SU1307152A1 - Vacuum deaerator - Google Patents

Abstract

The invention relates to a power system and m. used in thermal power plants and in industrial heating boilers. The invention allows to improve the deaeration process by increasing the intensity of heat and mass transfer and hydrodynamic stability on a bubbling sheet. In the evaporative compartment, a partition (P) U is installed, forming together with housing 1, part of the bubbling sheet 4 and vertical P 8, the steam distribution chamber (K) 11. P 8 in the upper part is made perforated and forms a hydraulic lock 12 together with P 10 and sheet 4. Overheated water (TL) is fed through pipe 13 to K 11, where, after boiling, it evaporates. The vaporized part of the liquid, having passed through the perforation P 8, is condensed in the jet compartment. The non-evaporating part of the PS through the water seal 12 and the section 14 of the sheet 4 is displaced from the K11 to the main section of the sheet 4. The other part of the RO through the pipe 9 is fed into the evaporation compartment, where it boils and passes through Sheet intensive processing. 1 il. & (L

Description

The invention relates to a power system and industrial heat engineering, namely to devices for carrying out vacuum de-aeration of water, and can be used in thermal power plants and in industrial heating boilers.

The aim of the invention is to improve the de-aeration process by increasing the intensity of heat and mass transfer and hydrodynamic stability on a bubble sheet.

The drawing shows a deaerator incision.

The device contains installed in the housing 1 water distributors 2 and 3 of the bubbling sheet 4, pipes 5 and 6 for supplying and discharging deaerated water; the outlet pipe 7 of the exhaust and formed by the housing 1, the vertical partition 8 and the bubbling sheet 4 evaporating compartment with the fitting 9 supplying heated water, the partition 10 is installed in the evaporation compartment together with the housing 1, part of the bubbling sheet 4 and the vertical partition 8 chamber 11. The vertical partition 8 in the upper part is made perforated and, together with the partition ID and the bubbling sheet 4, forms a hydraulic lock 12, the steam distribution chamber 11 is provided with an additional atrubkom 13 for supplying superheated water

The deaerator works as follows.

The water to be deaerated through the nozzle 5 is fed successively through the water distributors 2 and 3 into the jet compartment, where it is subjected to heating and coarse deaeration, then enters the section 14 of the bubbling sheet 4 adjacent to the chamber 11, where it mixes with the fluid displaced from chamber 11, additionally heated to a temperature close to the saturation temperature. Then, the initial water enters the main area of the barbed sheet 4, undergoes final de-aeration and is discharged from the deaerator through the nozzle 6. The overheated water through the nozzle 13 is fed into the steam distribution chamber 11, where it is evaporated. Having evaporated with a part of the liquid, passing through the perforated zone of vertical

the baffles 3 are condensed in the jet compartment,

The evaporated part of the overheated water through the water seal 12 and the section 14 of the bubbling sheet 4 is expelled from the chamber 11 to the main section of the bubbling sheet 4, which raises the temperature of the deaerated water at the entrance to the main section of the bubbling sheet 4 to a temperature close to the saturation temperature, improving deaeration capacity and hydrodynamic stability of the bubbling device.

Another part of the superheated water through the pipe 9 is fed to the evaporator

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through the holes of the bubbling sheet 4, exposes the water intensive processing. The gases released during this process, with part of the uncondensed vapor, are discharged into the first stage of the jet stage, where the final vapor condensation occurs and the non-condensable corrosive gases are removed through the pipe 7.

The increase in the temperature of the source water at the entrance to the main section of the bubbling sheet 4 to a temperature close to the saturation temperature, due to the additional use of heat of the heating fluid in the initial portion of the bubbling sheet 4, increases the intensity of heat and mass transfer and the hydrodynamic stability of the bubble stage of the deaerator, which improves deaeration process.

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formula of invention

A vacuum deaerator containing water distributors installed in the housing along with water distributors, a bubbling sheet, inlet and outlet nozzles of deaerated water and formed by a housing, a vertical partition and a bubbling sheet, evaporative compartment, which is so as to improve the deaeration process by improving the intensity of the deaeration process by improving the intensity of the deaeration process. and hydrodynamic stability on a bubbling sheet, in the evaporative compartment, an additional partition is installed, which, together with the housing, forms a vertical floor egorodkoy and part of the bubble sheet steam distribution chamber and a lower part installed with a septum and dopolnitenyh

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with a bubbling sheet - a water seal, a steam distribution chamber with a vertical partition in it provided with an additional pipe of the upper part made perforated - the supply of superheated water.

Claims (1)

SUMMARY OF THE INVENTION A vacuum deaerator comprising belt-mounted water distributors installed in the housing, a bubbler sheet, inlets for supplying and discharging deaerated water and formed by a housing, a vertical baffle 'and a bubble sheet, an evaporation compartment, which allows for the purpose improvement of the deaeration process by increasing the intensity of heat and mass transfer and hydrodynamic stability on the bubble sheet, an additional partition is installed in the evaporation compartment, forming together with the housing , And a vertical partition plate part bubbling steam distribution chamber, and with further fixed nizhney'chastyu septum and bubbling leaf - water seal, wherein the vertical partition is formed in the upper part is perforated hydrochloric, and steam distribution chamber provided with an additional pipe for supplying superheated water.