RU2225572C1 - Method for thermic deaeration of water - Google Patents

Abstract

FIELD: thermic deaeration of water, possibly in boiler aggregates. SUBSTANCE: method for thermic deaeration of water comprises steps of deaerating water in vacuum deaerator by feeding into deaerator initial water and heating agent; sustaining predetermined concentration of oxygen dissolved in deaerated water by successively controlling temperature of heating agent and temperature of initial water; when concentration of dissolved oxygen exceeds predetermined value at first increasing temperature of heating agent and then, if necessary increasing temperature of initial water; when oxygen concentration becomes lower than predetermined value at first decreasing temperature of initial water and then decreasing temperature of heating agent. EFFECT: enhanced efficiency, improved reliability of boiler aggregate. 1 dwg

Description

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

 Analogs are known - methods of thermal deaeration of water, by which the heating water is supplied with deaerator in a vacuum deaerator before being fed to the return line, for which source water and a heating agent are supplied to the deaerator (see the directory "Vacuum deaerators". M .: NIIINFORMTYAZHMASH, 1972 , Fig. 15, p.15). This analogue is adopted as a prototype.

 The disadvantage of analogues and prototype is the reduced efficiency of the method of thermal deaeration of water due to increased energy costs for heating the heating agent and the source water in front of the deaerator at a residual oxygen concentration in deaerated water below the required value. Since the normative quality of water deaeration, characterized primarily by the content of dissolved oxygen in deaerated water, can be achieved at significantly lower temperatures of the heating agent and the source water, deaeration almost always occurs with excessive temperatures of the heating agent and the source water. On the other hand, the disadvantage of this method is the low quality of water deaeration, leading to a decrease in the reliability of the boiler installation.

 The technical result achieved by the present invention is to increase the reliability and efficiency of the boiler installation by maintaining optimal temperature parameters of the heating agent and the temperature of the source water supplied to the deaerator.

 To achieve this result, a method of thermal deaeration of water is proposed, by which water is deaerated in a vacuum deaerator, for which a heating agent and feed water are supplied to the deaerator.

 The difference of the proposed method is that maintaining a predetermined concentration of dissolved oxygen in deaerated water is carried out by sequentially controlling the temperature of the heating agent and the temperature of the source water, and when the concentration of dissolved oxygen is increased relative to a predetermined value, the temperature of the heating agent is first raised, and then, if necessary, the temperature of the source water and on the contrary, when lowering the oxygen concentration relative to a given value, the temperature is first reduced and Khodnev water, and then the temperature of the heating agent.

 A new method of thermal deaeration of water can improve the reliability and efficiency of the boiler installation by ensuring the required quality of deaeration during economic operation of the boiler room.

 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 boiler installation, explaining the method.

 The boiler installation contains a vacuum deaerator 1 with pipelines of the source water 2 and a heating agent 3, connected by a pipeline of deaerated make-up water 4 with a return pipe 5, the heater of the source water 6 included in the pipeline of the source water 2 with the pipeline of the heating medium 7 and the heater 8 in the pipeline of the heating agent 3 to which the heating medium piping is connected 9. The station is equipped with a regulator of the dissolved oxygen content 10 in the make-up water of the heating system, which is connected to the dissolved content sensor oxygen 11 in deaerated make-up water and with regulatory bodies 12 on the heating medium pipeline of the source water heater and 13 on the heating medium pipeline of the heating agent heater.

 Consider an example of the implementation of the claimed method of thermal deaeration of water.

The make-up water of the heating network is deaerated in a vacuum deaerator 1 before being fed to the return line 5, for which source water and a heating agent are supplied to the deaerator. The source water is heated in heater 6, and the heating agent in heater 8. Maintaining a predetermined concentration of dissolved oxygen in deaerated make-up water is carried out by sequentially controlling the temperature of the heating agent and the temperature of the source water. When increasing the concentration of dissolved oxygen relative to a given value, first increase the temperature of the heating agent, and then, if necessary, increase the temperature of the source water within the thermal power of the source water heater or to a temperature t = 40-50 ^o C and, conversely, when lowering the oxygen concentration relative to the set value first reduce the temperature of the source water, and then the temperature of the heating agent.

 Thus, the new method allows to increase the reliability and efficiency of the boiler plant by providing a given concentration of dissolved oxygen in deaerated make-up water during economic operation of the boiler room as a whole.

Claims (1)

A method of thermal deaeration of water, in which water is deaerated in a vacuum deaerator, for which source water and a heating agent are supplied to the deaerator, characterized in that the predetermined concentration of dissolved oxygen in the deaerated water is maintained by sequentially controlling the temperature of the heating agent and the temperature of the source water, moreover, increasing the concentration of dissolved oxygen relative to a given value, first increase the temperature of the heating agent, and then, if necessary, increase the rate The temperature of the source water and, conversely, with a decrease in the oxygen concentration relative to a predetermined value, first reduce the temperature of the source water, and then the temperature of the heating agent.