RU208946U1 - Mass transfer apparatus - Google Patents

Abstract

The proposed utility model relates to heterophase chemical reactors, evaporators and mass transfer apparatuses and can be used in the chemical, petrochemical, food, biotechnological, paint and varnish and other industries, as well as in environmental processes for cleaning liquid and solid waste from harmful impurities. The technical result of the proposed design of the mass transfer apparatus is to increase productivity. The technical result is achieved by the fact that the mass transfer apparatus comprises a cover, a housing in which a vertical cylindrical centrifugal separator with a tangential feed device for the stream to be cleaned and a central gas outlet pipe, liquid inlet and outlet pipes, a cut-off plate, a reflector, is installed axisymmetrically, made in the form of a spherical segment, facing downwards with the section plane, a cylindrical spring attached to the central gas outlet pipe, on which the reflector and the cut-off t plate, while the coefficient of elasticity of the cylindrical spring is determined by the expression where K is the coefficient of elasticity of the spring, n/m; M is the mass of the cut-off plate, kg; m is the mass of the reflector, kg; housing, m, characterized in that the edges of the spherical segment of the reflector have a diameter equal to the diameter of the centrifugal separator housing, and are rigidly connected to the cut-off plate, made in the form of a ring with positive buoyancy and with a grid attached in its upper part, and the outer diameter of the cut-off plate ring is determined by the expression Dc/D=0.92÷0.96, (2) where Dc D are, respectively, the outer diameter of the ring and the diameter of the device, m.

Description

The proposed utility model relates to heterophase chemical reactors, evaporators and mass transfer apparatus and can be used in the chemical, petrochemical, food, biotechnological, paint and varnish and other industries, as well as in environmental processes for cleaning liquid and solid waste from harmful impurities.

A well-known design of a converter with a fluidized bed of a catalyst, consisting of a cylindrical body with a contact zone in the lower part, a gas distribution grid, heat exchangers built into the body with inlet and outlet pipes for air, steam, condensate and liquid reaction mass, as well as the upper part of the converter with filters and having larger diameter than the diameter of the contact zone. The filters are made of perforated ceramic or aluminum tubes, on which there are several successive layers of fiberglass or glass wool (V.P. Perevalov, G.I. Koldobsky. Fundamentals of design and equipment for fine organic synthesis. M: Chemistry, 1997, 288p., p. .225 and 226).

The reasons hindering the achievement of the desired technical result include the complexity and duration of the regeneration of glass fabric or glass wool in filters that trap fine dust, drops or foam of the reaction mixture, abrasive granules and catalyst grains. This reduces the main operating time and reduces productivity.

A well-known design of the Peterson collector for cleaning gas and vapors from mists of acids, oils, and small solid particles (for example, dyes and pigments), which consists of two chambers separated by a perforated grid, in the holes of which spiral springs are inserted with coils pressed against each other (like a compressed spring). For wetting particles in dusty air, a jet pump with a nozzle for supplying compressed air is installed in the first chamber (A.S. Timonin. Engineering and environmental reference book. Volume 1 - Kaluga: N.F. Bochkareva Publishing House, 2003, - 917p. : p. 452).

The reasons hindering the achievement of the desired technical result include insufficient productivity due to high hydraulic resistance associated with the small size of the gaps through which the purified gas, foam or gas-liquid mixture is filtered.

Various designs of spray separators for evaporators are known. For example, a louvered spray separator consists of a housing inside which vertical slots are made, the walls of which are bent outward, and the housing is attached to the support ring and is installed hermetically on the shell of the separation zone. Also known are the designs of surface spray separators, consisting of a supporting scarf, on which a package of grids is placed. Known designs of centrifugal spray separators, consisting of a cylindrical body with inlet windows, a baffle and fittings for the exit of secondary steam and draining the solution (A.S. Timonin. Engineering and environmental reference book. Volume 1 - Kaluga: Publishing house N.F. Bochkareva, 2003, - 917s .: pp. 518-520).

All the described designs of evaporator spray separators have a significant drawback associated with the large time spent on cleaning their working surfaces from thermal deposits, scale, salt stone, rust, and thermal degradation products. This reduces the main operating time and leads to a decrease in productivity.

The closest technical solution in terms of the set of features to the claimed object and taken as a prototype is the design of a centrifugal separator containing a vertical cylindrical body, a tangential feed device for the stream to be cleaned, a central exhaust pipe, fluid inlet and outlet pipes, and a cut-off plate with an axial hole located in the lower part housing, a reflector mounted above the axial opening of the cut-off plate and with a gap in relation to it, while the reflector and the cut-off plate are made in the form of spherical segments facing downwards with the section plane, and a cylindrical spring is attached to the central gas outlet pipe, on which rigidly connected between the ribs of the reflector and the cut-off plate, and the coefficient of elasticity of the cylindrical spring is determined by the expression

where K is the coefficient of elasticity of the spring, n/m;

M is the mass of the cutting plate, kg;

m is the mass of the reflector, kg;

s is the speed of sound in the purified gas, m/s;

h – hull height, m.

(Utility model to the RF patent No. 155459, В01D9/45/12, 2015)

The reasons hindering the achievement of the desired technical result include a decrease in productivity during the formation of foam and filling it with bubbles of the gas-liquid flow of the tangential device of the centrifugal separator. This leads to the need to periodically stop operation and clean the apparatus from foam.

The technical result of the proposed design of the mass transfer apparatus is to increase productivity.

The stated technical result is achieved by the fact that the mass transfer apparatus contains a cover, a housing in which a vertical cylindrical centrifugal separator with a tangential feed device for the stream to be cleaned and a central exhaust pipe, liquid inlet and outlet pipes, a cut-off plate, a reflector made in the form of a spherical segment , facing the section plane downwards, a cylindrical spring attached to the central exhaust pipe, on which the reflector and the cut-off plate are freely suspended, while the coefficient of elasticity of the cylindrical spring is determined by the expression

where K is the coefficient of elasticity of the spring, n/m;

M is the mass of the cutting plate, kg;

m is the mass of the reflector, kg;

C is the speed of sound in the purified gas, m/s;

h – hull height, m,

characterized in that the edges of the spherical segment of the reflector have a diameter equal to the diameter of the centrifugal separator body and are rigidly connected to the cut-off plate, made in the form of a ring with positive buoyancy and with a grid attached in its upper part, and the outer diameter of the cut-off plate ring is determined by the expression

D _to /D=0.92÷0.96, (2)

where D _to and D are, respectively, the outer diameter of the ring and the diameter of the device, m.

The equality of the diameter of the edge of the spherical segment to the diameter of the centrifugal separator housing prevents the foaming gas-liquid flow from slipping into the centrifugal separator housing and ensures the free flow of drops along the side wall of the housing down, and resonant vibration with a large amplitude, when condition (1) is met, thixotropically dilutes the flowing drops with a decrease in their viscosity and prevents them from sticking to the side wall of the housing and the outer spherical surface of the reflector. This increases uptime, reduces downtime, and thereby increases productivity.

The execution of the cut-off plate in the form of a ring with positive buoyancy ensures that this ring floats on the surface of the liquid when its level fluctuates in the apparatus, and the rigid fixation in the upper part of this mesh ring prevents drops from the surface of liquids, especially prone to foaming, when pH> 7 (alkaline environment), prevents the formation of foam and its accumulation in the device. This increases the efficiency of gas cleaning in the tangential gas flow supply device, reduces liquid entrainment along with the outgoing gas in the central gas pipe, which generally increases the liquid capacity.

The implementation of the outer diameter of the ring D _to with a relative size in relation to the diameter of the apparatus D less than the claimed lower limit in expression (2) and equal to 0.92, leads to an increase in the gap between the wall of the apparatus and the outer wall of the ring, and therefore an increase in the breakthrough of the foaming gas flow in no screens of the cut-off plate, which increases the carryover of the liquid, which forms the sinks of the foam bubbles. This reduces fluid performance.

An increase in the outer diameter of the ring D _to in relation to the wall of the device D above the declared upper limit can lead to distortion and jamming of this ring on the wall of the device when swinging the cut-off plate and reflector on a coil spring in a resonant mode of operation with a high amplitude. This would require a shutdown and repair, which would reduce the main work time and productivity.

The drawing shows a General view of the proposed design of the mass transfer apparatus.

It consists of a cylindrical body 1 with nozzles for inlet 2 and outlet 3 of liquid, a removable cover 4, on which a vertical cylindrical centrifugal separator 5 is fixed axisymmetrically with the mass transfer apparatus, containing a tangential feed device for the stream being cleaned 6, a central gas outlet pipe 7, a reflector 8 with mass m, made in the form of a spherical segment, turned by the section plane downwards and having an edge diameter equal to the diameter of the separator 5. The edges of the spherical segment of the reflector 8 are rigidly connected to the cutting plate mass M, made in the form of a ring 9 with positive buoyancy and with a grid 10 attached to its upper part. The ratio of the diameter of the ring 9 of the cut-off plate and the diameter of the apparatus 1 is determined by expression (2).

The upper part of the spring 11 is attached to the central exhaust pipe 7, on which the reflector 8 and the cut-off plate are freely suspended, made in the form of a ring 9 and a grid 10, and the elasticity of the cylindrical spring 11 is determined by expression (1), which provides resonant vibrations of the reflector 8 and the cut-off plate with high amplitude.

If a chemical reaction occurs in the liquid with the release of a gas (vapor) phase and no additional gas or steam is supplied, then it is necessary to supply gas or air to bubble the liquid into apparatus 1. To do this, a bubbler 12 is installed in the lower part of the apparatus, for example, in the form of a cylindrical tube with holes, rolled into a flat spiral.

The mass transfer apparatus operates as follows. The initial liquid (reaction mass) is poured into the apparatus 1 through the pipe 2 with the pipe 3 closed, and the reaction gas (air) is supplied through the bubbler pipe 12, bubbling the liquid in the apparatus 1. The gas bubbles rise up, pass through the holes in the grid 10, rise even higher and, passing through the slots of the tangential device 6 of the centrifugal separator 5, due to a sharp change in speed in magnitude and direction, they are divided into liquid droplets, particles of the dispersed phase and a purified stream that goes outside through the gas outlet pipe 7. The trapped drops and particles discarded by the centrifugal force in the slots of the tangential device 6 to the inner wall of the housing of the centrifugal separator 5, settle down under the action of gravity down on the surface of the spherical segment of the reflector 8, and then from its surface onto the grid 10. The purified gas flow, moving inside the cylindrical housing 5 with height h, creates oscillations with a frequency ν equal to the natural frequency of the spring ma pit formed by reflector 8 and ring 9 with mesh 10.

The resonant oscillation mode of the reflector 8 and the ring 9 with a grid 10 with a large amplitude suppresses the formation of foam and the entrainment of liquid droplets from its surface when gas is bubbling through the cells of the grid 10 (G.A. Kardashev. Physical methods for intensifying the processes of chemical technology. M: Chemistry, 1990 , 208s., p.126, I. A. Gorodetsky, A. A. Vasin, M. V. Olevsky, P. A. Lukanov, Vibratory Mass Transfer Apparatuses, M: Chemistry, 1980, 192 p., p. After the end of work, the liquid is removed from the apparatus through pipe 3, and the gas supply to the bubbler 12 is stopped.

Thus, the installation of a spherical segment of the reflector 8, having an edge diameter equal to the diameter of the centrifugal separator 5, and a rigid connection of this edge with a cutting plate made in the form of a ring 9 with positive buoyancy and with a mesh 10 attached to its upper part, as well as the implementation of an outer the diameter of the ring 9 of the cut-off plate, determined by expression (2), makes it possible to reduce the entrainment of liquid droplets from its surface, to suppress foam formation in the cells of the grid 10, to reduce the possibility of deposits on the surfaces of the centrifugal separator 5, the reflector 8 and the grid 10 due to the thixotropic destruction of the structure of the trapped particles and drops in the tangential feeder of the stream being cleaned 6 with resonant vibration of the reflector 8 with the grid 10 and a decrease in the effective viscosity of the trapped particles and drops, which contributes to an increase in productivity.

Claims (10)

A mass transfer apparatus containing a cover, a housing in which a vertical cylindrical centrifugal separator is axially symmetrically installed with a tangential feed device for the stream to be cleaned and a central gas outlet pipe, liquid inlet and outlet pipes, a cut-off plate, a reflector made in the form of a spherical segment, facing down, cylindrical a spring attached to the central exhaust pipe, on which the reflector and the cut-off plate are freely suspended, while the coefficient of elasticity of the cylindrical spring is determined by the expression

where K is the coefficient of elasticity of the spring, n/m; M is the mass of the cutting plate, kg; m is the mass of the reflector, kg; C is the speed of sound in the purified gas, m/s; h – hull height, m, characterized in that the edges of the spherical segment of the reflector have a diameter equal to the diameter of the body of the centrifugal separator, and are rigidly connected to the cut-off plate, made in the form of a ring with positive buoyancy and with a grid attached in its upper part, and the outer diameter of the cut-off plate ring is determined by the expression D _to / D \u003d 0.92-0.96, where D _to and D are, respectively, the outer diameter of the ring and the diameter of the device, m.

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