RU2269654C2 - Thermal power station operating process - Google Patents

Abstract

FIELD: thermal engineering; thermal power stations.

SUBSTANCE: proposed thermal station operating process is characterized in that steam extracted from turbines is passed to low- and high-pressure regenerative heaters wherein full-flow condensate downstream of condenser and feedwater are sequentially heated, then source makeup water is heated upstream of deaerator. Source makeup water is heater upstream of deaerator in low-pressure heater closest to condenser, and regenerative heating of full-flow condensate is started in low-pressure heater second form condenser.

EFFECT: enhanced economic efficiency and operating reliability of thermal power station.

1 cl, 1 dwg

Description

The invention relates to the field of power engineering and can be used in thermal power plants.

Analogs are known - methods of operating a thermal power plant, in which steam from turbine offsets is taken to regenerative heaters of low and high pressure, in which the main condensate of the turbines after the condenser and feed water are successively heated, the initial additional feed water in front of the deaerator is heated in the heater with steam from the upper heating selection (see Ryzhkin V.Ya. Thermal Power Plants, Moscow: Energia, 1976, Fig. 14-1 and description to it C.203). This analogue is adopted as a prototype.

The disadvantages of the analogues and the prototype are the reduced reliability and efficiency of the thermal power plant due to the difficulty of providing technologically necessary for the effective deaeration of the heating of the source water in front of the deaerator of additional feed water.

The technical result achieved by the present invention is to increase the reliability and efficiency of a thermal power plant by heating the source water to a technologically necessary temperature with a highly economical low-potential extraction of turbine steam with minimal capital costs for reconstruction of the power plant circuit.

To achieve this result, a method is proposed for operating a thermal power plant, in which steam from turbine offsets is taken to regenerative heaters of low and high pressure, in which the main condensate of the turbines after the condenser is sequentially heated and feed water is heated, the initial additional feed water is heated before the deaerator.

The peculiarity lies in the fact that in the regenerative low pressure heater closest to the condenser, the source feed water is heated in front of the deaerator, and the regenerative heating of the main condensate is started in the second low pressure heater from the condenser.

A new way of operating a thermal power plant allows you to increase the reliability and efficiency of the thermal power plant by heating the source of additional feed water to the technologically necessary temperature with low-grade steam with minimal costs for reconstruction of the power plant circuit.

Next, we consider the information confirming the possibility of carrying out the invention with obtaining the desired technical result.

The drawing shows a schematic diagram of a thermal power plant, explaining the proposed method. The station contains a boiler, a steam turbine 1 with steam extraction, a main condensate pipeline 3 connected to a condenser 2, low pressure regenerative heaters 4, 5, 6, 7, an initial feed water pipe 8 connected to a vacuum (atmospheric) deaerator 9. Regenerative heater low pressure 4, connected to the regenerative steam sampling closest to the condenser, is excluded from the main condensate heating circuit and is connected via a heated medium to the pipeline 8 of the initial additional feed water d vacuum (atmospheric) deaerator 9. The heater circuit of the main condensate includes only heaters 5, 6, 7.

Consider an example of the implementation of the claimed method of operation of a thermal power plant.

The steam generated in the boiler is sent to the turbine 1, the condensate of the exhaust steam from the condenser 2 is supplied through the main condensate pipeline of the turbine 3 to the regenerative low-pressure heaters 5, 6, 7 and then to the high pressure deaerator, after which the feed water is pumped through the high-pressure heaters by the feed pump and served in a steam boiler. Loss of steam and condensate from the plant cycle is compensated by additional feedwater. The initial additional feed water in front of the vacuum deaerator 9 is successively heated in the built-in bundle of the condenser 2 and in the regenerative low-pressure heater specially allocated for this purpose 4. The deaerated additional feed water is fed into the main condensate path 3.

Thus, the exclusion of the low-pressure heater 4, connected to the regenerative selection closest to the condenser 2, from the regenerative heating circuit of the main condensate and its inclusion in the heating circuit of the source additional feed water in front of the vacuum deaerator allows providing technologically necessary heating of the source water, thereby increasing reliability station. The use of low-potential lower regenerative selection steam to heat the initial supplementary feed water instead of commonly used higher-capacity steam samples increases the efficiency of the thermal power plant. The station’s efficiency is also increased by increasing the consumption of low-grade steam for the main condensate heating in the regenerative low-pressure heater 5 and by eliminating the cost of an additional heat exchanger for heating the source additional feed water to the temperature necessary for effective deaeration.

Claims (1)

The method of operation of a thermal power plant, in which the steam from the turbine offsets is led to regenerative heaters of low and high pressure, in which the main condensate of the turbines after the condenser and feed water are sequentially heated, the initial additional feed water in front of the deaerator is heated, characterized in that in the closest to the condenser the regenerative low-pressure heater warms up the initial supplementary feed water in front of the deaerator, and the regenerative heating of the main condensate begins dissolved in the second capacitor from the low-pressure preheater.