RU2220291C1 - Method of operation of thermal power station - Google Patents

Abstract

FIELD: heat power engineering; thermal power stations. SUBSTANCE: according to proposed method, system water is heated in system heaters by steam of heating extractions of extraction turbine, and feed water of heating system is deaerated in vacuum deaerator before delivering into return heating system pipeline. For this purpose source water and superheat water are fed into deaerator. Preset concentration of dissolved oxygen in deaerated water is maintained by sequential regulation of temperature of source and superheated water. In case of rise of dissolved oxygen concentration relative to preset value, first source water temperature is raised and then, if necessary, temperature of superheated water. In case of drop of dissolved oxygen concentration relative to preset value, first temperature of superheated water is decreased and then source water temperature. EFFECT: improved reliability and increased economy of thermal power station. 2 cl, 1 dwg

Description

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

Analogs are known - the methods of operation of a thermal power plant, in which the network water is heated in the network heaters with steam from the heating taps of the heating turbine, the heating water is deaerated in a vacuum deaerator before being fed to the return network pipe, for which source and superheated water is supplied to the deaerator (see. .s. SU 1328563, F 01 K 17/02, 08/07/1987). This analogue is adopted as a prototype.

The disadvantage of analogues and prototype is the reduced efficiency of the method of operation of a thermal power plant due to the increased energy costs of heating superheated and source water in front of the deaerator with a residual oxygen concentration in deaerated water below the required value. Since the normative quality of water deaeration, which is characterized primarily by the content of dissolved oxygen in deaerated water, can be achieved at significantly lower temperatures of the source and superheated water, deaeration almost always occurs with excessive temperatures of the source and superheated water. On the other hand, at insufficient temperatures of the source and superheated water, the quality of water deaeration decreases, which leads to a decrease in the reliability of the thermal power plant.

The technical result achieved by the present invention is to increase the reliability and efficiency of the thermal power plant by maintaining optimal temperature parameters of the source and superheated water supplied to the deaerator.

To achieve this result, a method is proposed for operating a thermal power plant, in which the network water is heated in the network heaters with steam from the heating taps of the heating turbine, the heating water is deaerated in the vacuum deaerator before being fed to the return network pipe, for which source and superheated water are supplied to the deaerator.

The difference of the proposed method is that the maintenance of a given concentration of dissolved oxygen in deaerated make-up water is carried out by sequentially controlling the temperature of the source and superheated water, and when the concentration of dissolved oxygen is increased relative to a given value, the temperature of the source water is first raised, and then, if necessary, the temperature of the superheated water and, on the contrary, when lowering the oxygen concentration relative to a given value, the superheat temperature is first reduced water, and then the temperature of the source water.

A new way of operating a thermal power plant improves the reliability and efficiency of a thermal power plant by ensuring the required quality of deaeration during economical operation of the plant.

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 method.

The station contains a cogeneration turbine 1 with steam extraction connected to the heating extraction via a heating medium and network heaters connected to the heating pipe via a heating medium, a vacuum deaerator 2 with source 3 and superheated water 4 pipes, connected by a deaerated make-up water pipe 5 with a return network pipe 6 included in the source water pipe 3 source water heater 7 with a low-potential heating steam pipe 8 and in the superheated water pipe 4 heater 9, to which a high-potential heating steam pipeline 10 is connected. The station is equipped with a dissolved oxygen controller 11 in the make-up water of the heating network, which is connected to a dissolved oxygen sensor 12 in the deaerated make-up water and to regulatory bodies 13 on the heating medium pipe of the source water heater and 14 on the heating medium pipeline superheater water heater.

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

The network water is heated in the network heaters with steam from the heating taps of the heating turbine 1, the make-up water of the heating system is deaerated in the vacuum deaerator 2 before being fed to the return network pipe 6, for which initial and superheated water is supplied to the deaerator. The source water is heated by the lower heating steam in the heater 7, and the superheated water by the higher steam extraction in the heater 9. A predetermined concentration of dissolved oxygen in the deaerated make-up water is maintained by sequentially controlling the temperature of the source and superheated water. With an increase in the concentration of dissolved oxygen relative to a predetermined value, first the temperature of the source water is increased within the thermal power of the source water heater or to a temperature of t = 40-50 ° C, and then, if necessary, the temperature of superheated water is increased, and, conversely, when the oxygen concentration is reduced relative to the set value first reduce the temperature of superheated water, and then the temperature of the source water.

As a regulator, it is possible to use the mass-produced microprocessor controller Remicont R-130, which allows to implement about 90 programs for controlling controlled processes, moreover, it has a number of self-tuning functions for controlled processes. The implementation with its help of the sequential control of the source water temperature and the temperature of superheated water provided for by the claimed method (this is the main distinguishing feature of the claimed method), when using the residual oxygen content as an adjustable factor, will present difficulties. The operations to block the signals from the regulator to the regulatory bodies are carried out by Ramikont himself on the basis of the sequence of work of the regulatory bodies entered into it and the intervals for changing the temperature of the source water and the temperature of superheated water that are valid for a particular power plant.

Thus, the new method allows to increase the reliability and efficiency of the thermal power plant by providing a predetermined concentration of dissolved oxygen in deaerated make-up water at an economical loading of turbine withdrawals.

Claims (1)

The method of operation of a thermal power plant, in which the network water is heated in the heaters with steam from the heating taps of a cogeneration turbine, the heating network feed water is deaerated in a vacuum deaerator before being fed to the return network pipe, for which source and superheated water is supplied to the deaerator, characterized in that it is maintained the concentration of dissolved oxygen in deaerated make-up water is carried out by sequentially controlling the temperature of the source and superheated water, m when the concentration of dissolved oxygen relative to a predetermined value initially increase the temperature of initial water, and then, if necessary, to increase the temperature of the superheated water, and conversely, when the oxygen concentration is lowered relative to a predetermined value, first reduce the temperature of superheated water, and then the temperature of the source water.

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