SU1346827A1 - Method of controlling steam-gas unit - Google Patents

Abstract

The invention allows to increase the efficiency of the installation. When the load is set at the initial moment of the t-ra, the gas turbine is at its nominal value, therefore, the output of the adder 14 will be a zero signal, and the output of the adder 13 of the load signals will be a positive J5 signal. The fuel consumption controller 18 passes a signal from the adder 14, and the fuel valve 3 does not change its position at the first moment. The signal from the adder 13 changes sign in the inverter 17 and simultaneously with the signal from the adder 14 enters the input of the selector 15. Recirculation controller 19 receives a negative signal on the load, which causes a decrease in the opening of the recirculation valve 12 to the value that provides the specified load. This leads to a reduction of t-ry before the compressor and, accordingly, to a decrease of t-ry before the gas turbine. As a result, a positive signal appears at the output of the adder 14. The fuel supply increases. By reducing the load, first reduce the fuel consumption in the combustion chamber until the start of the decrease in gas temperatures in front of the turbine, and then simultaneously increase the flow rate of the recirculated gases. 1 il. (L with N Oi 00 bO

Description

The invention relates to a power system and, in particular, to methods for controlling steam-gas plants with a waste-heat boiler (KU).

The aim of the invention is to improve efficiency.

The drawing shows the installation diagram for the implementation of the proposed method.

The installation contains a compressor 1, a chamber 2 C1 0rani with a fuel valve 3, a gas turbine consisting of a high part 4 and a low pressure part 5, a CG 6, a steam turbine 7, a condenser 8, a drum 9, an electric generator 10, a flue gas recirculation 11 gases to the compressor 1 inlet with recirculation valve 12, the adder 13 of the load signals for the frequency of rotation of the gas turbine shaft, the adder 14 of the signal-: iOB for the gas temperature before the gas turbine, selectors 15 and 16 minimum, inverter 17, fuel consumption controller 18 and recirculation adjuster 19.

The method is implemented as follows.

The air drawn from the atmosphere is mixed with the flow of recirculated gases entering through the recirculation duct 11 and directed to the inlet of compressor 1. The gas-air mixture is compressed in the compressor 1 and enters the combustion chamber 2. In the combustion chamber 2, fuel nozzles are burned and the resulting products of the C1 ori flow into the gas turbine, the high pressure part 4 causes the compressor 1, and the low pressure part 5 the electric generator 10. After passing the gas turbine, the flue gases are sent to KU 6, where produce drug This steam does work in a steam turbine 7.

Part of the flue gases from the CC to the recirculation flue 1 1 returns to the inlet of the compressor 1.

When recruiting a load (this means that p.p. where n is the set value of the frequency of rotation of the gas turbine shaft; n is the current value of the frequency of rotation of the shaft of the gas turbine) on the output of the adder 13 si1-load voltage will be a positive signal. The temperature in front of the gas turbine is at that moment at its nominal value. Consequently, in the course of the adder 14 of the signals, the temperature in front of the gas turbine will be a zero signal. The input of the minimum selector 16 receives a positive signal from the adder 13 of the load signals and a zero signal from the adder 14 of the signals according to the temperature in front of the gas turbine. On the flow controller 18, the smaller of these two signals, namely the zero one, passes. Thus, the fuel valve 3 at the first moment does not change its position. At the same time, the signal from the adder 13, directed to the minimum selector 15, changes sign to

opposite in the inverter 17. The minimum selector 15 arrives at the input: a zero signal from the cooler 14 signals in front of the gas turbine temperature and a negative signal from the adder 13 load signals. The recirculation regulator 19 receives a negative signal on the load, which leads to a decrease in the opening of the recirculation valve 12 to a value that provides a predetermined load. Reducing the flow of recirculated gases leads to a decrease in temperature before the compressor and, accordingly, to a decrease in temperature before the gas turbine. This, in turn, leads to a positive signal.

at the output of the adder 14. Now two positive signals come to the minimum selector 16 and a menipy of them passes to the fuel consumption controller 18, increasing the fuel supply.

Thus, even a small signal indicating a decrease in temperature before the gas turbine leads in this mode to an increase in the degree of opening of the fuel valve 3 and, accordingly, the fuel consumption in the combustion chamber to a value that ensures the maintenance of a predetermined, for example, nominal temperature gas turbine.

The transient process continues for some time, affecting the fuel valve 3 and the recirculation valve 12 and ending with a new load value and a given, for example, terminal temperature, the temperature before | azov turbine.

When the load is reset (p), the negative order from the adder 13 of the load signals passes through the minimum selector 16 to the fuel consumption regulator 18, reducing the opening of the fuel valve 3 to a value that provides the specified load. In this case, the temperature of the gas turbine decreases, which leads to the appearance of a negative, 1 signal on

sumat.matter 14. At the same time, two positive signals come to the selector 15 of the minimum, from which several are sent to recirculation controller 19, increasing the opening degree of recirculation valve 12.

As a result of an increase in the flow rate of the recirculated gases, the temperature at the inlet to compressor 1 increases and, therefore, the temperature ahead of the gas turbine rises. This process occurs as long as the temperature in front of the gas turbine

will not reach a predetermined, e.g. nominal, value.

Claims (1)

Invention Formula The method of regulating a steam-gas plant having a waste-heat boiler and a flue gas recirculation flue to the compressor inlet by increasing the fuel consumption into the combustion chamber while reducing the flow rate 2 1346827, recirculated gases in the process of gasing up to the moment of the beginning of the spi / kenload and the decrease in the consumption of the toning at the gas temperature before the turbine, after increasing recycled gas consumption — which simultaneously increases top consumption call in the process of reducing the load and pouring into the ci-Orani chamber, and if reducing the temperature of the gas before the turby-5 load, first reduce the consumption of the fuel in of a given value, which differs in the combustion chamber until the start, it decreases, in order to increase the eco-gas temperature in front of the turbine. nominalities, in the process of recruiting the load after which the consumption increases first reduce the consumption of recycle-recirculated gases.