SU1413300A1 - Multistage steam-jet ejector - Google Patents

Abstract

The invention relates to inkjet technology and m. B. used in multistage steam ejector designed to pump the gas-vapor mixture of devices operating under vacuum. The purpose of the invention is to increase the efficiency of the ejector. The compression stages 1 are successively communicated with each other and include coolers 2, supersonic nozzles 3 with equal areas of critical sections, displacement chambers 4 with cylindrical necks and diffusers 5. Ratio of areas of sections of necks of chambers 4 with cylindrical necks and diffusers 5. Ratio of sections of sections of necks of chambers 4 previous and subsequent steps is equal to two. The ratio of the areas of the output sections of the nozzles 3 of the previous and subsequent stages, as well as diffusers of the previous and subsequent stages is equal to two. With such ratios of flow areas of the nozzles, mixing chambers and diffusers, a significant increase in the ejection coefficient is achieved. 2 3. Clause f-ly, 1 ill. S

Description

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The invention relates to inkjet technology and can be used in multi-stage steam jet ejectors for pumping a vapor-gas mixture from apparatus operating under vacuum.

The purpose of the invention is to increase the efficiency of the ejector.

The drawing shows a multi-stage steam jet ejector.

The multistage steam ejector contains successively interconnected compression stages 1, including coolers 2, supersonic nozzles 3 with equal areas of critical sections, displacement chambers 4 with cylindrical necks and diffusers 5, the deviation of the areas of the sections of the neck 4 of the chambers 4, the previous and the subsequent stages 1 of compression is equal to two, from- fioiiicHne of the areas of output sections of nozzles 3 p) previous and the subsequent stages of 1 compression is two, the ratio of areas of output sections of diffusers 5 of the previous and the next stages 1 compression is two.

Multistage steam ejector works as follows.

The working steam, which has exhausted from the supersonic nozzles 3 into the displacement chambers 4, ejects the suction gas-vapor mixture successively in stages 1 of compression from the apparatus under vacuum.

The mixing of the working steam and the aspirated vapor-gas mixture is carried out in confused areas and throats of the chambers 1. In the diffusers 5, braking occurs with increasing vapor pressure.

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gas mixture. In chillers 2, cooling takes place 1.c; corn mixture, vapor condensation and removal of condensate.

The efficiency of the stepped ejector largely depends on the choice of the ratio of the flow areas of the nozzles 3, displacement chambers 4 and diffusers 5.

Based on the experimental study, it was found that an increase in the ejection coefficient is achieved at equal areas of the nozzle 3 neck sections, and the displacement area of the neck sections of the displacement chambers 4, the output sections of the nozzles 3 and diffusers 5 are reduced twice from the previous compression stage.

Claims (3)

1. A multi-stage steam jet ejector containing successively interconnected compression stages, including coolers, supersonic nozzles with equal areas of critical sections, displacement chambers with cylindrical necks and diffusers, that, in order to increase the efficiency, the ratio of the areas of the cross sections of the necks of the displacement chambers of the previous and subsequent compression stages is equal to two. 2. The ejector according to claim 1, characterized in that the ratio of the plots to the output plots nozzle sections of the previous and subsequent compression stages are two. 3. The ejector according to claim 1, characterized in that the ratio of the areas of the output sections of the diffusers of the previous and subsequent compression stages is two.