SU1511525A1 - Deaerating unit - Google Patents

Abstract

The invention can be used for thermal deaeration of feed and feed water in thermal power plants and in industrial heating boilers. The purpose of the invention is to increase the efficiency of the installation. The cylindrical body (K) 15 of the centrifugal-vortex deaerator is divided by an annular partition (П) 18 into the input and output bays 19 and 20 respectively. In the compartment 19, an annular plate 21 is formed, forming a gap 22 with an upper end cover 16 K 15, a discharge outlet 23 is connected to the central opening of the plate 21, and a condensate drain line 11 from the cooler is connected to a gap 22. In compartment 20 between P 18 and the bottom The end cover 17 K 15 can be concentrically mounted with the perforated shell 25. The compartment 20 can also be equipped with an annular П 31 forming the chambers 32 and 33, each of which is connected to the nozzle 28 for discharging deaerated liquid. The unit can operate in atmospheric and vacuum modes for the deaeration of both overheated and cold water. 2 hp f-ly, 3 ill.

Description

U

3151

The invention relates to a power system and industrial heat engineering and can be used for the thermal deaeration of feed and feed water in thermal power plants and in industrial heating boilers.

The aim of the invention is to increase efficiency.

FIG. 1 shows a deaeration plant; in fig. 2 - deaerator, longitudinal section; in fig. 3 is a section A-A in FIG. 2

The deaeration plant contains a deaerator 1, a vapor condenser 2, a tank 3, pipelines 4.5 and 6, respectively, supplying a deaerated liquid, draining the deaerated liquid and supplying a deaerating medium, each of which has regulators 7.8 and 9, pipeline 10, respectively. removing the vapor from deaerator 1 to cooler 2, line 1 1 condensate drain from cooler 2, steam to deaerator 1 and lines 12, 13 and 14 respectively supplying and discharging cooling medium to cooler 2 and venting from the last non-condensable gases.

The deaerator 1 has a cylindrical body 15 with upper and lower end flaps 16 and 17 and an annular partition 18 dividing the body 15 into an inlet 19 and an outlet 20 compartment. An annular plate 21 is formed in the inlet compartment 19, which forms a gap 22 with an upper collar 16, to the annular plate 21 a steam outlet pipe 23 connected to pipeline 10 is connected. The condensate drain line 11 from the condenser 2 is connected to the annular gap 22.

The annular shells 24 and 25 can be installed inside the housing 15 in the zone of the inlet 19 and the outlet 20 compartments between the partition 18 and the covers 16 and 17. The nozzles 26 are tangentially mounted on the shell 24 of the input compartment 19, and the shell 25 of the output compartment 20 is perforated.

The housing 15 in the zones of the inlet 19 and outlet 20 of the compartments is provided with nozzles 27 and 28, respectively, for supplying and discharging liquid. Nozzles 27 communicate via valves 29 with pipe 4, and nozzles 28 with a pipeline 5. In the absence of a shell 24, nozzles 27 are installed tangentially. To the lower part of the inlet compartment 19 through, the nozzle 30 and the regulator 9 are connected to a pipeline 6 for supplying a deaerating medium, for its additional supply the partition 18 can be made hollow and perforated. In the output compartment 20, an annular partition 31 can be additionally installed, dividing it into two chambers 32 and 33. In this case, each of the chambers 32 and 33 has a separate nipple 28 connected through its regulator 8 to the pipeline 5.

The installation works as follows.

The liquid to be deaerated (water) through line 4 through pipes 27 and 2 is fed into the inlet compartment 19 of the deaerator tangentially. The flow of deaerating medium (overheated water or steam) through conduit 6 and nozzles 30 through openings in shell 24 and partition 18 enters the inlet compartment 19. Flows of deaerated water and deaerating medium mix and rotate, causing the pressure in the fluid in the center of the flow to drop . A phase boundary is formed in the center of the deaerator 1. Vapor bubbles pass through a layer of water and are pushed beyond the interface. the liquid is then heated and released from the gases soluble in it.

The deaerated water passes along the partition 18 and enters the exit compartment 20, continuing to rotate. The same thing happens here with increasing twist radius, so that the pressure in the flow increases. The liquid is then removed from deaerator 1 through nozzles 28 through conduit 5 to storage tank 3. The evolved gases, together with the vapor phase, are removed from the deaerator through conduit 23 through exhaust conduit to cooler 2, where the vapor condenses and its condensate via line 1 returns to deaerator 15 in annular gap 22. Condensate flows down plate 21, mixes with the stream of deaerated water and is deaerated itself.

Installing the shell 24 with nozzles 26 allows you to organize a uniform supply of deaerated liquid in the inlet compartment 19, and the perforated shell 25 in the outlet compartment 20

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Compiled by L.Simoy L.T. Veselovska Editor Tehred A. Kravchuk Proofreader O. Tsiple

Order 5883/40

Circulation 381

VNIIPI State Committee for Inventions and Discoveries at the State Committee on Science and Technology of the USSR 113035, Moscow, Zh-35, Raushsk nab. 4/5

Production and Publishing Combine Patent, Uzhgorod, st. Gagarin, 101

8.3

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Claims (4)

Claim 1. A deaeration unit containing a centrifugal-vortex type deaerator, consisting of a cylindrical body with end caps and inlets for supplying and discharging a deaerated Liquid and a vapor outlet, an annular partition placed in the body separating its cavity at the inlet and outlet compartments, and an evaporator cooler with a line condensate drain, characterized in that, in order to increase work efficiency, an annular plate is additionally installed in the inlet compartment, forming a gap with an upper end cap, and a branch pipe pair is connected to the central opening of the plate, and condensate drain line from the cooler is connected to said gap. 2. Installation according to claim 1, wherein the perforated shell is concentrically installed in the output compartment of the housing between the partition and the lower end cover. 3. Installation according to claim 1, wherein the output compartment of the housing is additionally equipped with an annular partition forming a chamber, to each of which a pipe for removing the deaerated liquid is connected. —Tx] -fig. 1 Aa Compiled by L. Simoy Editor L. Veselovskaya Order 5883/40 Tehred A. Kravchuk Proofreader O. Tsiple Circulation 381 Subscription VNIIIPI State Committee for Inventions and Discoveries under the State Committee for Science and Technology of the USSR 113035, Moscow, Zh-35, Raushskaya nab., D. 4/5 Production and Publishing Plant Patent, Uzhhorod, st. Gagarina, 101