SU859313A1 - Vacuum deaeration unit - Google Patents

Description

The invention relates to a power system and can be used in heat exchangers of the succeeding type, mainly deaerators.

Known vacuum deaeration unit containing a deaeration column with pipelines for supplying a heating medium and feed water and a storage tank 0].

The disadvantage of this setup is that θ is that, to ensure reliable deaeration, the deaeration column contains a complex system of bubblers and inkjet plates and sectional partitions serving _tJ to increase the surface and contact time of interacting phases. The relationships only under certain _m sheniyah irrigation density and velocity of the first stream. Failure to comply with these ratios leads to a deterioration in the quality of deaeration.

Closest to the proposed is a vacuum deaeration unit containing a deaeration column with pipelines for supplying a heating medium and feed water communicated through manifolds with tangential nozzles, and a storage tank

The disadvantage of this setup is that at given speeds of movement of the interacting media, the transition from the drip mode of deaeration to the emulsified mode is not ensured. Drops of liquid retain their shape, which provides an almost constant contact surface of the phases. An increase in the intensity of the mass transfer process is possible only when the droplets are crushed into parts.

The purpose of the invention is to increase the efficiency of deaeration by intensifying mass transfer.

This goal is achieved by the fact that the tangential nozzle is made with an oblique cut and placed in one plane of the cross section of the deaeration column, and ejector partitions are installed in front of each tangential nozzle.

Figure 1 shows the proposed installation, a longitudinal section; figure 2 is a section aa in figure 1.

The vacuum deaeration unit contains a deaeration column 1 communicated via a deaeration water discharge pipe 2 with a storage tank 3, heating pipes and feed water pipelines 4 and 5, respectively connected to the manifolds 6 and 7 and tangential nozzles 1 and 8 with nozzles 8 and 9. Tangential nozzles 8 and 9 are located diametrically opposite in column 1 and are made with an oblique cut. In front of each tangential nozzle 8 and 9, directed tangentially to the circumference of the deaeration column 1, ejecting partitions 10 having the shape of a circular arc are placed.

Installation works as follows.

Feed water through the supply pipe 4 enters the collector 6 and then into the tangential nozzle 8. The heating medium through the supply pipe 5 enters the collector 7 and then through the tangential nozzle 9 into the lower part of the deaeration column 1, where it boils and is divided into steam and water and mixes with feed water. Due to the diametrically opposite placement of the tangential nozzles 8 and 9 in the lower part of the deaeration column 1, a uniform distribution of fluid flows is ensured. As a result of the interaction of the contacting media, they are intensively mixed, the cold feed water is heated to the saturation temperature and its deaeration by steam released from superheated water.

High flow rates disperse the gaseous medium

859313 ₄ in a liquid, an emulsification regime occurs corresponding to a region of freely developed turbulence, at which the mass transfer intensity increases. The mixing effect is enhanced by the ejection partitions 10. A liquid is sucked into the wide part of the passage between the column wall and the partition 10 ₍₀ from the central part of the deaeration column, which leads to repeated mixing of the contacting media.

As a result of the intense mutual _J5 action of the contacting media in the proposed installation, the mass transfer intensity increases, which increases the deaeration efficiency. In addition, simplifies the design and reduce. The dimensions of the installation are shaded due to the exclusion of bubblers and inkjet plates, as well as sectional partitions, which leads to a decrease in the cost of its manufacture.

Claims (2)

The invention relates to a power system and can be used in heat exchangers of the mixing type, mainly deaerators. Known vacuum-deaeration installation, containing deaeration column with a wedge and supply of heating medium and feed water and storage tank. serving to increase the surface and contact time of the interacting phases. In this case, the limiting drip mode of an apparatus of the jet type can only be achieved at certain ratios lotnosti reflux and velocity of the first stream. Non-observance of these ratios leads to deterioration of the quality of deaeration. Closest to the proposed is a vacuum-deaeration installation, containing a deaeration column with supply lines for the heating medium and feedwater, communicated through collectors with tangential nozzles, and the storage tank 23. The disadvantage of this installation is that interaction of the media is not provided a transition from the drip deaeration mode to the emulsified mode. Liquid droplets retain their shape, which provides an almost constant surface contact of the phases. Increasing the intensity of the process of mass transfer is possible only when crushing the droplets into pieces. The purpose of the invention is to improve the efficiency of de-aeration of mass exchange intersification. This goal is achieved by the fact that the tangential nozzles are made 3 with an oblique cut and placed in the same plane of the cross section of the deaeration column, and ejecting partitions are installed in front of each tangential nozzle. Figure 1 shows the proposed installation, a longitudinal section; figure 2 - section aa in figure 1. Vacuum-deaeration installation contains deaeration column 1, communicated by pipeline 2 of deaeration water to tank storage battery 3, pipelines 4 and 5 supplying heating medium and feed water respectively, connected to collectors 6 and 7 and tangential1 in nozzles 8 and 9. Tangential nozzles 8 and 9 are diametrically opposed in column I and are made with an oblique cut. In front of each tangential nozzle 8 and 9, directed along the tangent to the circumference of the deaeration column 1, ejection partitions 10, having the shape of an arc of a circle, are placed. The installation works as follows. Feed water through the pipeline 4 supply enters the collector 6 and then into the tangential nozzles 8. The heating medium through the pipeline 5 under the yes enters the collector 7 and then through the tangential nozzles 9 - into the lower part of the deaeration column 1, where it is boiled, divided into steam and water and mixed with feed water. Due to the diametrically opposite placement of the tangential nozzles 8 and 9 in the lower part of the deaeration column 1, the fluids are evenly distributed. As a result of the interaction of the contacting media, they are intensively stirred, heating cold feed water to the saturation temperature and its deaeration with steam, leached out of the superheated water. A higher flow rate leads to dispersion of the gas medium 34 in the liquid, and emulsification mode No. 1 occurs in the region of free-flowing turbulence, at which the intensity of mass transfer increases. The mixing effect is enhanced due to the ejection partitions 10. Fluid is sucked into the wide part of the passage between the wall of the column and the partition 10 from the central part of the deaeration column, which leads to multiple mixing of the contacting media. As a result of intensive interaction of the contacting media in the proposed installation, the intensity of mass transfer increases, which increases the efficiency of deaeration. In addition, the design is simplified and the size of the installation is reduced by eliminating bubbling and jet plates, as well as partitioning partitions, which leads to a reduction in the cost of its manufacture. The invention of the Vacuum de-aeration installation comprising a de-aeration column with pipelines for supplying heating medium and feed water, communicated through collectors with tangential nozzles, and a tank-battery, which, in order to increase the efficiency of de-aeration, the tangential nozzles are made with a slanting cut and placed in the same plane of the cross-section of the deaeration column, and ejecting partitions are installed in front of each tangential nozzle. Sources of information taken into account in the examination 1. Vacuum deaerators. M., Niyformt Zhmash, 1972, p.15. 2. USSR author's certificate No. 51 1291, cl. C 02 B 1/10, 1974 (prototype). .g one. Sh s / t 1 Riga.1 -CE (ri. g YU