SU1282879A1 - High-rate bag filter - Google Patents

Abstract

The invention relates to gas cleaning and can be used to clean the air from dust in the systems of ventilation and aspiration of industrial enterprises. Its use will reduce aerodynamic resistance and reduce the production area occupied by the filter. A high-speed filter comprising a cylindrical body 1 is provided with a fairing 18 and blades that are attached to the fairing 18 and the bottom 14 arranged on the outside of the bottom 14, while the gas supply nozzle is installed coaxially to the body 1 and the filter element 13. Rapid rotation of the bottom 14 is provided by the action of compressed air on the blades. The air is swirled around the blades and wraps around the fabric of the filter element 13, preventing the dust from entering. The regeneration of the filter element 13 is performed by reciprocating it along the axis of the housing by shaking it. 3 il. e

Description

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The invention relates to gas cleaning and can be used to clean the air from dust in the systems of ventilation and aspiration of industrial enterprises.

The purpose of the invention is to reduce aerodynamic drag and reduce the production area occupied by the filter.

FIG. 1 shows the proposed filter, a general view; in fig. 2 — node I in FIG. one; in fig. 3 shows section A-A in FIG. one.

The high-speed baghouse includes a housing 1, a hopper 2 for collecting dust, and an open-ended regenerating device in the form of a pipe 3 with longitudinal slits 4 and a vertical partition 5 (Fig. 3). The casing 1 houses the impeller 6 attached to the cylinder 7 and the shell 8, which contains the ring 9 and enters the annular slot 10 of the collector 11, which is connected to the supply pipe 12. A filter element 13 is fixed on the shell 8, containing the bottom 14 with the disk 15 and coupling 16 (Fig. 2). The bottom 14 is made with a hole 17, a closed fairing 18 connected to the bottom 14 of the vanes 19. To the housing 1 adjacent inlet 20 and outlet 21 of the nozzle.

Placing the filter housing coaxially with the inlet port reduces the aerodynamic resistance of the filter due to the slight deviation of the filtered gas flow from its path of filtration and also reduces the production area occupied by the filter.

Making the bottom of the filter element with a hole and supplying it with a disk with a sleeve and a fairing also reduces the filter resistance as a result of a flow of regenerated air swirled with blades flowing around the filter element having the same direction of movement with the gas being cleaned and ejecting the flow of gas being cleaned with a stream of compressed air flowing through annular gap between bottom and fairing.

The filter works as follows.

The dusty air moving through the inlet nozzle 20 enters the filter housing 1, with a large fraction of the dust falling into the dust bin 2. The penetration through the filter element 13, the air acts on the impeller 6 and causes it to rotate and together with it the filter element 13, as well as the bottom 14 associated with it, with a fairing 18 and vanes 19. The compressed air supplied to the regeneration pipe 3 slit 4 centers. the cylinder 7 with the impeller 6 fixed on it, as well as the exit from the slots 4, is jetting the fabric of the filter element 13. In addition, the air coming out of the open end of the regeneration pipe 3 pulls the fabric of the filter element 13 by acting on the fairing 18 as well as tightens the filter element 13 by more rapid rotation of the bottom 14 relative to the shell 8. The faster rotation of the bottom 14 is provided by the action of compressed air on the vanes 19. The air coming out through the gap between the bottom 14 and the fairing 18 ivaets blades 19

 and wraps around the fabric of the filter element 13, preventing the penetration of dust into it. In addition, the compressed air ejected into the annular gap between the bottom 14 and the fairing 18 ejects the gas to be purified, which contributes to a decrease in the filter resistance. The compressed air supplied to the pipe 12 enters the collector 11 and through the annular slot 10 penetrates into the housing 1, preventing the flow of dusty air from the housing 1 into the gas duct. Simultaneously compressed air,

0 acts on the shell 8, creates an air gap between the end of the ring 9 and the collector 11, thereby ensuring the free rotation of the impeller 6. Under the action of the impeller 6, the filter element 13 tends to move along the movement of the cleaned air stream within the gap of the annular slot 10. In the opposite direction the filter element 13 returns under the influence of the regeneration tube 3 coming out of the end of the compressed air jet

Q is the inner surface of the flap 18. Thus, the filter element 13 performs a sharp reciprocating motion along the axis of the housing 1, which ensures the regeneration of the fabric of the filter element 13 by shaking it. Not existing capacity of the regeneration pipe 3 increases the partition 5 (Fig. 3), placed along its horizontal section. The application of the invention provides a reduction in aerodynamic drag as well as a reduction in production

0 of the area occupied by the filter as a result of placing the nozzle coaxially. body. In addition, to increase the degree of air purification from dust, filters can be positioned sequentially one after the other in the duct, and instead of compressed air of the working fluid into the regenerating tube, the functionality of the proposed filter can be expanded, while the filter element impeller performs the functions of a spout.

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Claims (1)

Invention Formula A high-speed baghouse containing a cylindrical body with gas inlet and outlet nozzles, a dust collecting bin, a regenerating device, and a filtering element mounted on the body axis with an impeller and bottom distinguish This is due to the fact that, in order to reduce aerodynamic drag and reduce the production area occupied by the filter, it is equipped with vanes and fairing placed on the outside made with the bottom hole, fixed on the inner surface of the bottom disk and clutch, while the blades are attached to the fairing and the bottom, and the gas inlet is installed along the axis of the housing. YES one 77 sixteen fPu2.2 Dust u2.b