RU2203394C1 - Method of well cleanup during its operation - Google Patents

Abstract

FIELD: oil and gas production, mining industry. SUBSTANCE: in process of well cleanup clogging is ripped by rotation of pipes with fluke and ripper without opening of fluke. Clogging is sucked right after ripping through ripper and holes located at level of perforation holes in well casing. Fluke is removed from well. It is possible to fill up part of fluke and pipes above it with well fluid before start of ripping by short-time resting of ripper in clogs of sump and opening of fluke. Step-by-step well cleanup is also possible by ripping and suction of portion of clogging with repetition of cycles of ripping and suction till well is cleaned or fluke is filled. EFFECT: enhanced efficiency of well cleanup. 2 cl, 1 dwg

Description

 The invention relates to the oil, gas and mining industries and may find application in cleaning a well during its operation.

 A known method of cleaning a well, which includes creating a depressive effect on the bottom of the well and removing contaminants along the pipe string (A.A. Popov. Impact effects on the bottomhole zone of the wells. M., Nedra, 1990, p. 108, 109).

 The known method does not provide a mechanical effect on the pollution and in the presence of dense, caked pollution in the well is ineffective.

 Closest to the invention in technical essence is a method of cleaning a well during its operation, including mechanical impact on contaminants in the well sump, suction of contaminants into the borehole and extraction from the well (RF patent 2173760, publ. 2001 - prototype).

 In a known manner, it is possible to clean the sump of the well due to the suction of sand and sludge inside the baffle and extraction to the surface. In this case, the mechanical effect on contamination is only at the moment of touching the bottom of the well. However, in the presence of dense, compacted contaminants in the well sump, such an impact is not enough to loosen and remove them. The cleaning efficiency is low. In addition, the method has a very low impact on contamination in the perforation holes of the well, which reduces the possibility of its application.

 The invention solves the problem of increasing the efficiency of well cleaning.

 The problem is solved in that in a method for cleaning a well during its operation, which includes mechanical action on contaminants in a well sump, suction of contaminants into the choke and extraction from the well, according to the invention, the mechanical effect on contamination is carried out by loosening the contaminants by rotating pipes with the chipper and cultivator with the chuck closed, and the contamination is sucked in immediately after loosening the contaminants at the level of the perforation holes of the well casing and / or at the level of the sump.

 A stepwise cleaning of the well is carried out by loosening and sucking in part of the contaminants with repeating loosening and suction cycles.

 Before loosening, a short-term emphasis of the cultivator in the contamination of the sump and the opening of the flap fill part of the flap and pipes above it with well fluid.

The features of the invention are
1) mechanical impact on pollution in the sump of the well;
2) suction of contaminants into the bunker;
3) extraction from the well;
4) mechanical effect on pollution by loosening of pollution by rotation of the pipes with the choke and ripper when the choke is closed;
5) suction of contaminants immediately after loosening of contaminants at the level of perforation holes in the casing of the well and / or at the level of the sump;
6) stepwise cleaning of the well by loosening and sucking in part of the contaminants with repeating loosening and suction cycles;
7) before loosening, a short-term emphasis of the cultivator in the contamination of the sump and the opening of the bailer fill part of the bailer and pipes above it with well fluid.

 Signs 1-3 are common with the prototype, signs 4, 5 are essential distinguishing features of the invention, signs 6, 7 are particular features of the invention.

SUMMARY OF THE INVENTION
When cleaning the sump of a well from contaminants accumulated there, the most effective is the depressive effect. Before the depressive effect, a mechanical effect on the contaminants in the sump of the well is carried out by the impact of the chasing system on the contaminants. After that, open the bailer and suck it inside the biliary system of contamination. With this effect, it is possible not only to suck the contamination inside the choke, but also, due to a sharp decrease in pressure, to cause inflow from the formation through the perforations of the well casing. A double effect of cleaning the well and bottom-hole zone is achieved. However, the effectiveness of such a cleaning method is not high when compacted contaminants are located in the sump, the removal of which is impossible without loosening. In addition, since the depressive effect at the opening of the borehole is always followed by the repressive effect, which is manifested in the fluid flow into the perforations of the well casing, some of the impurities raised from the sump can settle in the perforations of the well casing and reduce the productivity of the well.

 The invention solves the problem of increasing the efficiency of well cleaning.

 The problem is solved as follows.

 An assembly of the choke is lowered into the well on the tubing string, the lower part of which is a string of pipes with a ripper from below, perforations in the pipe string at the bottom and a check valve to hold contaminants above the perforations in the pipe string. The distance from the bottom of the loosening organ to the perforations of the pipe string is set equal to the distance from the bottom of the cleaned sump to the perforations in the well casing. When cleaning a well, first the loosening of the contaminants is carried out by rotating the pipes with the choke and cultivator without opening the chute. In this way, the contaminants are transferred to a mobile, turbid state. The rotation is carried out with free suspension of the chute with the lower pipes without touching the choke rod of the shutter valve element of the choke with a stepwise lowering of the entire assembly into the well. Immediately after loosening the impurities in the sump, the rotation is stopped and the pipe string is lowered until the throttle rod touches the valve shut-off element and the throttle opens. Contamination is sucked through the cultivator and perforation holes of the pipe string located at the level of the perforation holes of the well casing. There is a suction of both sump contamination and contamination and clogging elements of the well bottom zone. The location of the perforation openings of the pipe string at the level of the perforation openings of the casing string of the well contributes to a more intensive cleaning of the bottomhole zone and ensures that sump contamination does not settle in the perforation openings of the casing string of the well.

 Not every well requires a maximum value of the depressive effect when opening the choke. For example, in case of intense sand development, a small effect is desirable, preserving the collector material from destruction. To mitigate the depressive effect of the bailer, it is possible to fill part of the bailer and pipes above it with well fluid before loosening with a short-term emphasis of the loosening organ in the contamination of the sump and opening of the bailer. This makes it possible to suck in a part of the contaminants into the chasing system, which do not need to be switched into an agitated state, and to reduce the amount of depression during the subsequent actuation of the chasing.

 For wells with a large number of contaminants, a stepwise effect is carried out. They abut the biliary system in contamination and briefly open the bailer. Suck in some of the pollution. Spreading of the contaminants is carried out by rotation of the pipes with the choke and cultivator without opening the chute. Once again the abutment system rests on the impurities and briefly open the abdomen. Partially fill the choke with suction of contaminants. The loosening and filling cycles of the choke are repeated until the well is cleaned or the choke is filled with contaminated borehole fluid.

 With a stepwise action, the perforation openings of the pipe string in the lower part are performed in the range of heights of immersion of the bilge system in contamination. In this case, the lower and upper perforations of the pipe string are placed respectively at the level of the perforation holes of the well casing at the beginning and end of the impact.

 After the suction of contaminants and the end of the work, the bunker is removed from the well.

 The drawing shows a bailer.

 The flap includes an upper pipe string 1, a housing 2, having an inner cylindrical cavity 3 with a valve seat 4, a ball 5, a spring 6 and a rod 7 having an inner hole along axis 8 with a plug 9 and slots at the end 10, and connected to case 2 the lower pipe string 11 with a hollow cultivator 12 and a poppet check valve 13 having a seat saddle 14 and a sealing belt 15 and a load 16, mounted on the axis 17. The rod 7 relative to the spring ball 5 is installed with a gap 18.

 The upper pipe string 1 is rigidly connected to the rod 7 via an adapter 19. The rod 7 is connected to the housing 2 through the dowels 20 and splines 21. Seals 22 are placed between the rod 7 and the housing 2. The inner cylindrical cavity 3 is connected to the borehole by openings 23 closed by a ring 24 The lower pipe string 11 is perforated with holes 25 from the bottom at a height equal to the distance from the bottom of the well to the perforations 26 of the casing of the well 27. The cultivator 12 can be muffled from the bottom.

 The choke is placed in the well 27 and lowered into the sump 28 with pollution 29.

 The flap works as follows.

 The entire structure is lowered into the borehole on the upper pipe string 1. As it descends, the lower pipe string 11 is filled with liquid. The air in the lower pipe string 11 is displaced by the fluid through the openings 23, lifting the ring 24, and exits into the space of the well 27. In this case, the rod 7 is in the upper position, the ball 5 is pressed against the seat 4 by the spring 6 and separates the liquid from entering the hole 8 and the upper pipe string 1. When the ripper 12 touches the impurities 29 in the sump 28, the lower pipe string 11 with the casing 2 stops, the upper pipe string 1 pushes the rod 7 down with its weight. The rod 7 presses the ball 5 with the plug 9, compresses the spring 6 and moves the ball 5 away from the valve seat 4. Since the liquid level in the well is much higher than the liquid level in the lower pipe string 11, the liquid will rush through the hollow cultivator at high speed 12, holes 25, the lower pipe string 11, the poppet check valve 13, past the ball 5, through the slots 10 into the inner hole along the axis 8 of the rod 7 and then into the upper pipe string 1 until the levels in the upper pipe string 1 and well 27 level out. this poppet check valve 13 from discontinuity, because the sealing belt 15 and the load 16 are rotated on the axis 17 under the action of the fluid flow and move away from the landing seat 14. When the fluid flow stops, the poppet check valve 13 closes, because under the action of the load 16, the sealing belt 15 and the load 16 are rotated on the axis 17 in the opposite direction and adjoin the landing seat 14.

 When liquid is filled with the lower pipe string 11 from the sump 28 of the well 27, contaminants 29 are sucked in, which are held in the lower pipe string 11 by a poppet check valve 13 and together with the entire structure are removed from the well 27. After emptying, the choke is ready for operation again.

 In the case of the use of a muffled cultivator 12, liquid is withdrawn only through openings 25 located close to the perforations 26 of the casing of the well 27, and preferential cleaning of the perforations 26 is performed.

 In the absence of holes 25, the sump 28 of the well 27 is preferably cleaned.

 If there are 28 dense, compacted contaminants in the sump 29 of the above actions to clean the well 27 is not enough. In this case, after touching the ripper 12 of impurities 29 in the sump 28 and stopping the lower pipe string 11 with the housing 2, the upper pipe string 1 with a sub 19 and the stem 7 are moved down by no more than the gap 18, i.e. until the plug 9 of the spring-loaded ball 5 touches. In this case, the ball 5 is pressed against the valve seat 4. The fluid does not enter the inner hole along the axis 8 of the rod 7 and then into the upper pipe string 1. Further downward movement of the upper pipe string 1 is stopped. The upper pipe string 1 is brought into rotation. The rotation through the sub 19 is transmitted to the rod 7 and through the dowels 20 and the slots 21 to the housing 2, the lower pipe string 11 and the cultivator 12. As the dirt is loosened 31, the cultivator 12, the lower pipe string 11, the housing 2 and the stem 7 fall down. The keys 20 and the slots 21 provide the transmission of rotational motion while simultaneously moving along the axis up and down. After sampling the gap 18, the upper pipe string 1 with the sub 19 and the rod 7 is further advanced downward by no more than the gap 18, and the upper pipe string 1 is again rotated. If necessary, the operations are repeated until the entire thickness of the contaminants is loosened 29. The rotation is stopped. The upper pipe string 1 is moved down by an amount greater than the gap 18; it moves the rod 7 down with its weight. The rod 7 with the plug 9 presses on the ball 5, compresses the spring 6 and pushes the ball 5 from the valve seat 4. There is a suction of impurities 29 in the chute.

 It is possible to carry out the suction of contaminants 29 after each loosening operation by briefly opening the borehole space and partially filling it with well fluid.

 The placement of holes 25 of the lower pipe string 11 from the bottom at a height equal to the distance from the bottom of the well to the perforations 26 of the casing of the well 27, allows you to simultaneously clean not only the sump 28 of the well 27, but also the perforations 26. This contributes to a more intensive cleaning of the bottom hole 27 and guarantees against settling of contaminants 29 in the perforations 26 of the well casing 27. The use of a hollow cultivator 12 allows you to take contaminants 29 directly from the sump 28. If the cultivator 12 is made for lushennym below, the effect of depression is preferably at the perforations 26 and their preferential purification occurs. Structurally, the lower part of the cultivator can be in the form of a drill, a cutting edge, a pen, a milling cutter, etc.

Case Studies
Example 1. Cleaning an oil well 27 with a depth of 1750 m, with a sump 28 with a depth of 30 m and solid pollution 29 with a thickness of 10 m. The perforation interval 26 in the well is 5 m. As a ripper 12 use a feather. The distance between the end of the pen 12 and the lower holes 25 is 25 m. The gap 18 is 0.5 m. At the beginning of the loosening, the holes 25 are slightly higher than the holes 26, but as the depth of the hole increases, the holes 25 and 26 are at the same level.

 Contamination is loosened by rotating the tubes with the choke and cultivator 12 with a choke closed with a depth of 0.5 m each and sucking contaminants immediately after loosening every 0.5 m through holes 25 and through pen 12 with repeated loosening and aspiration cycles until the bottom of the well is reached . As a result, sump 28 is completely free from contamination, and well production rate has increased by 40%.

 Example 2. Carry out the cleaning of an oil well 27 with a depth of 1750 m, with a sump 28 with a depth of 25 m and solid impurities 29 with a thickness of 2 m. The perforation interval 26 in well 27 is 5 m. A chute is lowered into well 27 in accordance with the drawing. As a ripper 12 use a feather. The distance between the end of the pen and the lower holes 25 is 25 m. The gap 18 is 0.5 m. Loosening of the contaminants is carried out by rotating the pipes with the chipper and a cultivator 12 with the choke closed with a depth of 0.5 m for each immersion and suction of contaminants immediately after loosening 2 m pollution through the holes 25 and through the pen 12. As a result, the sump 28 of the well 27 is completely cleaned of pollution, and the flow rate of the well 27 increased by 25%.

 Example 3. Perform, as example 2, but before loosening the short-term emphasis of the ripper 12 in the contamination 29 of the sump 28 and the opening of the flap, the third part of the flap is filled with borehole fluid. As a result, the sand from the bottom-hole zone of the well 27 during cleaning completely stopped.

 Application of the proposed method will improve the efficiency of well cleaning.

Claims (3)

 1. A method of cleaning a well during its operation, including mechanical action on the sump of the well, suction of contaminants into the bunker and extraction from the well, characterized in that the mechanical effect on the contamination is carried out by loosening the contaminants by rotating the pipes with the choke and ripper when the choke is closed, and the contamination is sucked in immediately after loosening the contamination at the level of the perforation holes of the casing of the well and at the level of the sump.  2. The method according to p. 1, characterized in that the stepwise cleaning of the well is carried out by loosening and suctioning part of the contaminants with repeating loosening and suction cycles.  3. The method according to claim 1 or 2, characterized in that prior to loosening with a short-term emphasis of the cultivator in the contamination of the sump and opening of the baffle, part of the bobbin is filled with borehole fluid.