SU1108223A1 - Method of starting power unit - Google Patents

Abstract

The ENERGY BLOCK STARTING METHOD by heating the path of the intermediate superheater by passing steam to a high pressure cylinder, increasing the rotor speed to a predetermined intermediate value and then maintaining this value, dumping the excess steam produced by the boiler into the turbine condenser through the start overflow device, resetting the steam from the intermediate superheat path, releasing the steam from the intermediate superheater to the turbine condenser condenser through waste valves with medium pressure regulating valves closed, closing relief valves and opening control valves with an increase in the rotor speed to the nominal value after the end of the heating up of the intermediate superheater path, the specified control valves are stopped in the intermediate position until the nominal vapor pressure at the exhaust of the high pressure cylinder is reached and the pressure is restored when the specified pressure is reached, characterized in that the purpose of increasing the efficiency of the power unit at start-up, after reaching the specified intermediate value of the rotor speed The panes are completely closed by restoring the specified setpoint value of the rotation frequency with a cover of the start-and-reset device, and oc (the setting of the medium pressure control valves is done when the nominal rotation frequency is reached.

Description

The invention relates to a power plant TiiKc and can be used in block power plants of a boiler-turbine with intermediate steam superheating.

The closest to the proposed in; 1 method is the start-up of a power unit by heating the path of the intermediate superheater by passing steam into a high pressure cylinder with increasing rotor speed to a predetermined intermediate value and then maintaining this value, dumping the excess steam produced by the boiler into the turbine condenser through the resetting device , steam discharge from the path of the intermediate superheater to the condenser through the relief valves with medium-pressure regulating valves closed, cover the discharge valve and open medium pressure valves with a rotor speed up to the pump, 1st value after the end of the nporpeiia of the intermediate superheater with stop of these control valves in the intermediate position until the vapor pressure at the high distance cylinder is reached and they are opened again. upon reaching the specified pressure 1.

The disadvantage of this method is the somewhat lower efficiency of the power unit during start-up due to significant energy notices when steam is discharged into the condenser and the feed water temperature and temperature.

The purpose of the invention is to increase the efficiency of the power unit during start-up.

In this case, according to the method of starting the power unit, by heating the intermediate superheater, steam is passed into the high pressure cylinder by increasing the rotor speed to a predetermined intermediate value and then keeping this value, resetting the steam generated by the boiler to the turbine condenser through the start reset device, discharge of steam from the path of the intermediate superheater to the condenser through the relief valves with medium pressure control valves closed, cover with After the end of heating of the intermediate superheater path, the specified control valves are stopped in the intermediate position until the nominal pressure of the steam at the high pressure cylinder is reached and the opening is resumed when the specified pressure is reached pressure, after reaching a predetermined intermediate value of the rotor speed, the discharge valves close completely, restoring pour specified

the value of the rotation frequency by the cover of the start-up device, and the stop of the medium pressure control valves is made when the nominal value of the rotation frequency is reached.

The drawing shows a schematic diagram, carrying out the proposed method.

The power unit contains a boiler 1 connected with fresh steam pipelines 2 with high pressure regulating valves 3 to a high pressure cylinder 4 (CVP). The HPC through the path 5 of the intermediate superheater is connected to the cylinder 6 of medium pressure (CSD), equipped with

 medium pressure control valves 7. The low pressure cylinder 8 (LPD) is connected to the condenser 9 through the exhaust steam. The fresh steam pipelines 2 are connected to the condenser 9 by the start-discharge valve.

0 by the device 10. The path 5 of the intermediate superheater before the medium pressure regulating valves 7 by the discharge line 11, on which the discharge valve 12 is installed, is connected to the steam receiving device of the condenser 9. The condenser 9 is connected to line 13, on which the condensate pumps 14 and the low pressure heaters 15 are installed, connected to deaerator 16, which is supplied with feedwater pipes 17 with feed pump 18 and three high-pressure heaters 19-21 that are connected to pipes 22 and 23, respectively, connected to flow h Parts of the HPC 4, and the high-pressure heater 19 by the pipe 24 are connected to the flow section of the central processing unit 6. The valves 22-24 have valves 25-27 installed. The heating unit 21 is connected to the heater 20 by a drain line 28 on which the valve 29 is installed. The heating unit 20 is connected to a heater 19 with a drain line 30 on which a valve 31 and a valve 32 are installed, and with a deaerator 16 - a line 33 on which a valve is installed 34. A heater 19 is connected to the deaerator 16 by a line 35 on which a valve 36 and a valve 37 are in series installed. to dea PA5 torus 16 is carried through line 38 with valve 39. In addition, the deaerator 16 is provided to connect to the conduit 23 line 40 with valve 41.

The rotational speed of the turbine rotor is measured by a sensor 42, the signals of which are fed to the indicating device 43 and to the turbine speed controller 44, controlling through the servo motor 45 the movement of the high-pressure control valves 3, and through the servo motor 46

moving regulating utapanov 7 medium pressure. Manual control of the valves 3 is carried out using the setting device 47 or the control device 48, and

manual control of the valves 7 - using the device 49. The position of the valves 7 is controlled by the sensor 50 and the secondary device 51. The waste valve 12 is controlled by the device 52, and their position is controlled by the sensor 53 and the secondary device 54.

The parameters of the fresh steam are monitored by a pressure sensor 55 and a temperature sensor 56 connected to the secondary devices 57 and 58, respectively. The exhaust pressure of the CVP 4 is controlled by the sensor 59 and the secondary device 60. The steam temperature in front of the CSD 6 is monitored by the sensor 61 and the secondary device 62. To monitor the temperature of the steam inlet part of the CVP 4, the sensor 63 with the secondary device 64 is used, and sensor 65 with secondary device 66.

The start-up of the power unit according to the proposed method is carried out as follows.

Organize the movement of condensate and feed water through the path. Condenser 9 - condensate pumps 14 - line 13 - low pressure heaters 15 - deaerator 16 - pipelines 17 - feed pumps 18 - high pressure heaters 19-21 - boiler 1.

At the same time, for partial heating of feedwater and organization of the deaeration mode, steam is supplied to the deaerator 16 through line 38 with valve 39. The boiler 1 is fired and the steam generated by the boiler is discharged through the discharge discharge device 10 to the high pressure regulator valves 3. The steam parameters in conduit 2 are controlled by secondary devices 57 and 58. Prior to supplying steam to the turbine, high-pressure heaters 20 and 21 are connected to the flow part of high-pressure cylinder 4 by opening valves 25 and 26 in conduits 22 and 23. Valve 27 in conduit 24 is closed position At the same time, a scheme for dumping condensate of heating steam from heaters 20 and 21 to deaerator 16 is organized by opening valves 29 and 31 and valve 34 and closing valves 32 and 37.

According to the temperature state of the steam inlet of the HPC 4, determined from the readings of the device 64, the values of the temperature and pressure of the fresh steam are established, which must be obtained by the moment steam is supplied to the turbine. The achievement of these parameters and the possibility of starting the turbine start are established according to the indications of the devices 57 and 58. Simultaneously with the increase in the pipeline 2, the parameters of fresh steam required by the temperature state of the HPC 4 perform the following operations; the impact on the device 52 of the control of the waste valve 12, controlling its position, measured by the sensor 53, according to

device 54 is turned on valve 12 to the fully open position; by acting on the manual control device 49 by the medium pressure regulating valves 7, the servo motor 46 is disconnected from the speed controller 44 and the valves 7 are switched to the fully closed position, monitoring this position, measured by the sensor 50, on the device 51.

0 After receiving in the pipeline 2 parameters of fresh steam required by the temperature state of the HPC 4, acting on the high-pressure control valve positioning device 48, steam is supplied to the HPC 4, ensuring

5 its movement along the HPC path 4 — path 5 — discharge line 11 with discharge valve 12 — steam intake device of condenser 9. Medium-pressure control valves 7 are closed, valve 12 is open and the rotors of DSC 6 and LPC 8 rotate under deep conditions vacuum. The degree of opening of the high-pressure control valves 3 is set in such a way as to ensure that the rotor reaches the specified intermediate value of the rotational speed, for example, 30-40% of the nominal frequency. The monitoring of the rotational speed of the rotor measured by the sensor 42 is carried out according to the indications of the device 43.

The excess steam generated by the boiler is discharged through the resetting device 10, the valve of which is open, to the steam receiving unit of the condensate.

Thereafter, to increase the pressure of the steam entering the preheaters 20 and 21

5 high pressure, gradually cover valve 12 until it is completely closed. The valve 12 is displaced by acting on the position control device 52, and the opening degree of the valve 12, measured by the position sensor 53, is controlled by the indications of the secondary device 54. The closing speed of the valve 12 is controlled based on the thermal condition of the pressure cylinder elements 4 and the device 64, and the thermal state of the tract 5, controlled by the temperature sensor 61 and the secondary device 62, maintaining their heating rate at a level not exceeding the maximum permissible rate. Closing the waste valve 12 results in an increase in vapor pressure per CVP 4.,

0 is controlled by the sensor 59 and the device 60, and in the flow part of this cylinder, and the steam overshoot, triggered in the HPC, is reduced, which leads to a decrease in the rotor speed, measured by the sensor 42. To restore it to the previous level

 increase steam consumption in the turbine. To this end, the impact on the device 48 provides an increase in the degree of opening of the high-pressure control valves 3, controlling the restoration of a predetermined intermediate value of the rotor rotation frequency measured by the sensor 42, according to the indications of the device 43. If necessary, simultaneously cover the valve of the start-up device 10. to a significant increase in pressure and consumption of steam supplied through pipelines 22 and 23 to the preheaters 21 and 20, as a result of which heating of the feedwater increases s supplied to the heaters of said deaerator 16. The steam supplied to the heaters 20 and 21, condenses, giving off its heat to the heated water. The heating steam condensate from the preheater 21 through the drain line 28 through the valve 29 enters the heater 20. The heating steam condensate from the heater 20 through the drain line 30 with the valve 31, then through line 33 with the open valve 34 is discharged into the deaerator 16. The valves 32 and 37 at This is closed, which prevents the preheater 19 from being filled with condensate and its possible overflow.

The higher the vapor pressure at the exhaust and in the flow section of the CVP 4, the greater the steam consumption enters the heaters 20 and 21 and the higher the heating of the feed water entering the boiler 1. The inflow of heated water reduces the fuel consumption in the boiler. An additional effect can be obtained if the deaerator 16 is connected to the pipeline 23 with the help of line 40 and valve 41. This connection is expedient if the deaerator 16 is fed with steam from an external source. When you open the valve 41 at the same time close the valve 39.

The heating of the path of the intermediate superheater is monitored by the change in steam temperature measured by sensor 61 in the reheat pipeline before the design and estimate documentation 6. The end of heating is determined by the specified steam temperature reaching a predetermined value, for example, a value equal to the temperature of the central inlet manifold 6, measured by sensor 65 and monitored by device 66.

When the sensor 61 and the device 62 reach the required steam temperature, in front of the CCD 6, steam is supplied to the CCD 6

and low-pressure cylinder 8. For this, the impact through the manual control device 49 on the servomotor 46 of the medium pressure regulating valves 7 opens the latter, at the same time controlling the change in the rotor speed as indicated by the device 43. When the nominal rotation frequency is reached, the impact through the device 49 on the servo motor 46 of the control valves 7 medium pressure is stopped and the valves are stopped in the reached position. After reaching the nominal rotation frequency, the generator (not shown) is synchronized with the network and the turbine is gradually loaded.

Upon completion of the heating of the reheat path and obtaining the required parameters, before the medium pressure regulating valves 7, the turbine rotor speed is increased to the nominal value by opening these valves and supplying steam to the central vacuum pump 6 and low pressure cylinder 8. When the nominal rotation frequency is reached, the opening of the valves 7 is stopped. The turbine is loaded first by covering the release switch 10 until it is completely closed, and then by increasing the steam capacity of boiler I.

When performing these operations, the vapor pressure at the exhaust of the high-pressure cylinder measured by the sensor 59 according to the indications of the device 60 is monitored, and since reaching the nominal value of this pressure, the degree of opening of the average pressure regulating valves 7 is increased by affecting the servo motor 46 through the control device 49, maintaining further loading this pressure to a constant — up to the complete opening of the indicated valves.

Thus, during the entire start-up, the proposed method provides an increased vapor pressure in the preheaters 20 and 21 and increased heating of the feed water entering the boiler. The increased feed water temperature reduces the fuel consumption in the boiler, which is necessary for steam generation, as a result of which the power unit operation efficiency during start-up modes is improved.

Claims (1)

METHOD FOR STARTING AN ENERGY UNIT by heating the path of the intermediate superheater by letting steam into the high pressure cylinder to increase the rotor speed to a predetermined intermediate value and then maintaining this value, dumping the excess steam generated by the boiler into the turbine condenser through a discharge device, and dumping steam from the intermediate superheater path to condenser through relief valves with closed control valves Sound? D 29 eleven 12 / average pressure, cover the relief valves and open the medium pressure control valves with increasing rotor speed to a nominal value after the heating of the intermediate superheater path with the stop of the specified control valves in the intermediate position until the nominal steam pressure at the exhaust of the high pressure cylinder is reached and with the resumption of opening when specified pressure, characterized in that, in order to increase the efficiency of the power unit at startup, after reaching the target of this intermediate value of the rotor speed, the relief valves are completely closed, restoring the specified speed value with the cover of the starting-reset device, and the control valves of the medium pressure are stopped when the nominal speed value is reached. SU. „L 108223