RU2495997C1 - Flow control filter for use during oil-field operation - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: device includes the main pipe designed with inlet, filtering pipe arranged on the main pipe, layer of flow direction formed between the main pipe and filtering pipe, and flow control device designed with inlet, channel and outlet. Inlet of flow control device is connected to the layer of flow direction. Outlet of flow control device is connected to inlet of the main pipe. At least one fixed support protruding inside is arranged on inner surface of filtering pipe wall.

EFFECT: simplifying manufacturing technology, improving production efficiency.

11 cl, 3 dwg

Description

The technical field of the invention

The present invention relates to a flow control filter for use in the operation of an oilfield.

BACKGROUND OF THE INVENTION

It is known to those skilled in the art that in the operation of oilfield equipment, flow control filters are typically used to control flow, control sand removal, filter sludge particles, etc. in an oil well, a gas well, a horizontal well, a vertical well, and a directional well. Such a filter comprises a main pipe, a through channel formed in the main pipe as an inlet of the main pipe, a filter pipe located on the main pipe, and an annular gap between the main pipe and the filter pipe, acting as a flow direction layer.

Due to factors such as water viscosity, which is much lower than oil viscosity and formation heterogeneity, the problem of water entering the oil well is very serious in oil production, seriously affecting the economic performance of the oil field.

An axial isolation flow control filter for the oilfield is an effective solution to the problem of significant water inflow due to reasons such as a high oil-water viscosity ratio in the oil reservoir. For example, an efficient flow control filter has been created in which the flow control device is located in the filter, the inlet of the flow control device is in communication with the flow direction layer, and the outlet of the flow control device is in communication with the inlet of the main pipe. In use, the filter pipe is insulated externally with both end rings of the filter so that the fluid can enter the flow direction layer only through the filter pipe. Since the flow direction layer communicates with the inlet of the flow control device and the outlet of the flow control device communicates with the inlet of the main pipe, the fluid passes through the filter pipe in series, the flow direction layer, the inlet of the flow control device, the flow control channel of the flow control device, the discharge of the flow control device , the inlet of the main pipe and, finally, the main pipe in the oil production process. This path is the only one, and there is no other path for the fluid to enter the main pipe outside the filter.

This type of flow control filter operates by decreasing the flow difference per meter to some extent in order to achieve flow control. It can solve the problem of increased water intake, due to such reasons as a high ratio of oil to water viscosity in the oil reservoir, uneven supply to the running meter of the wellbore in the process of pumping water, in the process of pumping chemicals, etc.

The gap of the flow direction layers in the filter is very small, usually about 1-10 mm, and the length of the crude oil flow in the flow direction layer during oil extraction can be up to 4-9 meters, and the resistance to the supply of raw oil in the flow direction layer is relatively large. The flow direction layer is free from obstacles or does not directly affect oil production.

In order to provide an unobstructed flow direction layer such that the flow direction layer does not close due to increased pressure around the filter in the formation, a technique known in the art is usually used to install longitudinal ridges at equal intervals in the flow direction layer. When external pressure acts on the filter pipe, the longitudinal ridges perform a supporting function, preventing the flow direction layer from closing, thereby keeping the direction layer free for flow.

For solutions such as installation at equal intervals of longitudinal ridges in the flow direction layer, the filter pipe has two forms: one with installation at equal intervals of longitudinal ridges on the outer surface of the main pipe and further winding the wire outside around the main pipe to form a filter pipe that requires special precision winding machine, which is expensive; another using a casing of metal mesh as a filter pipe, which is supported from the inside by a protective sleeve with many holes, while the casing of the metal mesh and the inner protection of the sleeve are located on the main pipe with longitudinal ridges. On the one hand, this method is very material intensive. On the other hand, the installation speed of the ridges is low, and the size of the mounting ridges is non-standard and has large deviations, which results in a large deviation from the diameter of the main pipe with longitudinal ridges and increases the difficulty of creating a filter tube sleeve.

SUMMARY OF THE INVENTION

The aim of the present invention is to eliminate at least one drawback of the known flow control filter and the creation of a flow control filter with fixed supports on the inner side of the filter pipe wall. An additional objective of the present invention is to provide a flow control filter that is simple in design and economical, significantly simplifies manufacturing technology and facilitates processing quality control and creates a flow direction layer that does not close due to increased pressure around the filter in the reservoir, while keeping it free of obstructions, and solve the problem significant water inflow due to reasons such as a high viscosity ratio of oil water in the oil reservoir during uatatsii oil field, observing the actual requirements in the production of oil.

According to the present invention, a flow control filter is created for use in oilfield operations, comprising a main pipe equipped with an inlet, a filter pipe placed on the main pipe so that the annular gap between the main pipe and the filter pipe forms a flow direction layer for fluid passage, and a control device a flow comprising an inlet, a flow control channel and an outlet, wherein the inlet of the flow control device is in communication with the flow direction layer, and the exhaust flow control is communicated with the inlet of the main pipe, while the filter pipe is made in the form of a metal pipe equipped with many filter slots in its wall, the metal pipe is made of a metal sheet, and at least one stationary support protruding inwardly is located on the inner surface of the filter pipe wall so that the flow direction layer is in communication with at least one part of the plurality of slots and is not closed by external pressure around the filter in the formation. Preferably, this can ensure that the flow direction layer can remain unobstructed by external pressure around the filter in the formation.

Preferably, the at least one fixed support comprises a plurality of fixed supports that are substantially uniformly distributed on the inner surface of the wall of the filter pipe or on one side of the metal pipe. One skilled in the art will recognize that since the filter pipe is made of a metal sheet and the fixed supports are usually not located near the edges of the metal sheet, there are no fixed supports near the joint on the wall of the filter pipe when the filter pipe is made using such a metal sheet. Thus, the terms “substantially uniformly distributed” or “uniformly distributed” are used to describe the distribution of “fixed supports” or “slots” in this document without taking into account the influence of the boundaries of the metal sheet or the joint on the wall of the filter pipe, which is clear to a person skilled in the art technicians.

Preferably, each of the fixed supports is a protruding part, fixedly mounted on the inner surface of the wall of the filter pipe, and the height of each of the protruding parts is set to ensure that the flow direction layer is not closed by external pressure around the filter in the formation.

Preferably, each of the fixed supports is a protruding part stamped inwardly in the wall of the filter pipe, and the depth of stamping of each of the protruding parts is greater than the wall thickness of the filter pipe, so that slits are formed in the form of side slots between the perimeter portions of the upper surface of each of the protruding parts and the shear planes not stamped sections of the wall of the filter pipe.

Preferably, the upper surface of each of the fixed supports has a substantially quadrangular shape. More preferably, the upper surface of each of the fixed supports is substantially square or rectangle in shape.

Preferably, the upper surface of each of the fixed supports has a substantially square or rectangle shape, and the slots are made in the form of side slots between two opposite side edges of the upper surface of each of the fixed supports and shear planes of non-stamped sections of the metal pipe wall.

Preferably, each of the slots extends parallel to the longitudinal axis of the filter pipe or extends at an angle relative to the longitudinal axis of the filter pipe of more than 0 degrees, but not more than 90 degrees.

Preferably, the plurality of slots contains a plurality of slit groups, the distribution configuration of which is such that the slots of each group are spaced at equal intervals in the direction along the periphery of the filter pipe, and the slit groups are arranged at equal intervals in the longitudinal direction of the filter pipe, or the slots of each group are arranged with equal intervals in a spiral direction on the wall of the filter pipe, and groups of slots are arranged at equal intervals in the direction along the periphery of the filter pipe.

Preferably, the filter pipe is a metal pipe made by welding a spiraling elongated metal sheet with preformed fixed supports.

The flow control filter of the present invention has a simple manufacturing technology and is economical, while the fixed supports are located on the inner surface of the wall of the metal filter pipe provided with slots, the fixed supports can be stamped on a metal sheet or mounted directly on a metal sheet by welding or gluing. In general, the fixed supports are arranged on the part from an elongated metal sheet, and the filter tube is made by spiraling the metal sheet with the fixed supports inside and then welding the resulting cylinder along the edges of the sheet.

When the filter pipe is worn on the main pipe, the stationary supports protruding inwardly function as longitudinal ridges in the flow direction layer between the filter pipe and the main pipe. When the filter tube compresses the external pressure, the fixed supports perform a supporting function so that the flow direction layer does not close with increasing external pressure, while an unhindered flow direction layer is maintained. Slots are designed to meet the filtering requirements of the filter. Since the filter tube is made of a metal sheet, such a filter tube has excellent overall strength and resistance to deformation. The supporting function of the stationary supports protruding inward makes the flow direction layer free of obstructions, reduces the resistance to the flow of crude oil in the flow direction layer, and is preferred for increasing oil production.

In addition, the filter according to the present invention is simple in design, economical, greatly simplifies manufacturing technology and facilitates quality control during processing, which ensures high performance and low cost of the filter in mass production.

Brief Description of the Drawings

1 is a schematic sectional side view of a flow control filter according to a preferred embodiment of the present invention with a fixed support and a groove.

Figure 2 schematically shows a part of a cross-section in side view of a flow control filter according to a preferred embodiment of the present invention with a plurality of fixed supports and a plurality of grooves.

Figure 3 schematically shows a cross section of a flow control filter according to a preferred embodiment of the present invention.

Detailed Description of Preferred Embodiments

To clarify the purpose, technical solution and advantages of the present invention, preferred embodiments of the present invention are described in detail below and shown in the accompanying drawings.

Figure 1 shows the flow control filter used in the operation of the oil field according to the present invention and containing a main pipe 1, equipped with an inlet 11, a filter pipe 2 located on the main pipe 1 so that the annular gap between the main pipe 1 and the filter pipe 2 forms a layer 3 flow directions for the passage of fluid flow, and a flow control device 4 comprising an inlet 41, a channel 42 and an outlet 43, the inlet 41 of the flow control device in communication with the flow direction layer 3, and an outlet 43 troystva regulate the flow inlet 11 communicates with the main pipe. In the flow control filter, the filter pipe 2 is made of a metal pipe provided with a plurality of filter slots 22 in its wall, the metal pipe being made of a metal sheet, and at least one stationary support protruding inwardly 21 is located on the inner wall surface of the filter pipe 1, so that the flow direction layer 3 in communication with at least one part of the plurality of slots 22 is not closed by external pressure around the filter in the formation. Preferably, the flow direction layer is free from obstruction.

Preferably, the filter comprises a plurality of fixed supports 21, which are substantially uniformly distributed over the inner wall of the filter pipe 2 or substantially uniformly distributed on the metal sheet (as indicated above, the influence of the edge zone or joint is not taken into account).

Preferably, each of the fixed supports 21 is a protruding part, fixedly mounted on the inner surface of the wall of the filter pipe 2, and the height of each of the protruding parts is set such that the flow direction layer does not close under the influence of external pressure around the filter in the formation, preferably , to keep the flow direction layer devoid of obstacles.

Alternatively, preferably, each of the fixed supports 21 is a protruding part stamped inwardly on the wall of the filter pipe 2, and the depth of stamping of each of the protruding parts is greater than the wall thickness of the filter pipe, so that the slots 22 are in the form of side slots between the peripheral portions of the upper surface of each protruding parts and shear planes of not stamped sections of the filter pipe wall.

Preferably, the upper surface of each of the fixed supports 21 has a substantially quadrangular shape and, more preferably, a square or rectangle shape. Of course, one skilled in the art will appreciate that fixed supports with upper surfaces of a different shape are also possible.

In a preferred embodiment, the top surface of each of the fixed supports 21 is substantially square or rectangle in shape. In addition, the slots 22 are in the form of side slots between two opposite side edges of the upper surface of each of the fixed supports 21 and the shear planes of the not stamped sections of the wall of the metal pipe.

Each of the slots 22 preferably extends parallel to the longitudinal axis of the filter pipe 2, or each of the slots 22 extends at an angle relative to the longitudinal axis of the filter pipe of more than 0 degrees, but not more than 90 degrees.

To simplify the understanding of the configuration of the distribution of slots in this document, many slots 22 can be divided into many groups of slots, i.e. many slots 22 contains many groups of slots. In a preferred embodiment, the distribution pattern of the plurality of slots 22 is configured such that the slots of each group are spaced at equal intervals in the direction along the periphery of the filter pipe 2 and the group of slots are spaced at equal intervals in the longitudinal direction of the filter pipe 2, or the slots of each group are arranged at equal intervals in in a spiral direction on the wall of the filter pipe, and groups of slots are spaced at equal intervals in the direction along the periphery of the filter pipe.

In addition, in the present invention, the filter tube 2 is preferably welded from a spiraling elongated metal sheet with preformed fixed supports.

The stationary supports protruding inwardly function as longitudinal ridges in the flow direction layer between the filter pipe and the main pipe. When the filter tube compresses the external pressure, the fixed supports perform a supporting function so that the flow direction layer does not close with increasing external pressure, while keeping the flow direction layer devoid of obstruction. Filter slots in the form of side slots are stamped with the same slot width to meet the filtering requirements of the filter. In particular, since the filter pipe of the present invention is made of a metal sheet, the resulting filter pipe has excellent overall strength and resistance to deformation. The supporting function of the stationary supports protruding inward makes the flow direction layer unobstructed, reduces the resistance to flow of crude oil in the flow direction layer, and is preferred for increasing oil production. Meanwhile, the flow control device can effectively solve the problem of significant water inflow due to reasons such as a high ratio of oil to water viscosity in the oil reservoir during the operation of the oil field.

The filter according to the present invention has a simple design, greatly simplifies manufacturing technology, promotes quality control during machining and is economical, which ensures high performance and low cost of the filter in mass production.

The description above refers only to preferred embodiments of the present invention, and is not intended to limit the invention. Any modifications, equivalent replacements and improvements may be made within the scope of the present invention defined by the claims.

Claims (11)

1. The flow control filter for use in the operation of an oil field, comprising a main pipe having an inlet of the main pipe, a filter pipe placed on the main pipe so that the annular gap between the main pipe and the filter pipe forms a flow direction layer for the passage of fluid, and a control device a flow comprising an inlet, a flow control channel and an outlet, wherein the inlet of the flow control device is in fluid communication with the flow direction layer, and the outlet of the flow control device the flow rate is in fluid communication with the inlet of the main pipe, while the filter pipe is made in the form of a metal pipe with many filter slots in its wall, and the metal pipe is made of metal sheet and at least one protruding is located on the inner surface of the wall of the filter pipe inwardly a fixed support so that the flow direction layer communicating with at least one part of the plurality of slots is not closed by external pressure around the filter in the formation, and each one of the fixed supports is a protruding part stamped inwardly in the wall of the filter pipe, and the stamping depth of each protruding part exceeds the wall thickness of the filter pipe, so that slots are formed in the form of side slots between the perimeter sections of the upper surface of each protruding part and the shear planes of the unstamped sections of the filter wall pipes. 2. The filter according to claim 1, in which at least one fixed support comprises a plurality of fixed supports, which are essentially uniformly distributed on the inner surface of the filter pipe wall. 3. The filter according to claim 1 or 2, in which each of the fixed supports is a protruding part, fixedly mounted on the inner surface of the wall of the filter pipe, and the height of each protruding part is installed so that the layer of the flow direction does not close under the influence of external pressure around the filter in the reservoir. 4. The filter according to claim 1 or 2, in which the upper surface of each fixed support has a substantially quadrangular shape. 5. The filter according to claim 4, in which the upper surface of each fixed support is essentially the shape of a square or rectangle. 6. The filter according to claim 1, in which the upper surface of each fixed support is essentially in the form of a square or rectangle, and the slots are made in the form of side slots between two opposite side edges of the upper surface of each fixed support and the shear planes of unstamped sections of the wall of the metal pipe . 7. The filter according to claim 1 or 2, in which each slot extends parallel to the longitudinal axis of the filter pipe. 8. The filter according to claim 1 or 2, in which each slot extends at an angle relative to the longitudinal axis of the filter pipe, which is more than 0 °, but not more than 90 °. 9. The filter according to claim 1 or 2, wherein the plurality of slots contains a plurality of slit groups, the distribution configuration of which is such that the slots of each group are spaced at equal intervals in the direction along the periphery of the filter pipe, and the slit groups are arranged at equal intervals in the longitudinal direction the filter pipe, or the slots of each group are arranged at equal intervals in a spiral direction in the wall of the filter pipe, and the groups of slots are located at equal intervals in the direction along the periphery of the filter pipe. 10. The filter according to claim 1 or 2, in which the filter pipe is a metal pipe made by welding a spiraling elongated metal sheet with pre-made fixed supports. 11. The filter according to claim 1 or 2, in which the fixed supports located on the inner surface of the wall of the filter pipe are made to ensure that the flow direction layer remains unhindered by external pressure surrounding the filter in the formation.

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