RU231408U1 - Gas-liquid ejector for vacuum ejection treatment of waste and drinking water - Google Patents

Abstract

The utility model relates to the field of jet technology, in particular to liquid-gas ejectors used to saturate a liquid with gas, compress gases or remove them, and can be used to purify wastewater and drinking water. The gas-liquid ejector for vacuum ejection treatment of wastewater and drinking water includes a coaxially mounted housing 1, a diffuser 2, a lock nut 3, an air supply pipe 4, and a replaceable nozzle insert 5. The housing 1 is made of chemically resistant impact-resistant plastic, in the form of a hollow cylinder. In the central part of the housing 1, a through radial opening is made, hydraulically connected to the air supply pipe 4, intended for sucking air into the mixing chamber 7, where it is mixed with the flow of purified water. The diffuser 2 is made of chemically resistant impact-resistant plastic. The threaded connection of the external thread 8 of the diffuser 2 and the internal thread 6 of the body 1 regulates the diameter d _cmsh of the mixing chamber 7. The lock nut 3, made of chemically resistant impact-resistant plastic, with an internal thread corresponding to the external thread 8 of the diffuser 2. Ceramic nozzles of various nozzle section diameters used in sandblasting are used as replaceable nozzle inserts 5. Replaceable ceramic inserts 5 protect the ejector structure from wear and corrosion. 1 ill.

Description

The field of technology to which the utility model relates

The utility model relates to the field of jet technology, in particular to liquid-gas ejectors used to saturate liquid with gas, compress gases or remove them, and can be used to purify waste and drinking water.

State of the art

A liquid-gas ejector is known (patent application No. 94037902, IPC class F04F 5/02, date of publication 10.07.1996), comprising a coaxially mounted active nozzle, a mixing chamber, a diffuser, a receiving chamber with a branch pipe for supplying a passive medium, and a branch pipe for supplying an active medium. The cavity of the branch pipe communicates with the mixing chamber at its inlet section by means of bypass channels equipped with control nozzles installed in the mixing chamber body and control throttles.

An adjustable water-gas ejector is known (RU Patent No. 2636275, IPC class F04F 5/04, date of publication 21.11.2017), comprising an input confuser 1, a diffuser 2 with an ejection gap 3 located between them, a branch pipe 4 for supplying gas communicating with the ejection gap 3 at the input of the confuser 2, at the point of its connection with the water supply pipeline an adjusting coupling 5 with a conical needle 6 is installed, which can move along the central axis of the confuser 2. The conical needle 6 is located along this axis and enters the confuser-diffuser transition, changing the area of its flow section during movement, the internal thread for fastening it to the external thread of the confuser 1.

An adjustable ejector is known (RU Patent No. 63472, IPC class F04F 5/48, date published 27.05.2007), including a housing containing medium supply pipes made of pipes connected in series with each other by means of flanges, a running unit consisting of a running nut with a flywheel mounted on it, a bearing, a retractable spindle with an indicator mounted on it perpendicular to a scale fixed to the housing, a distribution block, sealing rings, a central nozzle, an insert sleeve, a replaceable mixing chamber rigidly installed in an adapter and forming an annular supercharging nozzle with a diffuser, wherein through channels equally spaced along the diameter of the circle are made inside the diffuser in the axial direction from the inlet to the outlet section.

An ejector is known (RU Patent No. 40410, IPC class F04F 5/48, date published 10.09.2004), consisting of a housing containing passive and active medium supply pipes, made of pipes connected in series to each other by means of flanges, in coaxially executed bores of which a running unit is installed in the axial direction, consisting of a running nut with a flywheel mounted on it, a bearing, a retractable spindle with an indicator mounted on it perpendicular to a scale fixed to the housing, wherein the retractable spindle is rigidly connected to a distribution block, on the outer surface of which sealing rings are installed, including passive medium supply channels, a check valve installed in the low-pressure chamber, and a passive nozzle, an adapter, the outer surface of which is also provided with a sealing ring, together with the insert sleeve forming with the outer conical surface passive nozzle supersonic Laval nozzle (active nozzle) with oblique cut,

An ejector-mixer is known (RU Patent No. 222594, IPC class B01F 25/31, C02F 1/46, date of publication 05/17/2023), including a housing consisting of an input chamber, inside which there is a nozzle, and on the outside there are pipes for feeding the working fluid and the reagent solution, as well as a mixing chamber with an outlet pipe, and at the same time on the outside of the mixing chamber there are sources of magnetic and electric fields, and inside the mixing chamber there is a conical diffuser, and on the outside of the outlet pipe there is a grate with a live cross-section.

A liquid-gas ejector nozzle (variants) is known (RU Patent No. 2142073, IPC class F04F 5/46, published on 27.11.1999), intended for use in a liquid-gas ejector. The nozzle comprises a channel having an input part, tapering along the flow, and an output part, which are connected to each other. The surfaces of the input and output parts of the channel are connected to each other to form a sharp edge. In another embodiment, the surfaces of the tapering and output parts of the channel are connected to each other by a transition surface, the generatrix of which is made in the form of a curved line, the radius of curvature of which does not exceed 0.5 mm. As a result, energy losses in the nozzle are minimized.

The closest in design and area of application is the ejector-mixer (RU Patent No. 218231, IPC class B01F 25/10, C02F 1/46, date published 05/17/2023), including a housing consisting of an inlet chamber with a nozzle inside, and on the outside an inlet pipe for the liquid being purified and tangentially located to the housing pipes for feeding reagent solutions, as well as a mixing chamber with an outlet pipe, and at the same time, to improve mixing of reagent solutions and improve the quality of water purification, grooves are made inside the inlet chamber, and electrodes are installed inside the mixing chamber, connected to an alternating current source. The disadvantage of the given analogs and the prototype is the insufficient durability of the structures when working with aggressive environments.

Disclosure of the essence of the utility model

The technical result of the claimed utility model consists in increasing the durability of the design of a gas-liquid ejector for vacuum ejection treatment of waste and drinking water.

The specified technical result is achieved due to the fact that the gas-liquid ejector for vacuum ejection treatment of waste and drinking water includes a coaxially installed housing made of chemically resistant impact-resistant plastic in the form of a hollow cylinder with an external thread section, and the internal channel of the housing is made stepped with an internal thread section, while a through radial opening is made in the housing, hydraulically connected to the air supply pipe, while the diffuser is made of chemically resistant impact-resistant plastic, having the appearance of a hollow stepped cylinder with an external thread corresponding to the internal thread of the housing, while the lock nut is made of chemically resistant impact-resistant plastic , with an internal thread corresponding to the external thread of the diffuser, while a ceramic nozzle is used as a replaceable nozzle insert, coaxially installed inside the housing at the inlet of the water being purified.

Brief description of the drawings

Fig. 1 shows the design diagram of a gas-liquid ejector for vacuum ejection treatment of waste and drinking water.

Implementation of a utility model

The gas-liquid ejector for vacuum ejection treatment of waste and drinking water includes a coaxially installed body 1, diffuser 2, lock nut 3, air supply pipe 4, and replaceable nozzle insert 5.

The housing 1 is made of chemically resistant impact-resistant plastic, in the form of a hollow cylinder with a section of external thread from one of the ends. The internal through channel of the housing 1 is made stepped with a section of internal thread 6, made from the opposite end of the housing 1. In the central part of the housing 1 there is a through radial hole, hydraulically connected to the air supply pipe 4, intended for sucking air into the mixing chamber 7, where it is mixed with the flow of purified water, which promotes the oxidation of under-oxidized organic and inorganic substances in it.

Diffuser 2 is made of chemically resistant impact-resistant plastic, having the form of a hollow stepped cylinder with external thread 8 on the external cylindrical part with a smaller diameter, corresponding to internal thread 6 of body 1.

The internal through channel 9 of the diffuser 2 is made combined-conical in the cylindrical part with a large external diameter of the diffuser 2, passing into a cylindrical channel in the part with a smaller external diameter. Due to the threaded connection of the external thread 8 of the diffuser 2 and the internal thread 6 of the body 1, the diameter d _cmsh of the mixing chamber 7 is adjusted.

Lock nut 3, made of chemically resistant impact-resistant plastic , with an internal thread corresponding to the external thread 8 of diffuser 2, serves to fix the position of diffuser 2, preventing its accidental movement and ensuring stability of the settings.

Replaceable ceramic nozzles of various nozzle section diameters used in sandblasting are used as a nozzle insert 5. The nozzle insert 5 is coaxially installed inside the housing 1 at the inlet of the water being purified. Using nozzle inserts 5 with various nozzle diameters d _спл , by adjusting the pressure and flow rate, various levels of turbulence and the degree of aeration of the water being purified are created, affecting the efficiency of water saturation with oxygen, improving the process of contaminant oxidation. Replaceable ceramic inserts 5 protect the ejector structure from wear and corrosion.

Changing the ratio of the diameter d _cmsh of the mixing chamber 7 and the diameter of the nozzle d _spl allows for the regulation of the pressure and flow rate, which leads to the creation of optimal conditions for the formation of a stable gas phase and, as a consequence, the optimization of gas removal from the ejector discharge chamber.

The gas-liquid ejector for vacuum ejection treatment of waste and drinking water operates as follows:

Vacuum-ejection treatment of purified water, in which this design of gas-liquid ejector is used, is carried out due to the fact that purified water is fed under pressure into the ejector, in which the air fed into it and the discharged flow of purified water are mixed, the water is saturated with the supplied air, the non-oxidized components contained in the water are further oxidized, and the gas is then removed from the ejector's discharge chamber.

The purified water is fed to the inlet of the nozzle insert 5 of the body 1. At the outlet of the nozzle insert 5 with d _спл , in the low-pressure zone, air is drawn in from the branch pipe 4. In the mixing chamber 7, the oxidation of organic and inorganic substances occurs due to the oxygen contained in the incoming air. The resulting gas-liquid mixture is directed through the channel 9 of the diffuser 2 to the outlet of the ejector.

Depending on the volume of the pumped purified liquid, the design allows changing the diameter of the mixing chamber d _smsh 7 by connecting the internal thread 6 of the body 1 and the external thread 8 of the diffuser 2.

The ejection effect is achieved by giving the active medium a high speed on the nozzle of the product and thus obtaining a region of reduced pressure in the receiving chamber. In the mixing chamber 7 of the ejector, mixing and partial equalization of the pressures of the active and ejected media occurs. After which a smooth decrease in the flow rate and an increase in pressure are realized in the diffuser 2.

An example of calculating the main parameters of the ejector elements - the nozzle diameter d _spl and the mixing chamber diameter d _smsh - used in a technological system for cleaning waste and drinking water with a supply of purified water of about 29 ^m3 /hour, a number of ejectors of 10 pieces, and an inlet pressure of about 0.1 MPa.

Data for calculation:

provided that the purified liquid is distributed evenly - the flow rate is 2900 l/h for each ejector;

iron concentration in purified water - 1200 mg/l;

to oxidize 1 mg of iron in 1 liter of water, 0.14 mg of oxygen is used, while 1 ^m3 of water contains approximately 300 mg of oxygen;

for purified water with an iron concentration of 1200 mg/l, oxygen is supplied in a volume of 168 mg of oxygen per liter of purified water;

To oxidize the specified amount of iron in the purified water, air is supplied in the range of 168-300 mg oxygen/l of air or 0.56 l of air/l of water.

The required volume of air that passes through 2900 l/h of purified water was 1624 l of air per ejector. The diameter of the nozzle insert 5 of the ejector, taking into account the flow rate of 2900 l/h of purified water, a pressure of 0.1 MPa, was about 2.7 mm. It was experimentally determined that effective aeration of water is carried out with a ratio of the diameter of the mixing chamber 7 and the diameter of the nozzle insert 5 as 4:1. Accordingly, the diameter of the mixing chamber is 10.8 mm.

It has been experimentally established that with a nozzle diameter of insert 5 in the range of 3-5 mm, water flows at a high speed, increasing the volume of sucked air and increasing the aeration coefficient, but unstable, turbulent flows are formed, reducing the efficiency (quality) of mixing, and increasing energy costs, the efficiency of the device decreases.

It was also determined that with a nozzle diameter of 5 6-10 mm, aeration is less intense, but the mixing quality increases and the flow stability increases.

Thus, the degree of oxidation of organic and inorganic substances during vacuum-ejection treatment of waste and drinking water is carried out by the dependence of the diameter of the nozzle insert channel 5 and the diameter of the mixing chamber 7 of the ejector.

The technical result, consisting in increasing the durability of the structure when working with aggressive environments, is achieved due to the fact that the body 1, diffuser 2, lock nut 3 are made of chemically resistant impact-resistant plastic, and the nozzle inserts 5 with different nozzle diameters d _spl are made of ceramic.

Claims (1)

A gas-liquid ejector for vacuum ejection treatment of waste and drinking water, comprising a coaxially mounted housing, a diffuser, a replaceable nozzle insert, wherein the housing is made in the form of a hollow cylinder with an external thread section, and its internal channel is made stepped with an internal thread section, wherein a through radial opening is made in the housing, hydraulically connected to the air supply pipe, wherein the diffuser is made on the outside in the form of a hollow stepped cylinder with an external thread corresponding to the internal thread of the housing, wherein the lock nut is made with an internal thread corresponding to the external thread of the diffuser, characterized in that a ceramic nozzle is used as a replaceable nozzle insert, and the housing, diffuser and lock nut are made of chemically resistant impact-resistant plastic.