WO2022183898A1

WO2022183898A1 - Method for operating water injection well, and water injection well

Info

Publication number: WO2022183898A1
Application number: PCT/CN2022/076167
Authority: WO
Inventors: 裴柏林
Original assignee: 安东柏林石油科技（北京）有限公司; 裴柏林
Priority date: 2021-03-04
Filing date: 2022-02-14
Publication date: 2022-09-09
Also published as: CN115030697A

Abstract

A method for operating a water injection well, being capable of achieving relatively balanced water injection between different strata of the water injection well. The method comprises: providing a flow control screen pipe (140) in a well cavity (130), and by means of a wellhead (110), filling a packer particle carrying fluid in an annular space between the flow control screen pipe (140) and a well wall (120). The present invention further relates to a water injection well that uses the method for water injection.

Description

Method of operating a water injection well and water injection well

technical field

The present invention relates to a method of operating a water injection well, which enables relatively balanced water injection between different formations of the water injection well. The invention also relates to a water injection well suitable for water injection using this method.

Background technique

In the process of oilfield development, with the decline of oil layer energy, the production capacity of oil wells is also continuously reduced. In order to restore oil well production, a water injection development mode that increases oil layer energy by water injection is gradually formed. Water is injected into the reservoir through a special water injection well to maintain or restore the reservoir pressure, so that the reservoir has a strong driving force, so as to improve the production speed and recovery rate of the reservoir.

As shown in Figure 1, the injection wells and the production wells both penetrate multiple formations, and the permeability of each formation is different, and the viscosity of the oil in each formation is also different. In the process of water injection, under the condition of the same pressure difference between the water injection well and the production well, the seepage velocity of different formations may differ by several times, dozens of times or even higher, which will cause the production well in the high permeability formation to be very fast. In case of water breakthrough (ineffective water injection), the viscosity of water is lower than that of oil. After the water is penetrated, the seepage rate of the formation with high permeability is hundreds of times that of the formation with low permeability, and the corresponding production well fluid production is greatly increased, and the water cut is further improved. . Since the water in the high-permeability formation has been conducted, a short circuit is formed between the injection well and the production well, so the pressure difference cannot be accumulated between the injection well and the production well, resulting in the water in the low-permeability formation only very low to drive oil to production Flow in the direction of the well, the oil production is greatly reduced, and at the same time, the water in the high-permeability formation is circulating ineffectively, causing a lot of waste to the oil field and reducing the economic limit of the oil field. had to be abandoned. The horizontal water injection well also has the problem of serious uneven water injection in each section, because the permeability of each section is different, whether each section has cracks or not, and the reason why the water breakthrough of each section is different sooner or later.

In the actual production process, there needs to be a technology that can make the water injection well achieve the purpose of balanced water injection. At present, there are generally two types of methods for balanced water injection: chemical methods and mechanical methods.

The chemical method is also called the chemical profile control method. It is a method of injecting chemical agents (such as polymer polymer solution, gel, etc.) into the water injection well to increase the viscosity of the water and improve the water absorption profile of the water injection well. Small.

The mechanical method refers to dividing the corresponding position of the corresponding layer in the water injection well into a plurality of independent flow units with packers, and adding water nozzles to achieve the effect of layered and segmented balanced water injection. This method is widely used. For example, there are 20 formations in the water injection section of a water injection well in an oilfield, which can be divided into 5 units with 4 packers, with an average of 4 formations per unit. The mechanical isolation method is adopted to control the daily water inflow of the high-permeability unit through the nozzle on the water injection pipe string. The high-permeability unit has a large water injection flow, and the faucet has a large restriction on the flow rate, and the influent flow rate is greatly reduced. The formation in the permeable section achieves the purpose of relatively uniform water injection (see Figure 2). This method is widely used, with more than hundreds of thousands of wells all over the world using this technology.

However, the water injection technology of the current mechanical sealing method mainly has the following technical defects:

1. Due to the difficulty of the packer entering the well, only 4-5 packers can be installed. In the implementation process, there are 4 strata between every two packers on average, and the segments cannot be subdivided, and it is impossible to realize an independent water injection unit for each layer. The heterogeneity of these 4 strata is several times different. Each stratum can only achieve general water injection, and cannot be subdivided into sections, resulting in serious uneven water injection in the flow unit;

2. Because the packer entering the well needs to be inspected, the seal can only be inspected from the wellhead, such as the annular space, but only the first one can be inspected for leaks, and the second one cannot be inspected, so it is impossible to guarantee the seal after entering the well. Each packer can be effectively sealed, and it is possible that the next packer will not play an effective role in interlayer isolation. In addition, due to the timeliness of the packer, sealant peeling will occur over time. Leakage problem, failure of a packer will lead to general water injection in more layers;

3. In different flow units, the pressure in the water injection pipe string is the same. Due to the different resistance of the water nozzle, different pressure drops will be formed, resulting in inconsistent water pressure outside the water injection pipe string, which in turn leads to the difference between the flow units. There is also a pressure difference, and the long-term pressure difference will cause damage to the cement sheath, causing channeling problems (see Figure 7), and segmented water injection failure;

4. In cased wells whose casing perforation wells have been deformed and non-circular, because the packers cannot be sealed into the wells, and wells with severely deformed casings, the packers cannot be placed below the required position, and traditional mechanical packing cannot be used. method. And for open-hole wells, traditional mechanical isolation methods cannot be achieved due to irregular wellbore. If you want to use the mechanical isolation method, the open hole also needs to run casing, and then carry out tedious operations such as cementing, perforating, and completion, and the cost is high. If it is implemented at sea, one more day delay will cause millions of costs;

5. Due to the limited sealing effect of the packer, some oilfields need to use multiple sets of injection-production well patterns for development, which greatly increases the number of wells to be drilled and increases other costs such as well management and maintenance;

6. It is difficult to run the packer, and once the sealing is completed, it is extremely difficult to remove the packer, especially in some deep wells with relatively high salinity, which is not conducive to the adjustment of the completion method of the injection well in the later stage. If it needs to be overhauled and adjusted in the later stage, huge costs will be incurred;

7. After water injection for a period of time, the impurities in the injected water are easy to block the sand control net, and acidification is required to remove the blockage in the later stage. The cost is high, and the casing oil is damaged.

Accordingly, there is a need in the art to provide an improved method of water injection for oil wells that overcomes one or more of the above-mentioned deficiencies.

SUMMARY OF THE INVENTION

According to one aspect of the present invention, there is provided a method of operating a water injection well comprising a wellhead and a wellbore extending underground from the wellhead, the wellbore defining a wellbore, the method comprising controlling flow A screen tube is disposed in the wellbore. The flow control screen includes: a hollow base tube including a fluid-tight tube wall, the base tube wall defining a base tube lumen; a hollow filter tube including a fluid-permeable tube The filter tube is arranged around the outside of the base tube, so that a first annular space is formed between the filter tube and the well wall and a second annular space is formed between the filter tube and the base tube a space; and a flow control device having a flow cross-sectional area that allows fluid to flow therethrough. The method also includes filling the first annular space with a packer particle-carrying fluid via the wellhead, the packer particle-carrying fluid comprising packer particles and a liquid for carrying the packer particles, A portion of the liquid enters the second annular space via the tube wall of the filter tube, enters the base tube lumen via the flow control device, and returns via the wellhead, and another portion of the liquid passes through the The well wall penetrates into the formation and the filter tube blocks the packer particles so that the packer particles accumulate in the first annular space.

In one embodiment, disposing flow control screens in the wellbore includes disposing two or more flow control screens in the wellbore connected end to end such that each formation corresponds to one or more A flow control screen. Preferably, the flow cross-sectional areas of the flow control devices of the flow control screens corresponding to the same formation are the same.

In one embodiment, the method further comprises setting the flow control device of the flow control screen at the bottom of the water injection well to have a larger flow cross-sectional area than the flow control devices of other flow control screens. Preferably, the flow control device of the flow control screen at the bottom of the water injection well has a flow cross-sectional area of 1.1 to 5 times that of the flow control devices of other flow control screens.

In one embodiment, the method further comprises setting the flow cross-sectional areas of the flow control devices of at least two of the flow control screens to be different from each other.

In one embodiment, the water injection well further comprises a first valve for opening or closing fluid communication between the first annular space and the wellhead, and a second valve, the second valve a valve for opening or closing fluid communication between the base pipe lumen and the wellhead, the method further comprising: closing the first valve and opening the second valve; The inner cavity of the base pipe is filled with water, so that water enters the first annular space through the flow control device, the second annular space and the filter tube.

In one embodiment, the method further includes pressurizing the first annular space prior to closing the first valve and opening the second valve.

In one embodiment, the water injection well further comprises a first valve for opening or closing fluid communication between the first annular space and the wellhead, and a second valve, the second valve a valve for opening or closing fluid communication between the base pipe lumen and the wellhead, the method further comprising: opening the first valve and opening the second valve; The lumen of the base pipe is filled with water, so that water enters the first annular space through the flow control device, the second annular space and the filter tube, so as to seal off the accumulated in the first annular space The bulk particles are dispersed and the packer particles are allowed to flow back to the surface via the first valve.

In one embodiment, the method further comprises: opening the first valve and opening the second valve; and refilling the first annular space with a packer particle carrier fluid via the first valve.

In one embodiment, the method further includes positioning a hanging packer around the flow control screen at the top and hanging from the well wall.

In one embodiment, the method further comprises adjusting the flow cross-sectional area of the flow control device.

In one embodiment, the method further comprises replacing the flow control device with another flow control device having a different flow cross-sectional area.

In one embodiment, the water injection well further comprises a casing disposed in the wellbore and a cement sheath disposed between the casing and the well wall, and wherein the flow control screen is Disposing in the wellbore includes disposing the flow control screen in the casing, and filling the first annular space with a packer particle-carrying fluid via the wellhead includes injecting the flow control screen into the first annular space via the wellhead The annular space between the filter tube and the sleeve is filled with the separator particle-carrying fluid.

In one embodiment, the water injection well further comprises a casing disposed in the well cavity, a cement sheath disposed between the casing and the well wall, and a flow control disposed in the casing A tubular string and a mechanical packer disposed between the flow control string and the casing, the method further comprising removing the flow control screen from the well prior to disposing the flow control screen in the wellbore The cavity removes the mechanical packer and the flow control string, and disposing the flow control screen in the well cavity includes disposing the flow control screen in the casing.

In one embodiment, the tube wall of the filter tube has a pore size, the packing particles have a particle size, and the pore size is greater than or equal to 1/2 of the particle size and less than or equal to the particle size 2/3 of the size.

According to another aspect of the present invention, a water injection well is provided. The water injection well comprises: a wellhead; a wellbore extending from the wellhead underground, the wellbore defining a wellbore; and a flow control screen disposed in the wellbore. The flow control screen includes: a hollow base tube including a fluid-tight tube wall, the base tube wall defining a base tube lumen; a hollow filter tube including a fluid-permeable tube The filter tube is arranged around the outside of the base tube, so that a first annular space is formed between the filter tube and the well wall and a second annular space is formed between the filter tube and the base tube a space; and a flow control device having a flow cross-sectional area that allows fluid to flow therethrough. The water injection well also includes packer particles packed in the first annular space.

In one embodiment, the water injection well includes two or more flow control screens connected end to end, and the two or more flow control screens are arranged in the wellbore such that each formation corresponds to on one or more control screens. Preferably, the flow cross-sectional areas of the flow control devices of the flow control screens corresponding to the same formation are the same.

In one embodiment, the flow control device of the flow control screen at the bottom of the water injection well has a larger flow cross-sectional area than the flow control devices of other flow control screens. Preferably, the flow control device of the flow control screen at the bottom of the water injection well has a flow cross-sectional area of 1.1 to 5 times that of the flow control devices of other flow control screens.

In one embodiment, the flow cross-sectional areas of the flow control devices of at least two of the flow control screens are different from each other.

In one embodiment, the water injection well further comprises a casing disposed in the well cavity and a cement sheath disposed between the casing and the well wall, and the flow control screen is disposed in the wellbore in the casing, and the packer particles are packed in the annular space between the filter tube and the casing.

The present invention has the following advantages:

1. The strata of each section can be separated by continuous packing particles. For example, if there are 20 strata in the water injection section of a well, they can be separated into 20 independent units, which further refines the flow unit and realizes 20 strata. The formation is independently balanced with water injection.

2. A good axial isolation is achieved, and the problem of packer leakage will not occur. Because there are continuous packer particles outside the pipe string of the flow control filter, and the packer particles will automatically fill the lost places through migration, solving the problems of casing channeling and casing leakage;

3. Filling in open-hole wells, whether the open-hole well is big or small, the packer particles will fill them up (see Figure 5), and can fill various well conditions (including deformed cased wells) adaptively. , to solve the problem that the packer cannot be realized;

4. The process is simple and the operating cost is reduced;

5. It can effectively reduce the pressure difference of the high-permeability formation, reduce the injection volume of the high-permeability section, and increase the pressure difference of the low-permeability section of the injection well and the production well under the same liquid volume, which is beneficial to drive the low-permeability section The amount of oil in the formation increases the oil recovery factor;

6. The packing particles in the wellbore have the function of separation in the axial direction to prevent axial channeling; as a filter in the radial direction, it can effectively filter the impurity particles injected into the water, and on the premise of avoiding the clogging of the sand control net, the impurities can be effectively removed. At the same time, it can also have the function of unblocking, because when the particles of the packer are flowing back, they can blow away the impurities that are blocked and accumulated in the pore throats between the particles of the packer, After mixing with the packer particles in the carrier liquid medium, it flows back to the surface.

Description of drawings

Figure 1 shows a schematic diagram of a water injection well and a production well;

Figure 2 schematically shows a water injection well in the prior art with mechanical isolation;

Figure 3 schematically illustrates a water injection well according to an embodiment of the present invention;

Figure 4 schematically shows a tube wall of a filter tube and packing particles located outside the filter tube according to an embodiment of the present invention;

Figure 5 schematically illustrates a water injection well according to an embodiment of the present invention;

6-13 schematically illustrate some embodiments according to the invention.

Detailed ways

Figure 3 schematically illustrates a water injection well 100 according to one embodiment of the present invention. The water injection well 100 may include a wellhead 110 and a wellbore 120 . A wellbore 120 extends underground from the wellhead 110 and defines a wellbore 130 .

The injection well 100 may also include a flow control screen 140 disposed in the wellbore 130 . The flow control screen 140 may include a hollow base tube 150 , a hollow filter tube 160 and a flow control device 170 . The base tube 150 may include a fluid-tight tube wall 152 . The tube wall 152 of the base tube 150 defines a base tube lumen 154 . The filter tube 160 may include a fluid permeable tube wall 162 . The filter tube 160 may be disposed around the outside of the base tube 150 such that a first annular space S1 is formed between the filter tube 160 and the well wall 120 and a second annular space S2 is formed between the filter tube 160 and the base tube 150 . The flow control device 170 has a flow cross-sectional area that allows fluid to flow therethrough. The flow cross-sectional area of the flow control device 170 may be of various suitable shapes, such as circular, oval, rectangular, and the like. The flow cross-sectional area of the flow control device 170 may comprise a plurality of discrete sections. The flow cross-sectional area of the flow control device 170 may vary in the direction of flow.

The water injection well 100 may also include packer particles 180 . Packer particles 180 may be filled in the first annular space S1. Preferably, the packer particles 180 may completely fill the first annular space S1. During the water injection process, the water injected into the lumen 154 of the base pipe through the wellhead 110 can enter the second annular space S2 through the flow control device 170, and then pass through the pipe wall 162 of the filter pipe 160 into the first annular space S1, and then flow into the injection The formation between water and production wells.

Filter tube 160 may also be referred to as a screen tube. The tube wall 162 of the filter tube 160 may be in the form of a screen. The tube wall 162 of the filter tube 160 may allow the passage of formation fluids (eg, water, oil) while blocking the passage of the packer particles 180 . FIG. 4 schematically shows the tube wall 162 of the filter tube 160 and the packer particles 180 located outside the filter tube 160 (ie in the first annular space S1 ). Figure 4 also schematically shows smaller particle size impurities, eg from injected water. In one embodiment, the pore size of the tube wall 162 of the filter tube 160 is greater than or equal to 1/2 of the particle size of the packer particles 180 and less than or equal to 2/3 of the particle size of the packer particles 180 . Since the pore throat size between the packing particles 180 is about 1/5 of the particle size of the packing particles, the packing particles 180 can act as a filter in the radial direction, and most impurities in the injected water can pass through them. Pass through the tube wall 162 of the filter tube 160 (to avoid clogging of the filter tube 160 ), but are effectively intercepted at the pore throat between the packing particles 180 .

In one embodiment, the injection well 100 may include two or more flow control screens 140 connected end to end. In this embodiment, two or more flow control screens 140 are disposed in the wellbore 130 such that each formation corresponds to one or more flow control screens 140 . Preferably, the flow control devices 170 of the flow control screens 140 corresponding to the same formation may have the same flow cross-sectional area. During the water injection process, the water injected into the lumen 154 of the base pipe through the wellhead 110 can enter the second annular space S2 through the flow control device 170 of each flow control screen 140 respectively, and then pass through the pipe wall 162 of the filter pipe 160 and enter the second annular space S2. An annular space S1, and then flow into the corresponding formation.

The working principle of the packer particles 180 of the present invention is based on Darcy's formula of seepage mechanics:

Among them, K-rock permeability, Q-flow rate, μ-fluid viscosity, L-core length, A-core cross-sectional area, ΔP-pressure difference at both ends of core. According to Darcy's formula, the seepage resistance is proportional to the seepage distance and inversely proportional to the seepage area.

In the present invention, the stack formed by the spacer particles 180 in the first annular space S1 has a thin thickness, a small cross-section and a large axial length. When the formation fluid flows in the radial direction in the packing body particles 180, the seepage path is relatively short and the seepage area is relatively large, so the resistance is relatively small. However, when the formation fluid flows in the axial direction in the packing particles 180, the seepage path is relatively long and the seepage area is relatively small, so the resistance is relatively large. By appropriately selecting the particle size of the packing particles 180 and setting the radial thickness of the first annular space S1, the flow resistance of the formation fluid in the axial flow of several meters to several tens of meters can be made higher than that in the radial flow of several centimeters. The flow resistance is even larger, for example, thousands of times or even tens of thousands of times. Due to the existence of the packing particles 180, there is a huge difference between the axial and radial flow resistance, so under the action of the same pressure difference, the flow rate of the axial flow is much smaller than the flow rate of the radial flow, so that the seal The spacer particles 180 have passability in the radial direction and barrier properties in the axial direction. On the one hand, due to the passability of the packer particles 180 in the radial direction, the injected water can easily pass through the packer particles 180 in the first annular space S1 in the radial direction and flow into various formations, ensuring the packer Particles 180 do not interfere with the normal functioning of the injection well. On the other hand, due to the blocking properties of the packer particles 180 in the axial direction, the axial channeling of the water flowing out from the flow control devices 170 of the respective flow control screens 140 is reduced or prevented (axial channeling refers to the The water from one flow control screen, after entering the first annular space S1, flows axially to the formation where the other flow control screen is located). In the present invention, the radial direction and the axial direction are relative to the well bore 130 . Specifically, radial refers to a direction perpendicular to the wellbore 130 , and axial refers to a direction along the wellbore 130 .

In one embodiment, the flow control device 170 of the flow control screen 140 at the bottom of the water injection well 100 may have a larger flow cross-sectional area than the flow control devices 170 of other flow control screens 140 . Preferably, the flow control device 170 of the flow control screen 140 at the bottom of the water injection well 100 may have a flow cross-sectional area of 1.1 to 5 times that of other flow control screens 140 .

In one embodiment, the flow cross-sectional areas of the flow control devices 170 of at least two of the flow control screens 140 are different from each other. Preferably, the flow control device of each flow control screen 140 can be designed based on the physical parameters of the formation (for example, including permeability, porosity, oil saturation, phase permeability curve, etc.) The flow cross-sectional area of 170 makes the flow restriction capability of the flow control device 170 of each flow control screen 140 match the formation. In one embodiment, the flow cross-sectional area of at least one flow control device 170 is adjustable, so that the flow cross-sectional area of the flow control device 170 can be adjusted according to changes in formation physical parameters during production, so as to better control the flow The current limiting capability of the device 170 is matched to the formation.

In one embodiment, as shown in FIG. 3, the water injection well 100 may be an open hole well. That is, the packer particles 180 are directly packed in the first annular space S1 formed between the filter tube 160 of the flow control screen 140 and the well wall 120. Where the injection well 100 is an open hole, the well wall 120 may have an irregular shape, ie, may have different diameters at different depths. Correspondingly, the first annular space S1 also has an irregular shape, ie different radial thicknesses at different depths. Packer particles 180 of the present invention are particularly advantageous when filling open hole wells. As shown in FIG. 3 , regardless of the shape of the well wall 120 , the packer particles 180 can adaptively fill the first annular space S1 of various shapes due to their fluidity, so that they can adapt to the problems that the mechanical packer cannot handle. Well condition.

In one embodiment, as shown in FIG. 5, the injection well 100 may be a cased well. That is, the water injection well 100 may further include a casing 190 disposed in the wellbore 130 and a cement sheath 195 disposed between the casing 190 and the well wall 120 . In the case where the injection well 100 is a cased well, the flow control screen 140 may be disposed in the casing 190 , and the packing particles 180 may be packed in the annular space between the filter tube 160 of the flow control screen 140 and the casing 190 in space.

The method 200 for operating a water injection well in accordance with the present invention is described in detail below. The injection well includes a wellhead 110 and a wellbore 120 extending underground from the wellhead 110 . The well wall 120 defines a well cavity 130 . The method 200 may include positioning the flow control screen 140 in the wellbore 130 . The method 200 may also include filling the first annular space S1 with a packer particle-carrying fluid via the wellhead 110, the packer-particle-carrying fluid including the packer particles 180 and a liquid for carrying the packer particles 180, a portion of the liquid passing through The tube wall of the filter tube 160 enters the second annular space S2, enters the base tube lumen 154 through the flow control device 170, and returns through the wellhead 110, another part of the liquid penetrates into the formation through the well wall 120, and the filter tube 160 blocks the packing body particles 180 so that the packer particles 180 are accumulated in the first annular space S1.

In one embodiment, two or more flow control screens 140 may be disposed in the wellbore 130 connected end to end such that each formation corresponds to one or more flow control screens 140 . Preferably, the flow control devices 170 of the flow control screens 140 corresponding to the same formation may have the same flow cross-sectional area.

In one embodiment, the method 200 may further include the step of setting the flow cross-sectional areas of the flow control devices 170 of at least two of the flow control screens 140 to be different from each other.

As shown in FIG. 3, the water injection well may further include a first valve V1 and a second valve V2. The first valve V1 is used to open or close the fluid communication between the first annular space S1 and the wellhead 110 . The second valve V2 is used to open or close fluid communication between the base pipe lumen 154 and the wellhead 110 . In one embodiment, the method 200 may further include the steps of: closing the first valve V1 and opening the second valve V2; and injecting water into the base pipe lumen 154 via the second valve V2 so that the water passes through the flow control device 170, the second annular Space S2 and filter tube 160 enter the first annular space S1. This water injection process may serve to compact the packer particles in the first annular space S1.

In one embodiment, the method 200 may further include the step of pressurizing the first annular space S1 before closing the first valve V1 and opening the second valve V2. The compaction effect of the packer particles 180 can be further enhanced by appropriately pressurizing the first annular space S1 prior to water injection.

As previously described, most of the impurities in the water injected from the wellhead can pass through the tube wall 162 of the filter tube 160 , but are effectively intercepted at the pore throats between the packer particles 180 . After a period of water injection using the water injection well of the present invention, the pore throats between the packing particles may become blocked. When clogging is found, the packer particles need to be replaced. Replacement of packer particles can be accomplished by first removing the old packer particles and then refilling with new packer particles. When removing the packer particles, the following operations are performed: the first valve V1 is opened and the second valve V2 is opened; and water is injected into the base pipe lumen 154 via the second valve V2 so that the water passes through the flow control device 170, the second annular space S2 and the filter tube 160 enter the first annular space S1, so as to flush out the packing body particles 180 accumulated in the first annular space S1, so that the impurity which is intercepted and filtered out of the throat of the packing body particles 180 will follow the packing body The particles 180 are dispersed and mixed, and the packer particles 180 and impurities 182 are flowed back to the surface via the first valve V1. Next, the first annular space S1 may be refilled with new packer particle carrier fluid. When refilling the spacer particle-carrying liquid, the following operations are performed: opening the first valve V1 and opening the second valve V2; and refilling the first annular space S1 with the spacer particle-carrying liquid via the first valve V1.

In one embodiment, the flow control device 170 of the flow control screen 140 at the bottom of the injection well can be set to have a larger flow cross-sectional area than the flow control devices 170 of other flow control screens 140 . By making the flow control device at the bottom of the water injection well have a larger flow cross-sectional area, when removing the packer particles, a larger flow of water can be ensured from the flow control device at the bottom of the water injection well, so that the packer particles can be removed. Flowback is more thorough. This is advantageous for eliminating clogging.

In one embodiment, the method 200 may further include the step of positioning the hanging packer TP around the flow control screen 140 at the top and hanging from the well wall 120 . Figure 3 schematically shows a suspended packer TP. Suspending the packer TP can further prevent packer particles from escaping from the first annular space S1 and entering the flow control screen 140, thereby causing blockage.

In one embodiment, the method 200 may further include the step of: adjusting the flow cross-sectional area of the flow control device. In this way, the flow restriction capability of the flow control device can be better matched with the formation in the production process.

In one embodiment, the method 200 may further include the step of: replacing the original flow control device with another flow control device having a different flow cross-sectional area. In this way, the flow restriction capability of the flow control device can be better matched with the formation in the production process.

The method 200 of the present invention may also be used in the cased hole described above. Where injection well 100 is a cased well, flow control screen 140 may be positioned in casing 190 and the annular space between filter tube 160 and casing 190 is filled with packer particle-carrying fluid via wellhead 110 .

The method 200 of the present invention may also be used to retrofit existing cased wells employing mechanical packers and conventional flow control strings. Such cased wells include, in addition to the wellhead 110 and the wellbore 120 extending underground from the wellhead 110 , a casing 190 disposed in the wellbore 130 defined by the wellbore 120 and disposed between the casing 190 and the wellbore 120 The cement sheath 195 , the conventional flow control string disposed in the casing 190 , and the mechanical packer disposed between the conventional flow control string and the casing 190 . In remaking the cased well, the mechanical packer and conventional flow control string are first removed from the wellbore 130 , then the flow control screen 140 of the present invention is placed in the casing 190 , and then sent via the wellhead 110 to the control The annular space between the filter tube 160 of the flow screen tube 140 and the sleeve 190 is filled with the packer particle carrier fluid.

Example 1 (vertical well, open hole new well)

An offshore directional open-hole water injection well has 20 water injection layers and the size of the open-hole wellhead is 8.5 inches. The method and the water injection well of the present invention are adopted. A 5.5-inch flow control screen 140 is run in the open-hole well, and the first annular space between the flow control screen 140 and the well wall is filled with 40-70 mesh packer particles. The concentration of the packer particle carrying fluid is 5%, the filling pressure is 6MPa. After the packer particles carry the packer particles into the first annular space, the packer particles are continuously accumulated and filled in the first annular space until the packer particles fill the entire first annular space (see Figure 3) . Part of the liquid in the packer particle-carrying fluid enters the second annular space through the tube wall of the filter tube of the flow control screen 140, enters the lumen of the base pipe via the flow-control device, and returns from the wellhead, where the packer particle-carrying fluid is contained Another portion of the liquid penetrates into the formation via the wellbore. After being put into production, the pressure difference of the corresponding oil well reaches 5MPa, the daily oil production is 42 cubic meters per day, the daily liquid production is 120 cubic meters per day, the water content is 65%, and no water has been seen for 2 years. In contrast, the water injection well in the same block using the traditional mechanical isolation method, the corresponding oil well production pressure difference is only 3MPa, the daily oil production is 5 cubic meters per day, the daily liquid production is 100 cubic meters per day, and the water cut is 95%.

Example 2 (vertical well, conventional cased well)

An oilfield has a traditional cased well with more than 30 production layers. It is a reservoir condition covered by sand-mudstone interbeds (a layer of sandstone, a layer of mudstone, oil stored in the sandstone layer, and the mudstone layer is not permeable). Balanced water injection development is required to achieve the ideal development effect. The cased well adopts the traditional mechanical packing method, the completion structure is casing perforation, and four mechanical packers are used to divide the formation into five sections (see Figure 6). In the initial stage of production, the production pressure difference of the corresponding oil well is 1MPa, the production well produces 80 cubic meters of water per day, 5 cubic meters of oil per day per day, and the water cut rate is 94%. Due to the low daily oil production, the well had to be shut down to stop production.

The casing well is reconstructed by the method of the present invention. First remove the original mechanical packer and flow control string. Then a 3.5-inch flow control screen 140 is placed in the 7-inch casing, and the annular space between the flow control screen 140 and the casing is filled with 40-70 mesh packer particles, and the packer particles carry the liquid concentration is 5%, and the filling pressure is 6MPa. After the completion of the well, the production pressure difference of the corresponding oil well reaches 10MPa, the daily water production of the production well is 50 cubic meters per day, while the daily oil production is 45 cubic meters per day, and the water cut rate is 53%.

Comparison table of before and after production data

Implementation Column 3 (vertical well, traditional cased well, interlayer channeling, packer leakage problems)

An oilfield has a conventional cased well with a 7-inch casing perforated well that uses conventional mechanical methods to separate water injection. At the initial stage of production, the pressure difference of the corresponding oil wells reached 3MPa, the production wells produced 100 cubic meters of water per day, 20 cubic meters of oil per day, and the water cut was 83%. After a period of production, problems such as interlayer channeling and packer leakage occurred (see Figure 7). Due to the existence of perforation and channeling, if water is produced at the perforation channel a, the water in the formation enters the channeling channel b through the perforation channel a, and flows axially in the direction of the arrow in the channeling channel, and flows to the perforation channel At c, it enters the casing through the perforation channel c, and water enters the corresponding flow control filter d in the casing, which destroys the sealing effect of the cement ring. At the same time, due to the timeliness of the use of the packer, the sealant will leak over time, as shown in Figure 7 where the packer leaks e, which will also cause the packing failure, and the water will flow from the low-permeability formation to the high-permeability formation. , general water injection occurs. As a result, the pressure difference between the injection well and the production well is reduced to 0.5MPa, the production well produces 120 cubic meters of water per day, 2 cubic meters of oil per day, and the water cut is as high as 98%.

The casing well is reconstructed by the method of the present invention. First remove the original mechanical packer and flow control string. Then, a 3.5-inch flow control screen 140 is put into the 7-inch casing, and the annular space between the flow control screen 140 and the casing is filled with 30-50 mesh packer particles, and the packer particles carry liquid The concentration was 5%, and the filling pressure was 6MPa. The fluidity of the packer particles enables the packer particles to block the channeling and leakage points in the well wall in time, and has the function of self-repairing the well wall. Figure 8 shows a cased hole after reconstruction. After the reconstruction, the pressure difference of the corresponding oil wells reached 10MPa, the production wells produced 60 cubic meters of water per day, 42 cubic meters of oil per day per day, and the water content was reduced to 59%. See the table below for a comparison of the effects before and after the transformation.

Comparison table of before and after production data

Example 4 (horizontal well, conventional cased well)

A horizontal water injection well in an offshore oil field spans 600 meters before and after, and uses traditional mechanical isolation for balanced water injection (see Figure 9). Due to water channeling in the high permeability layer and casing leakage due to casing damage, the water cut is 95%, the corresponding oil well production pressure difference is 0.2MPa, the daily water production is 100 cubic meters per day, and the daily oil production is 5 cubic meters per day.

The casing well is reconstructed by the method of the present invention. First remove the original mechanical packer and flow control string. Then, a 3.5-inch flow control screen 140 is placed in the 7-inch casing, and the annular space between the flow control screen 140 and the casing is filled with 20-40 mesh packer particles, and the packer particles carry liquid The concentration was 5%, and the filling pressure was 6MPa. The fluidity of the packer particles enables the packer particles to adaptively manage the problem of casing leakage, without considering the position, quantity, and new casing leakage points in the future. Figure 10 shows a cased hole after reconstruction. After the reconstruction, the production pressure difference of the corresponding oil well reached 5MPa, the daily water production was 203 cubic meters per day, the daily oil production was 60 cubic meters per day, and the water cut was reduced to 77%. The comparison of production data before and after transformation is shown in the table below.

Comparison table of before and after production data

Implementation column 5 (the cased well using the water injection method of the present invention, the flow control device is replaced after a period of production)

There is a new well in an offshore oil field. The viscosity of the oil layer in this well is 142 cps, the viscosity of the formation water is 0.6 cps, the oil-water viscosity ratio is 237:1, and the diameter of the wellbore is 6 inches. The completion structure obtained using the technique of the present invention is shown in FIG. 11 . A 3.5-inch flow control screen 140 is run in the casing, and the annular space between the flow control screen 140 and the casing is filled with 20-40 mesh packer particles, and the packer particle carrying liquid concentration is 5% , the filling pressure is 6MPa. After the well was opened, the daily liquid production was 176 cubic meters per day, the daily oil production was 172 cubic meters per day, the water content was 2.3%, and the corresponding oil well production pressure difference was 3 MPa. After 30 months of stable production, the water cut gradually increased to 90%, the corresponding oil well production pressure drop was reduced to 1MPa, the daily liquid production was 200 cubic meters per day, and the daily oil production was 20 cubic meters per day. After comprehensive analysis, it is necessary to take measures to stabilize production by extracting liquid and replace the flow control screen 140 with flow control devices of different specifications. The cased well using the water injection method of the present invention is easy to take out the flow control screen 140 from the well, the process is simple, and the operation is convenient (as shown in FIG. 12 ).

Specifically, do the following:

Unseal the lift-up suspension packer (if any);

Water is injected into the inner cavity of the base pipe of the flow control screen to flow back the packing particles from the annulus;

Take out the flow control screen;

Replace the flow control device of the flow control screen;

The flow control screen is rerun and the packer particles are refilled.

After replacing the flow control device and refilling the packing particles, the pressure difference of the corresponding oil well reached 5MPa, the daily liquid production was 500 cubic meters per day, the daily oil production was 62 cubic meters per day, and the water cut was reduced to 87%. The comparison of production data before and after replacing the flow control device is shown in the following table.

Comparison table of before and after production data

Example 6 (cased well using the water injection method of the present invention, without a hanging packer at the top)

There is a water injection well in an oil field, the water injection layer involves 20, and the 7-inch casing is perforated and completed, and the water injection method of the present invention is used. A 3.5 inch flow control screen 140 is run in the casing, and the flow control screen 140 is suspended directly at the wellhead (no need to hang the packer). Open the first valve V1 and the second valve V2, and fill the annular space between the flow control screen and the casing through the first valve V1 with 40-70 mesh packing particles, and the concentration of the packing liquid carried by the packing particles is 5% , the filling pressure is 6MPa. After the packer particles are carried by the packer particles into the first annular space, the packer particles are continuously accumulated and filled in the first annular space until the packer particles fill the entire first annular space (see Figure 13) . A part of the liquid in the particle-carrying liquid of the packer enters the second annular space through the tube wall of the filter tube of the flow control screen 140, enters the lumen of the base pipe through the flow control device, and returns from the wellhead through the second valve V2, sealing the Another portion of the liquid in the bulk particle-carrying fluid penetrates into the formation via the wellbore.

During the water injection, the first annular space is properly pressurized, and the first valve V1 is closed. Water is injected from the second valve V2, so that the packing particles can be better compacted, so as to obtain a better separation effect. In the initial stage of water injection, the injection pressure was 10MPa and the water injection volume was 136 cubic meters per day; but after 3 years of water injection, when the water injection pressure increased to 20MPa, the water injection volume was 80 cubic meters per day. After analysis, there may be a blockage phenomenon, and it is necessary to remove the blockage of the water injection well.

Specifically, do the following:

Open the first valve V1 and the second valve V2;

Water is injected into the inner cavity of the base pipe of the flow control screen to flow back the packing particles, so that the impurity intercepted and accumulated at the pore throats between the packing particles is flowed back together with the packing particles through the first valve V1 to the ground. The flow control device of the flow control screen at the bottom of the injection well can be set to have a larger flow cross-sectional area than the flow control devices of the other flow control screens. By making the flow control device at the bottom of the water injection well have a larger flow cross-sectional area, it can ensure that a larger flow of water flows out of the flow control device at the bottom of the water injection well when the packer particles are backflowed, so that the packer particles can be discharged. Flowback is more thorough;

Replace with new 40-70 mesh packer particles and refill.

After the above measures, the water injection pressure was restored to 12MPa, and the water injection volume was 150 cubic meters per day. The comparison of production data before and after plug removal is shown in the table below.

Comparison table of before and after production data

While the invention has been described with reference to the exemplary embodiment(s), it will be understood by those skilled in the art that the invention is not limited to the exact structures and components described herein, but also without departing from Various modifications, changes and alterations will be apparent from the foregoing description within the spirit and scope of the invention as defined by the claims. The present invention is not limited by the illustrated ordering of the steps, as some steps may be performed in a different order and/or concurrently with other steps. Therefore, the inventions are not to be limited to the specific embodiment(s) disclosed, but are to include all embodiments falling within the scope of the appended claims.

Claims

A method of operating a water injection well (100) comprising a wellhead (110) and a wellbore (120) extending underground from the wellhead (110), the wellbore (120) defining a well cavity (130), the method comprising:

A flow control screen (140) is arranged in the well cavity (130), and the flow control screen (140) includes:

a hollow base tube (150), the base tube (150) including a fluid-tight tube wall (152), the tube wall (152) of the base tube (150) defining a base tube lumen (154);

A hollow filter tube (160) comprising a fluid-permeable wall (162), the filter tube (160) being disposed around the outside of the base tube (150) such that the filter tube (160) A first annular space (S1) is formed between (160) and the well wall (120) and a second annular space (S2) is formed between the filter pipe (160) and the base pipe (150); and

a flow control device (170) having a flow cross-sectional area allowing fluid to flow therethrough; and

The first annular space (S1) is filled with a packer particle-carrying liquid via the wellhead (110), the packer-particle-carrying fluid includes packer particles (180) and is used to carry the packer The liquid of particles (180), a part of which enters the second annular space (S2) via the tube wall (162) of the filter tube (160), and enters the base via the flow control device (170) The tube lumen (154) and back via the wellhead (110), another portion of the liquid permeates into the formation via the wellbore (120), the filter tube (160) blocks the packer particles ( 180), so that the packer particles (180) are accumulated in the first annular space (S1).
The method of claim 1, wherein disposing a flow control screen (140) in the wellbore (130) comprises disposing two or more flow control screens (140) connected end to end in the wellbore (130) In the well cavity (130), each formation corresponds to one or more flow control screens (140); preferably, the flow control device (170) of the flow control screens (140) corresponding to the same formation The flow cross-sectional area is the same.
The method of claim 2, wherein the method further comprises:

The flow cross-sectional area of the flow control device (170) of the flow control screen (140) located at the bottom of the water injection well is set to be larger than the flow cross-sectional area of the flow control devices (170) of other flow control screens (140) Preferably, the flow cross-sectional area of the flow control device (170) of the flow control screen (140) located at the bottom of the water injection well is the flow cross-section of the flow control device (170) of the other flow control screens (140). 1.1 to 5 times the area.
The method of claim 2, wherein the method further comprises:

The flow cross-sectional areas of the flow control devices (170) of at least two of the flow control screens (140) are set to be different from each other.
The method according to claim 1, wherein the water injection well (100) further comprises a first valve (V1) and a second valve (V2), the first valve (V1) for opening or closing the first valve (V1) An annular space (S1) is in fluid communication with the wellhead (110), and the second valve (V2) is used to open or close the flow between the base pipe lumen (154) and the wellhead (110). fluid communication,

The method also includes:

closing the first valve (V1) and opening the second valve (V2); and

Water is injected into the base pipe lumen (154) via the second valve (V2) so that water enters via the flow control device (170), the second annular space (S2) and the filter pipe (160) the first annular space (S1).
The method according to claim 5, wherein the method further comprises: before closing the first valve (V1 ) and opening the second valve (V2), performing an operation on the first annular space (S1 ) pressurized.
The method according to claim 1, wherein the water injection well (100) further comprises a first valve (V1) and a second valve (V2), the first valve (V1) for opening or closing the first valve (V1) An annular space (S1) is in fluid communication with the wellhead (110), and the second valve (V2) is used to open or close the flow between the base pipe lumen (154) and the wellhead (110). fluid communication,

The method also includes:

Open the first valve (V1) and open the second valve (V2); and

Water is injected into the base pipe lumen (154) via the second valve (V2) so that water enters via the flow control device (170), the second annular space (S2) and the filter pipe (160) the first annular space (S1) so as to disperse the packer particles (180) accumulated in the first annular space (S1) and to pass the packer particles (180) through the The first valve (V1) is discharged to the ground.
The method of claim 7, wherein the method further comprises:

Open the first valve (V1) and open the second valve (V2); and

The first annular space (S1) is refilled with packer particle-carrying liquid via the first valve (V1).
The method of claim 1, wherein the method further comprises:

A suspended packer (TP) is placed around the flow control screen (140) at the top and suspended from the well wall (120).
The method of claim 1, wherein the method further comprises:

The flow cross-sectional area of the flow control device (170) is adjusted.
The method of claim 1, wherein the method further comprises:

The flow control device (170) is replaced with another flow control device (170) with a different flow cross-sectional area.
The method of claim 1, wherein the water injection well (100) further comprises a casing (190) disposed in the well bore (130) and a casing (190) disposed in the well and the well a cement sheath (195) between walls (120), and wherein disposing the flow control screen (140) in the wellbore (130) includes disposing the flow control screen (140) in the wellbore (130) in the casing (190), and filling the first annular space (S1) with a packer particle-carrying fluid via the wellhead (110) includes feeding the filter tube (160) and the filter tube (160) and The annular space between the sleeves (190) is filled with the packing body particle-carrying fluid.
The method of claim 1, wherein:

The water injection well (100) further comprises a casing (190) arranged in the well cavity (130), a cement sheath (195) arranged between the casing (190) and the well wall (120) ), a flow control string disposed in the casing (190), and a mechanical packer disposed between the flow control string and the casing (190),

The method also includes removing the mechanical packer and the flow control tube from the wellbore (130) prior to disposing the flow control screen (140) in the wellbore (130) column, and

Disposing the flow control screen (140) in the wellbore (130) includes disposing the flow control screen (140) in the casing (190).
The method of claim 1, wherein the tube wall (162) of the filter tube (160) has a pore size, the packer particles (180) have a particle size, and the pore size is greater than or equal to the 1/2 of the particle size and less than or equal to 2/3 of the particle size.
A water injection well (100), comprising:

wellhead (110);

a well wall (120) extending underground from the wellhead (110), the well wall (120) defining a well cavity (130);

A flow control screen (140), the flow control screen (140) is arranged in the well cavity (130), and the flow control screen (140) includes:

a hollow base tube (150), the base tube (150) including a fluid-tight tube wall (152), the tube wall (152) of the base tube (150) defining a base tube lumen (154);

A hollow filter tube (160) comprising a fluid-permeable wall (162), the filter tube (160) being disposed around the outside of the base tube (150) such that the filter tube (160) A first annular space (S1) is formed between (160) and the well wall (120) and a second annular space (S2) is formed between the filter pipe (160) and the base pipe (150); and

a flow control device (170) having a flow cross-sectional area allowing fluid to flow therethrough; and

Packer particles (180) filled in the first annular space (S1).
The water injection well (100) of claim 15, wherein the water injection well (100) comprises two or more flow control screens (140) connected end to end, the two or more flow control screens (140) The screens (140) are arranged in the wellbore (130), so that each formation corresponds to one or more flow control screens (140); preferably, the flow control screens (140) corresponding to the same formation The flow cross-sectional areas of the flow control devices (170) are the same.
The water injection well (100) according to claim 16, wherein the flow control device (170) of the flow control screen (140) located at the bottom of the water injection well (100) has a larger flow cross-sectional area than other flow control screens The flow cross-sectional area of the flow control device (170) of the pipe (140); preferably, the flow control device (170) of the flow control screen (140) located at the bottom of the water injection well is other flow control 1.1 times to 5 times the flow cross-sectional area of the flow control device (170) of the screen (140).
The water injection well 100 of claim 16, wherein the flow control devices (170) of at least two of the flow control screens (140) have different flow cross-sectional areas from each other.
The water injection well (100) of claim 15, wherein:

The water injection well (100) further comprises a casing (190) arranged in the well cavity (130) and a cement sheath (195) arranged between the casing (190) and the well wall (120) ),

the flow control screen (140) is disposed in the casing (190), and

The packer particles (180) are packed in the annular space between the filter tube (160) and the sleeve (190).
The water injection well (100) of claim 15, wherein the tube wall (162) of the filter tube (160) has a pore size and the packer particles (180) have a particle size, the pore size More than or equal to 1/2 of the particle size size and less than or equal to 2/3 of the particle size size.