RU51407U1 - VACUUM EJECTOR - Google Patents

Abstract

The utility model relates to inkjet technology and can be used in vacuum systems, namely in steel vacuum systems.

The technical problem solved by the utility model is to increase the reliability of the regulatory device, the durability of the structure, simplicity of design, ease of maintenance.

A vacuum ejector comprising a receiving chamber with a confuser portion, a mixing chamber, a diffuser, an active nozzle, a nozzle for supplying an active medium and a regulating device installed at the inlet of the active nozzle is characterized in that the regulating device is made in the form of a needle installed in the nozzle for supplying active environment.

Description

The utility model relates to inkjet technology and can be used in vacuum systems, namely in steel vacuum systems in the production of steel in a converter and its subsequent casting on continuous casting machines (CCM).

A known vacuum ejector comprising a housing with a receiving chamber of an active medium, an active nozzle, a mixing chamber, a diffuser and a rotating interrupter with openings installed in the receiving chamber in front of the active nozzle. The ejector is equipped with a cap mounted at the outlet of the diffuser. (A.S. No. 1420247, class F 04 F 5/04).

The disadvantages of the known vacuum ejector are the large dimensions of the device as a whole, the difficulty in maintenance.

The closest analogue to the claimed device is a vacuum ejector containing a receiving chamber with a confuser section, a mixing chamber, a diffuser, an active nozzle, a pipe for supplying an active medium and a control device installed at the entrance to the active nozzle. (RF patent No. 2056546, F 04 F 5/20).

The disadvantages of the known vacuum ejector are the unreliability of the control device, inaccurate control of the flow rate of the active medium, fragility, design complexity, difficulty in maintenance.

The technical problem solved by the utility model is to increase the reliability of the regulating device, the durability of the structure, the simplicity of the structure, ease of maintenance, reduced accident rate during casting, and increased productivity of continuous casting machines.

The stated technical problem is solved in that in a vacuum ejector containing a receiving chamber with a confuser section, a chamber

mixing, a diffuser, an active nozzle, a nozzle for supplying an active medium and a regulating device installed at the entrance to the active nozzle, in contrast to the closest analogue, the regulating device is made in the form of a needle installed in a nozzle for supplying an active medium.

The essence of the utility model lies in the fact that when executing a regulating device in the form of a needle installed in a nozzle for supplying an active medium, leakages of the active medium are excluded, the range of regulation of the flow rate of the active medium is expanded, and the accuracy of regulation is increased. This design is more reliable, durable, easy to tin.

The drawing shows a vacuum ejector, a longitudinal section.

The vacuum ejector contains a receiving receiving chamber 1 with a confuser portion 2, a mixing chamber 3, a diffuser 4, an active nozzle 5, a nozzle for supplying an active medium 6 and a regulating device 7. The regulating device 7 is made in the form of a needle and installed in the nozzle for supplying an active medium 6 at the entrance to the active nozzle 5.

Vacuum ejector works as follows.

Steam is supplied through a pipe for supplying an active medium 6 through a regulating device 7, made in the form of a needle, into the active nozzle 5, which sets it to a supersonic speed. Due to the high steam velocity in the confuser part 2, gas is captured from the receiving chamber 1, which is connected to the gas duct 8. This leads to a vacuum in the evacuated cavity. In the mixing chamber 3 there is a mixture of steam and gas. Through the diffuser 4, the vapor-gas mixture is supplied to the next stage of the steam jet pump, designed to remove gases from the steel.

The vacuum ejector of the proposed design was tested in the oxygen-converter shop of OJSC “Magnitogorsk Iron and Steel Works” in a steam ejector pump to remove gases from steel in the process of evacuation.

Using this design allowed us to improve the operation of the steam jet pump without disrupting the vacuum mode during metal processing, thereby improving the preparation of the metal for casting, reducing the accident rate during casting, and increasing the productivity of continuous casting machines.

Claims (1)

A vacuum ejector comprising a receiving chamber with a confuser portion, a mixing chamber, a diffuser, an active nozzle, a nozzle for supplying an active medium and a regulating device installed at the inlet of the active nozzle, characterized in that the regulating device is made in the form of a needle installed in the nozzle for supplying active environment.