SU1125393A1 - Method of starting cold and non-cooled electric power station power unit - Google Patents

Abstract

A METHOD FOR STARTING FROM A COLD AND UNCLEANING STATE OF THE ELECTRIC POWER UNIT, having a station-wide auxiliary steam line, including supplying fuel and feed water to the boiler, supplying adjustable temperature to the turbine seals, applying a vacuum to a condenser, discharging a part of a heated tubing. steam in the flow part of the turbine and synchronization of the turbogenerator, characterized in that, in order to increase the efficiency, the turbine compaction and the general station highway b a pair of their own needs serves a part of the steam produced in the boiler, after which they begin to set the vacuum in the condenser.

Description

ABOUT

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9 The invention relates to the operation of the power units of power plants and can be used to improve their starting conditions. There is a method of starting a non-block steam boiler by supplying fuel and feedwater, discharging increasing parameters from the steam line until steam is supplied to the general station, in accordance with which the boiler is heated during the initial period and increases to a pressure slightly higher than in the public highway, after which steam from the boiler is fed to the latter) J However, when the power unit is started up, this method cannot be used, since it does not provide sufficient reliability and efficiency of equipment. i The closest in technical essence to the invention is the method of starting from the cold and unsatisfactory states of the power unit of the power station having its own station station own steam, including the supply of fuel and feed water to the boiler, the flow of steam at a controlled temperature to the turbine seals, a set of vacuum in the condenser, the discharge of a part of the superheated steam, along with the turbines to the deaerator, the subsequent supply of steam to the flow part of the turbine, and the synchronization of the turbogenerator 2. The disadvantages of the known starting method include Its relatively low efficiency, which is explained by the fact that the heat produced in the steam boiler, sent to the steam lines for heating, is not used. In addition, for quite a long time, incl. until the fuel is supplied to the boiler, energy and steam from the extraneous source is consumed. The aim of the invention is to improve the economy. The goal is achieved by the fact that, according to the method, from the cold and non-elapsed states of starting the power unit of the power plant, it has its own station-wide steam line, which includes the supply of fuel and feed water to the boiler. 932. supply of steam with adjustable temperature to turbine seals, vacuum set in a condenser, discharge of a part of produced steam in addition to the turbine to the deaerator, subsequent steam supply to the flow part of the turbine and synchronization of the turbogenerator, to the turbine seal and to the general station main steam of own needs serves part of the boiler in the boiler steam, then begin to set the vacuum in the condenser. FIG. 1 is a diagram of a block with a drum boiler, realizing the proposed method; in fig. 2 - block diagram with a flow boiler. The power unit (Figs. 1 and 2) contains a boiler 1 connected by a steam line 2 to a high pressure cylinder 3 (HPC) of the turbine, the exhaust of which is connected to the cold industrial steam line 4. The steam line 5 of the hot reheat is connected to the medium pressure cylinder 6 (DCP) connected to the condenser 7. Between the steam lines 2 and 4, a reduction and cooling unit (DOC) is turned on .8. Other DOCs are included in the block diagram: 9 - between the steam line 5 and the condenser 7 (Fig. 1); 10 - between the steam line 2 and the condenser 7 (Fig. 2); 11 between the steam line 5 and the station line 12, a pair of own needs (Fig. 1 and 2). The power unit (Fig. 1 and 2) contains a deaerator 13 connected to a condenser 7, a condensate storage tank 14, a feed pipe 15. The latter (Fig., T) an additional pipeline 16 is connected to a general station feedwater collector 17. The deaerator 13 is connected to the general station highway 12 a pair of auxiliary needs by pipeline 18 with shut-off and regulating bodies 19 and 20 to which pipeline 21 is connected. coupled to turbine seals (not shown). The block diagram with a direct-flow boiler (Fig. 2) is equipped with a steam line 22 with a valve 23 ,. a de-aerator 13 connecting the general station 12c, as well as a pipeline 24 connected between the last and a pilot dilator 25 equipped with a water discharge pipeline 26. The solvent 25 is connected to an integrated separator 27, which is ducted

with throttle valves connected to the path of the boiler 1 before and after the built-in valve 28.

The boiler and steam lines are equipped with drains connected to the drainage spreader, (not shown).

The start-up of power units equipped with boilers, which in the initial start-up period do not require a large feedwater flow, i.e. Direct flow boilers with recirculation of the medium and drum boilers (Fig. 1) are produced as follows. .

The boiler 1 is supplied with fuel and feed water through the feed pipe- t5 wire 15 from the station collector 17 through pipe 16. The steam produced in boiler 1 enters the steam pipeline 2 when the latter has open drains. Thereafter, as in the steam-20 conduit 2, the pressure will be equal to npH iepHO 0.05 nominal (when cold boiler starts) or will start to increase (when starting from an unheated state, i.e. in the initial state 25 of which overpressure), open DOC 8 by supplying the generated steam to the reheat system. Open drains last. After the steam pressure in the superheater section reaches 0.050, 07 nominal, DOC 11 is opened and the shut-off and regulating body 20 connected in the pipeline 18 provides the supply of 1 steam produced in the boiler to the deaerator 13, the deaeration of the feed water in last one. The shut-off regulator, connected to the pipeline 19, is opened, ensuring the supply of steam, discharged from boiler 1, to the turbine seals. Begin to set the vacuum in the condenser 7, In the event that, according to the condition of the initial thermal state of the turbine, the temperature supplied to. 5 steam should be higher; additional high-temperature (200-400 C) steam from an external source (not shown) is supplied to the seals, 50

After the deaeration of water in the deaerator 13 is completed, the water supply from the collector 17 is stopped and the supply of feed water to the boiler T from the deaeration air heater 13 is started. To do this, close the js shut-off regulator included in the pipeline 16 and open the shut-off regulator included in pipe 15, In the deaerator begin to supply water from the tank 14 of the condensate,

During the start-up period, after the pressure has increased beyond the DOC 11 to the corresponding value, steam discharged from boiler 1 is supplied to the trunk 12 by a pair of own needs.

After a sufficiently high vacuum in the condenser 7 and increasing the steam parameters in front of the turbine cylinders to the required values, steam is started to flow into the flow part of the HPC 3 and target 6, and after increasing the rotor speed of the turbine to the nominal one, synchronize the turbogenerator.

After a sufficiently high vacuum in condenser 7 has been set, if by the specified time the steam parameters in front of the turbine have not reached the required values for the reliability condition, DOC 9 can be turned on.

When starting from cold and cold states of boilers of these types, the use of the described sequence of operations necessitates changing the existing technology of the initial kindling process: until the vacuum in the condenser 7 is set, the flow rate discharged from the boiler 1 must not exceed the flow rate required for de-aeration of water compaction, as well as being supplied to the general station 12, therefore, the fuel consumption in boiler 1 after the start of steam generation in it is determined from the conditions of pressure at a speed close to the maximum allowable value for a given pair of discharged.

The start-up of the power unit with a flow boiler, (FIG. 2), is performed as follows.

From the public station 12 via the steam line 22, steam is supplied to the deaerator 13, providing pre-start deaeration of water, for example, when the feed pump is operating. At the end of the pre-start deaeration through the supply line 15 with the valve 28 closed, feedwater is supplied to the boiler and the fuel supply starts. The medium from the path of the boiler 1 to the valve 28 through the throttle valve is discharged into the separator 27 and further into the dilator 25. The resulting steam in the pipe 24 and the pipe 18 are fed into the pipeline 21 to the turbine seals; Vacuum is started in condenser 7. If necessary, the temperature is supplied. They are added to the turbine seals of the pa; they are increased either by adding high-temperature (200-400 ° C) steam from strangers. source, or the inclusion of electric heaters (not shown). With increasing steam flow from the expander 23 through the pipeline 24, it starts to be supplied to the deaerator 13, at the same time first reducing the flow and then stopping the flow of steam supplied through the steam pipeline 22 from the line 12. Increase the pressure in the expander 25 and, after reaching a higher pressure, than in line 12, the valve 19 is opened and steam is supplied from the spreader 25 to line 1 during the start-up period after steam supply to the outlet section of the boiler 1 (from the separator 27, or after the separator is turned off engine 28) in the steam line 12 may be supplied from steam lines 2 and 5 through the DOC 18 and 1K If necessary from the boiler 1 to provide a higher steam consumption is reduced in the steam supply line 12 out of general ronnego DC source (not shown). After vacuum vacuuming in the condenser 7, prior to synchronization of the turbogenerator, excess steam from the steam lines 2 is discharged to the condenser through the fast POC 10. During the start-up period, water from the spreader 25 is discharged through line 26, for example, to the deaerator 13 or to a water cleaning system (not shown). Water is supplied to the deaerator 13 either from the water treatment system or from the condensate storage tank 14. Implementing the process on power units with continuous flow boilers will require an increase. (compared to the existing) performance of start-up ejectors in order to ensure sufficiently fast (from the time of the start of water pumping in the path of the boiler 1 to the valve 28 until the moment at which the performance of the boiler reaches the value equal to the steam consumption for deaeration and compaction, as well as for own needs) a set of vacuum in the condenser. Thus, the proposed method makes it possible to reduce starting losses and, accordingly, increase the efficiency of the unit due to both the utilization of steam heat generated in the boiler, and reducing steam consumption from an external source and reducing the operating time of the own-needs mechanisms.

Claims (1)

METHOD OF STARTING FROM A COLD AND UNCOOLED STATE OF A POWER PLANT ENERGY UNIT, having a common-line steam supply line of its own needs, including supplying fuel and feed water to the boiler, supplying temperature-controlled steam to the turbine seals, collecting vacuum in the condenser, discharging part of the generated steam in addition to the turbine steam supply to the flow part of the turbine and synchronization of the turbogenerator, characterized in that, in order to increase efficiency, to seal the turbine and to the general steam line and for their own needs they supply part of the steam generated in the boiler, after which they begin to set up a vacuum in the condenser. 1 1125393