RU1827441C - Multi-stage jet-type pumping unit - Google Patents

Abstract

SUMMARY OF THE INVENTION: Each of the series-mounted gas-liquid jet pumps is made with a cylindrical displacement chamber, a receiving chamber, a diffuser and a nozzle (P) for supplying an active medium. The receiving chamber of the first stage is connected to the source of the pumped pulp. P supply of the active medium of the last stage is connected to a source of compressed air. The diffusers of jet pumps are made in the form of separators with an input P mixture of media and output P liquid and air. The inlet П of the mixture of media of each separator is connected to the mixing chamber of the corresponding jet on: coca. The output P of the liquid and the output P of the air of the separator are connected respectively to the receiving chamber of the pump of the next stage and to P of supplying the active medium of the previous stage. The output liquid P of the separator of the last stage is connected to the pressure pipe. The trick P of the air of the first stage is connected with the atmosphere. Jet pumps are made with the same weight ejection coefficient. The length of the mixing chamber of each pump is 7-10 diameters. 1 silt

Description

The invention relates to the construction, in particular, to hydrotransport systems for pumping abrasive and aggressive liquids and can be used in industrial enterprises of various fields.

The purpose of the invention is to expand the scope and increase the efficiency of a multi-stage jet pump by eliminating the energy of the working gas stream.

The drawing shows a diagram of a multi-stage inkjet installation.

The installation consists of series-connected gas-liquid ejectors, each of which contains a receiving chamber 1, a nozzle of the working stream 2, a cylindrical mixing chamber 3 and a vortex chamber 4. The latter is

a planar cylindrical volume having a tangentially located inlet for mixture 5, an outlet for liquid 6 and a centrally located nozzle for venting air 7. The inlet pipe of the mixture 5 of each vortex chamber directly connected to the mixing chamber 3 of the corresponding ejector, while the outlet of the liquid pipe 6 is connected to the receiving chamber 1 of the ejector of the next stage, and the outlet pipe of air 7, through the air duct 6, is connected to the air inlet of the working nozzle 2 of the previous stage ejector moreover, the outlet pipe of the liquid 6 of the last stage connected to the discharge pipe 9, and the air outlet 7 of the vortex chamber of the initial stage is in communication with

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the atmosphere. The receiving reservoir of the pulp 10 is connected to the receiving chamber 1, the ejector of the initial stage, and the compressed air source 11 is connected to the input of the nozzle 2 of the ejector of the last stage.

The installation works as follows.

After filling the system with water, from source 11; compressed air is supplied to the nozzle of the final stage. As a result, the ejector of the first stage takes liquid from the receiving tank 10, and after mixing, the air-water mixture, under pressure, through the inlet pipe 5, feeds into the vortex chamber 4, where air and liquid flows are separated as a result of circulation. At the same time, due to centrifugal forces, due to the high-pressure head, an increase in the pressure of the fluid flow occurs in the vortex chamber, which enters the next stage of the ejector through the outlet pipe 6, and the process is repeated after repeated ejection. Consequently, the fluid flow, passing all the stages, gradually increases its specific energy and is transported through the outlet pipe of the liquid of the last stage through the discharge pipe 9.

The air flow passed through the nozzle of the ejector of each stage, starting with the final one, gradually transfers its energy to the fluid flow and from the vortex chamber of the initial stage through the pipe 7, enters the atmosphere.

The number of stages of the installation is determined from the calculation that the ratio of the flow rates at the inlet of each ejector should provide a subsonic flow of the mixture flow along the flow part of the jet apparatus.

The economic effect of the proposed invention is that

the serial connection of gas-liquid ejectors, with vortex separators of flows, can significantly increase the efficiency of the installation and expand its scope.

Claims (1)

SUMMARY OF THE INVENTION A multi-stage jet pump installation comprising a pressure pipe, a source of pumped pulp, a source of compressed gas and sequentially installed gas-liquid jet pumps, each of which is provided with a cylindrical mixing chamber, a receiving chamber, a diffuser and a nozzle for supplying an active medium, while the receiving chamber of the jet pump the first stage is connected to the source of the pumped pulp, and the pipe for supplying the active medium the jet pump of the last stage is connected to a source of compressed air, characterized in that the diffusers of the jet pumps are made in the form of separators with an inlet nozzle of the mixture of media and outlet nozzles of the liquid and air, and the inlet nozzle of the mixture of media of each separator is connected to the mixing chamber of the corresponding jet pump, and fluid outlet and outlet separator air are connected respectively to the receiving chamber of the next stage jet pump and to the inlet of the active medium of the previous stage, while the outlet pipe of the last stage separator liquid is connected to the pressure pipe, the outlet pipe of the first stage separator air is connected to the atmosphere, and the jet pumps are made with the same weight the ejection coefficient and the length of the mixing chamber of each jet pump is 7-10 diameters thereof.