RU2142417C1 - Process of vacuum deaeration of water - Google Patents

Abstract

FIELD: heat power industry. SUBSTANCE: invention can find use at thermal power stations and in boiler plants. Proposed process of vacuum deaeration of water by desorption of oxygen dissolved in water during contact in deaerator between treated water and heating agent- overheated water that is heated prior to feed into deaerator. Flash steam and deaerated water formed in process of deaeration are drained out of deaerator. Temperature of heating agent fed into deaerator is controlled by value of specified residual content of oxygen dissolved in deaerated water. EFFECT: enhanced efficiency and improved quality of vacuum deaeration of water thanks to keeping optimum temperature of heating agent. 1 dwg

Description

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

 Analogs are known - methods of vacuum deaeration of water, in which the desorption of oxygen dissolved in water is carried out by contacting the treated water in the deaerator and the heating agent - superheated water, which is heated to a predetermined temperature before being fed to the deaerator, the vapor formed and the deaerated water is removed from the deaerator ( see the directory "Vacuum Deaerators", Moscow: NIIINFORMTYAZHMASH, 1972, Fig. 15 on p. 15, Fig. 16 on p. 16 and descriptions thereto). This analogue is adopted as a prototype.

The disadvantage of analogues and prototype is the reduced efficiency of the method of vacuum deaeration of water due to excessive energy costs for heating the heating agent - superheated water before being fed to the deaerator, and in other cases due to a deterioration in the quality of deaeration. So, in accordance with the prototype, a heating agent is constantly supplied to the deaerator — superheated water with a temperature equal to or higher than 70 ^o C. Since the normative quality of water deaeration, characterized primarily by the content of dissolved oxygen in deaerated water, can be achieved in a number of modes, especially at low deaerator loads, at lower temperatures of the heating agent - superheated water, deaeration almost always occurs with excessive temperature of the heating agent and reduced efficiency. On the other hand, in a number of modes, despite maintaining the set temperature of the heating agent, this temperature may be insufficient to ensure the normative quality of deaeration, for example, at high loads of the deaerator. Thus, the second disadvantage of this method is the low quality of deaeration of water.

 The technical result achieved by the present invention is to increase the efficiency and quality of vacuum deaeration of water by maintaining the optimum temperature of the heating agent supplied to the deaerator.

 To achieve this result, a method is proposed for vacuum deaeration of water, in which the desorption of oxygen dissolved in water is carried out by contacting the treated water in the deaerator and the heating agent — superheated water, which is heated before being fed to the deaerator, and the vapor formed and deaerated water is removed from the deaerator.

 The difference of the proposed method is that the temperature of the superheated water supplied to the deaerator is controlled by the value of the predetermined residual content of dissolved oxygen in the deaerated water.

 Carrying out the temperature control of the heating agent supplied to the deaerator by the value of the specified residual dissolved oxygen content allows to ensure the quality and efficiency of vacuum deaeration by maintaining the optimum temperature of the heating agent, i.e. the exclusion of deaeration regimes with excessive or insufficient temperature of the heating agent.

 The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources, and the identification of sources containing information about analogues of the claimed invention, allowed to establish that the applicant did not find an analogue characterized by features identical to all the essential features of the claimed invention. The definition of the prototype, as the closest in the set of essential features of the analogue, allowed to identify the set of essential in relation to the technical result of the distinguishing features set forth in the claims. Therefore, the claimed invention meets the condition of "novelty."

 To verify the compliance of the claimed invention with the condition "inventive step", the applicant conducted an additional search for known solutions in order to identify features that match the distinctive features of the claimed method from the prototype. The search results showed that the claimed invention does not follow explicitly from the prior art for the specialist, since the influence of the transformations provided for by the essential features of the claimed invention on the achievement of the technical result is not revealed from the prior art determined by the applicant. In particular, the claimed invention does not provide for the addition of a known agent to any known part attached to it according to known rules to achieve a technical result in respect of which the effect of such additions is established. So, the operation of regulating the temperature of the heating agent cannot be attributed to such a transformation, since this operation in the claimed method is carried out in a different set of essential features of the method and according to different rules compared to known methods, which allows to achieve the desired technical result.

 Therefore, the claimed invention meets the condition of "inventive step".

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

 The drawing shows a schematic diagram of an installation for vacuum deaeration of water, explaining the method.

 The installation included in the heating water make-up water treatment system at a thermal power plant contains a vacuum deaerator 1 with connected pipelines of treated water 2, a heating agent — superheated water 3, deaerated water 4, evaporator 5, and a heater 6 installed on the pipeline of heating agent 3 and connected to the steam line 7. A regulating body 8 is installed on the steam line 7, connected to a temperature controller 9, to which a dissolved oxygen sensor 10 is mounted, mounted on the pipeline e 4.

 Consider a specific example of the implementation of the claimed method of vacuum deaeration of water.

The desorption of oxygen dissolved in water is carried out by contact in the DV-800 type deaerator of treated water supplied to the deaerator through pipeline 2 in an amount of 800 t / h and a heating agent — superheated water supplied in an amount of 280 t / h through pipeline 3. Deaerated water removed from the deaerator via pipeline 4, and the vapor formed during deaeration - through pipeline 5. The temperature of the heating agent supplied to the deaerator is controlled by the value of the specified residual dissolved oxygen content in the deaerated with 50 µg / l of water using a control valve 8 installed on the steam line 7, a temperature controller 9 and a sensor 10. So, when 800 t / h of treated water with a temperature of 30 ^o C and a heating agent are supplied to the deaerator, 280 in the amount of 280 t / h to maintain a predetermined residual content of dissolved oxygen of 50 mg / l, in the heater 6 heating agent - superheated water is heated to 100 ^o C. When changing any of the mode parameters, e.g., flow of treated water, the temperature of the heating agent is controlled by a given the residual oxygen content in deaerated water: when the flow rate decreases, the temperature of the heating agent is lowered, for which, with the help of the regulating body 8, to which the signal from the regulator 9 is supplied, the steam flow to the heater 6 is reduced, and when the flow rate of the treated water increases, the temperature of the heating agent is increased by increase the steam flow to the heater 6. In all other vacuum deaeration modes, the temperature of the heating agent is also maintained necessary and sufficient to ensure a given residual content dilution of dissolved oxygen 50 μg / l, which eliminates the work of the deaerator with excessive or insufficient temperature of the heating agent.

Thus, the above information indicates that when using the claimed method the following set of conditions:
- a tool embodying the claimed method is intended for use in industry in the field of heat power;
- for the claimed method in the form described in the claims, the possibility of its implementation using the means and methods described in the application is confirmed;
- a method of vacuum deaeration of water embodying the claimed invention, when implemented, is able to achieve the desired technical result.

 Therefore, the claimed invention meets the condition of "industrial applicability".

Claims (1)

 The method of vacuum deaeration of water, in which the desorption of oxygen dissolved in water is carried out by contacting the treated water and a heating agent in contact with the deaerator — superheated water, which is heated before being fed to the deaerator, the vapor formed and the deaerated water is removed from the deaerator, characterized in that the temperature control superheated water supplied to the deaerator is produced by the value of a predetermined residual content of dissolved oxygen in deaerated water.