UA10087U - Dust catcher with stepped separator and bunker - Google Patents

Abstract

Dust catcher with stepped separator and bunker contains housing, tangential inlet duct, axial outlet and dust-outlet branch pipes and louver separator. Louver separator consists of three sections of different diameter, the number of louver in which decreases in the direction toward dust-outlet branch pipe proportionally with the ratio of the diameters of sections of the separator, constituting in the same direction 4/3 and 3/2. The housing of apparatus unites dust-removing apparatus and bunker into one whole, the bunker having cylinder-conic shape.

Description

Description of the invention

The useful model is intended for cleaning the air from dust and can be used in all branches of the national 2 economy.

The closest to the proposed dust collector in terms of design is the device (A.s. Mo1606157 VO1045/12, Bull. Mo42 dated 11.15.1990) - a prototype that includes a body, a tangential inlet nozzle, axial: outlet and dust outlet nozzles and a shutter separator.

The dust-air mixture, entering tangentially into the body of the apparatus, makes a helical movement along the 70 spiral guide around the outlet nozzle, where, under the action of centrifugal forces, primary cleaning of the mixture takes place in a known manner. Then the already separated layer-by-layer flow, which moves around the grid of the louver separator, passes through the gaps between the louvers, making a sharp turn of a small radius at an angle greater than 90, but less than 180 degrees. At the same time, dust particles, due to their inertia, do not keep up with the flow and collide with the shutters of the separator. Thus, after making several collisions with the shutter 72 of the separator, dust particles fall into the flow moving either along the wall of the case, along the spiral guide, or into the air flow that rotates around the next shutter grid, where the cleaning process is similar. Passing in this way along all the louver grids, dust particles are discharged through the dust outlet. Purified air, which passes through the shutter separator, is discharged from the device through the outlet of the purified flow.

The known device cannot provide a significant increase in the efficiency of dust collection due to the impossibility of ensuring a constant speed of movement of the dust and gas flow through the openings between the blinds along its entire height from top to bottom, and, accordingly, the pressure across the cross-section of the device.

The basis of a useful model is the task of creating such a dust collector, in which the implementation of a louvered separator made of three sections of different diameters, the number of louvers in which decreases towards the dust outlet nozzle, allows maintaining a constant speed of movement of the dust-air mixture in the body of the apparatus /- when the dust-gas flow passes through the holes between shutters of the separator, allows to increase the efficiency of work, and the execution of the dust collector body in such a way as to combine the dust cleaning device and the hopper into one unit with certain ratios of the height and diameter of the device body to the height and diameter of the hopper and a certain diameter of the dust nozzle allows to normalize the pressure in the middle of the device and thereby reducing its hydraulic resistance, which in turn also leads to an increase in the capture efficiency. with

The task is solved by the fact that a dust collector with a step separator and a hopper, which contains a body, a tangential inlet nozzle, axial: outlet and dust outlet nozzles and a louver o separator, according to a useful model, the louver separator consists of three sections of different diameters, Ha») number of louvers in which it decreases in the direction of the dust discharge nozzle in proportion to the ratio of the diameters of the 3o separated sections, which is 4/3 and 3/2 in the same direction, and the body of the device unites the dust cleaning device -- and the hopper into one whole, and the hopper has a cylindrical conical shape.

Figure 1 shows a dust collector (general view).

Fig. 2 - louvered separator (bottom view, schematic). "

The dust collector consists of a body 1, a tangential inlet nozzle 2, axial nozzles for the outlet of purified air Z and dust outlet 4, a louvered separator 5, which consists of three sections 6, 7, c 8, a louver 9, a hopper 10, a nozzle for the dust outlet from the hopper 11 . with" The dust collector works as follows.

The dust-air mixture enters tangentially into the housing 1 through the nozzle 2, where it moves spirally from top to bottom. After entering the apparatus, the flow is affected by a force of force due to which the flow is separated into layers, and the flow approaches the louvered separator divided into two: a coarse flow moves near the wall - the body, and a finely dispersed flow moves around the exhaust nozzle. Blind av! separator 5 is the second stage of cleaning, when passing through it, the already layer-separated flow is further cleaned of finely dispersed dust particles, and after passing through the slits, it is carried out of the device through nozzle 3. Secondary cleaning of air from dust. is carried out sequentially in the direction of 20 to the dust discharge nozzle when passing sections 6, 7, 8 of the separator.

In order to maintain a constant speed of movement of the dust and gas flow through the gaps between the shutters of each section of the tm separator, it is necessary to reduce the area of their live cross-section.

It is clear from Figure 2 that the live cross-sectional area of each section of the separator is determined both by the distance between the blinds (perpendicular OB is the shortest distance between the blinds) and by the number of blinds. Based on the condition 29 of maintaining a constant velocity of the dust-air flow through the louvered separator in each of its sections, we assume that the perpendicular OB is constant for all sections (соп5зи), then the number of louvers in each subsequent section in the direction of the dust discharge nozzle will be reduced in direct proportion to diameters of each subsequent section to the previous one.

Considering that each subsequent section of the separator fits the amount of the dust-air mixture, which is reduced by the amount of it that has already passed through the previous section of the louvered separator and was discharged through the nozzle From the outlet of purified air, that is, less, we, reducing the number of louvers in each subsequent section 6, 7, 8 in the direction of the dust discharge nozzle, thereby reducing the cross-sectional area of each subsequent section relative to the previous one in the same direction, thanks to which we ensure a constant speed of movement of the dust-air mixture through the openings between the shutters, which is optimal for this type of dust. You can reduce the number of 62 blinds in each section 6, 7, 8, leaving a constant distance between them, only by reducing the diameter of these sections.

This reduction in the diameter of each subsequent section separated by a louver is calculated on a computer. in such a way that with the ratio of the diameter of the louver of the separable section b to the diameter of the louver of the separable section 7, which is equal to 4/3, and with the ratio of the diameter of the louver of the separable section 7 to the diameter of the louver of the separable section 8, which is equal to 3/2, the speed of passage of the dust-air mixture through the louvered separator will be the same for all three sections. The amount of air is determined for each section. Which should pass through it and the speed of its passage is determined.

This value of the optimal ratio of the diameters of the separator sections is explained by the fact that only in this version, while leaving the distance between the shutters in each section of the separator unchanged, we achieve a constant speed of movement of the dust-air mixture through the openings between the separator shutters by decreasing the diameters of the separator sections in the same direction.

All large particles of dust separated from such a flow fall down along the cylindrical and then along the conical part of the device body, and the smaller dust particles that are reflected by the shutters of the separator /5 also fall down along the separator and all the way to the hopper 10, from where they are removed through the dust discharge nozzle 11.

Experimental studies proved that the optimal conditions for the operation of the apparatus are: - the height of the bunker is 1/3 of the height of the apparatus body; - the ratio of the casing diameter to the hopper diameter is 1.11--1.15; - the shape of the hopper is cylindrical-conical; - the diameter of the dust outlet in the device is equal to the inlet diameter of the hopper.

When the speed of the flow in the body of the device decreases and when it passes through the openings between the shutters according to Bernoulli's law, the static pressure around the separator increases. In the presence of the above optimal operating conditions of the device, gas suction at the junction of the housing and the hopper is significantly reduced, and in the center of the dust collector from the dust collector hopper, a secondary helical vortex moves from the bottom up with a much smaller radius and speed, which eliminates or reduces the amount of dust captured by it, and this in turn, leads to an increase in the efficiency of dust collection.

At the experimental stand of the Lviv Polytechnic National University, studies of the proposed dust collector with a prototype are presented, the results of which are shown in the table in Table 1.

Quartz sand with a median diameter (8, 32, 50): 10 m.

Air consumption, | Median diameter o 8161 cm shin shishshi o p VO yuyu 11156 vv « 011 vm 11110001 i 1100 i syayu 138 . yuyu 01121 g» 011716 yav yuyu 17771111 11111111 yuyu 11300001 - yuyu 111 о ов /1777711111111111вва вв 1111 («c) The proposed design of the dust collector allows to keep constant both the speed of movement of the dust gas bo 50 and the passage between the gaps in the housing and the dust trap shutters of the separator, and the presence of a hermetic cylindrical-conical hopper equalizes the pressures inside the apparatus body and in the hopper. If the pressure in the casing and the hopper is different, then where the pressure is lower, gas suction will begin and thus the circulation of the suctioned gas into purified gas will be established in the apparatus, which immediately shifts the uniformity of the distribution of velocities and pressures, and immediately reduces the efficiency of its work .

Thus, in the given structure, the following occurs: the flow is equalized inside it, the flow is calmed, the speed of turbulent eddies is reduced, the radius of the secondary vortex is reduced, which moves in a helical manner from the bottom up to meet the movement of the dust-gas mixture, which moves from top to bottom and gas suction is turned off at the point of compression of the housing with the hopper , and this, in turn, significantly increases the efficiency of the device and reduces its hydraulic resistance. As can be seen from Table 1, we 60 managed to increase the efficiency of dust collection in the proposed dust collector by 4-695 in comparison with the prototype, reducing its hydraulic resistance by 1.2-1.4 times.

Claims (1)

The formula of the invention b5 A dust collector with a step separator and a hopper containing a body, tangential inlet nozzle, axial outlet and dust outlet nozzles and a louvered separator, which is characterized by the fact that the louvered separator consists of three sections of different diameters, the number of louvers in which decreases in the direction of the dust outlet the nozzle is proportional to the ratio of the diameters of the separator sections, which is 4/3 and 3/2 in the same direction, and the body of the device unites the dust cleaning device and the hopper into one unit, and the hopper has a cylindrical-conical shape. that 2 th- (ee) «c) «c) є - with . and? - («c) («c) (ee) that p 60 b5