RU2571113C1 - Rotary separation filter, booster pump station and its operation - Google Patents

Abstract

FIELD: engines and pumps.SUBSTANCE: claimed filter comprises vertical housing with the central, in fact, cylindrical portion, top and bottom portions, in fact, of hemispherical shape, tangential inlet of fluid including oil and particles to be filtered put and arranged at the housing top portion, axial pipe for filtered fluid discharge concentric with the housing and fitted at its top portion, and multiple conical plates located around the axial pipe, one above the other. The bed of said plates is directed downward relative to the housing position, particles removed from the fluid being discharged via outlet arranged at the housing bottom portion. Note here that said axial pipe is continuous, its bottom end being provided with perforated plug secured under the bed of the lowest of said multiple plates nut above said outlet for discharge of removed particles. Note here that conical plates are secured at the axial pipe and fixed relative to each other and feature different-diameter beds. Note that the diameter of said beds increases in direction from tangential inlet to outlet for discharge of removed particles. The booster pump station comprises the buffer tank, fluid leaks accumulation and discharge assy, the vessel for removed particles, the pump unit, multiple plugs for emergent gas discharge and centrifugal separation filter. Operation of this station comprises the steps that follow. Fluid containing the oil and particles to be filtered out are received in the buffer tank while fluid is fed into the filter via communicating pipes. Particles are separated from oil by means of the rotary separation filter. Filtered particles removed from oil are accumulated in the adequate tank. Pressure in the pump unit is boosted for further transfer of fluid containing oil to oil transfer network or to that of main oil lines.EFFECT: stable fluid flow, separation of different-size particles.18 cl, 2 dwg

Description

FIELD OF THE INVENTION

The present invention relates to the operation of booster pumping stations in oil fields, namely to improved centrifugal separator filters, booster pumping stations with such filters and methods of operating such stations.

BACKGROUND

As a rule, booster pumping stations (BPS) are used in remote oil fields. The need for the use of BPS is due to the fact that often in such fields the energy of the oil and gas reservoir is not enough to transport the oil and gas mixture before installing a preliminary discharge of water, designed to separate formation water and associated gas from oil, as well as heating the oil and increasing the specific energy of the flow of oil to the next system oil preparation.

BPS equipment, primarily pumps, provides oil with the additional pressure necessary for transportation in the direction of high-pressure sections through collection and preparation systems. Booster pumping stations also perform the functions of separating oil from intrinsic particles, mechanical impurities, sludge, fine crystalline suspension, corrosion products and other solid particles that break out from the formation and near the bottomhole zone, which are extracted by the stream to the wellhead and enter the oil and gas collection system, creating serious problems there.

The most important factor in the effective operation of pumps on the pumping station is the quality of well production. This is all the more important because the cost of the equipment used (its overhaul, maintenance) is very high. In connection with the removal from the reservoir of a large number of different particles on the gratings of the previously used filters, traffic jams appeared that adversely affect the further movement of the fluid. With an increase in the size of the openings in the filter grate, clogging of the working elements of the DNS pump occurred with subsequent failure. Otherwise, there was an increase in working pressure at the filter intake and a non-categorical failure (breakthrough) of the pipeline.

Due to the aforementioned reasons, various filter separators are widely used, the operation of which is based on the centrifugal principle, when the fluid to be cleaned is fed into a cylindrical or cone-shaped body, and due to the different density of polluting particles and the fluid, they separate under the action of centrifugal forces.

Thus, a centrifugal filter separator is known (RU 129414, publ. 06/27/2013, IPC B01D 45/12, B04C 5/00), characterized in that it includes a vertical cylindrical body with a top cover and a lower conical bottom forming the inner cavity of the filter -separator, the line of tangential input of the cleaned fluid into the internal cavity connected to the housing near the top cover; outlet pipes for purified liquid and sediment; a central outlet pipe with a bottom end closed by a cap, placed in the center coaxially with the body, passing through the top cover and having openings adjacent to the plug in the lower part of the pipe wall, characterized in that it is additionally equipped with upper and lower cylindrical inserts coaxial with the body, moreover, the lower insert has a diameter greater than the upper; the upper insert is located below the tangential inlet of the fluid to be cleaned and forms an inner annular gap with the central outlet rough, and an outer annular gap with the body wall; the upper cylindrical insert is connected to the housing by a continuous annular diaphragm located between the upper and lower ends of this insert; an annular sludge receiver is installed outside the casing adjacent to it at the level of the diaphragm; it is communicated by openings with the internal cavity of the casing above the diaphragm and having at least one pipe for draining the sediment; the upper end of the lower cylindrical insert is located in the outer annular gap below the diaphragm, and its lower end is placed below the lower end of the upper cylindrical insert and connected to the large base of the additional insert in the form of a truncated cone, the smaller base of which is connected to the plug of the central outlet pipe; the lower conical bottom is equipped with a outlet pipe for the purified liquid.

A disadvantage of the known filter separator is the insufficient filtration ability of the device, because the removed particles are discharged along the central outlet pipe in the direction from the bottom end closed by the plug to the upper cover, while the cleaned fluid is discharged through the inner annular gap located upstream of the fluid from the bottom end of the central outlet pipe, which means that not all particles enter into the central outlet pipe.

Also known in the prior art are centrifugal gas-liquid separator filters described in patents RU 2290252 (publ. 12/27/2006, IPC B01D 45/12), RU 2290984 (publ. 10.01.2007, IPC B01D 45/12), RU 2295999 (publ. 03/27/2007, IPC B01D 45/12), the first of which is selected as the closest analogue for the inventive centrifugal separator filter.

A common disadvantage of the known centrifugal separator filters is the lack of filtration ability of the device, because the differences in the characteristics of the particles to be separated are not taken into account, and, in particular, the fact that lighter in mass and smaller in transverse size particles cannot be filtered sufficiently efficiently and, therefore, can enter the filter outlet with a common fluid stream. Moreover, the axial tube of the filter selected as a prototype 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 expansion. So, during the operation of the filter, it is possible to change its filtering ability due to the movement of the perforated nozzles relative to each other, which can negatively affect the filter’s ability to pass particles of one size and retain particles of another size. In addition, with a sudden change in the position of the perforated nozzle, the stability of the fluid flow may be impaired, and in the event of a stall, local swirls may occur that impede proper particle filtration.

SUMMARY OF THE INVENTION

To solve the problem of overcoming the above problems, namely, ensuring a stable fluid flow, which allows filtering particles of different sizes with equal efficiency, the authors in one aspect of the invention proposed a centrifugal separator filter containing:

a vertical housing having a central part of a substantially cylindrical shape and upper and lower parts of a substantially hemispherical shape,

tangential fluid inlet containing oil and particles to be filtered, located in the upper part of the housing,

an axial pipe with the release of filtered fluid having a concentric arrangement with the body and fixed in its upper part,

a plurality of cone plates arranged around the axial tube one above the other, the base of the cone plates pointing downward relative to the position of the housing,

the release of particles removed from the fluid located in the lower part of the housing, while

the axial tube is continuous, and a perforated plug is attached to its lower end, located in the housing below the base of the lowest of the many conical plates, but above the outlet of the particles removed from the fluid, and the conical plates are fixed to the axial pipe in a fixed position relative to each other and made with bases of different diameters, the diameter of the base of the cone plates increasing in the direction from the tangential inlet to the outlet of particles removed from the fluid.

In one embodiment, a filter is proposed in which the increase in the diameter of the base of the cone plates is uniform.

In one embodiment, a filter is proposed in which the increase in the diameter of the base of the cone plates is uneven.

In one embodiment, a filter is provided in which the cone plates are fixed to the axial tube by welding.

In one embodiment, a filter is proposed in which the cone plates are integral with the axial tube.

In one embodiment, a filter is provided that provides a fluid flow rate of 60 m ³ / h.

In one embodiment, a filter is proposed in which the tangential inlet passage diameter is 125 mm.

In one embodiment, a filter is proposed in which the diameter of the axial pipe is 125 mm.

In one embodiment, a filter is provided in which the outer diameter of the tangential inlet is 138 mm.

In one embodiment, a filter is proposed in which the outer diameter of the axial pipe outlet is 138 mm.

In one embodiment, a filter is proposed in which the outer diameter of the vertical housing is 377 mm.

In one embodiment, a filter is provided that provides filtering of particles whose transverse size is 5 μm or more.

In one embodiment, a filter is provided that provides filtering of particles with an efficiency that is from 70% to 90%.

In one embodiment, a filter is provided that provides a solids content at the outlet of the filtered fluid of not more than 0.2% of the mass of the fluid.

Thus, this filter provides increased filtering ability due to the fact that the cone plates are fixed on the axial tube in a fixed position relative to each other, which guarantees the stability of the fluid flow and the absence of stalls, moreover, this ensures constant filter characteristics in separation from fluid particles of various sizes, and the filtration of both small and large particles is guaranteed by the fact that the conical plates are made with bases of different diameters , The diameter of the base of conical plates increases in the direction from the tangential inlet to the outlet remote from the fluid particles

In one of the additional aspects of the invention, there is provided a booster pump station comprising a buffer tank, a unit for collecting and pumping oil leaks, a filter, a reservoir for removed particles, a pump unit and a plurality of candles for emergency gas discharge, the filter being a centrifugal separator filter made in accordance with with the first aspect of the invention.

In one additional aspect of the invention, there is provided a method of operating a booster pump station, comprising the steps of:

receive a fluid containing oil and particles to be filtered into a buffer tank,

supplying fluid to the filter through connecting pipes,

filtering the fluid to separate particles to be filtered from oil by the centrifugal separator filter of the first aspect of the present invention.

accumulate oil-filtered particles in the reservoir for the removed particles,

pressurize the pump unit for subsequent transportation of a fluid containing oil, purified from particles to be filtered,

supplying a fluid medium containing oil purified from particles to be filtered into a transportation network or a network of oil trunk pipelines.

In one embodiment, a method is provided, further comprising the step of collecting fluid in a collection and pumping unit for oil leaks in the event of an oil leak.

In one embodiment, a method is provided, further comprising the step of relieving excess fluid pressure by means of a plurality of candles for emergency gas discharge.

It should be understood that the proposed booster pump station and the method of its operation also provides a stable fluid flow, which allows equal efficiency to filter particles of different sizes contained in the fluid entering the buffer tank of the booster pump station. This means that the reliability of the booster pump station is improved, the service interval of the centrifugal separator filter is increased, and, as a result, the interval between overhauls of the booster pump station is increased.

BRIEF DESCRIPTION OF THE DRAWINGS

Next, the most preferred embodiments of the invention will be described in more detail with reference to the drawings, in which:

in FIG. 1 shows a cross section of a centrifugal separator filter,

in FIG. 2 shows a section along line AA in FIG. one.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

The following description relates to the operation of booster pumping stations in oil fields, namely to improved centrifugal separator filters, booster pumping stations with such filters and methods of operating such stations.

As a rule, booster pumping stations (BPS) are used in remote oil fields. The need for the use of BPS is due to the fact that often in such fields the energy of the oil and gas reservoir for transporting the oil and gas mixture to a preliminary water discharge unit designed to separate formation water and associated gas from the oil, as well as to heat the oil and increase the specific energy of the produced oil stream to the next treatment system oil is not enough.

BPS equipment, primarily pumps, provides oil with the additional pressure necessary for their transportation in the direction of high-pressure sections through collection and preparation systems. Booster pumping stations also perform the functions of separating oil from intrinsic particles, mechanical impurities, sludge, fine crystalline suspension, corrosion products and other solid particles that break out from the formation and near the bottomhole zone, which are extracted by the stream to the wellhead and enter the oil and gas collection system, creating serious problems there.

In FIG. 1 shows a cross section of the proposed centrifugal separator filter, and FIG. 2 shows a section along line AA in FIG. one.

 The filter of FIG. 1 is a centrifugal separator filter comprising a vertical housing 1 having a central portion of a substantially cylindrical shape and a top and bottom portion of a substantially hemispherical shape, a tangential inlet 2 of a fluid containing oil and particles to be filtered, located in the upper parts of the housing 1, the axial pipe 3 with the outlet 4 of the filtered fluid having a concentric arrangement with the housing 1 and fixed in its upper part, a plurality of conical plates 5 located around the axial t loss 3 under each other, with the base of the cone plates 5 directed downward relative to the position of the housing 1, the outlet 6 of particles removed from the fluid located in the lower part of the housing 1, while the axial tube 3 is continuous, and to its lower end located in the housing 1 below the base of the lowest of the many conical plates 5, but above the outlet 6 of particles removed from the fluid, a perforated plug 7 is attached, while the conical plates 5 are fixed to the axial tube 3 in a fixed position relative to each other and they are made with bases of different diameters, the diameter of the base of the conical plates 5 increasing in the direction from the tangential inlet 2 to the outlet 6 of particles removed from the fluid.

The action of the filter is based on the separation of fine-crystalline suspension and particles of a flowing fluid with different densities, as a result of the action of centrifugal force on solid particles during tangential flow inlet at high speed with radial acceleration inside the body.

Centrifugal separation occurs inside the housing 1, and in the proposed filter provides increased filtering ability due to the fact that the conical plates 5 are fixed on the axial tube 3 in a fixed position relative to each other, which guarantees the stability of the fluid flow and the absence of stalls, moreover, with This ensures that the filter characteristics are constant in terms of separation of particles of various sizes from the fluid, and the filtration of both small and large particles is guaranteed by the fact that The fifth plates 5 are made with bases of different diameters, the diameter of the base of the conical plates 5 increasing in the direction from the tangential inlet 2 to the outlet 6 of particles removed from the fluid.

It should be borne in mind that in some embodiments, the increase in the diameter of the base of the conical plates 5 may be uniform, and in others uneven. With a uniform increase in the diameter of the cone plates 5, the increase in the diameter of the cone plates 5 in the direction from the tangential inlet 2 to the outlet 6 of particles removed from the fluid occurs with the same step. The increment may be arbitrary, for example, amounting to 5% of the diameter of the base of the conical plate 5. If the diameter of the conical plates 5 is unevenly increased, the diameter of the conical 5 plates increases in the direction from the tangential inlet 2 to the outlet 6 of particles removed from the fluid with a variable step. In any case, with an increase in the diameter of the conical plates 5, particles of a smaller transverse size will separate from the fluid stream with greater efficiency.

The filter can be made of any available material that can withstand the pressure of the fluid to be filtered, up to 1.6 MPa, preferably of light and sufficiently strong metals, such as stainless steel. In various embodiments, the conical plates 5 may be secured to the axial tube 3 by welding, or they may be integral with the axial tube 3 by known stamping, casting, and other metal processing methods.

The cleaned fluid is discharged through an axial tube 3, at the inlet end of which a perforated plug 7 is installed for introducing the cleaned fluid. Contaminants, sludge and other particles to be filtered, as a result, settle and accumulate in the lower part of the filter housing 1, from where they can be regularly or cyclically removed by maintenance personnel by releasing 6 particles removed from the fluid. Also in this case, the perforated plug 7 serves as an additional filtration element, because ensures the pre-filtering of particles that can be picked up by the flow of fluid from the bottom of the lower part of the filter housing 1. In one embodiment, the outlet 6 of the particles removed from the fluid can be connected to the reservoir for the removed particles of the booster pump station, while the outlet 4 is fluidly connected to the pump unit of this station.

The filter is mounted by flange connections (not shown) onto existing transfer lines. Obvious is the installation of various taps and valves at the inlet and outlet of the filter to shut off the fluid flow, for example, in case of need for repair and other maintenance work. One of the options for using the proposed filter is its operation as part of a booster pump station containing a pump unit. It can be based on a centrifugal pump sectional (CNS) type CNS-60, i.e. having a fluid flow rate of 60 m ³ / h

In such a use case of the present invention, it is preferable to provide a filter providing a fluid flow rate of 60 m ³ / h. Then, in order to ensure the indicated flow rate and for the convenience of installation, the proposed filter can be made so that the diameter of the tangential inlet passage is 125 mm and / or the diameter of the axial pipe outlet is 125 mm and / or the outer diameter of the tangential inlet is 138 mm and / or the outer diameter of the axial pipe outlet is 138 mm. In general, in such an embodiment, the outer diameter of the vertical housing will be 377 mm, and the total height (together with the outlet 4 of the filtered fluid and the outlet 6 for the removed particles) of the filter will be 1,450 mm.

The reliability of booster pumping stations and, in particular, the pumps used, like any machines and mechanisms, is determined by a number of factors. Firstly, it depends on the perfection of the design and, accordingly, the completeness of its adaptation to the operating conditions of the machines. Secondly, it is determined by the quality of factory manufacturing. And finally, it depends on the operating conditions of the pumps and on the characteristics of the transported fluid. It should be noted that typically centrifugal pumps are designed to pump oil products uncontaminated by mechanical impurities and water with oil impurities.

Therefore, in order to guarantee long service life of booster pumping stations pumps and to increase the overhaul intervals in one of the options, the filter must provide filtering of particles whose transverse size is 5 microns or more, thereby guaranteeing filtering of particles whose transverse size exceeds 0.2 mm, which required for proper operation of the pump type CNS-60. Preferably, particle filtration should be provided with an efficiency of between 70% and 90%. This ultimately can provide a solids content at the outlet 4 of the filtered fluid is not more than 0.2% of the mass of the fluid.

As already mentioned, it is typical to use centrifugal separator filters at booster pump stations, in particular at a booster pump station containing a buffer tank, a unit for collecting and pumping out oil leaks, a filter, a reservoir for removed particles, a pump unit and many candles for emergency gas discharge, and the filter is a centrifugal separator filter made in accordance with the first aspect of the present invention.

A method of operating such a booster pump station includes the steps of:

receive a fluid containing oil and particles to be filtered into a buffer tank,

supplying fluid to the filter through connecting pipes,

filtering the fluid to separate particles to be filtered from oil,

accumulate oil-filtered particles in the reservoir for the removed particles,

pressurize the pump unit for subsequent transportation of a fluid containing oil, purified from particles to be filtered,

supplying a fluid medium containing oil purified from particles to be filtered into a transportation network or a network of oil trunk pipelines.

It should be understood that the step of filtering the fluid is carried out by means of a centrifugal separator filter according to the first aspect of the present invention. In addition, the method may further include the stage of accumulating fluid in the unit for collecting and pumping oil leaks in the event of an oil leak, and may also further include relieving the excess pressure of the fluid through a plurality of emergency release candles gas known from the prior art.

In the proposed booster pump station and the method of its operation, a stable fluid flow is also provided, which allows filtering particles of different sizes contained in the fluid entering the buffer capacity of the booster pump station with equal efficiency. This means that the reliability of the booster pump station is improved, the service interval of the centrifugal separator filter is increased, and, as a result, the interval between overhauls of the booster pump station is increased.

It should be understood that the structures and methods disclosed in the materials of the present description are exemplary in nature, and that these specific embodiments should not be construed in a limiting sense, since numerous variations are possible. The subject of this description includes all the latest and non-obvious combinations and subcombinations of various systems and methods, and other features, functions and / or properties disclosed in the materials of the present description. The following claims in detail indicate some combinations and subcombinations considered as new and non-obvious.

Claims (18)

1. Centrifugal separator filter containing
a vertical housing (1) having a central part of a substantially cylindrical shape and upper and lower parts of a substantially hemispherical shape,
tangential inlet (2) of a fluid containing oil and particles to be filtered, located in the upper part of the housing (1),
an axial tube (3) with a filtered fluid outlet (4) having a concentric arrangement with the body (1) and fixed in its upper part,
a plurality of cone plates (5) located around the axial tube (3) under each other, the base of the cone plates (5) pointing downward relative to the position of the housing (1),
the release (6) of particles removed from the fluid located in the lower part of the housing (1), while
the axial tube (3) is continuous, and a perforated plug (7) is attached to its lower end located in the housing (1) below the base of the lowest of the many conical plates (5), but above the outlet (6) of the particles removed from the fluid wherein the cone plates (5) are fixed on the axial tube (3) in a fixed position relative to each other and are made with bases of different diameters, and the diameter of the base of the cone plates (5) increases in the direction from the tangential inlet (2) to the outlet (6) removed from the fluid particles. 2. The filter according to claim 1, in which the increase in the diameter of the base of the conical plates is uniform. 3. The filter according to claim 1, in which the increase in the diameter of the base of the conical plates is uneven. 4. The filter according to claim 1, in which the conical plates are fixed to the axial pipe by welding. 5. The filter according to claim 1, in which the cone plates are made in one piece with the axial tube. 6. The filter according to claim 1, providing a flow rate of a fluid equal to 60 m ³ / h. 7. The filter according to claim 1, in which the diameter of the passage of the tangential inlet is 125 mm 8. The filter according to claim 1, in which the diameter of the axial pipe outlet is 125 mm. 9. The filter according to claim 1, in which the outer diameter of the tangential inlet is 138 mm 10. The filter according to claim 1, in which the outer diameter of the axial pipe outlet is 138 mm. 11. The filter according to claim 1, in which the outer diameter of the vertical housing is 377 mm 12. The filter according to claim 1, providing filtering of particles whose transverse size is 5 μm or more. 13. The filter according to p. 12, providing for filtering particles with an efficiency that is from 70% to 90%. 14. The filter according to claim 12 or 13, providing a solids content at the outlet of the filtered fluid is not more than 0.2% of the mass of the fluid. 15. A booster pump station containing a buffer tank, a unit for collecting and pumping oil leaks, a filter, a reservoir for removed particles, a pump unit and a plurality of candles for emergency gas discharge, the filter being a centrifugal separator filter according to any one of claims. 1-14. 16. A method of operating a booster pump station, comprising the steps of:
receive a fluid containing oil and particles to be filtered into a buffer tank,
supplying fluid to the filter through connecting pipes,
filtering the fluid to separate particles to be filtered from oil by means of a filter according to any one of paragraphs. 1-14.
accumulate oil-filtered particles in the reservoir for the removed particles,
pressurize the pump unit for subsequent transportation of a fluid containing oil, purified from particles to be filtered,
supplying a fluid medium containing oil purified from particles to be filtered into a transportation network or a network of oil trunk pipelines. 17. The method according to p. 16, further comprising the stage of accumulating the fluid in the unit for collecting and pumping oil leaks in the event of an oil leak. 18. The method according to p. 16 or 17, further comprising the step of releasing the excess pressure of the fluid through a plurality of candles for emergency gas discharge.

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