RU2356632C1 - Filter for gas flow treating - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention refers to gas treating and can be implemented in various branches of industry and power engineering for filtration of flow from aerosol particles contained in the flow, including separation of condensed component of gas flow fumes. The filter consists of a rotation drive connected to a porous settling electrode, the plane of which is directed along the treated gas flow. Electrically isolated corona-forming electrodes are assembled with a gap relative to plane of the settling electrode from the side of treated gas flow; these electrodes are connected with a power source; the filter is equipped with a system of porous settling electrode orientation relative to the treated gas flow, with a system of generating air flow directed to the porous settling electrode from the side of the treated gas flow and with a system of treated gas flow cooling.

EFFECT: reduced dimensions of filter design.

4 cl, 1 dwg

Description

The invention relates to the field of gas purification and can be used in various industries and energy to separate from the gas stream contained aerosol particles, including the condensable component of the vapor of the gas stream (condensate).

The book (A.G. Amelin "Theoretical Foundations of Fog Formation", M., Chemistry, 1966, p. 164) presents a device for the separation of steam from gases, containing a vertical cylindrical body with pipes for the inlet and outlet of the cooling agent, and two lattices on which tubes are fixed. The upper chamber is mounted in the housing for the entrance of the gas-vapor mixture, and the lower chamber is mounted for the outlet of the separated condensate and purified gas. In this device, the vapor-gas mixture passes through the upper chamber through pipes cooled by a refrigerant moving in the annulus. In contact with the cold surface of the pipes, the gas cools and the vapor contained in the gas condenses on this surface. The liquid condensed in the pipes is collected in the lower chamber and flows out of it through the condensate outlet pipe. The gas purified from condensate leaves through a branch pipe of the lower chamber.

In the described device, condensation and separation is carried out only for that part of the vapor of the gas mixture, which manages to come into contact with the surface of the pipes during the residence of the mixture in the pipe. The rest of the vapor remains in the mixture leaving the device. Thus, to increase the degree of purification of the mixture from vapors, an increase in the overall dimensions of the known device is required. In addition, the known device does not provide for cleaning the mixture from aerosols.

In the same book (see A.G. Amelin "The theoretical basis for the formation of fog", M., Chemistry, 1966, p. 202), a device for separating sulfuric acid vapor is presented, containing a refrigerator with inlet and outlet pipes and a vertical tower with upper and lower cameras. The lower chamber is equipped with a pipe for the entrance of the gas mixture and a pipe for the exit of sulfuric acid, connected to the inlet pipe of the refrigerator. The upper chamber contains the outlet pipe of the purified gas and the inlet pipe of sulfuric acid connected to the outlet pipe of the refrigerator and the finished product receiving line. The gas mixture enters through the lower chamber into a vertical tower. Rising up the tower, the gas mixture is irrigated with sulfuric acid flowing down from the top of the tower. Droplets of sulfuric acid cool the gas mixture and condense on its surface the vapors contained in the gas mixture, dragging them with them into the lower chamber of the tower. The gas purified from vapors rises and through the upper chamber of the tower is directed to the outlet of the purified gas. Drops of acid drop down and through the lower chamber of the tower are sent to the pipe to exit sulfuric acid.

When the gas mixture is cooled and the vapor contained in it is condensed, sulfuric acid is heated. To close the working cycle, the acid leaving the tower before being fed to the upper part of the tower for irrigation of the gas mixture and for shipment of finished products to the highway is passed through the refrigerator.

In the described device, in contrast to the previously mentioned device, the condensation of the vapors contained in the gas mixture occurs not only on the surface of structures (pipe walls, towers), but also on the surface of droplets of irrigated sulfuric acid. Since the surface area of the droplets is significantly larger than the area of the structures, it is possible to achieve an increase in the degree of purification of the mixture in the described device without significant increases in the overall dimensions of the device.

At the same time, in the described device, when sulfuric acid is condensed, a high supersaturation of steam occurs, which is why part of the sulfuric acid vapor condenses in volume with the formation of fog, which is removed from the tower as part of the purified gases.

The closest technical solution to the proposed one is a gas stream purification filter, presented in the patent of the Russian Federation for invention No. 22935897, IPC B01D 53/32. The filter contains a porous precipitation electrode with open pores larger than 0.1 μm, including vertical capillary channels, the passage size of which satisfy the ratio:

a> 2 · σ / (p · g · h),

where a is the effective radius of the pores, h is the height of the precipitation electrode, σ is the surface tension coefficient of the condensate, ρ is the density of the condensate installed along the gas stream to be cleaned, with a gap relative to which, from the side of the gas stream to be cleaned, the corona electrodes connected to the source are electrically isolated nutrition.

In the known filter, aerosol particles and condensate droplets formed as a result of the activation of condensation processes using generated electric charges move under the influence of a force field and electric wind towards a porous precipitation electrode. An increase in the degree of purification in the known filter is achieved by initiating condensation processes in the entire volume of the gas stream and by ensuring the passage of condensate droplets into the porous surface of the precipitation electrode and ensuring the most favorable heat transfer conditions.

However, the withdrawal of condensate from the pores of the precipitation electrode in a known filter is provided due to gravitational forces. To overcome capillary forces, especially from small pores, it is necessary to provide a high column of liquid, which forces to increase the dimensions of the filter.

The aim of the present invention is to reduce the overall dimensions of the filter structure.

To achieve the stated goal, a gas stream purification filter containing a porous precipitation electrode, the plane of which is oriented along the gas stream to be cleaned, with a gap relative to the plane of which, on the side of the gas stream being cleaned, the corona electrodes connected to the power source are electrically isolated, is equipped with a rotation drive connected to mounted rotatably with a porous precipitation electrode;

orientation system of the porous precipitation electrode relative to the cleaned gas stream;

equipped with a system for forming an air flow directed to the porous precipitation electrode from the side of the cleaned gas stream;

equipped with a cooling system for the cleaned gas stream.

The proposed technical solution allows centrifugal forces, the value of which is proportional to the square of the angular velocity of rotation of the precipitation filter, to take the condensate out of the filter design. This will not only reduce the pore length, and therefore the design dimensions, but also provide a more complete release of the pores from the accumulated condensate and aerosol particles. That will allow to achieve a higher degree of purification and increase the terms of inter-regulation periods.

The drawing shows a diagram of the proposed filter.

The filter includes a corona electrode 1 connected to a high voltage source (not shown). Structural schemes for the implementation of the corona electrode 1 and the supply of a high voltage to it can be very different and widely covered in the literature (see, for example, RF patents No. 2002510 according to CL B03C 3/38, No. 2008100, 2001687 according to CL B03C 3/41 and other). In the drawing, the corona wire 1 is represented in the form of a wire with a small radius of curvature of the surface, stretched with a gap relative to the precipitation electrode 2. The surface of the precipitation electrode 2 is made porous, the open pores of which contain capillary channels extending from the axis of the structure to the outside in its peripheral part. The pore size is preferably performed with a size of more than 0.1 μm, which allows the flow of the gas to be cleaned to flow freely into the sedimentation electrode and to avoid the formation of a wall layer of the gas stream to be purified. The grounded structure is mounted rotatably and connected to a rotation drive 3. The dimensions of the capillaries of the vertical channels are selected based on the conditions for the condensed liquid to flow out of them. Based on the diameter of the precipitation electrode 2 and the revolutions of rotation of the actuator 3, it is easy to determine the minimum pore size from known ratios. Capillary-porous materials are known from the literature (see, for example, http://itp.uran.ru/kpm.htm, http://www.pmi.basnet.by/structure/branch2-27.php), porous cermet , see, for example, http://resti.udmnet.ru/f_gazez.htm and other open-pore materials, i.e. pores overlooking the inner surface of the structure. The noted sources indicate that various methods of manufacturing porous materials with a predetermined porosity are known. That allows you to perform a grounded design of the proposed device based on known methods from known materials. The rotation drive with the help of supports 4 is fixed in the air channel 5, in which an annular groove 6 is made in the region of rotation of the precipitation electrode to collect and discharge the condensed liquid discharged from the precipitation electrode 2. To drain the condensed liquid in the lower part of the annular groove 6 can be made through the hole with a fitting connection with a hose for collecting condensed moisture (not shown).

When mounting the proposed filter on a pipe of a gas stream leaving the free atmosphere, the filter can be equipped with a filter orientation system relative to the stream of gas to be cleaned. The orientation system can be performed similarly to the horizontal orientation system of the axis of rotation of the wind wheel of wind power plants and includes a rotary shoulder strap 7 mounted on the pipe of the gas stream 8 to be cleaned with a reversal drive 9. A schematic and structural design of a rotary shoulder strap 7 and a reversal drive 9 relative to the pipe being cleaned gas flow 8 can be performed based on the general design requirements. The control system of the headland drive can be based on wind direction sensors and can be created on the basis of well-known design principles for tracking systems.

In order to enhance the intensity of condensation processes, the filter can be equipped with a cooling system, which, for example, can be made in the form of a cooling radiator of the incident wind stream 10, installed in front of the outlet stream of the cleaned gas stream A in the direction of the precipitation electrode 2.

At low wind speeds, the filter can be equipped with a special system for the formation of air flow. Structurally, the airflow formation system can be performed based on the specific operating conditions of the filter and the requirements for its operational characteristics. In the drawing, the airflow formation system is made in the form of an axial fan 11 mounted on the axis of the rotation drive 3 of the precipitation electrode 2.

The filter works as follows.

The gas system intended for cleaning in the filter passes in the discharge region of the corona electrode 1. The electric charges arising during the corona discharge fall on the aerosol particles and condensate droplets contained in the gas stream and charge them.

Charged aerosol particles due to the small radius of curvature of their surface in the adjacent region of space create powerful, highly inhomogeneous electric fields that attract dipole molecules of condensed vapors. Under the influence of the electric field of the corona electrode 1 and the space charge, electrically charged aerosol particles and condensate droplets condensed in the volume of the gas stream move to the precipitation electrode 2, capturing condensed vapor molecules in their path. Given that the surface of the precipitation electrode is made porous, the dispersed flow formed due to the action of electrodynamic forces moves toward the precipitation electrode and penetrates inside its surface. This makes it possible to transfer even the smallest, submicron particles to a precipitation electrode with an electrodynamic flow. During the movement of condensate droplets along the pores of the precipitation electrode, the surrounding surface is wetted, the droplets merge and, due to surface tension forces, the capillary channels are filled with condensate liquid. Thus, condensate droplets are delayed during the movement of the dispersed medium through the precipitation electrode by the pore surface, and the gas component freely flows out through the open pores (stream B is marked in the drawing). Due to the rotation of the precipitation electrode 2 by means of drive 3, the resulting centrifugal forces carry condensed moisture through the capillary channels of the porous surface of the precipitation electrode to its outer surface and then to the annular groove 6 of channel 5 and through the through hole (not shown) in the drainage system.

Thus, the proposed design of the filter allows the use of capillary and centrifugal forces for forced movement throughout the entire porous part of the precipitation electrode of the droplets of condensate released from the gas stream. In this case, two tasks are solved. First, the electrode surface is drained and condensed droplets contact directly with the design of the colder electrode. The second - due to the use of the developed pore surface, the heat transfer surface area from the condensate to the electrode structure significantly develops without a significant increase in the overall dimensions of the structure.

The process of condensation of the vapors contained in the gas stream, as well as the removal of condensation heat and cooling of the gas stream to be purified, is carried out by mixing the gas stream to be purified with an additional cooler additional stream W. The additional stream is formed either due to wind, by orienting the filter so that the wind stream ran onto the cleaned and carried him to the precipitation electrode. To do this, using the wind direction sensor (not shown), the angle between the wind direction W and the axis of rotation of the precipitation electrode 2 is determined. The obtained value of the mismatch angle is processed by the rotation drive 8. When the wind flow is small, the minimum value of which is set in the initial design data, it turns on air flow forming system. For the design scheme shown in the drawing, the inclusion and regulation of the intensity of the generated air flow can be carried out by turning the blades of the axial fan 5. Additional cooling of the cleaned gas stream is carried out using a heat exchanger 10 installed in the path of the incoming wind W stream.

The design of the filter allows the inclusion of a control system in it that regulates the volume and temperature of the air stream mixed with the gas stream being cleaned, as well as adjusting the rotation speed of the precipitation electrode rotation drive. As a controlled parameter, the temperature of the precipitation electrode can be determined.

If it is necessary to use the proposed filter for cleaning gas streams containing an insufficient amount of condensable moisture, it is allowed to supply condensed liquid vapors (water, oil, etc.) into the gas stream. The design of the supply of condensed liquid vapor can be decided on the basis of various ways based on the general principles of design structures. Not shown in the drawing.

If in the known device the condensate was withdrawn from the capillary channels of the precipitation electrode due to gravitational forces, the intensity of which is determined by the gravitational acceleration g (9.8 m / s ² ), then in the proposed technical solution the force intensity is proportional to ω ² r, where r is the radius active part of the precipitation electrode, the values of which can reach more than 100 m / s ² with a radius of the active part of the precipitation electrode. At r = 2 cm and a rotation frequency of the precipitation electrode n = 1000 rpm (ω ~ 1001 / s) ω ² r = 200 m / s ² ), which allows condensate to be removed from the capillary channels of the precipitation electrode at small overall dimensions and to achieve the objectives of the invention.

In addition, due to an increase in forces on condensate droplets and aerosol particles entering the precipitation electrode, the likelihood of pore clogging is reduced, which allows to increase the inter-filter maintenance period.

Thus, the proposed design of the electrostatic precipitator due to the proposed previously unknown new combination of distinguishing features allows for the removal of condensate with smaller dimensions of the precipitation electrode and to reduce the size of the filter structure and achieve the purpose of the invention.

Claims (4)

1. A gas stream purification filter containing a porous precipitation electrode, the plane of which is oriented along the gas stream to be cleaned, with a gap relative to the plane of which the corona electrodes connected to the power source are electrically isolated mounted on the side of the gas stream to be cleaned, characterized in that it is provided with a rotation drive, connected to a rotationally mounted porous precipitation electrode. 2. The filter for cleaning the gas stream according to claim 1, characterized in that it is provided with an orientation system for the porous precipitation electrode relative to the gas stream to be cleaned. 3. The filter for cleaning the gas stream according to claim 1, characterized in that it is equipped with a system for forming an air stream directed to the porous precipitation electrode from the side of the gas stream being cleaned. 4. The filter for cleaning the gas stream according to claim 1, characterized in that it is equipped with a cooling system for the purified gas stream.