RU2640535C1 - Mesh vertical filter - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: mesh vertical filter contains a body mounted on the cover of a steam-dust mixture source, inlet and outlet branch pipes, a filter element in the form of a rotating rotor, which is rotation exponential and made of two stainless meshes, sprayed with nozzles, a sludge pan, filter sprayed zone in the form of coaxial cylindrical shell. Each spray nozzle has a hollow cylindrical housing with throttle washer connected with union nut to which liquid flow divider is secured, and consisting of coaxially arranged perforated conical shells, the space between which is filled with a fine-meshed grid, wherein the vertices of conical surfaces of shells are directed away from the throttle washer. A cylindrical perforated segment fastened on the perforated conical shells is fixed in the lower part of the divider. In the cylindrical perforated segment, there is a flow swirler made in the form of a spring.

EFFECT: higher efficiency and reliability of dust separation by increasing the liquid spraying level by the nozzles.

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Description

The invention relates to techniques for wet dust collection and can be used in chemical, textile, food, light and other industries.

The closest technical solution to the claimed object is a gas scrubber, known from RF patent No. 2323540 (prototype), comprising a housing, a pipe for introducing dusty gas, a pipe for exiting purified gas, an irrigation device and a sludge collector.

The disadvantage of the prototype is the relatively low efficiency of the dust collection process due to the underdeveloped spray surface of the liquid.

EFFECT: increased efficiency and reliability of the dust collection process by increasing the degree of liquid atomization by nozzles.

This is achieved by the fact that in the vertical mesh filter containing a housing mounted on the shelter of the source of the steam-dust mixture, the inlet and outlet nozzles, a filter element in the form of a rotating rotor having the shape of an exponential rotation and made of two stainless mesh irrigated by nozzles, a sump for sludge and the irrigated filter zone in the form of a coaxial cylindrical shell, each of the nozzles contains a hollow cylindrical housing with a throttle washer connected to a union nut to which the flow divider is attached moreover, the fluid flow divider consists of coaxially arranged, perforated conical shells, the space between which is filled with a fine mesh, and the vertices of the conical surfaces of the shells are directed away from the throttle washer, and a cylindrical perforated segment fixed to the perforated conical shells is fixed at the bottom of the divider while in the cylindrical perforated segment, mounted in the lower part of the divider on the perforated conical shell ah, there is a flow swirl made in the form of a spring.

In FIG. 1 shows a longitudinal section through a vertical mesh screen; FIG. 2 is a diagram of a nozzle for spraying liquids.

The vertical mesh filter is a casing in the form of a cylinder 1 m high and 0.8 m in diameter, installed on the shelter 8 of the source of steam-dust mixture 9. Its filtering element is a rotating rotor 1, having the shape of a rotation exhibit and made of two stainless mesh irrigated by nozzles 4 , the liquid under pressure enters the collector through channel 10. On the way from the shelter to the filter element, the vapor-dust mixture passes sequentially an annular curtain 5 of sludge flowing into the pan 6 and the irrigated zone of the filter 3 in the form coaxial cylindrical shell. Particles coagulated by coagulation come into contact with the filter element. The shape of the latter is designed in such a way that the particles under the influence of the resulting force are sent to the side walls 2 of the filter, through which they flow into the pan 6. The cleaned air through the slit of the uniform intake 7 is discharged into the atmosphere.

Each of the nozzles 4 (Fig. 2) contains a cylindrical hollow body 11, consisting of a cylindrical part with an external thread for connecting to the fitting (not shown) of a distribution pipe for supplying fluid, and a union nut 16 with a divider 17 fixed to the lower part of the housing fluid flow. In the housing 11, coaxially to it, a cylindrical hole 12 is made, in the upper part of which a strainer 14 is installed, and in the lower part there is a throttle washer 13 with a nozzle 15. To the end surface of the union nut 6, axisymmetrically to the housing 11, a liquid flow divider 17 is attached, consisting of coaxially arranged, perforated conical shells 18 and 19, the space between which is filled with a fine mesh, and the vertices of the conical surfaces of the shells 18 and 19 are directed away from the throttle washer 13, and in the lower part of the divider I 17 is fixed to a spherical (not shown in the drawing) or cylindrical perforated segment 20 so that the top of the outer conical shell 19 coincides with the center of the cylindrical surface of the perforated segment 20. In the cylindrical perforated segment 20 mounted in the lower part of the divider 17 on the perforated conical shells 18 and 19, a flow swirl is arranged in the form of a spring 21.

The nozzle works as follows.

When the fluid is supplied to the nozzle body 11 under the influence of a pressure drop of 0.4 ... 0.8 MPa, it rushes into the cylindrical hole 12 through the strainer 14, and then into the throttle washer 13 with the nozzle 15. From the nozzle 15, the fluid flow enters the divider 17 , consisting of coaxially arranged, perforated conical shells 18 and 19, in which the fluid flow is crushed to a finely dispersed phase, and a cylindrical perforated segment 20, mounted on perforated conical shells 18 and 19, allows you to increase the fineness of the phase ra liquid fervor.

Using the nozzle as a finely dispersed sprayer of the described design makes it possible to obtain a stream of droplets of finely dispersed surfactant that is uniform in volume in the range of droplet diameters from 30 to 150 microns at a supply pressure of no more than 1 MPa.

The presence of gas inclusions in a liquid additionally perturbs its surface, which leads to wave formation and volumetric crushing of the liquid film. The loss of mechanical energy during external acceleration (on the external conical surface) is reduced compared with the same acceleration in a closed channel.

The mesh vertical filter operates as follows.

The filtering element is a rotating rotor 1, having the shape of an exponential rotation and made of two stainless mesh irrigated by nozzles 4. On the way from the shelter to the filtering element, the dust-vapor mixture passes sequentially an annular curtain 5 of sludge flowing into the pan 6 and the irrigated filter zone 3. Enlarged by coagulation particles come in contact with the filter element. The shape of the latter is designed in such a way that the particles under the influence of the resulting force are sent to the side walls 2 of the filter, through which they flow into the pan 6. The cleaned air through the slit of the uniform intake 7 is discharged into the atmosphere. Such filters are installed in places of the highest allocation of the steam-dust mixture, for example, at the reloading nodes of the pellet return path. Filters were placed on the shelters of reloading units with the removal of sludge through the pan, which made it possible to dispense with the often-failed water seal. The vertical design of the filters did not interfere with the maintenance of the reloading units and did not require the use of supply ducts, which are very quickly clogged with adhering dust.

At an initial dust concentration of 2.5 × 10 ⁻³ kg / m ^{3, the} degree of filter cleaning was 98.6%.

Claims (1)

A vertical mesh filter containing a housing mounted on the shelter of a source of steam-dust mixture, an inlet and an outlet pipe, a filter element in the form of a rotating rotor having the shape of an exponential rotation and made of two stainless screens irrigated by nozzles, a sludge tray and an irrigated filter zone in the form of a coaxial a cylindrical shell, characterized in that each of the nozzles contains a hollow cylindrical body with a throttle washer connected to a union nut to which a liquid flow divider is attached spine, and the liquid flow divider consists of coaxially arranged perforated conical shells, the space between which is filled with a fine mesh, and the vertices of the conical surfaces of the shells are directed away from the throttle washer, and a cylindrical perforated segment fixed to the perforated conical shells is fixed at the bottom of the divider this in a cylindrical perforated segment, mounted in the lower part of the divider on perforated conical shells, times the flow swirl is arranged in the form of a spring.

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