SU613169A1 - Vortex pipe - Google Patents

Description

therefore, only one source of compressed gas is required.

However, this pipe is characterized by constructive complexity and insufficiently high thermodynamic efficiency, since through slit diffusers the selection takes place along the entire length of the pipe and the bypass gas has a high temperature.

The purpose of the invention is to develop thermodynamic efficiency.

This is achieved by the fact that an annular recess is made in the housing directly behind the snail nozzle inlet, to which the second end of the overflow pipeline is connected.

FIG. 1 schematically shows the proposed vortex tube; in fig. 2 is a sectional view in FIG. one.

The vortex tube contains a housing 1 with a snail nozzle inlet 2 connected via a trunk 3 equipped with a pressure gauge 4 and a thermocouple 5 to a source of compressed gas (not shown in the drawings). An annular undercut 6 is made in the housing 1 directly behind the nozzle inlet 2, and a diaphragm 7 is installed on the other side of the inlet 2 for outputting the cold flow. The hot flow nozzle 8 has a slot diffuser 9 at the outlet end. An overflow conduit 10 connected to the downstream zone of the nozzle 8 is connected to the other end of the recess 6. A pressure gauge 12 is installed in the conduit 10 to regulate the pressure of the bypass gas. temperature produced by thermocouple 13.

The vortex tube works as follows.

Compressed air (gas), entering through the nozzle inlet 2 into the housing 1 of the vortex tube, twists and divides into two streams: a cold stream coming out through the diaphragm 7 and a hot stream coming out of the pipe 8 through the slot diffuser 9. part of the air through the annular recess 6 is taken out to create an additional flow, the pressure of which is regulated by the valve 11. The additional flow is transferred through the pipe) to the 10 gorge in the paraxial zone of the socket 8. As experiments have shown, the selection of air flow 5 from the annular recess 6 with temperature, nical equal to the temperature of air entering the nozzle na input 2 is not uhudschaet characteristics of the vortex tube, and even more povyschaet them.

10 The air pressure in the undercut 6 is lower than at the inlet to the nozzle inlet 2 due to the fact that part of the pressure energy is expended on spinning the flow in the snail inlet itself. The extraction of a portion of air through the annular recess 6 to create an additional stream with a certain pressure prevents the use of a costly autonomous source of closed air. To increase the flow rate of the additional flow, the overflow conduit 10 may be connected to the active nozzle of an ejector sucking air from the atmosphere.

The proposed vortex tube can operate both in air and in gases and vapors.

Claims (2)

1. Piralischlnli Sh. D., Mikhailov V. G. Experimental investigation of a vortex tube with an additional flow. Trudy KuAI, Kuybishchev, vol. 56, 1973. 2. USSR author's certificate №399690, cl. F25B 9/00, 1971. ten pLLZ .; FIG.