RU2006596C1 - Steam power station - Google Patents

Abstract

FIELD: heat and power engineering. SUBSTANCE: steam power station has at least two extraction turbines 1, source water piping 6 to supply make-up water to heating system where heating surface of turbine condenser 7, water-cooled water heater 8, chemical water treatment system 9, and vacuum deaerator 11 with intermediate vessel 12 are connected in series. Bottom heating-system water heater 17 and top one 18 of one of turbines and water-cooled water heater 8 for heating source water are connected in series in deaerated feed-water piping 16 between vacuum deaerator 11 and storage tank 15. Heating agent piping 19 of vacuum deaerator 11 is connected to feed-water piping 16 upstream of water-cooled water heater 8. EFFECT: improved design. 1 dwg

Description

 The invention relates to a power system and can be used in combined heat and power plants with open heat supply systems.

Analogs are known - thermal power plants containing cogeneration turbines with condensers and built-in lower and upper network heaters connected to the heating taps included in the mains water pipelines, the source water pipeline for replenishing the heating network, which includes a turbine condenser and chemical water treatment, a vacuum deaerator with an intermediate tank connected by a make-up water pipe to a make-up water storage tank, a make-up pump and a heating return pipe (C Dwarf EY District heating and heat networks M.:. Energoizdat, 1982 Figure 3.1b on page 53 and the description on page 54)...
Station by bus St. N 336272 adopted as a prototype.

The disadvantage of analogues and prototype is the inability to provide disinfection of make-up water for the heating system with open water for hot water. "Sanitary Rules and Operating device centralized hot water systems" issued by Ministry of Health of the USSR in 1989, at prescribed heating up water required for water pumping systems open up to 100 ^C. In the known plants with a vacuum deaerator feed water temperature does not exceed 70 ^{° C,} i.e. the temperature of the water used for hot water supply. Currently, this drawback has become a serious obstacle to the use of vacuum deaerators in projects of new and expandable stations. Another disadvantage of the analogues and the prototype is the reduced quality of deaeration of the make-up water due to seasonal fluctuations in the temperature of the source water heated in the turbine condenser and the heating agent, the network water from the supply line.

The aim of the invention is the provision of thermal disinfection of make-up water for a heating system with open hot water supply by heating this water to 100 ^about With the economical operation of the station, as well as improving the quality of deaeration of make-up water.

 This goal is achieved by the fact that the built-in lower and upper network heaters of one of the turbines and the water-to-water source water heater are connected in series in the deaerated make-up water pipeline between the vacuum deaerator and the storage tank, and the pipeline of the heating agent of the vacuum deaerator is connected to the make-up water pipe in front of the water-to-water heater.

 The drawing shows a schematic diagram of a thermal power station.

 The station contains a cogeneration turbine 1, a return 2 and supply 3 network pipelines, to which network heaters of other station turbines (not shown) are connected by pipelines 4 and 5. A condenser 7 of a turbine 1, a water-water heater 8, a chemical water purifier 9 with a decarbonizer 10 and a vacuum deaerator 11 with an intermediate tank 12 are sequentially included in the source water pipe 6 for replenishing the heating system 12. A feed pump 14 and a storage tank 15 are connected to the return network pipe 2 with a make-up pipe 13 make-up water. In the pipeline 16 of deaerated make-up water between the deaerator 11 with a capacity of 12 with a storage tank 15, lower 17 and upper 18 are integrated in series with the integrated turbine network heaters 1 and the feed water heater 8. To the pipeline 16 in front of the heater 8 is connected to the pipeline 19 of the heating agent of the deaerator 11.

 The station operates as follows.

Return network water through pipelines 2 and 4 is supplied to the network heaters of the turbines of the station, then water heated according to the temperature schedule of the heating system in accordance with the temperature of the outside air is supplied to consumers through pipelines 5 and 3. Leaks of water from the heating system and its consumption for open hot water supply are compensated by make-up water. Source water from the aqueduct ppimerno heated to 20 ° ^C in the condenser 7 of the turbine 1, to 50 ° ^C - in the preheater 8, softened, dekarboniziruetsya and then deaerated in the deaerator 11 where it is heated to about 60 ° ^C deaerated feed water is heated up sequentially 100 ^C. heaters 17 and 18 heats the heating steam turbine 1, and then cooled to a temperature of the water for hot water 70 ° ^C in the preheater 8 and enters the storage tank 15, from where appropriate pump 14 is supplied into the return network truboprovo d 2. Part heated ^to 100 ° C deaerated feed water is withdrawn before the heater 8 is used as the heating agent 11 in the deaerator.

 The significance of the distinguishing features of the claimed solution is due to the new interconnection of station elements. The inclusion of the lower and upper network heaters of one of the station's turbines in the pipeline of deaerated make-up water between the vacuum deaerator and the storage tank allows to constantly make-up water to a temperature that ensures thermal disinfection of this water. It is significant that the proposed solution allows providing such heating of make-up water with maximum efficiency by steam of heating taps and with the effect of stepwise heating. The inclusion in the pipeline of a deaerated make-up water of a water-water heater makes it possible to provide heating of the source water necessary for high-quality deaeration and to cool the make-up water before being supplied to the storage tank and to heat up to a temperature equal to the temperature of the water supplied to the hot water supply. The connection of the heating agent pipe of the vacuum deaerator to the make-up water pipe in front of the water-water heater allows us to stably maintain the temperature of the heating agent necessary for effective vacuum deaeration.

 (56) Copyright certificate of the USSR N 336272, cl. C 02 F 1/20, 1972.

Claims (1)

 THERMAL ELECTRIC STATION, containing at least two cogeneration turbines with condensers and integrated lower and upper network heaters connected to the heating taps, a source water pipe to feed the heating network with the cooling surface of the steam turbine condenser, a chemical water treatment system, and a vacuum deaerator equipped with a vacuum deaerator and a connected make-up water pipe through the make-up water storage tank and a make-up feed pump heating system house, characterized in that, in order to improve the quality of make-up water, it is equipped with a water-water source water heater, located in the pipeline of the latter behind the cooling surface of the steam turbine condenser and in the heating medium included in the makeup water pipeline to the storage tank, the lower and upper network heaters of one of the turbines for the heated medium are placed sequentially in the make-up water pipeline behind the vacuum deaerator, additionally connected via a pipe rovoda heating agent conduit to feed water to the water-steam preheater.