RU2213195C1 - Method of tapping of oil and gas well producing formations - Google Patents

Abstract

FIELD: well drilling and servicing, particularly, secondary tapping of producing formations. SUBSTANCE: method includes provision in producing formation and higher of its uncased section of main wellbore, with slime washing with drilling mud, of secondary tapping by drilling in bottomhole formation zone, with use of tool assembly with deflecting tool, of radially directed perforation channels with curved side wellbores spirally converging in radial direction and consisting of descending sections passing into horizontal and/or horizontal-ascending sections with inlets in uncased section of main wellbore and outlets ensuring tapping of all interlayers of producing formation, and subsequent induction of formation fluid inflow to main wellbore. In so doing, after provision of uncased section of main wellbore, it is reamed, and plug is formed in it by filling with hardening composition. After hardening of said composition, formed in its plug is auxiliary wellbore coaxial to main wellbore with diameter and depth sufficient for drilling of perforation channels which are drilled with inlets located in uncased section over helical line by interval by interval axial displacement and turning of tool assembly with deflecting tool in auxiliary wellbore. EFFECT: increased overhaul period of well, its production rate, reduced pressure differential between formation and bottomhole pressure by increase of filtration zone of bottomhole formation zone, reduced permeability and increased stability of wellbore section of bottomhole formation zone. 3 cl, 5 dwg

Description

 The invention relates to the field of drilling and well repair, in particular the secondary opening of reservoirs.

 A known method of opening productive formations of oil and gas wells, including the creation in the productive formation and above its uncased section of the main trunk with drilling mud drilling fluid, the secondary opening of the formation by drilling in its bottom-hole zone instrumental layout with a deflector radially directed perforation channels with descending trunks with entrances to the entrances open area and waste, providing the opening of the interlayers of the reservoir, causing the influx of the reservoir product into the well [1].

 The disadvantage of this method is that during its implementation, the opening of the reservoir by drilling inclined perforation channels with descending trunks, the waste values of which from the main barrel are determined by the thickness of the reservoir and the angle of inclination of the main diameter of the main trunk, which does not allow to extend the perforation channels, increase the number of openings productive strata of the formation, the filtration zone of the bottomhole zone and the conditional radius of the well, as well as increase stability and reduce permeability spine near-wellbore region, thus it is impossible to increase the turnaround period of operation of the well, its production rate, reduce the differential between the reservoir and the bottomhole pressure.

 The closest method of the same purpose to the claimed invention in terms of features is a method of opening productive formations of oil and gas wells, including the creation in the productive stratum and above its uncased portion of the main wellbore with flushing drilling fluid, re-opening the formation by drilling in its bottom-hole zone with an instrumental layout with a diverter of radially directed perforation channels with arched trunks consisting of descending sections that are horizontal nye and / or horizontally-rising portions from entrances in the open hole portion and the waste opening providing interlayers producing formation calling product reservoir inflow into the wellbore [2].

 The disadvantages of the known method adopted for the prototype are that due to the drilling of perforation channels in the uncased section of the main shaft in the reservoir and above it, in particular, folded by unstable highly permeable rocks, the number of openings of individual layers representing highly permeable interlayers and closed lenses with formation fluid in a heterogeneous productive formation, it is not possible to obtain continuous along the length of the intersection of the radial flow perforation channels reservoir fluid, for these reasons limited filtration area bottom zone, unstable rock collapses to near-wellbore region of the latter, which leads to its water cut or gas indications, reduced overhaul period of operation of the well, its flow rate, significant differential between reservoir and downhole pressures.

 The problem to which the invention is directed is to increase the coefficient of well productivity and reservoir productivity.

 The technical result of the invention is to increase the overhaul period of the well’s operation, its production rate, lower the differential between the reservoir and bottomhole pressures by increasing the filtration zone of the bottomhole formation zone, reducing permeability and increasing rock stability of its near-stem region.

 The specified technical result is achieved by the fact that according to the method of opening productive formations of oil and gas wells, including the creation in the productive formation and above its uncased section of the main trunk with drilling fluid drilling, secondary opening of the formation by drilling in its bottom-hole zone with an instrumental arrangement with a deflector of radially directed perforations channels with arched trunks, consisting of descending sections, turning into horizontal and / or horizontally ascending sections, with odes in the uncased section and waste, providing the opening of the interlayers of the reservoir, the inflow of the reservoir product into the well, according to the invention, after the creation of the uncased section of the main trunk, they are expanded, then they form a cork in it by filling with a hardening compound, after which they are coaxially formed in the cork an auxiliary shaft with a diameter and depth sufficient for the subsequent drilling of perforation channels that are drilled with entrances, we have in an uncased section along a helical line by interval-wise axial movement and rotation of the instrumental arrangement with a deflector in the auxiliary shaft.

 In addition, a feature of the method is that prior to the expansion of the uncased section of the main trunk, an insulating composition, for example, a gelling agent, is injected into the bottomhole zone of the formation to a depth less than the distance of the perforation channels, but exceeding the diameter of the expanded part of the main trunk.

 In addition, a feature of the method lies in the fact that the auxiliary shaft is preliminarily formed with a diameter smaller than sufficient for drilling perforation channels and with a depth that ensures the deposition of sludge during subsequent drilling of the perforation channels and the final formation of the auxiliary shaft by its expansion with a diverter without washing with drilling fluid.

 The expansion of the uncased portion of the main trunk in the reservoir and above the reservoir, the formation of plugs in it by filling with a hardening composition, the formation after solidification of the latter coaxially to the main auxiliary trunk with a diameter and depth sufficient to drill perforations, makes it possible to form a thick-walled casing ring with considerable strength and impermeability, which allows to increase the stability of the rock near-stem region of the bottom-hole zone to shedding and collapses, with form entrances and initial sections of perforation channels both in overlying non-exploitable and productive layers by drilling channels in a plug, prevent the formation of gas-oil, water-oil and gas-water contact cones or eliminate them, as a result of which increase the flow rate of wells and increase the overhaul period of its operation. Prevention of gas breakthroughs from the gas "cap" of the reservoir will help to maintain a high reservoir pressure and flow rate for a no longer period of operation, thereby increasing the yield of the reservoir.

 The implementation of the perforation channels in the form of arcuate shafts spiraling out from the well in the radial direction, which are drilled with helical entries by interval-wise axial movement and rotation of the tool assembly with a deflector in the auxiliary shaft, will help to prevent the tool assembly from accidentally falling into previously drilled perforation channels, to obtain more a rational grid of their placement in the reservoir, makes it possible to open individual layers, representing they are highly permeable interlayers and closed lenses with formation fluid in a heterogeneous productive formation, the effective intersection by such trunks of fluid flow directions to the well during flat-radial filtration, as a result, the well filtration zone will increase, the differential between the reservoir and bottom-hole pressures will decrease, and the likelihood of formation of water-oil and gas-oil cones will decrease contacts, thus increasing the overhaul period of the well’s operation, its production rate, productivity and yield coefficient fin.

 All the signs of an independent claim are essential, that is, necessary to ensure a technical result. The remaining features are part essential, necessary for the implementation of special cases of the method.

 So, the injection into the bottomhole zone of the insulating composition to expand the uncased section of the main trunk to a depth less than the distance of the perforation channels, but exceeding the diameter of the expanded section of the main trunk, will allow to avoid undesirable penetration of the drilling fluid filtrate into the bottomhole zone of the formation during expansion of the trunk, to increase the tightness of the plug reduce the likelihood or slow down the formation of cones of interproductive contacts during well operation, thereby increasing its overhaul period.

 Preliminary formation of the auxiliary wellbore with a diameter smaller than sufficient for drilling perforation channels and a depth that ensures sludge deposition during subsequent drilling of the perforation channels and the final formation of the auxiliary wellbore by expanding it without washing with drilling fluid, makes it possible to reduce the hydrodynamic pressure on the formation and reduce its filtrate pollution and solid phase, and due to the support of the diverter on the narrowing between the final and preliminary auxiliary st oxen to receive a more rational placement of side channels in the well, which will increase its flow rate.

 Due to the fact that the set of features characterizing the proposed invention is not known from the art, it can be concluded that the claimed invention meets the condition of "novelty."

 Although some of the signs relating to the expansion of the uncased portion of the main trunk, the creation of a plug in it by filling with a hardening compound, are given in the source of information [3], according to which these techniques are carried out below the reservoir, which makes it inefficient to form entrances and initial sections of perforation channels in the plug, but in combination with other distinguishing features of an independent claim, the formulas are not obvious to specialists in this industry.

 From the above it follows that the invention meets the condition of "inventive step".

 The proposed method can be implemented according to the schemes.

 In FIG. 1 shows a three-dimensional arrangement of one of the perforation channels; figure 2 - arrangement of perforation channels of one tier on the projection in the radial plane (top view); figure 3 is a diagram of their drilling in the auxiliary trunk instrumental layout; figure 4 - layout of the grid of inputs of perforation channels along a helical line in the auxiliary barrel; figure 5 - layout of the insulating composition in the bottomhole zone before the expansion of the uncased portion of the main trunk, the formation of cork, the expansion of the auxiliary shaft and drilling the perforation channel.

Figure 1-5 shows the position:
1 - the main trunk; 2 - its uncased area; 3 - reservoir; 4 and 5 - its interlayers; 6 - perforation channel with a curved arched shaft extending from the wellbore; 7 - its descending section; 8 - horizontal section; 9 - horizontally ascending section; 10 - trajectory of an arcuate trunk spiraling outward from a well in a projection onto a radial plane; 11 - an expanded part of the uncased portion of the main trunk; 12 - cork from a hardening composition in the form of a thick-walled casing ring; 13 - auxiliary barrel; 14 - direction of formation fluid flows to the well during flat radial filtration; 15 - highly permeable interlayer; 16 - a lens with a reservoir fluid; 17 - instrumental layout; 18 - bit; 19 - diverter; 20 - input perforation channel; 21 - helical lines of the grid for the placement of entrances of perforation channels; 22 - preliminary auxiliary barrel; 23 - sludge sediment from the expansion of the auxiliary trunk and the rock drilled in the perforation channels; 24 - aquifer; 25 - screw cutting elements; 26 - calibrating cutting elements; 27 - injection boundary of the insulating composition
The possibility of carrying out the invention to obtain the above technical result is confirmed as follows.

 After creating an uncased section 2 of the main shaft 1 (Fig. 1) in the reservoir 3 and above the reservoir with drilling fluid drilling, expand it using a drilling assembly, including hydromechanical and hydroerosive expanders, with the subsequent formation of plug 12 in the expanded part 11 by filling with a hardening composition according to known technology, most often with cement mortar, after hardening of which a thick-walled casing ring is formed by drilling in a tube coaxially mu auxiliary shaft 13 with a diameter and depth sufficient for subsequent drilling of the perforation channels 6. In the process of creating perforation channels with arched spiraling radially extending trunks (Fig. 2), the inlets 20 (Fig. 3) of the upper tier are drilled in a plug above the productive the formation along a helical line 21 (Fig. 4) by interval-wise axial movement and rotation of the tool assembly 17, including a bit 18 and a deflector 19 mounted on the shaft of the "curved" spindle of the downhole motor. x 4 and 5, first, a descending section 7 is drilled, then a horizontal 8 and / or horizontally ascending 9 section, forming a path 10 spiraling out from the well in the projection onto the radial plane, which increases the likelihood of opening highly permeable interlayers 15 and closed lenses 16 in an inhomogeneous interlayer and intersections of directions 14 of formation fluid flows to the well during flat-radial filtration.

 Then produce by known methods the call of the inflow of the reservoir product.

 In the particular case, before expanding the uncased portion of the main trunk, an insulating composition is injected into the bottomhole zone (Fig. 5), for example, gel-forming to a depth defined by the boundary 27, less than the distance of departure of the perforation channels 5, but larger than the diameter of the expanded part 12 of the main trunk. The insulating composition strengthens the near-stem zone of the near-wellbore zone, makes it poorly permeable for water and gas breakthroughs, which can significantly increase the overhaul period of the well’s operation and reduce the water cut of the produced oil.

 In the particular case, it is possible to form a preliminary auxiliary shaft 22 (Fig. 5) with a diameter smaller than sufficient for drilling perforation channels and a depth that ensures the deposition of sludge 23 during subsequent drilling of the perforation channels 6 and the final formation of the auxiliary shaft 13 by expansion. The extension of the pre-auxiliary barrel is carried out by a diverter 19 having screw 25 and gauge 26 cutting elements, without flushing with drilling fluid. The cutting elements 25 form a helical groove in the barrel 22, with which the deflector is held (anchored) in it. Then, the perforation channel 6 is drilled with the instrumental arrangement 17. After the drilling is completed, it is removed from the channel, the diverter is rotated and simultaneously moved down the hole to drill the next perforation channel, while the final formation of the auxiliary shaft is completed with calibrating cutting elements 26. Thus, pollution can be reduced already drilled channels with leachate and solid phase drilling fluid, increase well production.

 Thus, the tool embodying the claimed method in its implementation is intended for use in the oil and gas industry, namely in the field of drilling and well repair, in particular, the secondary opening of reservoirs. For the claimed method in the form as described in the independent paragraph of the claims, the possibility of its implementation is confirmed.

An example of the implementation of the claimed method can serve as follows. Before the overhaul of a production oil well cased with a 146 mm casing, productive sandstone with a permeability of 80-140 mdars was opened by sandblasting perforation in the range of 1644-1652 m, the daily production rate was Q = 12.8 m ³ at an oil cut of 60% (k _n = 0.4), reservoir pressure R _pl = 10.2 MPa, bottomhole pressure during pump production R _zab = 8.6 MPa, well productivity coefficient, calculated on the basis of the known dependence [4], amounted to
k = k _n Q / (R _{pl -R zab} ) = 0.4 • 12.8 / (10.2-8.6) = 8.192 m ³ / day • MPa
After opening the formation by drilling through the uncased section of the main trunk, obtained by cutting and removing part of the casing, arched perforation channels, consisting of downward and horizontal sections, with a diameter of 50 mm, 12 m long, 8 m waste, descent slot filter, daily average flow rate during month was equal to 18.2 m ³ with a water cut of 10% (k _n = 0.9), P _PL = 10.2 MPa, P _Zab = 9.3 MPa, the productivity coefficient was
k = 0.9 • 18.2 / (10.2-9.3) = 18.2 m ³ / day • MPa.

Sources of information
1. RF patent 2087671, cl. E 21 B 7/06, 1997.

 2. Kalinin A. G. et al. Drilling of deviated and horizontal wells. Directory. - M .: Nedra, 1997, pp. 11-12.

 3. A.S. USSR 981555, class E 21 B 7/04, 1982.

 4. Amirov A.D. and others. Overhaul of oil and gas wells. - M.: Nedra, 1975, p. 91-93.

Claims (3)

 1. The method of opening productive formations of oil and gas wells, including the creation in the productive stratum and above its uncased portion of the main trunk with rinsing with drilling fluid, re-opening the formation by drilling in its bottom-hole zone with an instrumental arrangement with a deflector of radially directed perforation channels with arched trunks consisting from descending sections turning into horizontal and / or horizontally ascending sections, with entrances to open-air section and waste, providing opening layers of the productive formation, causing the influx of formation fluid into the well, characterized in that after the creation of the uncased section of the main trunk, it is expanded, then a cork is formed in it by filling with a hardening composition, after hardening of which the auxiliary casing is formed coaxially with the main diameter and depth, sufficient for subsequent drilling of perforation channels, which are drilled with entrances located in an open-air section along a helical line by an interval axial displacement and rotation of the instrumental layout with a diverter in the auxiliary shaft.  2. The method according to p. 1, characterized in that prior to the expansion of the uncased section of the main trunk, an insulating composition, for example, a gel-forming one, is injected into the bottom-hole zone of the formation to a depth less than the distance of the departure of perforation channels, but exceeding the diameter of the expanded part of the main trunk.  3. The method according to any one of paragraphs. 1 and 2, characterized in that the auxiliary shaft is preliminarily formed with a diameter smaller than sufficient for drilling perforation channels and a depth that ensures the deposition of sludge during subsequent drilling of the perforation channels and the final formation of the auxiliary shaft by its expansion with a diverter without washing with drilling fluid.

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