RU2003125210A - AXIAL FAN OPERATION METHOD AND AXIAL FAN - Google Patents

Claims (35)

1. The method of operation of the axial fan, including the unwinding of the air flow by the blades and its advancement in the pressure head round channel, characterized in that in the pressure channel the axial flow is organized opposite to the movement of the main stream. 2. The method of operation of the axial fan according to claim 1, characterized in that the axial flow is organized as a result of the return of part of the main flow due to its reflection from the cover installed at the end of the pressure channel. 3. The method of operation of the axial fan according to claim 1, characterized in that the axial flow is organized as a result of introducing an additional flow through the cover of the pressure channel. 4. The method of operation of the axial fan according to claim 2, characterized in that the axial flow is organized by cutting out part of the main stream with the sharp edges of the reflector having a cup-shaped (concave) shape. 5. The method of operation of the axial fan according to claim 4, characterized in that the axial flow is organized due to the smooth bending of the protrusion located along the axis of the bowl-shaped reflector. 6. The method of operation of the axial fan according to claims 2 and 3, characterized in that the axial flow is organized by mixing part of the main stream and the stream leaving the axial hole located in the cover of the pressure channel. 7. The method of operation of the axial fan according to claims 3 and 6, characterized in that the amount of gas supplied is regulated through an axial hole located in the cover of the pressure channel. 8. The method of operation of the axial fan according to claim 1, characterized in that at the outlet of the reflector, the axial flow is straightened (rotation is stopped). 9. The method of operation of the axial fan according to claim 1, characterized in that the axial flow is removed from the channel through the hollow fan hub. 10. The method of operation of the axial fan according to claim 9, characterized in that they create a vacuum inside the hollow core of the fan. 11. The method of operation of the axial fan according to claim 9, characterized in that they create a vacuum at the outlet of the hollow fan hub. 12. The method of operation of the axial fan according to claim 1, characterized in that on the inner surface of the energy separation chamber, radiation is emitted from the gas flows and removed from the radiation zone. 13. An axial fan containing a sleeve with blades mounted inside the casing, characterized in that the output part of the casing is made in the form of an elongated pressure channel, at the end of which a cover is installed, made for example in the form of a flow reflector, and the sleeve is hollow. 14. The axial fan according to item 13, wherein the beginning of the elongated pressure channel is made in the form of a conical deflector, articulated by the wide side with the fan casing. 15. The axial fan according to item 13, wherein the flow reflector is made in a cup-shaped (concave) shape. 16. The axial fan according to item 13, characterized in that the bowl-shaped reflector of the flow has pointed edges. 17. The axial fan according to item 13, characterized in that in the center of the bowl-shaped reflector is a protrusion having a smooth mate with the concave surface of the reflector. 18. Axial fan according to claims 13 and 17, characterized in that the pressure channel cover has an axial hole located on the axis of the reflector. 19. The axial fan according to item 13, wherein the axial flow rectifier-expander is placed on the reflector. 20. The axial fan according to claim 13, characterized in that in the cavity of the sleeve there is a spiral guide made, for example, either in the form of a screw or spiral protrusions and / or grooves. 21. The axial fan of claim 13, wherein the sleeve cavity is connected to the suction side of the air pump. 22. The axial fan according to item 21, wherein the centrifugal air pump is located on the sleeve. 23. The axial fan according to item 13, wherein the length of the cylindrical pressure channel is in the range from 15 to 30 diameters. 24. The axial fan according to item 13, wherein the pressure channel is made conical. 25. The axial fan according to paragraph 24, wherein the length of the pressure cone channel is in the range from 5 to 10 of the initial diameter of the cone. 26. The axial fan according to paragraph 24, wherein the angle of the cone of the pressure channel is in the range from 4 to 15 angular degrees. 27. The axial fan according to item 13, wherein the inner surface of the energy separation chamber is designed to absorb radiation emanating from gas flows. 28. The axial fan according to item 27, wherein the inner surface of the energy separation chamber has a dark color. 29. The axial fan of claim 28, wherein the inner surface of the energy separation chamber is roughened. 30. The axial fan according to claim 28, characterized in that the inner surface of the energy separation chamber is covered with a layer having the property of an Absolutely Black Body. 31. The axial fan according to item 27, wherein the inner surface of the energy separation chamber is coated with a smooth layer transparent to the trapped radiation. 32. The axial fan according to p. 31, characterized in that the smooth transparent layer and the absorbing surface are placed with a gap. 33. The axial fan of claim 32, wherein the gap is filled with coolant. 34. The axial fan according to claim 33, wherein the coolant is dark in color or dye is introduced into it. 35. The axial fan according to claim 33, characterized in that the cavity formed by the gap between the smooth transparent layer and the absorbing surface comprises nozzles connected to a device for pumping coolant.