SU1052778A1 - Method of keeping-up optimal vacuum in steam turbine condenser - Google Patents

Abstract

THE METHOD OF SUPPORTING AN OPTIMAL VACUUM IN THE STEAM TURBINB1 STEAM CAPACITOR by changing the capacity of the circulating pump when the signal of the generator electric power and the control signal changes, which in order to improve efficiency, measure the flow rate and temperature at the inlet and outlet of the circulation condenser water, determine the temperature difference, and use the product of the temperature difference obtained by the circulation water as a control signal. UE (L SP 1chE 00

Description

The invention relates to the automation of steam turbines of energy blocks.

A known method of maintaining the optimum vacuum in the condenser of a steam turbine, and changes in the performance of the circulation pump when changing 5 signal for electric power of the generator and the control signal.

In this method, as a control signal, a signal is used for the electric power of the generator [1]. Yu

The disadvantage of this method is that the control system is insensitive to changes in the capacity of the heat flow of the circulating water caused by changes in the temperature of the cooling water and condensate. On the one hand, this leads to overcooling or an increase in the temperature of the condensate and, consequently, to deviations of the vacuum in the condenser from the optimum value, and, on the other hand, to an overexpenditure of electric energy for the circulation pump 2q.

The purpose of the invention is improving efficiency.

This goal is achieved by the fact that according to the method of maintaining the optimum vacuum in the steam turbine condenser by changing the capacity of the circulation pump when changing the signal according to the electric power of the generator and the control signal, the flow rate and temperatures at the inlet and outlet of the circulating water condenser are measured, the difference is determined temperature and as a control signal using the product of the obtained temperature difference on the flow of circulating water.

The drawing shows a diagram of the implementation of the proposed method using 35 standard measuring, functional and regulatory equipment.

The circuit contains a full pressure sensor 1, temperature sensors 2 and 3 at the inlet and outlet of the circulating water from the condenser ₄ θ of the condenser, respectively, a turbogenerator active power sensor 4 with a normalized current output, a differential pressure gauge 5 with a normalized current output, signal converters 6 and 7 with normalized current output, square root extraction device 45 8, multiplier 9, summing devices 10 and I, low-frequency (temporary) filter 12 — inertial link of the first order, adjuster 13 of optimal value vacuum in the condenser, an automatic control device ⁵⁰ and a regulatory body 15.

The scheme works as follows.

With the help of sensor 1, a signal is obtained proportional to the total pressure in the circulating water conduit, the received signal is successively converted in the differential pressure gauge о with the current output and the root extraction device 8, the output signal of which is proportional to the flow rate of the circulating water and the water.

Using the summing device 10 receiving signals from the transducers b and 7, connected with the sensors 2 and 3 of the temperature of the circulating water at the inlet and outlet of the condenser, the difference in the indicated temperatures is determined.

Using the multiplier device 9, a signal is generated proportional to the heat loss, for which a signal proportional to the flow rate from the output of the device 8 and a signal proportional to the temperature difference at the output and input of the capacitor are output from the output of the summing device 10. The resulting signal is proportional the heat loss in the condenser, from the output of the multiplying device 9 is fed to the summing device 11, where it is compared with a signal proportional to the actual power of the turbogenerator received from the filter RA 12, associated with the sensor 4 of the active power, and a predetermined vacuum value supplied from the setter 13. The output signal of the summing device 11 is used as input to the control device 14, which controls the movement of the regulatory body 15 and the flow rate of circulating water.

In the steady state of operation of the turbogenerator, the signals arriving at the adder 11 balance each other and the resulting signal is zero. When changes in the power of the turbogenerator, the temperature of the circulation water at the inlet, or the heat transfer conditions in the condenser lead to a change in the vacuum in the condenser, as well as when the reference signal at the input to the control device 14 changes, an error (inconsistency) signal appears, which will be processed last. In this case, the flow rate of circulating water changes in the direction of reducing the control error and bringing the vacuum to a predetermined optimal value. The flow rate of circulating water is changed in one way or another (by turning the blades of the circulating pump using the reversal mechanism, by changing the speed of the electric drive using a fluid coupling or a thyristor converter of electrical frequency).

Thus, the proposed method allows with greater accuracy, by measuring the actual heat loss in the condenser, to maintain the optimal vacuum value, which ultimately reduces the heat loss in the turbine condenser and the consumption of electric energy for the circulation pump drive.

ВНИИПИ Order 8833/31 Circulation 424 Subscription

Branch of the PPP "Patent", Uzhhorod, st. Project, 4

Claims (1)

METHOD FOR SUPPORTING OPTIMUM VACUUM IN A STEAM TURBINE CONDENSER by changing the circulation pump capacity when the signal changes in the electric power of the generator and the control signal, characterized in that, in order to increase efficiency, the flow rate and temperatures at the inlet and outlet of the circulation water condenser are measured, and the temperature difference is determined and as a control signal, the products of the obtained temperature difference by the flow of circulating water are used.