RU51523U1 - CENTRIFUGAL GAS-LIQUID SEPARATOR FILTER - Google Patents

Abstract

The proposal relates to equipment for cleaning gas and liquid from mechanical impurities and can be used in gas, oil, energy and other industries. A centrifugal gas-liquid separator filter containing a vertical housing with a conical cover and a bottom, a tangential mixture inlet, an axial tube, shielding conical plates, cleaned gas and liquid outlet pipes with corresponding valve assemblies that do not allow liquid or gas to pass through. The bottom conical bottom is equipped with a device for the selection of solid fractions, and the axial tube is made in the form of a set of perforated nozzles, the lower part of which is telescopically inserted into the upper part of another perforated nozzle with the possibility of limited rotation. The lower perforated nozzle telescopically enters the outlet pipe of the purified liquid, which is bent to the side and is configured to recirculate the liquid. The conical plates are provided with the upper end of each perforated nozzle, and the upper perforated nozzle, above its shielding conical plate, is rigidly connected to the outlet of the purified gas. The outlet pipe of the purified gas is hermetically installed in the conical cover with the possibility of rotation and fixation in extreme positions, made with the possibility of recirculation of gas. The holes of the perforated nozzles are blocked externally by filters, which are configured to change their throughput when the perforated nozzles rotate relative to each other. Filters are made in the form of cylindrical meshes tightly and coaxially inserted into each other with the possibility of rotation relative to each other, the upper end of one of the cylindrical meshes being sealed to the perforated nozzle above the holes, and the lower end of the other cylindrical mesh to the upper edge of the other perforated nozzle or nozzle the output of the purified liquid into which the perforated pipe with the first cylindrical mesh is inserted. The outlet pipe of the purified liquid with a settling chamber is equipped with a magnetic element. Using a similar design of a centrifugal gas-liquid separator filter allows you to clean the gas-liquid mixture with almost any gas content in the liquid, up to just liquid or gas, eliminate clogging of the liquid especially when the flow of the mixture is cut off and pressure drops, remove metal suspensions from the purified liquid, and self-clean the filters, which significantly increases the overhaul period of the device and the quality of gas and liquid purification.

Description

The proposal relates to equipment for the purification of gas and liquid from mechanical impurities and can be used in gas, oil, heat and other industries.

The well-known "Separator" (patent RU No. 2147914, B 01 D 45/12, publ. 04/27/2000), comprising a housing with nozzles for inlet and raw gas, gas and liquid outlet, separation elements located on a plate equipped with a drain pipe wherein a cyclone is installed in it, the inlet of the gas inlet pipe of which is mounted in the cavity of the raw gas inlet pipe, and the axial zone is connected to the end of the liquid drain pipe.

One of the disadvantages of this device is its high metal consumption, since the cyclone is located inside a housing equipped with separation elements.

The closest in technical essence is the "Centrifugal two-stage gas-liquid separator" (patent SU No. 1492522, B 01 D 45/12, publ. 01/15/1994), containing a vertical housing, separated by a horizontal partition on the upper and lower separation chambers, tangential entry a separable mixture, located under the partition, an axial pipe connecting the upper and lower chambers, an axial outlet pipe installed with a gap above it, a shielding plate located in the lower chamber under the axial pipe, a recirculation pipe, Connects the upper and lower chambers, the recirculation pipe placed on the axis of the housing, one end is connected to the upper chamber through the wall of the axial pipe and the other is located above the shielding plate with a gap with respect to its surface, wherein the shielding plate is formed as a cone.

Common disadvantages of these devices are the inability to separately purify gas and liquid, the likelihood of mixing the liquid with the solid fractions separated during cleaning, especially when the flow supplied through the tangential nozzle is interrupted, and it is not possible to self-clean and remove metal suspensions from the liquid, which subsequently play an active role in corrosion destruction of metal parts of pipelines and heat and water supply systems.

The technical objectives of the proposed utility model are:

firstly, the expansion of functionality due to the possibility of separate cleaning of gas and liquid, as well as the release of gas with a low content of liquid and liquid with a low gas content;

secondly, an increase in the overhaul period of the device and an increase in the quality of cleaning liquid and gas by adding a self-cleaning function;

thirdly, the exclusion of the possibility of clogging with solid fractions of the liquid, including when the flow of the mixture is disrupted or the pressure drops;

fourthly, the removal of metal suspensions from the purified liquid.

The technical problem is solved by a centrifugal gas-liquid separator filter containing a vertical housing, a tangential mixture inlet, an axial tube, conical shielding plates, outlet pipes for purified gas and liquid.

What is new is that the housing is equipped with a conical cap and a bottom, respectively, from the bottom and top, while the conical bottom is equipped with a device for selecting solid fractions, the axial tube being made as a set of perforated nozzles, the lower part of which is telescopically inserted into the upper part of another perforated nozzle with the possibility of limited rotation, while the lower part of the lower perforated nozzle telescopically enters the outlet pipe of the purified liquid, which is bent to the side, equipped with a valve assembly, n it is gas-permeable, a settling chamber provided with a magnetic element, and is made with the possibility of liquid recirculation, and shielding conical plates are provided with the upper end of each perforated pipe except for the upper one, which is connected from above to the purified gas outlet pipe, which is hermetically mounted in the conical cover with the possibility of rotation and fixation in extreme positions, equipped with a valve assembly that does not allow fluid to pass through, and configured to recirculate the gas, while the holes are perforated pipes outside overlapped filters, wherein the filters are adapted to change its capacity when rotating perforated pipes relative to each other.

It is also new that the filters are made in the form of cylindrical meshes tightly and coaxially inserted into each other with the possibility of rotation relative to each other, the upper end of one of the cylindrical meshes being hermetically attached to the perforated nozzle above the holes, and the lower end of the other cylindrical mesh to the upper the edge of another perforated nozzle or outlet of the purified liquid, into which a perforated nozzle with a first cylindrical mesh is inserted.

The drawing shows a diagram of a centrifugal gas-liquid separator filter in cross section.

The centrifugal separator filter contains a vertical housing 1, a tangential input 2 of the mixture, an axial tube 3, shielding conical plates 4, outlet pipes

purified gas 5 and liquid 6. The housing 1 from the bottom and from the top is respectively equipped with a conical cover 7 and a bottom 8, and the conical bottom from the bottom is equipped with a device for selecting solid fractions 9. The axial tube 3 is made in the form of a set of perforated nozzles 10, the lower part 11 of which is telescopically inserted into the upper part 12 of the other pipe 10. The lower part 11 of the lower perforated pipe 10 is telescopically included in the outlet pipe of the cleaned liquid 6, which is bent laterally, equipped with a valve assembly 13 that does not allow gas to pass through, a settling chamber 14, is equipped th magnetic member 15 and configured to recycle fluid. Shielding conical plates 4 are provided with the upper end of each perforated pipe 10, with the exception of the upper. The upper perforated pipe 10 is rigidly connected from above to the purified gas outlet pipe 5, which is hermetically mounted in the conical cover 7 with the possibility of rotation and fixing in extreme positions, axial upward movement, provided with a valve assembly 16 that does not allow liquid to pass through, and is configured to recycle gas. To enable limited rotation of the perforated nozzles 10 relative to each other and the outlet of the purified liquid 6, on the inner side the ends of the upper parts 12 of the perforated nozzles 10, with the exception of the top and the outlet of the purified liquid 6, are equipped with stops 17 that interact with the stops (to the drawing. not shown) located on the outer side of the lower ends 11 of the perforated nozzles 10. The holes 18 of the perforated nozzles 10 are blocked externally by the filters 19. The filters 19 are made with possible NOSTA change its capacity when rotating perforated pipes 10 relative to each other. Filters 19 are made in the form of cylindrical meshes tightly and coaxially inserted into each other 20 and 21 with the possibility of rotation relative to each other, with the upper end 22 of one of the cylindrical meshes 20 being hermetically connected to the perforated nozzle 10 above the holes 18, and the lower end 23 of the other cylindrical mesh 21 - to the upper edge of another perforated nozzle 10 or outlet pipe of the purified liquid 6, into which the perforated nozzle 10 with the first cylindrical mesh 20 is inserted.

Centrifugal gas-liquid separator filter operates as follows.

Before starting work, the outlet pipe of the purified gas 5 is fixed in the extreme position relative to the conical cover 7 of the housing 1. At the same time, the stops 17 of the perforated nozzles 10 and the nozzle of the liquid outlet 6 interact with the limiters of the interacting perforated nozzles 10, which are installed so that the cells (in Fig. shown) of the cylindrical meshes 20 and 21 of the filter 19 are mutually half

are blocked. Then, the gas-liquid mixture is supplied at a high speed along the tangential input 2 into the vertical casing 1, where this mixture under the action of inertia and gravity forces forms a spiral flow downward, and the heavier the fraction, the farther they are from the central axis of the casing 1. As a result solid heavy fractions of the gas-liquid mixture along the walls of the housing 1 are lowered into the conical bottom 8, from the bottom of which they are selected by the device for the selection of solid fractions 9. In practice, a screw with an outlet a valve that controls the degree of extraction (not shown in the drawing), or a settling chamber (not shown in the drawing), which was cleaned as necessary with the valve 24 closed. The purified gas-liquid mixture is pressed to the central axis of the housing 1, from where it enters through the filters 19 and holes 18 of perforated nozzles 10 into the axial tube 3. The presence of shielding conical plates 4 and filters 19 eliminates clogging of the cleaned gas-liquid mixture taken from the axial tube 3 when the flow is cut off or pressure drops in the tangential inlet 2. At the entrance to the building whisker 1 from the tangential input 2, the mixture enters the rarefaction zone, since the cross-sectional area of the housing 1 exceeds the cross-sectional area of the tangential input 2, while the mixture is also rotated in the housing 1, in an area close to its axis, which, in aggregate, causes intense gas evolution from the gas-liquid mixture. The released gas, passing through the shielding conical plates 4 and the conical roof 7 from the bottom, through the filters 19, the holes 18 of the perforated nozzles 10 of the axial pipe 3 is selected by the purified gas outlet pipe 5. The remaining purified liquid from the axial pipe 3 is selected by the purified liquid outlet pipe 6, which is removed on the side of the housing 1, so as not to interfere with the intensive selection of solid fractions from the conical bottom 8. Next, the purified liquid, passing through the settling chamber 14, is freed from the metal suspensions by the magnetic element 15, Some are periodically removed as they accumulate from the settling chamber 14.

In cases where a very small amount of dissolved gas is contained in the gas-liquid mixture, the purified liquid can rise through the outlet pipe of the purified gas 5 and further into the gas extraction system (not shown in the drawing). Therefore, in order to prevent liquid from entering the gas extraction system, the purified gas outlet pipe 5 is provided with a valve assembly 16 that does not allow liquid to pass through. The valve assembly 16 in practice was made in the form of a float valve (not shown in the drawing), which, when the liquid level was above the permissible level, blocked the passage channel (not shown in the drawing) of the purified gas outlet 5.

In cases where there is a very large amount of dissolved gas in the gas-liquid mixture, the purified gas can enter the outlet pipe of the purified liquid 6 and then into the liquid extraction system (not shown in the drawing). Therefore, in order to prevent gas from entering the fluid withdrawal system, the outlet pipe 6 of the purified liquid is equipped with a valve assembly 13 that does not allow gas to pass through. This valve assembly 13 was made in practice in the form of a bypass line with a float valve (not shown in the drawing), which, when the liquid level was below the acceptable level, blocked the passage channel (not shown) of the outlet pipe for the purified liquid 6.

In practice, valve assemblies 13 and 16 were also used in the form of electronic valves operating depending on the liquid level in the axial tube 3.

According to the requirements of the quality of cleaning, measure the size and quantity of solid fractions in the purified gas and purified liquid. If the quality of the cleaning has ceased to meet the specified requirements (for example, GOST), then, therefore, the filter 19 must be cleaned. To do this, the device is stopped, the outlet pipe of the purified gas 5 is turned until it stops relative to the conical cover 7 with subsequent fixation. The cylindrical mesh 20 and 21 are rotated relative to each other due to the fact that the upper end 22 of one of the cylindrical mesh 20 is hermetically connected to the perforated pipe 10 above the holes 18, and the lower end 23 of the other cylindrical mesh 21 is in the upper edge of the other perforated pipe 10 or output pipe purified liquid 6, into which a perforated pipe 10 with a first cylindrical mesh 20 is inserted. In this case, the stops 17 of the upper parts of the perforated pipes 10 and the liquid outlet pipe 6 interact with other limiters of the lower ends 12 of the interacting perforated nozzles 10, which are installed so that the cells (not shown) of the cylindrical grids 20 and 21 coincide, which increases the throughput of the filter 19 almost twice as compared to the initial installation.

After that, the purified gas outlet pipe 5 or the purified liquid outlet pipe 6 is put into recirculation mode, that is, back-flushing (washing) of the filter 19. As a result, the filter 19 is cleaned. Next, the pipe 5 of the purified gas is turned to its original state and fixed relative to the conical cover 7.

Then the centrifugal gas-liquid separator filter is again put into operation.

Using a similar design of a centrifugal gas-liquid separator filter allows you to clean the gas-liquid mixture with almost any gas content in the liquid, up to just liquid or gas, to eliminate clogging of the liquid

especially when the flow of the mixture is disrupted and the pressure drops, remove metal suspensions from the purified liquid, self-clean the filters, which significantly increases the overhaul period of the device and the quality of gas and liquid purification.

Claims (2)

1. A centrifugal gas-liquid separator filter containing a vertical housing, a tangential mixture inlet, an axial tube, shielding conical plates, cleaned gas and liquid outlet pipes, characterized in that the housing is equipped with a conical cover and a bottom, from the bottom and from the top, and a bottom equipped with a conical bottom selection of solid fractions, and the axial tube is made in the form of a set of perforated nozzles, the lower part of which is telescopically inserted into the upper part of another perforated nozzle with limited rotation, while the lower part of the lower perforated nozzle telescopically enters the outlet of the purified liquid, which is bent laterally, equipped with a valve assembly that does not allow gas to pass, a settling chamber equipped with a magnetic element, and is configured to recirculate the liquid and shielding conical plates the upper end of each perforated nozzle is provided with the exception of the upper one, which is connected from above to the outlet of the purified gas outlet, which is hermetically installed in the conical edge an arm with the ability to rotate and fix in extreme positions, equipped with a valve assembly that does not allow fluid to pass through and made with the possibility of gas recirculation, while the holes of the perforated nozzles are blocked from the outside by filters, and the filters are made with the ability to change their throughput when the perforated nozzles are rotated relative to each other . 2. The centrifugal gas-liquid separator filter according to claim 1, characterized in that the filters are made in the form of cylindrical hermetically and coaxially inserted into each other with the possibility of rotation relative to each other, the upper end of one of the cylindrical meshes being hermetically connected to the perforated nozzle above the holes, and the lower end of the other cylindrical mesh to the upper edge of the other perforated pipe or outlet of the purified liquid, into which the perforated pipe with the first cylinder is inserted netric grid.