RU2004103544A - METHOD OF OPERATION OF THE VORTEX DEVICE AND THE VORTEX DEVICE - Google Patents

Claims (19)

1. The method of operation of a vortex device, including passing a gas stream through a nozzle, accelerating and cooling it, and also tangentially supplying a curved wall to the inner surface of the curvilinear wall, characterized in that after cooling the flow, the cold is taken from the outside of the heat-conducting curved wall. 2. The method of operation of the vortex device according to claim 1, characterized in that after cooling the flow in the accelerating nozzle and before selecting the cold flow is passed through the nozzle extension. 3. The method of operation of the vortex device according to claim 1, characterized in that in the process of moving along a curved wall, the flow is isolated (separated) from the axis of rotation using a circular deflector. 4. The method of operation of the vortex device, including passing a gas stream through the nozzle, its acceleration and cooling, as well as its tangential supply to the inner surface of the curved wall, characterized in that after cooling, condensate is taken from the part of the stream moving along the inner peripheral curved surface. 5. The method of operation of the vortex device according to claims 1 and 4, characterized in that the flow is fed to the input of the vortex tube energy separation chamber. 6. A vortex device containing a supply nozzle and an inner surface of a curvilinear wall tangentially conjugated thereto forming a swirl chamber, characterized in that the length of the curved surface tangentially conjugated with a supply nozzle is made larger than the nozzle inlet section (L> h). 7. The vortex device according to claim 6, characterized in that the feed nozzle is associated with a curved surface through an extension of the nozzle. 8. The vortex device according to claim 7, characterized in that the length L _{2 of the} nozzle extension is taken based on the condition L ₂ ≥ W ₂ t _k , where W ₂ is the flow rate in this section; t _k is the time required for the condensation jump to occur. 9. The vortex device according to claim 6, characterized in that along the axis of the cavity formed by the curved wall, a deflector is arranged in the form of a round rod or a hollow tube. 10. The vortex device according to claim 9, characterized in that the wall of the deflector is made of porous material. 11. The vortex device according to claims 6 and 7, characterized in that the wall of the curved surface and / or nozzle extension is made of porous material. 12. The vortex device according to claim 7, characterized in that the swirling chamber is made in the form of a curved (twisted) tube (tubular spiral). 13. The vortex device according to claim 6, characterized in that on the outer side of the wall there is a heat exchange device. 14. The vortex device according to item 13, wherein the heat exchange device is made in the form of heat exchange ribs. 15. The vortex device according to item 13, wherein the heat exchange device is made in the form of a heat pipe. 16. The vortex device according to claim 6, characterized in that the swirl chamber has a conical shape. 17. The vortex device according to claim 6, characterized in that the peripheral part of the curved wall contains a condensate collector. 18. The vortex device according to claim 6, characterized in that the output of the swirl chamber is connected to the input of the energy exchange chamber of the vortex tube through a confuser. 19. The vortex device according to PP.17 and 18, characterized in that between the swirl chamber and the input of the energy exchange chamber is located the entrance of the condensate collector.