SU1370398A1 - Aerodynamic drying unit - Google Patents

Abstract

The invention relates to the design of aerodynamic heating devices, in which the heat generator is a rotor of an aerodynamic heating fan driven by an electric motor, and m. used for drying glass wool coils in light and chemical industries when high intensity and uniformity of the drying or heat treatment process is required. The purpose of the invention is to improve the quality when drying material laid in the form of horizontal coils with axial channels. For this, the discharge channels on the supply side of the heat transfer fluid to the cells have walls with central holes 15 that coincide with the axial channels of the coils 13 and arcuate slots 16 located around the openings 15 and are made with an inner diameter equal to the outer diameter of the coils 13. Such a dryer design allows you to ensure the directional speed of the blower. The air entering through the holes 15 and the slots 16 blows the inner and outer surfaces of the coils 13, which leads to a deepening of the evaporation zone. 3 il. l

Description

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The invention relates to the design of aerodynamic heating devices, in which the main heat generator is an aerodynamic heating fan rotor (centrifugal heating rotor) driven by an electric motor and can be used for drying glass wool coils in light and chemical industries when high intensity and uniformity of process is required drying or heat treatment.

The purpose of the invention is to improve the quality when drying material laid in the form of horizontal coils with axial channels, by providing directional high-speed blowing.

FIG. 1 shows schematically the aerodynamic drying installation in FIG. 2 — node I in FIG. one; in fig. 3 shows section A-A in FIG. 2

The aerodynamic drying unit comprises a heat-insulated chamber 1, inside of which are located the drying chamber 2 and the rotor 3 of the aerodynamic heating fan. In front of the suction inlet of the rotor 3, a disk screen 4 and a steam radiator 5 are sequentially installed perpendicular to its axis, which are means for controlling the drying process. The walls 6 of the chamber 1 and the side walls 7 of the drying chamber 2 form injection channels 8 for supplying coolant to the drying chamber 2 at the location of the inlet and outlet openings 9 and 10. In the drying chamber 2 there is a closed overhead conveyor 11 passing through the openings with the stands 12, on which coils 13 with axial channels are located horizontally. Cages 12 periodically move around chamber 2 and have a strictly fixed position.

The injection channels at the point of supply of coolant to openings 9 and 10 and to the first and last cages 12 have walls 14 with central holes 15 and with arcuate slots 16. Holes 15 are on the same axis with the axial channel of the coils 13. Arched slots 16 They are located around the holes 15 and are made with an inner diameter equal to the outer diameter of the coils 13. In the side wall 6 of the chamber 1 there are nozzles 17 and 18 for drawing in fresh air and for ejecting part of the spent heat carrier, equipped with control flaps 19 and 20.

Aerodynamic drying j j

Novka works as follows.

The rotor 3 of the aerodynamic heating fan, rotating, creates air circulation through the closed loop RU channels 8 air through the walls 14 with openings 15 and slots 16 two opposite flows into the chamber 2, where it is mixed and directed to the preheated

f, the steam to the heater 5 blows through it and, skirting the disc screen 4, is sucked in by the rotor 3. When the unit is put into operation, the nozzles 17 and 18 are blocked by the control flaps 19 and 20.

0 After reaching the set temperature in the drying chamber 2, the automatic control system (not shown) reduces the steam supply to the heater 5, and through the opening 9 the conveyor 11

5 periodically starts the cage 12 with horizontally arranged glassworking coils 13. When the cage 12 is fed through the opening 9 to the wall 14, the air entering through the opening 15 and the slot 16 blows the inner and outer surfaces of the coils 13, which leads to a deepening of the evaporation zone . As the stands 12 move, the material is gradually dried to the required moisture. When the cage 12 is in the chamber 7. The position is in front of the opening 10 and is installed against the wall 14, the air through the hole system

0 15 and slots 16 again blows the inner and outer surfaces of the coils 13, heat-treating them, which completes the drying process.

The proposed installation is compact,

5 is simple in design, reliable in operation and maintenance.

Claims (1)

Invention Formula Aerodynamic drying unit containing a heat-insulated chamber with inlet and outlet openings, a closed conveyor carrying an adhesive with the material being dried and passing through the openings, the rotor of the aerodynamic heating fan connected to the -charging channels communicated with the cells in the place of their entrance BUT Fig.Z