SU1650209A1 - Bag filter - Google Patents

Abstract

The invention relates to dust collection equipment. Its use makes it possible to increase the efficiency of hose regeneration and operational reliability. The filter includes a housing with inlet and outlet nozzles, a partition with sleeves and a regenerating device in the form of a chamber and a rod for transmitting the shaking forces to the sleeves. The upper part of the chamber is provided with a pipe connected to the purge gas supply collector, and the lower part is connected to a purge nozzle. The rod is placed inside the nozzle and is equipped with a hemisphere, with the concave part facing in front of the purge gas flow. The sleeves are fixed on the partition through the elastic elements. When the purge gas is introduced into the chamber, the latter is removed into the concave part of the hemisphere, inserting the sleeve through the rod, changes its direction and enters the sleeve cavity through the purge nozzle, blowing through its walls. The filter can be equipped with shells, placed coaxially with the outer surface of the sleeves and made with openings and flap valves on the lateral surface, as well as shut-off valves with an electromagnetic actuator installed in the upper part of the nozzles of each chamber 1 Cfp, 6 silt (Ls

Description

The invention relates to dust collection, namely, devices for cleaning air from dust, and can be used in various sectors of the national economy.

The purpose of the invention is to increase the efficiency of hose regeneration, operational reliability and productivity.

Figure 1 shows the scheme of the proposed filter, a general view; figure 2 - node I in figure 1 (regenerating device); on fig.Z - section aa in figure 2; figure 4 is a filter sleeve with a casing; figure 5 - section bb in figure 4; figure 6 - node

II in figure 4 (the time of the reverse purge of the sleeve with the casing).

The bag filter includes a housing 1 with an inlet 2 and an outlet 3 with nozzles, a horizontal partition 4 with filter sleeves 5 and a regeneration device in the form of a chamber 6, and a rod 7 for transmitting jogging forces to the sleeves.

Camera 6 is located above each sleeve. The upper part of the chamber 6 is equipped with a nozzle 8 connected to the collector 9 of the pulsed flow of purge gas, and the lower part is connected to the purge nozzle 10. The rod 7 is placed coaxially inside

A purge nozzle 10 and a bottom end of the radial rods 11 are connected to a support ring 12, on which the upper part of the sleeve is fixed. The upper end of the rod 7 is provided with aerodynamic resistance in the form of a hemisphere 13 placed in the chamber 6 with a gap. The hemisphere 13 is installed with a concave part under the nozzle 8. The output part of the nozzle 8 is designed as a confuser 14. The sleeves 5 are fixed to the partition 4 through elastic elements 15.

It is advisable that each sleeve be provided with a housing 16 coaxially fixed with a gap, provided with openings 17 with flap valves 18, for example, in the form of a rubber cylindrical ring reinforced around the perimeter of the housing 16 in its middle part.

In this case, on the pipe 8, a stop valve 19 with an electromagnetic actuator must be installed.

Bag filter works as follows. The dust-laden gas through the nozzle 2 enters the interstitial space, is filtered through the walls of the sleeves 5, exits through their upper open part and through the nozzle 3 is sent to the consumer.

As the hydraulic resistance of the sleeves increases, they are regenerated by pulsed compressed gas through a manifold 9. Compressed gas is fed through pipe 8 to confusor 14, where its rate of flow increases significantly, a collision occurs in the concave part of the hemisphere 13, under the action of which the rod 7 descends sharply down along with the sleeve 5, compressing the elastic element 15, shaking the sleeve. After the collision with the hemisphere 13, the gas flow abruptly changes its direction and flows around this aerodynamic resistance, pulling out of the nozzle 10 into the inside of the sleeve 5, which ensures the sleeve blowing, as the gas pulses alternate after a short period of time, the sleeves are intensely vibrated with their simultaneous blowing, which creates an effective removal of dust from the pores of the fabric of the sleeves.

Due to the fact that the hemisphere is facing the gas flow by a concave part, a significant part of the energy of the gas pulse is spent on the shaking pulse by transferring it to the rod 7.

When installing covers 16 and valves 19 with an electromagnetic drive, it is possible to filter the gas while simultaneously regenerating one or several hoses. In this case, the valve 19 opens the nozzle 8 and the gas impulse passes inside the sleeve, producing simultaneously its shock by analogy with that described. When passing through the wall of the sleeve, the purge gas blows out dust and closes the valves 18. thereby isolating the sleeve from supplying the dusty gas from the interstitial space to filtration. Dust, along with a stream of purge gas moving down the gap between the casing 16 and the sleeve, comes out of the lower end of the casing, where due to a sharp fall

0 speed dust settles to the bottom of the case. In this way, it is possible to alternately regenerate all the hoses without stopping the filter. In the absence of a hose purge, the source gas freely opens

5 flap valves 18 and filtered through a sleeve.

The technical and economic efficiency of the proposed filter is to improve the quality of gas cleaning from dust to

0 by increasing the shaking pulses on the sleeves due to the installation of aerodynamic drag inside the chamber in a hemispherical form with a concave part against the flow of purge gas.

5Installation of sleeves on the horizontal

the septum through the elastic elements reduces the consumption of a shaking pulse on this septum and thereby contributes to an increase in the efficiency of regeneration

0 sleeves.

In the case of using covers on each sleeve, it is possible to perform alternate regeneration of the sleeves at the time of filtration, which increases

5 filter performance up to 15-20% due to the continuity of its work.

The walls of the chamber are rigid, which allows to increase the reliability of the regenerating device, and therefore also the filter.

Claims (2)

Claims 1. Bag filter comprising a body, filter sleeves fixed on a horizontal partition and 5, a regenerating device in the form of a chamber placed above each sleeve, the upper part of which is provided with a nozzle connected to the collector of the purge gas supply, and the lower part is connected to the blowing nozzle, and a rod for transmitting the shaking forces to the sleeves characterized in that. in order to increase the efficiency of regeneration of the sleeves and reliability in operation, the filter is equipped with a semi-sphere placed in a chamber with a gap, a concave part of which is installed under the chamber nozzle and attached to the upper end of the rod located coaxially inside the purge nozzle and fixed with its lower part on the upper part of the sleeve . the outlet part of the nozzle is made in the form of a confuser, and the sleeves are attached to the partition by elastic elements. 2. The filter according to claim 1, characterized in that, in order to increase the productivity, the filter is provided with covers placed coaxially with the outer surface of the sleeves and made with openings and flap valves on the side surface and shut-off valves with an electromagnetic actuator installed in the upper part of the nozzles. 19 9 86 Ii / / FIG. I / rb / Fig.Z il. ehhhh oooh FI.5 oooh oooh J AT 18 Phie, 6