RU2056545C1 - Water-jet ejector - Google Patents

Abstract

FIELD: fluid flow pumping. SUBSTANCE: water-jet ejector has common inlet chamber and flow-throw parts being connected in parallel to the inlet chamber. Each fluid mixture outlet pipeline is provided with compressed air inlet pipeline with pilot isolation valve. The valve is connected to fluid mixture outlet pipeline downstream from isolation valve. EFFECT: high pressure. 3 cl, 2 dwg

Description

 The invention relates to inkjet technology and can be used for pumping various media.

 Known water-jet ejector [1] containing four parallel-connected flow parts with a common receiving and discharge chambers, with four nozzles mounted in the upper receiving chamber, with each flowing part includes a cylindrical mixing chamber and a diffuser.

 The disadvantage of this ejector is the low efficiency of its use, for example, when the steam-air mixture is sucked from the condenser of a steam turbine, since the ejector is not regulated during operation, and the air suction in the condenser changes significantly during operation of the installation.

 Also known is an inkjet apparatus [2] comprising a receiving chamber with nozzles for supplying active and passive media, active nozzles radially located in the chamber, equipped with spring-loaded control needles connected to a drive rod mounted along the axis of the receiving chamber, the rod being mounted for rotation and configured to a radial hole and bevels located on one side of the axis of the hole, and the regulating needles are connected to the drive rod by means of cables passed through the radial hole and in contact x with bevels when turning the stem.

 The disadvantage of this jet apparatus is the impossibility of independent operation of the flowing parts, and therefore the range of regulation of its performance is limited.

 Structurally closer to the proposed one is a water-jet ejector [3] containing a common receiving chamber, at least two active nozzles and parallel flowing parts connected to the receiving chamber, the number of which corresponds to the number of active nozzles, each flowing part consists of a mixing chamber, a diffuser and a pipeline for discharging a mixture of media, each nozzle is equipped with a separate pipeline for supplying an active medium, and each pipeline for discharging a mixture of media and a pipeline for supplying an active medium are equipped with a regulating locking device.

 The disadvantage of such a water-jet ejector is the possibility of flooding the receiving chamber if it is turned on in a closed circuit.

 EFFECT: increased efficiency of using a water-jet ejector.

 The technical result is achieved in that in a water-jet ejector containing a common receiving chamber, at least two active nozzles and parallel flowing parts connected to the receiving chamber, the number of which corresponds to the number of active nozzles, each flowing part consists of a mixing chamber, a diffuser and a pipeline discharging a mixture of media, each nozzle is equipped with a separate pipeline for supplying an active medium and each pipeline for discharging a mixture of media and a pipeline for supplying an active medium are equipped with a control shut-off device, each pipeline for discharging a mixture of media is equipped with a pipeline for supplying compressed air with a controlled shut-off valve, the latter being connected to a pipeline for discharging a mixture of media behind a control shut-off device.

 A comparative analysis of the proposed technical solution and the prototype allows us to conclude that there are new distinctive features, therefore, the claimed technical solution meets the criteria of the invention of "novelty."

 In the known solutions to science and technology, no combination of distinctive features of the claimed solution was found, exhibiting similar properties and allowing to achieve the result indicated in the purpose of the invention, therefore, the solution meets the criteria of the invention "significant differences".

 In FIG. 1 shows a water-jet ejector, general view; in FIG. 2 shows a section AA in FIG.

 In the water-jet ejector containing a common receiving chamber 1, at least two active nozzles 2 and parallel to the receiving chamber 1 flow parts 3, the number of which corresponds to the number of active nozzles 2, each flow part 3 consists of a mixing chamber 4, a diffuser 5 and pipeline 6 for discharging a mixture of media, each nozzle 2 is equipped with a separate pipe 7 for supplying an active medium and each pipe 6 for discharging a mixture of media and a pipe 7 for supplying an active medium are equipped with a control shut-off device 8 and 9, each pipe the wire 6 for discharging a mixture of media is provided with a pipe 10 for supplying compressed air with a controlled shut-off valve 11, while the latter is connected to a pipe 6 for discharging a mixture of media behind a control shut-off device 8.

 The ejector can be equipped with active medium flow dividers, the number of which corresponds to the number of active nozzles. Active nozzles 2 can be multi-hole.

 Water jet ejector works as follows.

 At low ejector performance, the active medium, which may be water or another liquid, enters one of the active nozzles 2 by opening the corresponding control shut-off device 9 on the active medium supply pipe 7. The receiving chamber 1 is connected by a corresponding pipeline, for example, to the steam space of the turbine condenser, from which the air-vapor mixture is aspirated. At the same time, the regulating locking device installed on the pipeline 6 for discharging the mixture of media is open to the flow part 3, into the nozzle 2 of which the active medium is supplied.

 If it is necessary to increase the productivity of the ejector, the active medium is supplied to the second nozzle 2 by opening the corresponding control shut-off device 9. Moreover, before supplying the active medium to the nozzle 2 with a closed control shut-off device 8, it is purged with compressed air supplied through a controlled shut-off valve 11 and having a pressure slightly higher pressure behind the ejector diffuser behind the regulating shut-off device 8 of the pipeline 6 for removal of the mixture of media in order to remove water from it, and then When the air-water mixture enters the diffuser 5, the control shut-off device 8 opens and the ejector reaches full capacity or increased.

 Depending on the range of regulation of the performance of the ejector, the number of nozzles and, accordingly, the number of flow parts can be different. The proposed ejector provides the minimum energy consumption and the consumption of the working environment when working in fractional modes.

 In order to increase the efficiency, the ejector may contain active medium flow dividers, the number of which corresponds to the number of active nozzles 2, which, due to the separation of the active medium flow into many jets, increase the interaction surface of the active and passive media. The design of the flow dividers can be varied, and their arrangement in the ejector can also be different. Currently, various structural solutions for flow dividers and their installation locations in the ejector are known.

 Also, to increase the efficiency of the ejector, the active nozzles 2 can be made multi-hole, which improves the conditions for the interaction of two media by increasing the interaction surface. The characteristics of the nozzles, including geometric dimensions and others, and accordingly their flow parts can differ from each other, providing different performance in order to increase the number of partial modes of operation of the ejector.

 The use of the invention mainly in condensing units of steam turbines, as well as in other branches of engineering, allows to reduce energy consumption for the operation of the ejector due to the choice of rational modes of its operation, ensures the compactness of the ejector.

Claims (3)

 1. A WATER-JET EJECTOR, comprising a common receiving chamber, at least two active nozzles and parallel flowing parts connected in parallel to the receiving chamber, the number of which corresponds to the number of active nozzles, each flowing part consisting of a mixing chamber, a diffuser and a pipeline for discharging a mixture of media, each the nozzle is equipped with a separate pipeline for supplying an active medium and each pipeline for withdrawing a mixture of media and the pipeline for supplying an active medium are equipped with a regulating shut-off device, characterized in that each boprovod removal media mixture is provided with a compressed air supply duct with a controllable shut-off valve, the latter being connected to a conduit for removing a fluid mixture regulating shut-off device.  2. The ejector according to claim 1, characterized in that it is equipped with active medium flow dividers, the number of which corresponds to the number of active nozzles.  3. The ejector according to claim 1, characterized in that the active nozzle is multi-hole.

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