RU70696U1 - LIQUID-GAS EJECTOR - Google Patents

Abstract

The proposed technical solution relates to inkjet technology and is aimed at improving the efficiency of the liquid-gas ejector. The liquid-gas ejector contains an active nozzle with trunks that are evenly spaced along its end surface at angles that ensure the axis of the trunks to converge at a point located in the center of the final section of the mixing chamber.

Description

The utility model relates to jet pumps, in particular to technical devices of liquid-gas ejectors, in which the induced medium is a stream of liquid flowing out under pressure from a multi-barrel active nozzle.

The proposed utility model can be used in various fields of technology, for example, energy in devices and installations for creating a vacuum, or installations for cleaning and vacuum drying of transformer oils.

Known and widely used in various fields of technology are liquid-gas ejectors containing an active nozzle, a cylindrical mixing chamber connected to an expanding conical diffuser.

(AS USSR No. 767405 according to class F04F 5/04 published September 30, 1980).

In the known device, the barrel of the active nozzle is located coaxially with the longitudinal axis of the ejector along the length of the mixing chamber having a fixed length.

During operation of the known device due to braking of a two-phase supersonic flow in an expanding diffuser, a pressure jump forms, the stability of the location of which determines the magnitude of the created vacuum in the mixing chamber, as well as the efficiency of the ejector. With the parallel arrangement of the active nozzle shafts, the location of the shock wave depends on the ratio of the areas of the nozzle and the mixing chamber, the length of the mixing chamber, the opening angle of the cone of the diffuser, and other design characteristics of the ejector. In addition, when the pressure of the active medium changes, the location of the shock wave changes, as a result of which the stability of the ejector, and therefore its efficiency, changes.

Thus, the problem of increasing the efficiency and stability of the liquid-gas ejector is to stabilize and fix the location of the shock wave along the length of the mixing chamber, the solution of the technical problem is to create such a design in which

the location of the shock wave would be fixed at a certain point along the length of the mixing chamber, and would not depend on the magnitude of the pressure change of the active medium.

Known liquid-gas ejector containing a receiving chamber, a cylindrical mixing chamber, an active nozzle with a nozzle with evenly spaced channels, the output sections of which have axes located at an angle to the axis of the nozzle, while the axis of each output channel is located at a variable angle to the axis of the nozzle. (A.S. USSR No. 1038618 according to class F04F 5/04, published August 30, 1982).

A disadvantage of the known technical solution is the complexity and reliability of sealing a rotating nozzle, resulting in a loss of pressure of the active fluid through the seals, and thus reduces the efficiency of the liquid-gas ejector. In addition, the implementation of channels in the form of holes with a variable angle of inclination to the axis of the nozzle leads to the formation of tangential rotation of the supersonic flow in the mixing chamber along a helical path, which leads to a loss of flow energy and does not allow stabilization of the location of the shock wave when the pressure of the active medium changes.

The formation of a helical flow in the mixing chamber does not allow the shock wave to isolate the interior of the mixing chamber from atmospheric pressure, which reduces the efficiency of creating a vacuum inside the liquid-gas ejector.

Also known is a liquid-gas ejector containing active nozzles with an oblique cut of the output section, a receiving chamber with a confuser output section, a mixing chamber and a diffuser. In the proposed ejector, the passage sections of the nozzles are cylindrical, and the angle of inclination of the output section of the active nozzles to the axis of the nozzles is 10-90 degrees.

The disadvantages of the known technical solutions are:

- reduced efficiency of the ejector due to the loss of part of the energy of the hydrodynamic fluid flow to overcome the resistance of the walls of the mixing chamber,

- the uncertainty of the location of the shock wave along the length of the mixing chamber due to the multiple reflection of part of the flow from the walls of the chamber

mixing due to the fact that the angle of the output section of the nozzles is more than 10 degrees.

Known liquid-gas ejector containing a multi-barrel active nozzle, a prechamber and a mixing chamber with a diffuser, while the nozzle shafts are arranged in pairs, and the axes of each pair are tilted one to the other and are located at an angle of 2-10 degrees to the ejector axis. (A.S. USSR No. 985462 in class F04F 5/04, published July 24, 1981)

The disadvantages of the known technical solutions adopted for the prototype are:

- uneven arrangement of the nozzle stems along the transverse projection of the mixing chamber, which leads to uneven splitting of the liquid droplets during the decay of the nuclei of the liquid jets when the flow moves inside the mixing chamber, which causes a decrease in the efficiency of the ejector,

- the paired arrangement of the barrel of the active nozzle leads to a unilateral collision between the pair of jets, which reduces the density of the shock wave, thereby causing a decrease in the efficiency of the ejector,

- in addition, the implementation of a liquid-gas ejector with an angle of inclination of the axes of the paired shafts of 2-10 degrees does not allow to fix the location of the shock wave at the end of the section of the mixing chamber of the ejector, as the most optimal, especially when changing the length of the mixing chamber of the ejector, which also leads to a decrease the performance of the liquid-gas ejector in question.

The purpose of the utility model is: increasing the efficiency of the liquid-gas ejector due to the fullest use of the energy of the collision of liquid droplets during the decay of the cores of adjacent jets of active liquid, and stabilization of the location of the shock wave at the end of the ejector mixing chamber.

This goal is achieved by the fact that in a liquid-gas ejector containing an active nozzle with shafts, a mixing chamber and a diffuser, the shafts of the active nozzle are evenly placed on the end plane of the nozzle with the axes inclined at an angle that ensures the convergence of the axes in the center of the final section of the mixing chamber.

The proposed technical solution is illustrated by the drawing, in which Fig. 1 shows a General view of the device in section, and Fig. 2 shows a fragment of a substantial part of the nozzle side.

The liquid-gas ejector contains an active nozzle 1 ending in shafts 2, which are evenly spaced along the plane of the nozzle. The trunks 2 are arranged in such a way that their axes are inclined to the axis of the mixing chamber 3, ensuring the convergence and intersection of the axes between themselves at a point located in the center of the final section of the mixing chamber in the immediate vicinity of the expanding diffuser 4.

The proposed device operates as follows.

The active liquid under excess pressure is supplied to the active nozzle 1, which contains evenly spaced shafts 2. Since the shafts are uniformly located along the plane of the nozzle, the liquid flows evenly out of the nozzle block 1 in the form of numerous jets, thus being uniformly distributed along the plane of mixing chamber 3. B due to the fact that the axis of the shafts are inclined to the axis of the displacement chamber at a certain angle, the convergence of intersecting disintegrating jets of fluid flow at a point located in the center of the final section of the chamber with mixing 3 in the immediate vicinity of the expanding diffuser 4. At the point of intersection of the jets, their additional and volume crushing occurs due to a more complete use of the kinetic energy of the outgoing jets. In this case, a “shock wave” is formed, which is guaranteed to be located in the final section of the mixing chamber 3 in the immediate vicinity of the expanding diffuser 4, which provides reliable “locking” of the mixing chamber and isolating it from external atmospheric pressure, which ensures an increase in the vacuum created by the ejector. A further increase in the pressure of the active medium at the inlet to the active nozzle increases the uniform additional crushing of the liquid jets, which ensures an increase in the effect of locking the mixing chamber, and, as a result, leads to an increase in the efficiency of the liquid-gas ejector. Regardless of the change in pressure of the active liquid, the location of the “shock wave” does not change.

When changing the length of the mixing chamber, only the angle of inclination of the shaft axes changes, the location of the “shock wave” and the additional effect of volumetric crushing of intersecting jets do not change, which also increases the efficiency of the liquid-gas ejector.

Claims (1)

A liquid-gas ejector containing an active nozzle with trunks, a mixing chamber and a diffuser, characterized in that the trunks of the active nozzle are evenly distributed along its end plane with the axes tilted at angles ensuring the convergence of the axes in the center of the final section of the mixing chamber.