RU1802261C - Method of level control in regenerative heater of steam turbine - Google Patents

Abstract

Usage: heat power, for automation of regenerative heaters of steam turbines. SUMMARY OF THE INVENTION: A signal is added to the controller for the rate of change of the heat load, which eliminates the imbalance between steam inflow and condensate drain in the heater when the load of the power unit changes. The signal for the rate of change of the heat load is generated by the rate of change of the position of the control valves of the turbine or by the rate of change of the vapor pressure in front of the turbine, libre by the rate of change of the electric power of the turbine, or by the rate of change of the steam flow rate in the heater. 4 s.p. f-ly, 4 ill. ;

Description

The invention relates to a power system and can be used to automate regenerative heaters of steam turbines.

The purpose of the invention is to improve the quality of level control in the regenerative heater when the load of the power unit changes.

In FIG. 1 is a diagram of an implementation of this method for generating a signal according to the rate of change of the heat load in the form of a signal according to the position of the control valves of the turbine; in FIG. 2 - the same, for generating a signal according to the rate of change of the heat load in the form of a signal according to the vapor pressure in front of the turbine; in FIG. 3 - the same, for generating a signal according to the rate of change of the heat load in the form of a signal of the electric power of the turbine; in FIG. 4 - the same for signal generation

according to the rate of change of the heat load in the form of a signal for the flow of steam into the heater,

In the circuit of FIG. 1, 2, 3, and 4, the first input of controller 1 of heater 2 is connected to a sensor 3 for signal of level deviation in heater 2, and the output is connected to valve 4 on the condensate drain pipe of heating steam through an actuator 5. The second input of controller 1 is fed a signal on the position of valve 4 from mechanism 5. The control valve 6 of the turbine is connected to a high pressure cylinder 7, which is connected through a low pressure cylinder 8 to a generator 9.

In FIG. 7, a signal at the position of the control valves 6 of the turbine from the sensor 10 of the control valves of the turbine is connected to the third input of the controller 1. Signal on the rate of change of thermal load

ABOUT

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is formed by the rate of change of the position of the turbine control valves in the differentiator 11 and is connected to the fourth input of the regulator 1, the input of the differentiator 11 is connected to the output of the sensor 10 of the turbine control valves.

In FIG. 2, a pressure sensor 12 of steam in front of the turbine is connected to the third input of controller 1. A signal of the rate of change of the heat load is generated by the rate of change of the position of the turbine control valves in the differentiator 13 and is connected to the fourth input of the regulator 1, the input of the differentiator 13 is connected to the output of the pressure sensor 12. steam in front of the turbine.

In FIG. 3, the electric power sensor 14 of the turbine is connected to the third input of the controller 1. A signal 1 of the rate of change of the thermal load is generated by the rate of change of the electric power of the turbine in the differentiator 15 and connected to the fourth input of the controller 1, the input of the differentiator 15 is connected to the output of the electric power sensor i4.

In FIG. 4, a signal from the sensor 16 for the consumption of heating steam is connected to the third input of the controller 1. A signal according to the rate of change of the thermal load is generated in the -differential 17 according to the rate of change of the steam flow rate into the heater and is connected to the fourth input of the controller 1. The input of the differentiator 17 is connected to the output of the sensor 16 of the turbine control valves.

The circuit shown in FIG. 1 operates as follows.

When the position of the control valve 6 of the turbine changes, the power of the generator 10 proportionally changes, and the steam consumption for the regenerative heater 2 changes accordingly. The controller 1, under the influence of the signals from the sensor 10 and the differentiator 11, changes the position of the valve 4, without waiting for the level deviation in the heater. The degree of opening of the control valves 4 varies in proportion to the change in the position of the control valves 6 of the turbine and its rate of change, i.e. the signal from the output of the differentiator 11.

In the circuit shown in FIG. 2, when the vapor pressure changes in front of the control valves 6, the controller 1, under the influence of signals from the pressure sensor 12 and from the differentiator 13, changes the position of the valve 4, without waiting for the level deviation in the heater. The degree of open regulation. control valves 4 is proportional to the change in steam pressure in front of the turbine, as well as its rate of change, i.e., the signal

from the output of the differentiator 13. In this case, the deviation of the level in the heater 2 from the set will be negligible,

In the circuit shown in FIG. 3 at

When the electric power of the turbine changes, the controller 1, under the influence of signals from the electric power sensor and from the differentiator 15, changes the position of the valve 4 without waiting for the level deviation

in the heater.

In the circuit shown in FIG. 4, when changing the flow rate of heating steam in the heater under the influence of signals from the sensor 16 for the flow of heating steam and from

 the differentiator 17 changes the position of the valve, not waiting for the level deviation in the heater.

Thus, improving the quality of regulation in the heater in the dynamic mode of operation of the power unit is achieved by introducing a signal to the controller in terms of the rate of change of the heat load. This ensures that there is no imbalance between steam inflow and discharge.

condensate to the heater when changing

power unit loads.

The proposed method for regulating the level in the regenerative heater of a steam turbine is laid down in the documentation for the 0 newly developed version of the ASUT-1000 and ASUT-750 systems.

F o uaiz gains

Claims (5)

1. A method of controlling the level in the regenerative heater of a steam turbine of the generator drive by changing the valve position on the heating steam condensate drain pipe by signaling the level deviation in the heater and the heat load of the heater on the valve regulator, characterized in that, in order to increase accuracy at changes in the load of the power unit, additionally determine the rate of change of the heat load and. received signal 5 are fed to the controller. 2. The method according to claim 1, characterized in that the signal is determined from the rate of change of position of the turbine control valves and the obtained signal 0 is used as a signal from the rate of change of the heat load. 3. The method according to p. 1, about t l i. by determining the rate of change vapor pressure in front of the turbine and the received signal is used as a signal by the rate of change of the heat load. 4. The way to pop. 1, characterized in that the rate of change of the electric power of the turbine is determined and the obtained signal is used as a signal from the rate of change of the heat load. 5. The method according to claim 1, characterized in that the signal is determined from the rate of change of the steam flow rate in the heater and the obtained signal is used as a signal from the rate of change of the heat load. Fia. 3. 9ut.l Fi1.4