RU2353820C1 - Ejector - Google Patents

Abstract

FIELD: engineering industry.

SUBSTANCE: ejector is meant for transporting various working media. Ejector consists of a hollow casing with a side branch, a nozzle having outside thread at the inlet and connected to the hollow casing by means of a connection preventing nozzle rotation, and a mixing chamber, which are installed in hollow casing coaxially, thus forming therebetween a receiving chamber, diffuser and control mechanism equipped with rotation device thereof, which is rigidly attached to hollow casing. Nozzle is installed in hollow casing so that it can be moved axially, and is connected thereto by means of a key joint. At the outlet, nozzle is equipped with a hard-alloy head fixed by means of a bushing. Mixing chamber is rigidly connected to diffuser and fixed in hollow casing by means of a coupling nut. Control mechanism consists of a casing of bulk bearings, which is made in the form of a stepped bushing with inside thread that is a mating part relative to nozzle outside thread. Inside the casing of bulk bearings there rigidly installed is a branch pipe the middle part of outer surface whereof is made in the form of inner body meant for single bulk bearing, and the outlet end of branch pipe is located in nozzle inner part. Rotation device of control mechanism is made in the form of handles.

EFFECT: improving ejector operating efficiency.

1 dwg

Description

The invention relates to inkjet technology and can be used in the oil and gas industry.

Analysis of the existing level showed the following:

- an ejector is known, including a hollow body with a lateral outlet (supply pipe), a nozzle connected to the hollow body by a connection preventing the nozzle from rotating, and a mixing chamber coaxially mounted in the hollow body to form a receiving chamber between them, a diffuser and a control mechanism (regulating valve), equipped with a means of its rotation, rigidly connected with the hollow body (see AS “Jet pump” No. 775409 dated June 12, 78 according to class F04F 5/02, published in OB No. 40, 1980 )

The disadvantage of this device is the low efficiency of the device, due to the following.

The value of the maximum possible pressure of the ejector, the pressure of the gas injected in this case, and the ejection coefficient depend on the hydraulic characteristics of the apparatus, and the latter depends on the geometric characteristics of the ejector and the relative position of its main parts (nozzle, mixing chamber, diffuser, etc.). The impossibility of changing the distance between the nozzle and the mixing chamber during operation does not allow to achieve optimal parameters of the ejector at different technological modes. Changing the flow rate of active and passive media will lead to the need to change the geometric characteristics of the device, which cannot be done without stopping the process and dismantling the main parts of the device.

An ejector including a hollow body with a lateral outlet (suction channel), a nozzle (jet tube) having an external thread connected to the hollow body with a connection preventing the nozzle from rotating, and a mixing chamber coaxially mounted in the hollow body, with the formation of a receiving chamber between them, a diffuser and a control mechanism (moving device), equipped with a means of its rotation, rigidly connected to the hollow body (see AS "Variable displacement jet pump" No. 251372 dated 06.24.68, class F04F 5/00, publ. in ON №27, 1969) The diffuser is made receiving the conical cavity and the conical mixing chamber. The nozzle is connected to the hollow body by a pin connection, and the roller is the means of rotation of the regulation mechanism.

The disadvantage of this device is the low efficiency of the device, which is due to the following.

The diffuser moving device is made in the form of a bevel gear. When the diffuser moves downward, the resistance force arising in the thread will be directed upward. This will result in a gap between the lower surface of the gear nut and the horizontal bearing surface of the housing. In this case, the tangential force arising in the bevel gear applied in the same line of engagement will lead to the formation of torque on the gear nut in a vertical plane, which will lead to a skew of the latter and, accordingly, to possible jamming of the screw-nut gear.

The technical result that can be obtained by implementing the invention provides an increase in the efficiency of the device due to:

- the possibility of changing the hydraulic characteristics of the ejector during transportation of various media at different technological modes, without dismantling from the technological strapping;

- exclusions of jamming of the device.

The technical result is achieved using a known device comprising a hollow body with a lateral outlet, a nozzle having an external thread at the inlet, connected to the hollow body by a connection preventing the nozzle from rotating, and a mixing chamber coaxially mounted in the hollow body, with the formation of a receiving chamber between them, a diffuser and a control mechanism provided with a means of its rotation, rigidly connected with the hollow body.

According to the invention, the nozzle is mounted in a hollow housing with the possibility of axial movement and is connected with it by means of a key connection. At the exit, the nozzle is equipped with a carbide nozzle fixed by a sleeve.

The mixing chamber is rigidly connected to the diffuser and fixedly mounted in the hollow body with a union nut.

The control mechanism consists of a housing of bulk bearings, made in the form of a stepped sleeve with an internal thread, a reciprocal external thread of the nozzle, which ensures the movement of the latter in a hollow housing. The input of the bulk bearing housing is the outer cage of the single bulk bearing, and the output is the outer cage of the dual bulk bearing, in which the inner cage of the dual bulk bearing is rigidly connected to the input end of the hollow housing. A nozzle is fixedly installed inside the bulk bearing housing, the outer surface of which in the middle part is made in the form of an inner cage for a single bulk bearing, and the outlet end of the nozzle is located in the inner part of the nozzle.

The rotation mechanism of the control mechanism is made in the form of handles.

Thus, the claimed technical solution meets the criterion of novelty.

The analysis of the inventive step showed the following: from the sources of patent documentation and scientific and technical literature, we have not identified technical solutions that are based on features that match the distinctive features of the claimed technical solution. The technical result achieved is due to the unknown properties of the structural elements and the relationships between them, providing the ability to change the hydraulic characteristics of the ejector during transportation of various media at different technological modes, without dismantling from the technological strapping and eliminating jamming of the device.

Thus, the essential features claimed by us do not follow explicitly from the analyzed prior art, i.e. correspond to the condition of inventive step.

The drawing shows a longitudinal section of the proposed device.

The ejector comprises a hollow body 1 with a lateral branch 2. The ends of the hollow body 1 and side branch 2 have a connecting thread 3. In the hollow body 1, a nozzle 4 and a mixing chamber 5 are coaxially mounted, with the possibility of forming a receiving chamber 6. The nozzle 4 is installed with the possibility of axial movement in the hollow body 1 and is connected with the last key connection 7, preventing the rotation of the nozzle 4. At the inlet, the nozzle 4 has an external thread and is equipped with a hard alloy nozzle 8 fixed by a sleeve 9. The mixing chamber 5 is rigidly connected and with a diffuser 10 in a single unit and is rigidly fixed in the hollow body 1 with a union nut 11. The hollow body 1 is rigidly connected to the regulation mechanism. The control mechanism comprises a bulk bearing housing 12, made in the form of a stepped sleeve with internal thread. The internal thread of the bulk bearing housing 12 corresponds to the external thread of the nozzle 4, allowing the latter to move in the hollow housing 1. The input of the bulk bearing housing 12 is the outer race 13 of a single bulk bearing 14, and the output is the outer race 15 of a double bulk bearing 16. In the inner part of the outer race 15 of the double bulk bearing 16, an inner race 17 of the double bulk bearing 16 is mounted, rigidly connected to the input end of the hollow housing 1. Inside the housing of the bulk bearings 12 a pipe 18 is installed, the outer surface of which in the middle part is made in the form of an inner cage 19 of a single bulk bearing 14. The output end of the pipe 18 is located in the inner part of the nozzle 4. The control mechanism is equipped with a means of rotation made in the form of handles 20.

The device operates as follows.

The ejector is included in the process piping. Through the pipe 18 in the ejector serves the working fluid with high pressure. A stream of liquid flowing out of the nozzle 4 at high speed creates a vacuum in the receiving chamber 6 and ejects the transported medium from the lateral branch 2. Next, the jet of the working fluid with the transported medium enters the mixing chamber 5, where the flows are mixed, their velocities are balanced, and the kinetic energy of the mixed flow is partially converted to pressure energy. In the diffuser 10, the pressure of the mixed flow is finally restored to pressure — the pressure of the ejector.

Changing the hydraulic characteristics of the ejector during operation at different technological modes occurs due to a change in the distance between the nozzle 8 and the mixing chamber 5, which is carried out by the control mechanism without dismantling the ejector from the technological strapping. When the adjustment mechanism rotates, the threaded end of the nozzle 4 moves along the thread of the bulk bearing housing 12, smoothness of movement and preventing jamming of the nozzle 4 is ensured by the structural design of the bulk bearing housing 12 and bulk bearings 14, 16. The keyed connection 7 prevents the nozzle from rotating in the hollow housing 1. Full the overlapping nozzle 4 of the lateral outlet 2 of the hollow body 1 allows the use of an ejector as a conventional pipeline.

Thus, we can conclude that the proposed technical solution meets the criterion of industrial applicability.

The present invention meets the condition of patentability, as it is new, has an inventive step and industrial applicability.

Claims (1)

An ejector comprising a hollow body with a lateral outlet, a nozzle having an external thread at the inlet, connected to the hollow body by a connection preventing the nozzle from rotating, and a mixing chamber coaxially mounted in the hollow body to form a receiving chamber between them, a diffuser and a control mechanism provided means of its rotation, rigidly connected with the hollow body, characterized in that the nozzle is mounted in the hollow body with the possibility of axial movement and is connected with it by means of a key connection, while the nozzle at the outlet is equipped with but a nozzle made of hard alloy fixed by a sleeve, and the mixing chamber is rigidly connected to the diffuser and fixedly mounted in the hollow housing with a union nut, and the control mechanism consists of a bulk bearing housing made in the form of a stepped sleeve with an internal thread, a reciprocal external thread of the nozzle, providing movement the latter in a hollow housing, while the input of the bulk bearing housing is the outer cage of a single bulk bearing, and the output is the outer cage of a dual bulk bearing in which the inner sleeve of the double bulk bearing is mounted rigidly connected to the inlet end of the hollow housing, while a pipe is stationary inside the housing of the bulk bearings, the outer surface of which is made in the middle part as the inner race of a single bulk bearing, and the outlet end of the pipe is located in the inner part of the nozzle, and the means of rotation of the control mechanism is made in the form of handles.