PL164363B1 - The method and system of control of the power unit - Google Patents

Abstract

1. Method and system for controlling a power unit, with a step-set change in power by an automatic frequency and power control signal - ARCM, in which the efficiency of the mill fan is changed by a part of its regulation range corresponding to a relative change in the set power and at the same time the amount of coal supplied to the coal mill is changed by an amount exceeding the amount necessary to generate energy in the newly set value, and then this surplus amount of coal is gradually reduced, characterized in that at the moment of a step-set change in the set power of the unit, the set steam pressure before the turbine is changed so that the change in the generator power for a period shorter than 2 minutes does not exceed 0.5 MW, at the same time the amount of air to the steam generator and the amount of exhaust gases discharged from the steam generator are changed by a part of the regulation range corresponding to a relative change in the set power of the unit for a period shorter than 2 minutes.

Description

The subject of the invention is a method and system for controlling a power unit with a boiler equipped with corner dust burners, intended for the automatic load control system of a power unit controlled by a set signal of automatic frequency and power control - ARCM. The block load control system includes the power control system, fresh steam pressure control in front of the turbine, oxygen content control in the exhaust gas and vacuum in the combustion chamber.

The known method of controlling a power unit from the Polish patent description No. 152729, with a step change in power, especially with an automatic frequency and power control system, where the block consists of coal feeders, coal mills, especially with fans of the steam generator furnace, steam turbine and electric generator. The power unit is equipped with an automatic load control system, upstream pressure control that affects the turbine control valves, and a power regulator that affects the amount of fuel.

The method of controlling the power unit is based on the fact that at the moment of a step change in the power unit's set power, the operation of the power control system, in particular its dynamic elements, is turned off, and at the same time the efficiency of the mill fan changes by a part of its adjustment range corresponding to the relative change in the set power, at the same time changing the amount of coal supplied to the coal mill by an amount exceeding the amount necessary to generate energy in the newly set value, the excess amount of coal is then reduced to zero, and after the time needed to achieve at least 60% of the heat change, the operation of the control system is activated

164,363 power. The increase in the amount of coal supplied to the mill increases by 1.5 times, exceeding the necessary increase for energy production of the newly set value, and disappears with the time constant Td> t-t0. When the power is changed, the control valves of the turbine are influenced in such a way as to ensure compliance with the specified algorithm in the entire control range of the block.

The known power unit control system from Polish Patent No. 156003, which implements the method known from Polish Patent No. 152729, consists in parallel connection of the inputs of the power regulator and the fast power change regulator with the output of the power generator. The output of the power regulator and the quick-change power regulator combine in the power control summation node, which, with the output signal, affects the coal feeder, the power control controller takes a differentiated signal from the power setter, and one removal of the said driver affects the mill fan, and the second output is coupled with the input of the power regulator. In addition, the power controller has an input to receive a signal about the power output status of the electric power unit generator. Said power control controller comprises a polarized relay driven by a differential signal variation, and through the contacts of the timer relays it generates control signals, respectively, of the power regulator and the steering apparatus of the mill fan. In a particular embodiment, said power change control controller is connected to an output of the fast dial controller from where it receives a differential power change signal.

A known method and system for controlling a power unit that does not ensure the required rate of power changes at a given step signal from the automatic frequency and power control system, in particular for the sides with the OP-215 boiler, while the forced change of the block output power is associated with high costs, because in the state of dynamic, the efficiency of the dynamic cycle is definitely deteriorating.

The essence of the invention in the field of power unit control system consists in the fact that at the moment of a step change of the set power of the unit, the set pressure of the steam in front of the turbine changes so that the change in the generator power for less than 2 minutes does not exceed 0.5 MW, at the same time the amount of the air directed to the steam generator and the amount of exhaust gas discharged from the steam generator by the part of the control range corresponding to the relative change in the set power of the unit for a time shorter than 2 minutes.

The essence of the invention in the field of the power unit control system consists in the fact that the output of the system generating the power unit set power signal is connected to a non-linear element, to the output of which is connected a steam regulator upstream of the turbine, and also a regulator of oxygen content in the exhaust gas and a vacuum regulator in the furnace chamber.

The non-linear element contains a limiting circuit, the output of which is connected to the input of the pulse distributor, the outputs of which are connected to a steam regulator upstream of the turbine, a regulator of oxygen content in the exhaust gas and a vacuum regulator in the combustion chamber. The shaper consists of a proportional and derivative element connected in parallel, the outputs of both elements being summed at the summation node.

Thanks to the method according to the invention, when the value of the set power is changed, the flame core in the furnace chamber is immediately raised by changing the exhaust gas velocity in the furnace chamber resulting from increasing the efficiency of the blast fan and the draft fan, the amount of coal dust to the furnace chamber is quickly changed by increasing the amount of primary air to mills forming part of the air stream downstream of the blast fan, and preparing high-pressure control valves to regulate the steam pressure upstream of the turbine in accordance with the characteristics of the controlled slip. This ensures that the unit's power is increased by about 0.5 MW for a period shorter than 2 minutes. After this time, the amount of coal dust fed to the combustion chamber increases significantly, and therefore the power of the block increases to the value resulting from the set power of the block, and it is set at the set value within no more than 4 minutes.

The system according to the invention ensures, above all, a quick change of the block output power with a step change of the block set power. The state of the steady-state real power with a step change of the set power is obtained within 4 minutes, while the gradient of the increase of steam pressure upstream of the turbine does not exceed 0.025 MPa per minute. The oxygen content in the exhaust gas does not exceed 4%

164,363 by volume, and the vacuum is maintained at 3mm ± 10%. Moreover, the efficiency of the thermodynamic cycle practically does not change in the dynamic state.

The invention will be explained in more detail in the embodiment shown in the drawing, which is a schematic diagram of a power unit control system.

The signal Y0, which is a five-level representation of the power unit's set power, is fed to the galvanic separator 1 and then to the forming system 2 with a proportional-differentiating characteristic. The output of the forming system 2 is led to the input of the non-linear element composed of the up-down limiter 3 and the pulse splitter 4, the limiter 3 being set in such a way that the saturation of the formed pulse Yo is not less than 40 sec. Three independent outputs of the impulse distributor system 4 are led parallel to the inputs of the steam pressure regulator upstream of the turbine 5, the oxygen content regulator in the exhaust gas 6 and the vacuum regulator in the combustion chamber 7.

The leading signal of pressure regulator 5 is the steam pressure before the turbine Prz, while the instantaneous power of the block Nrz is a correction signal, and Wz is the setpoint of the pressure regulator 5. The pressure regulator 5 on the output side has an ignition switch for switching automatic or manual control, the output itself connected it is provided with an actuator 8 which enables the correct rotation of the actuator 9 in automatic operation. The task of the pressure control system upstream of the turbine is to maintain an appropriate pressure at the turbine inlet, and the shaped Yo signal causes a momentary increase in pressure in a dynamic state when the power set for the power unit is decreased or the pressure is temporarily dropped when the power unit set power increases. The above operation enables a quick change of the block output power with a stepwise change of the block set power.

The leading signal of the oxygen content controller in the exhaust gas 6 is the oxygen content in the exhaust gas O2 before the water heater, while the instantaneous power of the Nrz block is a correction signal, and W _z is the set point of the oxygen content controller in the exhaust gas 6. The oxygen content controller in the exhaust gas 6 from the side of the output to the ignition switch for switching automatic or manual control, the output itself is connected to the actuator 10. The task of the exhaust gas oxygen control system is to maintain the appropriate value of the oxygen content in the exhaust gas, while the shaped Yo signal causes a momentary increase in a dynamic state amount of air to the boiler with an increase in the set power of the unit For a simultaneous increase in the amount of coal to the mills, the increase in the amount of air increases the amount of air passing through the coal mills, and thus the amount of fuel fed to the furnace chamber increases. This causes a rapid change in the power unit output power. In the case of lowering Yo, the amount of air to the boiler is reduced, and thus the amount of air to the coal mills, which reduces the amount of fuel supplied to the combustion chamber and the block output power is quickly reduced.

The leading signal of the vacuum regulator in the furnace chamber 7 is the vacuum value AP, and W _with the setpoint value of the regulator 7, while the vacuum regulator in the furnace chamber 7 on the output side has an ignition switch for automatic or manual control, while the output itself is connected to the actuator 11. The formed forcing signal Yo fed to the regulator 7 stabilizes the negative pressure in the dynamic state.

The method of controlling the power unit according to the invention consists in changing the set steam pressure in front of the turbine at the moment of imposing a stepwise increased output power of the generator in such a way that the change of the generator power for a time shorter than 2 minutes does not exceed about 0.5 MW. At the same time, the efficiency of the blast fan and the exhaust fan changes by a part of the adjustment range corresponding to the relative change of the power unit's preset power for a time shorter than 2 minutes. Along with this, the amount of coal supplied to the coal mill varies by no more than 1.5 times the amount of coal necessary to obtain an increase in the electric power of the generator, according to a new stepwise output power, and then this excess amount of coal returns to zero after 1 minute .

164 363

The control of the power unit is such that with a stepwise set power of the unit in less than 4 minutes, a full change of the actual power of the generator is achieved with practically unchanged efficiency of the thermodynamic cycle of the boiler and the turbine in the dynamic state.

The technical solutions according to the invention are intended for power units, in particular with boilers equipped with corner dust burners.

Publishing Department of the UP RP. Circulation of 90 copies

Price: PLN 10,000

Claims (4)

Patent claims 1. The method and system for controlling a power unit, with a stepwise change of power with the signal of automatic frequency and power control - ARCM, in which the efficiency of the mill fan changes by a part of its regulation range corresponding to the relative change of the set power and at the same time the amount of coal supplied to the coal mill changes by an amount exceeding the amount necessary to generate energy in the newly set value, and then this surplus amount of coal is gradually reduced, characterized in that at the moment of a step change of the set power of the block, the set vapor pressure in front of the turbine changes so that the generator power change for a time shorter than 2 minutes does not exceed 0.5 MW, at the same time the amount of air to the steam generator and the amount of exhaust gases discharged from the steam generator change by a part of the control range corresponding to the relative change of the set power of the unit for a time shorter than 2 minutes. 2. Power block control system, with a step change of the block output power, especially with the signal of automatic frequency and power control - ARCM, which power block includes a furnace, work generator, steam turbine and electric generator, and is equipped with automatic block and pressure control systems steam upstream of the turbine, oxygen content in exhaust gas, vacuum in the furnace chamber, characterized in that the output of the forming system (2), the block power signal is connected to a non-linear element (3 and 4), to the output of which is connected the steam regulator upstream of the turbine ( 5) and also the regulator of the oxygen content in the exhaust gas (6) and the regulator of the vacuum in the combustion chamber (7). 3. The control system according to claim 2. A method according to claim 2, characterized in that the non-linear element comprises a limiting circuit (3), the output of which is connected to the input of the pulse distributor (4), the outputs of which are connected to a steam regulator upstream of the turbine (5), an oxygen content regulator in the exhaust gas (6) and the vacuum regulator in the combustion chamber (7). 4. The control system as claimed in claim A method as claimed in claim 2, characterized in that the shaping system (2) consists of a proportional and a derivative element connected in parallel, the outputs of both elements being summed in the summation node.