RU2280012C1 - Method of the two-stage deaeration of water - Google Patents

Abstract

FIELD: heat power engineering; methods of deaeration of the feeding water on the heat power plants and in the industrial steamed boiler rooms.

SUBSTANCE: the invention is pertaining to the field of the heat power engineering and may be used for deaeration of the feeding water on the heat power plants and in industrial steamed boiler rooms. The method of the two-stage water deaeration provides, that desorption of the dissolved corrosive-active gases is conducted first in the vacuum deaerator, the formed vented steam is withdrawn through the pipeline for the vented steam withdrawal; the deaerated water is removed into the tank-collector of the vacuum deaerator. Further the water is subjected to deaeration in the high pressure deaerator. At that the vacuum deaerator and the high pressure deaerator are mounted on the tank-accumulator of the high pressure deaerator and the heating agent is fed into the vacuum deaerator from the water space of the tank- accumulator of the high pressure deaerator due to rarefaction in the vacuum deaerator. The invention ensures reduction of the overall dimensions, reduction of the losses of heat and expenditures on the heat transfer mediums pumping over inside the installation.

EFFECT: the invention ensures reduction of the overall dimensions, the reduced losses of heat and expenditures on the heat transfer mediums pumping over inside the installation.

3 cl, 1 dwg

Description

The invention relates to the field of power engineering and can be used for deaeration of feedwater in thermal power plants and in industrial steam boiler rooms.

An analogue is known - a method of two-stage deaeration of water, in which the desorption of dissolved corrosive gases is carried out first in a vacuum deaerator by contacting the source water and the heating agent, the resulting vapor is discharged through the discharge pipe, and the deaerated water is discharged into the vacuum deaerator storage tank, then water deaerated in the deaerator of high pressure, deaerated water is discharged into the storage tank of the deaerator of high pressure, installed under it (see AS No. 1028945, M. Cl. F 22 V 1/00). This analogue is adopted as a prototype.

The disadvantage of this method is the reduced efficiency due to the need for large capital costs for the construction of the installation and the building in which it is located, as well as for the installation of long pipelines connecting the vacuum deaerator and deaerator of high pressure.

The technical result achieved by the present invention is to increase the efficiency of the method of two-stage deaeration of water by reducing its size, reducing heat loss and the cost of pumping coolant inside the installation.

To achieve this result, a method of two-stage deaeration of water is proposed, according to which the desorption of dissolved corrosive gases is carried out first in a vacuum deaerator, the resulting vapor is discharged through the discharge pipe, the deaerated water is discharged into the vacuum deaerator storage tank, then the water is deaerated in a high pressure deaerator, deaerated water is diverted to the storage tank of the high pressure deaerator installed under it.

The peculiarity lies in the fact that the heating agent in a vacuum deaerator located on the accumulator tank of the high pressure deaerator is supplied from the water space of the accumulator tank of the high pressure deaerator; from the vacuum deaerator, deaerated water is discharged into the vacuum deaerator storage tank placed under the pressure storage tank of the deaerator; steam to the ejector of the vacuum deaerator is supplied from the heating steam pipe of the high pressure deaerator.

The new interconnection of elements allows to increase the efficiency of the two-stage deaeration of water by reducing capital costs for the installation of the installation, reducing the length of pipelines and building volume required to accommodate the installation, as well as by reducing heat losses and the cost of transporting coolants inside the installation.

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 two-stage deaeration plant, explaining the proposed method.

The installation contains a vacuum deaerator 1 with pipelines of source water, a heating agent and a vapor outlet, connected by a pipeline of a deaerated water to a storage tank of a vacuum deaerator 2, a deaerator of high pressure 3 with pipelines of a deaerated and deaerated water, a heating agent and a vapor outlet mounted on a storage tank 4 high pressure deaerator 3. Vacuum deaerator 1 is installed on the storage tank 4 high pressure deaerator 3. The storage tank of the vacuum deaerator 2 is located under the tank ak the accumulator 4 of the high pressure deaerator 3. The pipeline of the heating agent 5 of the vacuum deaerator 1 is connected to the water space of the storage tank 4 of the high pressure deaerator 3. The pipeline of the working medium of the ejector 6 of the vacuum deaerator 1 is connected to the pipeline of the heating agent 7 of the high pressure deaerator 3.

Consider an example of the implementation of the claimed method of two-stage deaeration of water. The source water is supplied to the vacuum deaerator 1, water is supplied to it from the storage tank 4 of the high pressure deaerator 3 as a heating agent. The vapor removal from the vacuum deaerator 1 is carried out using a steam ejector 6. After the vacuum deaerator 1, the deaerated water is discharged into the storage tank 2, from which a pump is fed to the high pressure deaerator 3. A heating agent is supplied to the high pressure deaerator 3 — steam, which is also supplied as a working medium to the steam-jet ejector 6 of the vacuum deaerator torus 1.

Due to the placement of the vacuum deaerator 1 on the storage tank 4, heat losses from the deaerator to the environment are reduced and the consumption of the heating agent supplied through pipeline 5 is reduced for vacuum deaeration. In addition, the proposed solution allows to increase the efficiency of the water deaeration method by reducing capital costs by the construction of a deaeration plant, reducing the length of pipelines and the construction volume necessary to accommodate the installation.

Claims (3)

1. A method of two-stage deaeration of water, in which the desorption of dissolved corrosive gases is carried out first in a vacuum deaerator, the resulting vapor is discharged through the discharge pipe, the deaerated water is discharged into the vacuum deaerator storage tank, then the water is deaerated in a high pressure deaerator, deaerated in the accumulator tank of the high pressure deaerator installed below it, characterized in that the heating agent is in a vacuum deaerator located on the deaerator storage tank high pressure torus, fed from the water space of the storage tank of the high pressure deaerator due to the vacuum in the vacuum deaerator. 2. The method of two-stage deaeration of water according to claim 1, characterized in that the deaerated water is drained from the vacuum deaerator into the vacuum deaerator accumulator tank located under the pressure deaerator accumulator tank. 3. The method according to claim 1, characterized in that the steam to the ejector of the vacuum deaerator is supplied from the heating steam pipe of the high pressure deaerator.