RU2074989C1 - Pneumatic ejector vacuum pump - Google Patents

Abstract

FIELD: fluidics. SUBSTANCE: flow section of nozzle is formed by two cones with narrowing parts directed towards each other. Ratio of maximum diameters of nozzle in way of flow of compressed air ranges from 1.44 to 1.76 and conicity of flow section of nozzle in way of flow ranges from 1: 13.5 to 1:16.5 and 1:40 to 1:60. EFFECT: enhanced reliability. 1 dwg

Description

 The invention relates to inkjet technology, specifically to a pneumatic ejector vacuum pump, which can be used in a wide variety of industries, for example, in galvanic industries for overflowing aggressive liquids (acids and alkalis), in machines for filtering and pumping various liquids, in paint and varnish industries for filtering and overflow of paints and varnishes and other liquids, high viscosity, as well as for transporting them through underground and other highways.

 Known ejector, [1] which can be used for pumping gas. It contains coaxial annular nozzles, a receiving and mixing chamber, a diffuser, coaxial nozzles for supplying an active and passive medium. In this case, the receiving and mixing chambers and the diffuser are formed by symmetrical grooves of two disks installed with a gap relative to each other, with the possibility of changing the bore, and the ejector is equipped with an additional supply of a passive medium. Due to the independent regulation of the annular nozzles and mixing chambers, more precise adjustment of this device is achieved.

 The disadvantages of this device include the design complexity, high consumption of compressed air, low suction force, low efficiency, (efficiency) of the ejector and a high noise level during its operation.

 Closest to the claimed object, we have chosen as a prototype, is a gas ejector [2] It contains a nozzle for high-pressure gas, a receiving and mixing chamber and a diffuser. The working surfaces of the ejector are covered with a protective material that is not wetted by moisture during the condensation process. This implementation of it allows you to prevent freezing of its working surfaces at the lowest material cost and ensures its high performance.

 The disadvantages of this gas ejector include a small suction force, high consumption of high-pressure gas, low efficiency and a high level of noise from it during its operation.

 The objective of the invention is to increase the suction force of the pneumatic ejector vacuum pump, reduce the flow of compressed air supplied to it, increase its efficiency and reduce noise during operation.

The task in the proposed technical solution is achieved by the fact that in a pneumatic ejector vacuum pump containing a nozzle for compressed air, a receiving and mixing chamber and a diffuser, the nozzle is made in the form of two conical holes with tapering sides to each other, with a taper along the compressed air 1/15 and 1/50 ± 10% with the ratio of the largest diameters of these cones equal to 1.6 ± 10% with the ratio of the largest cross-sectional area of the outlet cone to the cross-sectional area of the mixing chamber 0.3 ± 10%, while the pneumatic ejector vacuum pump is installed Inside the housing of the muffler, constructed as a cylindrical sleeve having a hole diameter of 2 mm 3 ^o C with a total passage area of 0,9 ± 10% of the output area of the slice cone.

 It is the proposed implementation of the active nozzle in the form of two conical holes tapering side to side, with a taper along the compressed air 1/15 and 1/50 ± 10% with a ratio of the largest diameters of these cones, / D / d /, equal to 1.6 ± 10% with the ratio of the largest cross-sectional area of the outlet cone to the cross-sectional area of the mixing chamber 0.3 ± 10%; in this case, a pneumatic ejector vacuum pump is installed inside the silencer body, made in the form of a cylindrical cup having openings with a diameter of 2-3 mm with a total passage area of 0, 9 ± 10% of the output area with cut diffuser, allows you to talk about the novelty and significant differences of the claimed technical solution.

 In FIG. 1 shows a general view of a pneumatic ejector vacuum pump. It contains a flange 1, it has a nozzle 2 with conical openings 3 and 4, with a taper along the compressed air 1/15 and 1/50 ± 10% and with a ratio of diameter D to diameter d equal to 1.6 ± 10% and fittings 5, 6 and 7. In the diffuser 8 there is a receiving chamber 9 and a mixing chamber 10. The muffler 11, consisting of an inner cup 12 with holes 13 and an outer cup 14 connected to the nozzle 7. The outer and inner cups 12, 14 are fastened with screws and nuts (not shown). Adjusting gaskets 15 are installed between the diffuser 8 and flange 1. And a plug 16 is installed in the muffler. All parts are made of polyethylene, which prevents them from freezing during operation at subzero temperatures.

 The pneumatic ejector vacuum pump works as follows: compressed air is supplied through the nozzle 5 to the nozzle 2, which, passing through the receiving chamber 9, the mixing chamber 10 and the diffuser 8 through the nozzle 6 connected to it capacity (not shown) pumping gases and creates It has a certain vacuum, with the help of which it is possible to overflow various liquids.

 Adjustment of work is carried out using gaskets 15, changing the size of the gap "e". And the condensate drain from the muffler 11 is produced by turning the plug 16.

 Thus, the proposed technical solution allows in comparison with the prototype to increase the suction force; reduce the consumption of compressed air, increase efficiency, and also reduce the noise level during its operation.

Claims (1)

 A pneumatic ejector vacuum pump containing a nozzle for supplying compressed air, a receiving and mixing chamber and a diffuser, characterized in that the flow part of the nozzle is formed by two cones facing the tapering part to each other, while the ratio of the largest diameters of the nozzle along the flow of compressed air is from 1 , 44 to 1.76, and the taper of the flowing part of the nozzle along the stream is respectively from 1 13.5 to 1 16.5 and from 1 40 to 1 60.