UA9011U - Swirl pipe - Google Patents

Abstract

The swirl pipe has the chamber of power distribution with cooling jacket and nozzle inlet, chamber for condensate collection, there the branch pipe with the cold flow unswirler is placed. The branch pipe with the unswirler is arranged with the inlet and the outlet parts placed with axial gap. At the side of the hot flow of the chamber of power distribution and at the outlet of the branch pipe with unswirler valves are placed. The chamber for collection of condensate is connected to the cooling jacket.

Description

Description of the invention

The useful model refers to means of regulating air temperature parameters. Useful model 2 refers to refrigeration equipment, in particular to installations that use the vortex effect of gas distribution into hot and cold streams and can be used in air conditioning and drying systems and other gases.

The closest known in terms of technical essence is the vortex tube, taken as a prototype, see Vortex tube, patent

of the Russian Federation Mo2052736, Cl. 2 25 89/04, Bul. Mo2 1996), which contains a nozzle inlet, an energy distribution chamber and a nozzle with a cold flow swirler, contains a cooling jacket and a condensate collection chamber. The energy distribution chamber is located in the cooling jacket, the nozzle with the cold flow diffuser is installed in the condensate collection chamber, the nozzle is made of inlet and outlet parts placed with a guaranteed axial gap, the diffuser is located in the outlet part of the nozzle, and the condensate collection chamber is connected to the cooling jacket .

The shortcomings of the known pipe include its insufficiently high thermodynamic efficiency. t The task of this useful model is to increase the temperature of hot air and decrease the temperature of cold air to increase its thermodynamic efficiency.

The task is solved by the fact that in the vortex tube, which contains the energy distribution chamber with a cooling jacket and nozzle inlet, the condensate collection chamber, which is made of inlet and outlet parts placed with an axial gap, a nozzle with a cold flow swirler installed in 70 a valve is installed at the outlet of the nozzle, on the side of the hot flow of the energy distribution chamber, while the condensate collection chamber is connected to the cooling jacket, according to the useful model, a valve is additionally introduced, installed at the outlet of the nozzle with a cold flow diverter, which allows you to adjust the ratio of hot and cold flow The analysis of known technical solutions in this field of technology showed that features distinguishing the proposed solution from the prototype were not found and therefore they 29 provide the claimed technical solution with the criterion of "Significant differences". shsh

The proposed technical solution is explained by the drawing, where in fig. the scheme of the vortex tube is shown.

The vortex tube includes a nozzle inlet 1, an energy distribution chamber 2 with a cooling jacket C and a nozzle 4 with a cold flow swirler 5, located in a condensate collection chamber 6, nozzle 4 is made of inlet 7 and outlet 8 parts placed with a guaranteed axial gap. The swirler 5 is installed in - the outlet part 8 of the nozzle 4. The condensate collection chamber 6 is connected to the cooling jacket with the nozzle 10. "-

A valve 9 is installed at the outlet of the energy distribution chamber 2 from the side of the hot flow, which regulates the ratio of hot and cold flows, and the same valve 11 is installed at the outlet of the chamber 2 from the side o of the cold flow. Ge")

The proposed vortex tube works as follows.

The compressed gas enters tangentially through the nozzle input 1 into the energy distribution chamber 2, where as a result of swirling, it is divided into hot and cold streams. The hot flow exits from the perforated area of the energy distribution chamber 2 through the valve 9. The swirling cold flow, which includes particles of ice and condensate formed as a result of the cooling of vapors in the compressed gas, exits from the axial area of the energy distribution chamber 2 distribution through nozzle 4, swirler 5 and 70 valve 11. During the passage of cold flow in the zone of the guaranteed axial clearance, particles of ice and condensate c under the action of centrifugal force are thrown through this gap into the condensate collection chamber 6. Condensate that :z" accumulates flows along nozzle 10 into the cooling jacket C, where it is heated and evaporated, as a result of which the chamber 2 of the energy distribution cools down.

Thanks to the introduction of the valve, which allows you to adjust the ratio of hot and cold flow, at the outlet 15 of the nozzle with a cold flow deflector, there is an opportunity to significantly increase the thermodynamic efficiency of the vortex tube, as well as to increase the reliability of its operation. (ав) Application of the proposed design of the vortex tube allows to increase its thermodynamic efficiency - in comparison with the existing vortex tubes. another 50

Claims (1)

The formula of the invention is a vortex tube containing an energy distribution chamber with a cooling jacket and a nozzle inlet, a condensate collection chamber, in which there is a nozzle made with inlet and outlet parts located at a distance of 5 mm with an axial gap, a nozzle with a cold flow deflector installed in the outlet part of the nozzle, a valve is installed on the hot flow side of the energy distribution chamber, while the condensate collection chamber is connected to a cooling jacket, which is distinguished by the fact that it additionally contains a valve installed at the outlet of the nozzle with a cold flow diffuser. 60 b5