal for controlling the opening of the main steam valve so that the deviation becomes zero, and outputs the signal to the adder 40. The output of the steam turbine output setting unit 37 is simultaneously input to the function setting unit 41, and the function setting unit 41 calculates an opening degree signal correction value based on the steam turbine output command value and outputs it to the adder 40. The output of the PI controller 39 and the output of the function setting unit 41 are added by the adder 40, and the obtained signal (first main steam valve opening signal) is input to the low value selector 42.
[0041]
Further, the load command value (MWD) to the plant is set by the function setting units 46, 53, and 62, respectively, the gasification furnace 7 outlet pressure setting value, the main steam valve 18 inlet pressure setting value, and the oxidant supply valve 22 flow rate setting. Converted to a value.
[0042]
The subtractor 47 to which the output of the function setter 46 (gasifier 7 outlet pressure set value) is input is a gas that is the output of the generated gas outlet pressure detector 28 from the input gasifier 7 outlet pressure set value. The crude gas pressure at the outlet of the converter is subtracted, and the obtained deviation is transmitted to the PI controller 48 and the dead zone setting device 50.
[0043]
The dead zone setting device 50 outputs a signal when the input deviation exceeds the set range, and the output from the dead zone setting device 50 is converted into an opening signal of the gas turbine bypass valve 24 by the function setting device 51. It is converted and output to the switch 52. The function setter 51 outputs a signal so as to increase the opening of the gas turbine bypass valve 24 when the deviation output from the subtractor 47 is negative, and to decrease the opening when the deviation is opposite.
[0044]
Since the dead zone setter 50 outputs a signal when the input deviation exceeds the set range, the gas turbine bypass valve due to a minute fluctuation of the subtractor 47 output in a region where the set value and the actual pressure are close to each other. Thus, the variation in the outlet pressure of the gasification furnace 7 can be suppressed by suppressing the variation in the opening degree of 24.
[0045]
In addition to the output of the function setter 51, the output signal of the subtractor 38 is PI-calculated by the PI controller 45 and input to the switch 52. The PI controller 45 generates and outputs an opening signal for controlling the opening of the gas turbine bypass valve 24 so that the output of the subtractor 38 becomes 0, and selects the gas turbine bypass load control (the gas turbine bypass valve 24). Switch 52 is turned on, and a signal from the PI controller 45 is output as a valve opening signal of the gas turbine bypass valve 24. The subtractor 38 and the PI controller 45 constitute bypass gas amount adjusting means. When the switch 52 is off, the switch 52 outputs a signal from the function setting unit 51 as a valve opening signal of the gas turbine bypass valve 24. In other words, during normal operation, the gas turbine bypass valve 24 is controlled in accordance with the deviation between the set value of the gasifier outlet pressure and the actual pressure to suppress fluctuations in the gasifier 7 outlet pressure. When the gas turbine bypass load control is selected, such as when the pressure of the steam supplied from the heat recovery apparatus 10 falls below a specified value, the control is performed based on the output of the PI controller 45 that performs PI calculation on the deviation between the steam turbine output and the output command value. Therefore, even when a large gasifier 7 outlet pressure fluctuation is predicted, the pressure fluctuation can be effectively suppressed. The subtractor 47, dead zone setter 50, and function setter 51 constitute a purified gas bypass amount adjusting means.
[0046]
Through the above processing, in the case of normal operation, the gas turbine bypass valve 24 can be operated mainly by the steam turbine output so as to suppress fluctuations in the outlet pressure of the gasification furnace 7 and during load fluctuations and gas turbine trips.
[0047]
The output of the function setter 53 (main steam valve 18 inlet pressure set value) is input to the subtractor 54. The subtractor 54 subtracts the main steam pressure input from the main steam pressure detector 29 from the output of the function setting unit 53, and the obtained deviation is sent to the PI controller 56 via the dead band setting unit 55 and the dead band setting unit 55A. Are respectively transmitted to the PI controller 61 via.
[0048]
The PI controller 61 performs PI calculation on the input deviation and outputs it as an opening signal of the bypass valve 19. When the input deviation is negative (when the actual pressure is higher than the set value), the PI controller 61 outputs a signal for increasing the opening of the bypass valve. The output of the subtractor 54 is input to the PI controller 61 through the dead zone setter 55 to suppress the opening degree variation of the bypass valve 19 due to a minute variation in deviation in a region where the set value and the actual pressure are close to each other. Thus, fluctuations in the main steam pressure generated in the exhaust heat recovery apparatus 10 can be suppressed. With the above processing, even when the load fluctuates and when the gas turbine trips, the steam turbine output change rate can be made larger than the gas turbine output change rate and the main steam pressure change can be suppressed. The subtractor 54, dead zone setter 55A and PI controller 61 constitute a steam bypass flow rate adjusting means.
[0049]
On the other hand, the PI controller 56 performs PI calculation on the input deviation, and generates a signal (second main steam valve opening signal) for controlling the opening of the main steam valve 18 so that the deviation becomes zero, This signal is input to the low value selector 42 and the function setter 57.
[0050]
The output of the PI controller 56 (second main steam valve opening signal) input to the low value selector 42 is compared with the output from the adder 40 (first main steam valve opening signal). The lower one is input to the switch 43. The switch 43 is turned on by load follow mode selection (mode when MWD fluctuates), and outputs a signal from the low value selector 42 as an opening signal of the main steam valve 18. On the other hand, when the switch 43 is off, the full opening degree signal preset in the constant setting unit 44 is output from the switch 43 as the opening signal of the main steam valve 18. With the above processing, the output of the steam turbine 5 can be increased while suppressing the fluctuation of the generated steam pressure in the exhaust heat recovery apparatus 10 when the load changes. Further, when the load of the entire plant follows the MWD and the generated gas composition value in the gasifier 7 is stable, the main steam valve 18 can be fully opened by canceling the load following mode selection. .
[0051]
Therefore, the main steam valve opening is determined by subtractor 38, PI controller 39, adder 40, function setter 41, low value selector 42, function setter 53, subtractor 54, dead zone setter 55, and PI controller 56. Is adjusted by a main steam valve opening adjusting means constituted by: a constant setter 44 as an opening restricting means; and a switch 43 as a switching means.
[0052]
The output of the PI controller 56 input to the function setting unit 57 is converted into a coal supply amount by the function setting unit 57 and transmitted to the adder 58. The PI controller 48, to which the deviation between the set value of the gasifier outlet pressure and the detected value is input, calculates the deviation PI and transmits it to the adder 49 as a correction value of the coal supply amount. Since the output of the adder 35 is also input to the adder 49, the output of the adder 35 and the output of the PI controller 48 are added by the adder 49, and the output of the adder 49 is further input to the adder 58. Is done. The adder 58 adds the input (correction value) from the adder 49 and the input (coal supply amount) from the function setting unit 57 and inputs the result to the + side of the subtractor 59. The subtractor 59 subtracts the coal supply amount from the coal supply amount detector 26 input to the − side input from the output of the adder 58 input to the + side, and the obtained deviation is supplied to the PI controller 60. input. The PI controller 60 performs PI calculation on the input deviation, and generates and outputs an opening signal for controlling the opening of the coal supply valve 21 connected to the bunker 6 so that the deviation becomes zero. The adder 58, the subtractor 59, and the PI controller 60 constitute supply coal amount adjusting means. By the above processing, the plant output can be set to a predetermined value when the MWD changes.
[0053]
In the function setting unit 62, an optimum value of the oxidant supply amount with respect to the amount of coal supplied to the gasifier 7 (coal supply amount corresponding to MWD) is set in advance, and the oxidant supply amount set value is input with MWD as an input. Output. The outputted oxidant supply amount set value becomes the + side input of the subtractor 63, and the subtracter 63 subtracts the output of the oxidant supply amount detector 27 inputted to the − side from the oxidant supply amount set value. The obtained deviation is transmitted to the PI controller 64. The PI controller 64 performs a proportional integral operation on the input deviation, generates a signal for controlling the opening degree of the oxidant supply valve 22 so that the deviation becomes zero, and outputs the signal to the adder 65 as a valve opening degree signal. . The opening signal of the coal supply valve 21 output from the PI controller 60 is input to the adder 65 as a correction value, and the opening signal for the oxidant supply valve 22 input to the adder 65 is the coal opening signal. The opening signal of the supply valve 21 is added and corrected, and then output to the oxidant supply valve 22. By the above processing, an appropriate amount of oxidant can be introduced in accordance with fluctuations in the amount of coal supplied to the gasification furnace 7, and the gasification reaction in the gasification furnace 7 can be stabilized. The subtractor 63 and the PI controller 64 constitute an oxidant supply amount adjusting means.
[0054]
As described above, according to the above embodiment, in the control of the coal gasification combined power plant, the time delay until the coal is input into the gasification furnace, converted into purified gas and reaches the gas turbine combustor. The load follow-up delay due to can be reduced by performing the steam turbine load change in advance. Also, at the time of load following, the operation of the gas turbine fuel flow control valve before the increase in the amount of purified gas from the gasifier is eliminated, and the sensible heat held by the gas from the gasifier is directly converted into steam by the heat recovery boiler. By recovering heat, fluctuations in gas pressure and gasifier pressure can be suppressed.
[0055]
Further, by performing the bypass operation of the purified gas only when the gas turbine trips or when the load fluctuates, it is possible to suppress a reduction in gas turbine output during normal operation.
[0056]
【The invention's effect】
According to the present invention, in the control of a coal gasification combined power plant, the delay in load following due to the time delay until the coal is input into the gasification furnace, converted into purified gas and reaches the gas turbine combustor, It can be corrected by performing the turbine load change in advance. Also, According to another invention, By eliminating the operation of the gas turbine fuel flow adjustment valve before the increase in the amount of purified gas from the gasifier during load following, the sensible heat held by the gas from the gasifier is directly recovered as steam, Variations in gas pressure and gasifier pressure can be suppressed.
[Brief description of the drawings]
FIG. 1 is a system diagram showing a main configuration of a combined coal gasification combined power plant according to an embodiment of the present invention.
FIG. 2 is a control system diagram showing a main configuration of an operation control apparatus according to an embodiment of the present invention.
[Explanation of symbols]
1 Entrance guide wing
2 Compressor
3 Combustors
4 Turbine
5 Steam turbine
6 Bunker
7 Gasification facilities
8 Heat recovery boiler
9 Gas purification equipment
10 Waste heat recovery device
11 Condenser
12 Gas turbine generator
13 Steam turbine generator
14 Steam separator
15 Water supply pump
16 Pressure regulating valve
17 Flow control valve
18 Main steam valve
19 Bypass valve
20 Water supply pump
21 Coal supply valve
22 Oxidant supply valve
23 Gas turbine bypass piping
24 Gas turbine bypass valve
25 Purified gas combustion equipment
26 Coal supply detector
27 Oxidant supply amount detector
28 Generated gas outlet pressure detector
29 Main steam pressure detector
30 Gas turbine output detector
31 Steam turbine output detector
32 Gas turbine output setting device
33, 38, 47, 54, 59, 63 Subtractor
34, 39, 45, 48, 56, 60, 61, 64 PI controller
35, 40, 49, 58, 65 Adder
36, 41, 46, 51, 53, 57, 62 Function setter
37 Steam turbine output setting device
42 Low value selector
43, 52 switch
44 Constant setter
50, 55, 55A Dead band setting device
66, 72, 73, 74 pipeline
67 Purified gas supply line
68 Exhaust pipe
69, 75 Steam pipe
70 Steam bypass pipe
71 Water supply pipe
76 Combustion gas line

Claims (7)

Gasification equipment for generating coal by gasifying coal to generate steam using generated heat, and a refined gas that is disposed connected to the gasification equipment to remove unnecessary substances in the crude gas A gas refining facility, a gas turbine connected to the gas refining facility through fuel gas piping and using the purified gas as fuel, and an exhaust gas disposed connected to the gas turbine and discharged from the gas turbine In a coal gasification combined power plant comprising: an exhaust heat recovery device that generates steam using, and a steam turbine that uses steam generated by the gasification facility and the exhaust heat recovery device as a power source,
A gas turbine bypass pipe that is branched from the fuel gas pipe and includes a gas turbine bypass valve capable of adjusting a flow rate; a purified gas combustion apparatus that burns the purified gas that flows through the gas turbine bypass pipe; and the purified gas combustion Combustion gas pipes communicating the combustion gas outlet side of the apparatus and the exhaust gas inlet side of the exhaust heat recovery device are provided ,
A control device for controlling an opening degree of the gas turbine bypass valve, wherein the control device sets a deviation between an output of the steam turbine and an output command value of the steam turbine, which is varied according to plant load fluctuation, to zero; The coal gasification combined power plant characterized by controlling the opening degree of the gas turbine bypass valve . Gasification equipment for generating coal by gasifying coal to generate steam using generated heat, and a refined gas that is disposed connected to the gasification equipment to remove unnecessary substances in the crude gas A gas refining facility, a gas turbine connected to the gas refining facility through fuel gas piping and using the purified gas as fuel, and an exhaust gas disposed connected to the gas turbine and discharged from the gas turbine An exhaust heat recovery device that generates steam using the steam, a steam turbine that is generated by the gasification facility and the exhaust heat recovery device and is supplied via a main steam valve as a power source, the gasification facility, and the A steam bypass pipe connecting a pipe for guiding steam generated by the exhaust heat recovery device to the steam turbine to a condenser of the steam turbine via a flow rate adjusting valve; and a valve on the purified gas outlet side of the gas purification facility. Contact And a purified gas combustion device for burning purified gas, and a combined gasification combined cycle power generation system comprising: a combustion gas outlet side of the purified gas combustion device and an exhaust gas inlet side of the exhaust heat recovery device. In the operation control device that controls the operation of the plant based on the plant load command value,
Load command distribution means for distributing the plant load command value to the gas turbine load command value and the steam turbine load command value;
Fuel flow adjustment opening adjustment means for adjusting the fuel flow adjustment opening of the gas turbine so that the difference between the actual output of the gas turbine and the gas turbine load command value is 0;
A first main steam valve opening signal for adjusting a main steam valve opening of the steam turbine so that a difference between the actual output of the steam turbine and the steam turbine load command value is zero; A second main steam valve opening signal that adjusts the main steam valve opening of the steam turbine so that the difference between the steam pressure and the set value of the inlet main steam pressure with the plant load command value as an argument is zero; Main steam valve opening degree adjusting means for adjusting the main steam valve opening degree by value selection;
The amount of coal supplied to the gasification facility is adjusted so that the difference between the actual pressure of the crude gas at the crude gas outlet of the gasification facility and the set value of the crude gas outlet pressure using the plant load command value as an argument is zero. A signal that is corrected based on the output signal of the fuel flow control valve opening adjusting means and a signal that is generated based on the second main steam valve opening signal and that adjusts the amount of coal supplied to the gasification facility And a supply coal amount adjusting means for adjusting the supply coal amount to the gasification facility from
Oxidant supply amount adjustment that adjusts the oxidant supply valve opening so that the difference between the actual supply oxidant amount to the gasification facility and the oxidant supply amount setting value with the plant load command value as an argument is zero Means,
When the crude gas actual pressure is larger than the crude gas outlet pressure set value, the amount of purified gas bypass introduced from the gas purification facility to the purified gas combustion device is increased, and the crude gas actual pressure is increased to the crude gas outlet. A purified gas bypass amount adjusting means for reducing the purified gas bypass amount when the pressure setting value is smaller,
When the inlet main steam pressure is larger than the inlet main steam pressure set value, an opening of a flow rate adjustment valve interposed in a steam bypass pipe that directly vents steam from the exhaust heat recovery device to the steam turbine condenser is performed. A steam bypass flow rate adjusting means for increasing the degree,
An operation control device for a combined coal gasification combined cycle plant.   3. The operation control apparatus for a coal gasification combined cycle plant according to claim 2, wherein the main steam valve opening degree adjusting means is configured to open the main steam valve opening degree when the main steam pressure is lower than a predetermined pressure. An operation control device for a combined coal gasification combined power plant, characterized in that a degree regulating means is added.   The operation control apparatus for a coal gasification combined cycle power plant according to claim 2, wherein the opening control means for outputting a signal for making the main steam valve opening constant, and the main control valve in the case of operation for improving load following performance. Switching means for controlling the opening degree of the main steam valve by the output of the opening degree regulating means when performing the opening degree control of the main steam valve by the output of the steam valve opening degree adjusting means and operating at the maximum power generation efficiency. An operation control apparatus for a combined coal gasification combined power plant.   5. The operation control apparatus for a coal gasification combined power plant according to any one of claims 2 to 4, wherein the refined gas bypass amount adjusting means sets in advance a difference between the crude gas actual pressure and the crude gas outlet pressure set value. An operation control device for a combined coal gasification combined power plant, wherein the purified gas bypass amount is increased or decreased when the allowable value is exceeded.   The operation control apparatus for a coal gasification combined power plant according to any one of claims 2 to 5, wherein the steam bypass flow rate adjusting means is configured such that the inlet main steam pressure exceeds an allowable value than an inlet main steam pressure set value. An operation control device for a combined coal gasification combined cycle plant that increases the opening degree of a flow rate adjustment valve interposed in a steam bypass pipe when it is large.   The operation control apparatus for a coal gasification combined cycle plant according to any one of claims 2 to 6, wherein the refined gas bypass amount adjusting means is configured to supply the steam turbine load command value and the actual output of the steam turbine when the load changes. An operation control device for a combined coal gasification combined power plant, characterized in that a bypass gas amount adjusting means for adjusting the purified gas bypass amount is added so that the difference between the two is zero.

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