PL152729B1 - Method of controlling operation of a power unit - Google Patents

Description

PATENT DESCRIPTION

Additional patent to patent no. - Pending: 8? 04 06 (P.

Priority ^{* 1}

265055)

152 729

Int. Cl. ⁵ F23N 5/00 G05D 7/03 F22B 35/00 F24B 9/00

Application announced: 88

The patent description was published:

here at LIlK ttiUH

1991 07 31

Creators of the invention: Diter Ochot, Zdzisław Szymoniak, Leszek Skrzypek,

Klemens Ścierski, Henryk Tymowskk, Janusz Sajkowski,

Janusz Tchórz

Authorized by the patent: Southern Energy District ^^ i; oiS <^^ - ^ l.ekti ^ owtn.a, Łaziska Łaziska Górne (Poland), PrzedsiębiorstwoθSsra Państwowe Energorozruch,

Gliwice (Poland)

THE METHOD OF CONTROLLING THE ENERGY BLOCK

The subject of the invention is a method of controlling a power unit with a step change of the unit's output power, especially with a signal of automatic regulation of frequency and power AROM. The invention relates to an energy block consisting of coal feeders, coal mills, especially with ventilators, a furnace, a steam generator, a steam turbine and an electric generator equipped with a load regulation system, which includes a power and fresh steam pressure regulation system.

The method of controlling a power unit known from the Polish patent specification No. 118,919 with a step change of the set power consists in a step change in the amount of coal supplied to coal mills. The known method consists in creating a step signal controlling the amount of coal supplied to the mills, wherein the signal is the sum of two signals. The first is made of a signal showing the current state of steam pressure in the steam generator and a signal corresponding to a given value of the step change in the input electric power of the generator. The signal formed in this way coincides in the adder with the second signal, which is created by differentiating the first signal twice. According to Patent Specification No. 118,919, the first of these signals hypothetically changes in the first chiwii to a certain value, and then increases the lintswt for the delay period of the object's response. On the other hand, the second signal, which was repeated by the double differentiation of the first, hypothetically according to description No. 118 919 increases in the first moment abruptly, and then maae to zero in the period of the object's response delay. The sum of these signals creates, at the output from the aforementioned adder, a signal affecting the carbon feeds, which signal increases abruptly in the first moment, and then, for the period of delay of the object's reaction, it maintains a constant value determining the feed of carbon, much greater than the amount of carbon necessary to obtain the set increased power. This signal after the delay period of the maaeje object's reaction to the value that determines the amount of coal supplied to the coal mill in order to obtain the given target

152 729

152,729 of increased power output. The known method assumes that the sudden increase in power demand is initially satisfied with the heat stored in the steam generator.

The automatic load control system known from the Polish patent description No. 142 413 introduces the dependence of the set pressure on the load.

The disadvantage of the methods and systems known from the patent descriptions No. 118 919 and 142 413 results from the failure to take into account the delay that occurs in the supply of coal to the furnace and from the need to use the heat accumulated in the pore generator in the first place. The almost instantaneous change in the amount of coal supplied by the boilers, with the change of power, means that a long time elapses before the coal reaches the furnace through the mills and gives off heat to the water in the steam generator. During this time, however, the control system will cause the valve in the steam line to the turbine to open too much, and this will cause a drop and a sudden drop in steam pressure also in the steam generator. These changes induce further reaction of the system and regulation, generating an extended period of thermal imbalance of the unit and disturbances in the quality of the generated electricity. This limits the control range of the unit control power to approx. 6% of the nominal power. A further disadvantage of the above-mentioned solutions is that they have the same effect both when changing the setpoints and when disturbing the steam generator. Correctly operating at a change of the setpoint, known solutions erroneously influence the disturbances repeatedly aggravating the initial stage of the disturbance. This has a negative effect on the service life of the steam generator and turbine.

The objectives of the invention are such a control of the power unit that, at a short period of thermal imbalance of the unit, the desired large and fast power change is achieved, and in the event of disturbances in the steam generator, it is prevented from rapid changes in parameters of short term imbalances

This aim has been achieved with the control method according to the invention, which consists in switching off the operation of the constant power control system of the generator or only its dynamic elements when the output power of the generator is subjected to a stepwise increase. At the same time, the efficiency of the mine fan changes by the part of its regiHation range corresponding to the relative power change. Along with this, the amount of coal supplied to the coal mill becomes colder by an amount not less than 1.5 times the amount of coal necessary to obtain an increase in the electric generator power according to a new stepwise input power, and then this excess amount of coal gradually decreases to zero. After the time needed to obtain at least 60% of the set change in heat input of the steam generator, the operation of the power regulator is restarted, or its dynamic indications, the step impulse of change of the set power simultaneously affects the turbine control valves to such an extent that immediately no later than within 10 seconds to reach the set power and maintain it until the thermal equilibrium of the block is achieved.

The method of control according to the method is characterized in that the increase in the quality of the coal supplied to the mill is increased by 1.5 times, exceeding the necessary increase for generating energy of the newly set value, and decays with a time constant> t - t _Q. Control of the process is performed such that the change in power acts on the turbine control valves in such a way that the entire adjusting range block to provide a three-- Maiia algorithm P P _T = _N - K · An, where

P - P o <K <—ϊί-—, gazees

ΔΝ

P _T is the value of the desired pressure ahead of the turbine as a function of power, P _N is the nominal pressure, · Pp - pressure upstream of the turbine at minimum control power j, Kmin "in skid work, which can be read from the graph as the intersection of the S line with the ordinate axis. The K coefficient is assumed according to is ^ 0 [m ^] ^^; ΐ of the relationship. ΔΝ is the control range, ^part lived ΔΝ ^N jj - ^Ν _η ^ _. ·

Due to the methods according to the invention, at the moment of changing the value of the set power, the increased speed of the fan and the interaction with the coal mill causes rapid delivery of an additional portion of coal dust to the furnace. This additional amount of dust is derived from the accumulation of the coal mill. This has the additional effect that the emptied mill will receive an increased carbon axis, which will be supplied by the coal feeder without causing the phenomenon of damping of the mill fan blower. Otherwise, the additional amount of coal contained in mi ^: ni-e will dampen the blast of the fan and thus extend the period of reaching the increased amount of coal to the burners, i.e. it will extend the period of energetic instability of the unit. Tc fast delivery of additional coal to the burners will prevent excessive pressure change in the steam generator. The power control system or its dynamical members turned off at that time allow for changes in the amount of coal supplied by the feeders in amounts according to the method, but deviating from the amounts that would be provided by the ARCM power control system. The point is therefore that the regulator adapted to operate in the event of a disturbance inside the steam generator is switched off for a certain period of time, and the power unit is controlled by a regulator adapted to large step changes in power. External disturbances are eliminated by the power regulator, which has appropriately selected settings influencing the amount of coal supplied to the furnace. In turn, the dependence of the steam pressure on the power of the unit causes the pressure in the steam generator to change during the variations, and thus the energy accumulated in the steam generator is given up or taken away. This energy softens the rate of change of thermal parameters of the block. The control method according to the invention thus ensures a very stable operation with the possibility of achieving a very fast control power. The use of such fast ARCM regulating power will definitely improve the stability of the energy system.

An example of the method application is described using the lines, in which Fig. 1 shows a step change in the set power, Fig. 2 - a change in the amount of black coal supplied to the mill, Fig. 3 - the change in the efficiency of the ventilator, Fig. 4 - shows the times of switching on the power regulator, and Fig. 5 - the power curve of the block, and Fig. 6 shows the power curve with disturbances inside the steam generator, and Fig. 7 - pressure crossover before the turbine in During the disturbance according to Fig. 6, Fig. 8 - changes in steam pressure upstream of the turbine as a function of power.

The original signal M1 caused the electric generator to have an escape power ET, which is obtained by supplying the amount of W1 per time unit by the coal feeder. The coal from the coal mill is supplied to the furnace with air supplied to the mill in the amount of P1 per unit time. Due to the feedbacks and the power system, the output power E1 is kept constant. The tendency of the energy block to change the input power value E1 is prevented by the power control circuit. When, for example, the calorific value of coal has cooled down and the output power E1 begins to decrease, the regdation system causes the amount of carbon W1 to increase to compensate for the shortage of thermal energy. The control system is able to maintain the value of the output power E1 within + 1%.

When the order to increase the output energy of the generator is sent from outside to the power unit, step by step to E2, i.e. E2 - E1 = E, this is done by introducing the signal M2 and M1 + ΔΜ into the control system, where ΔΜ corresponds to the change in the output power E, by more than 3%. According to the method, the signal M2, which appeared in the οίΝίϋ, causes the combination of the operation of the power regulator, or only its dytcmicztyoh steps, as shown in Fig. 4. At the same time, the signal M2 causes that the regulating circuit causes an increase in efficiency by a large amount. ΔΡ. The value ΔΡ corresponds to the increase of the amount of blown air corresponding to the part of the fan regulation range that corresponds to the change of the signal Μ1 by ΔΜ. This sudden change in the amount of air blown causes the air to blow out of the coal mill not only the amount W1 of coal as before, but to carry away additional amounts of dust that has so far remained in the mill.

this one reaches the furnace in a short time, providing additional heat energy. At this time, the carbon dioxide gas starts to provide an increased amount of carbon, namely the amount of carbon W1 + 1.5 (AW). The carbon gain AW is the difference between the amount of carbon W2 required to obtain the output power E2 of the electric generator, and the amount W1 of carbon supplied prior to the appearance of the signal M2. So the mill will receive an increased amount of carbon by 1.5 (AW) in a moment. However, the surplus decreases with time so that in ώηϋ! t was already Δ W. Due to the earlier sudden increase in the amount of air from P1 to P1 + ΔΡ, the larger amount of W1 + 1.5 (Δ>) coal flows into the previously emptied mill. It is a temporary early discharge of dust from the mill that prevents the unfavorable4

152 729 mu of the phenomenon, which consists in the momentary suppression of the blast in the mill by the temporary overflow of this place.

Sudden blowing into the furnace at the moment of additional amount of coal and then increasing the amount of coal supplied to the mill causes the increase of the output electric power of the generator from the value of E1 to the value of E2. When the increase in the value of the output power reaches at least 0.6 ΔΕ in the value t, the power regulator or its dynamic elements are turned on again, which starts to control the further increase of the output power E to the given importance E2 by the signal M2.

Fig. 8 shows a plot where power N is indicated on the abscissa and the vapor pressure upstream of the turbine P is indicated on the ordinate axis. A point is marked on the plot for the nominal power N ^ and the nominal pressure Pj. This point defines a regulation area limited on the other hand by the nominal control power Nmin, located at the beginning of the system. The course of changes S is the change that occurs with a slippery block, that is, when the steam control valves remain unchanged in their degree of opening. Line S shows the course during which we influence the process by changing the opening of the steam valve. It is advantageous when the power is changed so that the control valves of the turbine, i.e. the steam valve, are influenced in such a way as to achieve the allegorism in the entire steam regulation range.

P _T »Pn - K · ΔΝ, o <K <~ ^P P ^from ,

ΔΝ where P _T is the value of the desired upstream pressure as a function of power, Pn is the nominal pressure, Pp - the pressure at the turbine at minimum control power,

Nmin - for skid work, which can be read from the diagram as the intersection of line 5 with the ordinate axis. The coefficient K is assumed according to the coefficient of known dependence. ΔΝ denotes the control range, ie ΔΝ »N ^ - Nmin.

Claims (3)

Patent claims 1. The method of controlling the power unit with a step change of power, especially with the automatic frequency and power control system, which consists of coal feeders for mills, especially with fans of the steam generator furnace, steam turbine and electric generator, and equipped with an automatic load control and pressure control system in front of the turbine, affecting the turbine control valves and the power regulator influencing the amount of fuel, characterized in that in the step change of the set power of the block, the operation of the power control system, in particular its dynamic elements, is switched off and at the same time the efficiency of the mill fan changes by a part of its range corresponding to its rules relative change of 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 size of the new task, the excess amount of coal will then become zero, and after time the pot required to achieve a heat change of at least 60%, the operation of the power control system is enabled. 2. The control method according to p. The method of claim 1, characterized in that 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 - to 3. The control method according to p. 1, characterized by the fact that the turbine control valves are influenced during the power change in such a way as to ensure compliance with the Pt = - K · ΔΝ algorithm in the entire control range of the block, where: P _w ~ o <κ <—2—- ^E f ΔΝ where Pt is the value of the desired upstream pressure as a function of power, P ^ is the pressure German 152,729 nominal, Pp - pressure before the turbine at minimum control power, Nnin - for skid work, which can be read from w ^ ssu as the intersection of the S line with the ordinate, where the coefficient K is taken according to the aforementioned relationship, and ΔΝ denotes the control range, i.e. ΔΝ = - N ^^ n * Fig. 6 152 729 Department of Publishing of the UP RP. Circulation 100 copies Price: PLN 3,000