RU2494247C1 - Development method of water-flooded oil deposit - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method involves drilling of a deposit with production wells crossing the formation with water-saturated and oil-saturated zones separated with a non-permeable natural interlayer, lowering of a casing string with further formation perforation, investigation of its water-oil saturation and their deposit intervals, dimensions of non-permeable natural interlayer, creation of a screen from an insulating compound, which separates water-saturated zone of the formation from oil-saturated zone, cutting of some part of the casing string, enlarging the well shaft at that interval; filling of the enlarged interval of the well shaft with insulating compound, drilling of insulating compound in the well so that the screen remains opposites oil-saturated zone of the formation after waiting period of the insulating compound hardening, perforation opposite oil-saturated zone of the formation, and development of the well. At arrangement of water-saturated zone below oil-saturated zone of the formation and thickness of non-permeable natural interlayer of 0.5 to 4 m at the bottom interval of non-permeable natural interlayer there installed is a blind packer; some part of the casing string is cut out from the blind packer to the roof of the formation oil-saturated zone; the well shaft is expanded at the interval of the cutout part; the expanded well shaft interval is filled with insulating compound. Microcement is used as the above insulating compound so that an insulating bridge is obtained. After waiting period of microcement hardening, the insulating bridge and the blind packer are drilled so that the screen remains opposite non-permeable natural interlayer and oil-saturated zone of the formation with the diameter equal to inner diameter of the casing string; water-saturated formation zone is cutout by placing in the casing string below the cut-out part of a stationary packer with a perforated shank with a limit stop on the working face from below and a sealing joint from above. After that, the cut-out section of the casing string is fixed in the well by lowering an additional string with its installation opposite the cut-out section of the casing string and tight fixation of upper and lower ends of the additional string in the casing string above and below the cut-out section in the well. When oil-saturated zone of the formation is being introduced to the development, drilling perforation of an additional string is performed opposite oil-saturated zone of the formation. During development of water-flooded oil deposit, periodic operation of oil-saturated and water-saturated formation zones is performed.

EFFECT: improving efficiency of the method owing to excluding behind-the-casing flow in the well between water- and oil- saturated zones of the formation.

6 dwg

Description

The invention relates to the field of development of oil fields, the strata of which are composed of water and oil-saturated zones, separated by impermeable natural layers and is intended to isolate annular flows in the wells between the oil and water-saturated zones of the reservoir.

A known method of developing a water-oil deposit (patent RU 2015312, IPC Е21В 4 3/22, publ. 06/30/1994), including the injection of the insulating composition into the reservoir and the creation of an artificial screen, and before the injection of the insulating composition determine the minimum size of the cross section of the natural lenticular layer in a monolithic deposit and the thickness of the cut-off layer of the aquifer, and an artificial screen is created under the lenticular layer with a radius equal to twice the thickness of the cut-off layer of the aquifer and 1st pressure excerpt in 30-80 atm.

The disadvantage of this method is the low strength of the created screens.

A known method for the development of waterlogged oil fields (patent RU 2065025, IPC ЕВВ 33/13, ЕВВ 43/30, published in bul. 22 from 08/10/1996), including drilling their production wells, at least part of which crosses natural impermeable interlayers in the reservoir, and the creation of screens based on insulating compositions that separate the water-saturated zones of the reservoir from oil-saturated, characterized in that the insulating composition is fed into the reservoir under the natural layer and over it with the possibility of setting interlayers with screens above and below, while the thickness of the screen above the natural layer is taken from the condition of isolation of the natural layer from the reservoir, and the total thickness of the screens is taken from the condition of their resistance to the pressure drop that occurs during well operation.

The disadvantages of this method are:

- firstly, the total thickness of the screens is taken from the condition of their resistance to the pressure drop that occurs during the operation of the well, and the volume of insulating material is determined from the ratio determined by calculation, while the pressure drop can vary with time, and the radius of the insulating screen may not be enough for reliable isolation of the water-saturated zone from the oil-saturated zone of the formation with a sharp jump in pressure drop;

- secondly, in the best case scenario, the radius of the screen should correspond to twice the thickness of the cut-off water-saturated zone of the formation, and the thickness of the screen should provide its resistance to the maximum possible pressure drop that occurs during well operation, it should be borne in mind that one meter of the thickness of the natural layer withstands the pressure drop up to 1.5 MPa. This condition is not always maintained, which leads to premature flooding of the oil-saturated zone of the reservoir;

- thirdly, the low efficiency of the method, due to the fact that the presence of a screen opposite and lower than the natural layer during the development of an irrigated oil reservoir does not exclude the possibility of a breakthrough of water from the bottom up (behind-the-casing flows) into the oil-saturated zone of the reservoir due to their low strength, which reduces anhydrous well operation period;

- fourthly, the complex technology of preparing an insulating composition, which is prepared by mixing equal parts of an organosilicon emulsion, oil and water in a mixing unit and pumped into the perforated intervals of the formation with the sale of its cement, also the high costs of components of the insulating composition.

The closest in technical essence and the achieved result is a method of developing flooded oil fields (patent RU 2420657, IPC ЕВВ 43/32, Е21В 33/134, published in Bulletin 16 of 06/10/2011), including drilling them with production wells crossing tight natural interlayers in the reservoir, casing stringing followed by perforation of the reservoir, study of its oil saturation and intervals of their occurrence, the size of the impermeable natural layer and the creation of screens from isol uyuschego composition separating from the water-saturated zone of the formation of oil-saturated zones. Based on the research results, the thickness of the oil-saturated zone of the formation is determined, when the thickness of the oil-saturated zone of the formation is more than 4 m, a part of the casing string is cut out in the interval above the lower perforations of the oil-saturated zone of the formation and until the bottom of the well, the wellbore is expanded in this interval, the extended interval of the wellbore is filled with an insulating composition, which is used as a cement mortar, and when the thickness of the oil-saturated zone of the formation is less than 4 m, temporary isolation of the intervals of perforation of the productive surface is performed with a colmatizing compound, cut out a part of the casing from the roof of an impenetrable natural layer to the bottom of the well, expand the wellbore in this interval, fill the extended interval of the well with the insulating composition and create a packer by introducing into the bottomhole zone of the oil saturated zone of the well, after waiting for the insulating composition to solidify, make a hole packer to the roof of the natural interlayer with leaving a screen opposite the oil-saturated zone, after which repeated perforation of adnoy column opposite net pay zone formation and development wells, with inflow of oil from the oil saturated formation zone below produce viable quantities without acid treatment pressure.

The disadvantages of this method are:

- firstly, the low efficiency of the development of water-saturated oil fields, which is associated with the isolation of water-saturated zones of the reservoir during the implementation of this method, which leads to a complete rejection of the water-saturated zone of the reservoir and its withdrawal from further development of the water-flooded oil field, often when developing a water-flooded oil field there is a need to use the water-saturated zone of the reservoir both to maintain reservoir pressure, and for intra or inter-well pumping of water;

- secondly, the effect of the application of this method is not long, which is associated with the rapid destruction of cement stone during subsequent operation of the well due to the absence of a significant part of the casing, i.e. the design of the well loses its strength due to the cutting of the casing from the roof of an impenetrable natural layer to the bottom of the well. In addition, when creating the slightest depression in the well, the bottom-hole zone of the well is destroyed;

- thirdly, cement does not provide uniform penetration into the pores of an impermeable natural layer, which means that it is not possible to obtain a reliable monolithic screen from an insulating composition that separates the water-saturated zone from the oil-saturated zone of the formation in the range of the impermeable natural layer.

- fourthly, a significant part of the casing is cut (from the roof of an impenetrable natural layer to the bottom), which leads to an increase in the complexity of the method.

The objective of the invention is to increase the efficiency of the method of developing an irrigated oil field by eliminating annular cross-flow in the well between the water and oil saturated zones of the formation with the possibility of developing both the oil saturated zone and the water saturated zone of the formation, as well as increasing the strength of the well structure.

The problem is solved by a method of developing an irrigated oil field, including drilling it with production wells intersecting a formation consisting of water-saturated and oil-saturated zones separated by an impermeable natural layer, lowering the casing with subsequent perforation of the formation, studying its oil saturation and the intervals of their occurrence, the size of the impermeable natural , creating a screen from an insulating composition that separates the water-saturated zone of the reservoir from oil of the saturated zone, cutting out a part of the casing string, widening the borehole in this interval, filling the extended interval of the borehole with an insulating compound, drilling an insulating composition in the well with leaving a screen opposite the oil-saturated zone of the formation after waiting for the insulation to solidify, perforation opposite the oil-saturated zone of the formation, well development.

New is that when placing the water-saturated zone below the oil-saturated zone of the formation and the thickness of the impenetrable natural layer from 0.5 to 4 m in the interval of the sole of the impenetrable natural layer, a deaf packer is installed, a part of the casing is cut from the deaf packer to the roof of the oil-saturated zone of the formation, and the trunk is expanded wells in the interval of the cut out part, fill in the extended interval of the wellbore with an insulating composition, which is used as microcement to obtain an insulating bridge, after waiting hardening of microcement, the insulating bridge and the blank packer are drilled, leaving a screen opposite the impermeable natural layer and the oil-saturated zone of the formation with a diameter equal to the inner diameter of the casing, cut off the water-saturated zone of the formation by landing in the casing below the cut part of the stationary packer with a perforated tail end bottom and sealing unit on top, after which the cut section of the casing is fixed in the well by lowering an additional casing with its installation opposite the cut-off section of the casing and hermetically fixing the upper and lower ends of the additional casing in the casing above and below the cut-out section in the well, when introducing the oil-saturated zone of the formation into the development, drilling a perforation of the additional column opposite the oil-saturated zone of the formation and during development the watered oil field periodically exploits the oil-saturated and water-saturated zones of the formation.

Figure 1, 2, 3, 4, 5, 6 schematically and sequentially depicts the implementation of the method of developing a waterlogged oil field.

The method is implemented as follows.

A method for developing a watered oil field involves drilling it with production wells 1 (see FIG. 1) intersecting formation 2.

For example, consider one production well 1. Formation 2 consists of a water-saturated zone 3, separated by an impermeable natural layer 4 with an oil-saturated zone 5. A casing string 6 is lowered into the well 1 and fixed therein. In the casing 6 of the well 1, the oil-saturated zone 5 of the formation is perforated 2 with the formation of perforations 7.

During the operation of well 1, water from the water-saturated zone 3 of the formation 2 along the annulus 8 of the casing 6 of the well 1 and the impermeable natural interlayer 4 breaks through the perforations 7 of the oil-saturated zone 5 of the formation 2 into the well 1, and the produced oil is irrigated. This is due to the fact that the pressure in the water-saturated zone 3 of the formation 2 is higher than in the oil-saturated zone 5 of the formation 2.

According to field studies, the nature of oil saturation is specified, i.e. the location of the water-saturated zone 3 relative to the oil-saturated zone 5 of formation 2 and the intervals of occurrence of water-saturated 3 and oil-saturated zones 5 and the size of the impermeable natural layer 4. For example, the interval of occurrence of water-saturated zone 3 is 1742-1737 m; above in the interval 1737-1734 m there is an impermeable natural layer 4, above which in the interval 1734-1728 m lies the oil-saturated zone 5 of formation 2. The porosity and residual oil saturation of formation 2 are determined.

When placing the water-saturated zone 3 below the oil-saturated zone 5 of the formation 2 and the thickness of the impermeable natural layer 4 from 0.5 to 4 m to create a screen of insulating composition in the interval of the sole of the impermeable natural layer 4, a blank packer 9 is placed (see Fig. 2) of any known designs. For example, a deaf drillable packer (PWG) designed by the TatNIPIneft institute (see RU patent No. 2405911 “Drillable packer.” IPC EV 33/12 published in bulletin No. 34 dated 12/10/2010 or patent RU No. 2137902 “Packer drillable plug ", IPC Е21В 33/12, ЕВВ 33/134 publ. in Bulletin No. 26 of 09/20/1999).

In the casing 6, a section 10 (see FIG. 2) is cut from the deaf packer 9 to the roof of the oil-saturated zone 5 of formation 2 (see FIG. 1) by any known device, for example, by means of a universal cutting device (CVD) deflated a well on a pipe string (not shown in FIGS. 1, 2, 3, 4, 5, 6). The length of the cut section 10 provides reliable isolation annular flow in the well 1 (see figure 1).

The wellbore is expanded in the interval of the cut-out part 10 (see FIG. 2) of the casing 6 (see FIG. 1), for example, by lowering the nozzle on the pipe string (in FIGS. 1, 2, 3, 4, 5, 6 shown) and pumping a liquid, for example fresh water, through a pipe string through a hydraulic nozzle that expands the borehole 1 under the pressure of a liquid stream. Thus, an extension 11 (extended interval) (see Fig. 3) of the borehole 1 (see Fig. 1) in the interval of the cut out part 10 (see Fig. 2) of the casing 6 (Fig. 1).

After removing the nozzle with the pipe string into the well 1, the pipe string is lowered (not shown in FIGS. 1, 2, 3, 4, 5, 6) and the extended interval 11 (see FIG. 2) of the wellbore is filled with an insulating composition with the formation of an insulating bridge 12. For this, an insulating composition is used as a microcement to be pumped into the casting pipe string.

As microcement they use superthin ultracement produced by NPO Polytsell CJSC (Vladimir) according to TU 5739-019-56864391-2010. Apply a mixture of microcement with water. Water is mixed with microcement in a mass ratio, respectively, of 2: 3. The use of microcement ensures that the mixture of water and microcement penetrates into the thin pores and cracks of the formation 2 opposite the extended interval 11 of the wellbore 1. The mixture of water and microcement has high mobility, and the strength of the obtained insulating bridge 12 (see figure 3) is higher than the strength of the cement stone obtained from a mixture of water with conventional cement cement used in the repair of wells, which allows you to create a reliable and durable screen that prevents the flow of water. The amount of insulating composition, for example, 2 m ³ , to be injected in order to isolate the annular flow in the well 1, is determined by the technological service of oil and gas production control experimentally and depends on the height and diameter of the extended interval 11 of the wellbore 1.

Selling microcement is carried out using squeezing liquid, for example, wastewater, with a density of 1180 kg / m ³ with the formation of an insulating bridge 12 (figure 3). After that, the column of casting pipes is removed (not shown in FIGS. 1, 2, 3, 4, 5, 6) and well 1 is left (see FIG. 1) to wait for the hardening of microcement (OZM). After OZM, an insulating bridge and a blank packer 9 (see Fig. 2) are drilled, leaving a screen 13 (see Fig. 4) opposite the impermeable natural layer 4 (see Fig. 1) and oil-saturated zone 5 of formation 2 with a diameter equal to the inner casing string diameter 6.

Drilling is carried out, for example, using a bit and a downhole screw motor lowered into the well 1 on a pipe string (not shown in FIGS. 1, 2, 3, 4, 5, 6).

Next, cut off the water-saturated zone 3 (see Fig. 1) of the formation 2 by landing in the casing 6 below the cut part 10 (see Fig. 2) of the stationary packer 14, for example, in the range of 1737-1739 m (see Fig. 4) perforated a shank 15 with an emphasis on the bottom 16 from the bottom and the sealing unit 17 from the top. As a stationary packer 14, a packer is used to maintain the reservoir pressure of an axial or rotary installation of the П-ЯДЖ-О or П-ЯДЖ brand produced by the Packer research and production company (Oktyabrsky, Republic of Bashkortostan, Russian Federation).

Then, the cut-out section 10 (see FIG. 2) of the casing 6 (see FIG. 1) is fixed in the well 1 by lowering an additional string 18 (see FIG. 5) with its installation opposite the cut-off section 10 (see FIG. 2) casing string 6 (see FIG. 1) and hermetically fixing the upper end and lower end of the additional string 18 (see FIG. 5) in the casing 6 (see FIG. 1) above and below the cut-out portion 10 (see figure 2) in the well 1 (see figure 1).

The installation of an additional string 18 (see Fig. 5) is necessary to strengthen the design of the well and to prevent displacement of the casing string 6 (see Fig. 1), as well as to eliminate the destruction of cement in the well 1 and to extend its life.

As an additional string 18 (see FIG. 5), a metal pipe with an outer diameter smaller than the inner diameter of the casing 6 and a wall thickness precluding displacement of the casing 6 in the well 1 with the possibility of hermetically fixing its lower 19 (see FIG. .5) and the upper 20 ends in the casing 6 (see FIG. 1), for example, a metal “plaster” or a metal pipe with a two-packer arrangement, i.e. equipped with top and bottom packers (in figures 1, 2, 3, 4, 5, 6 not shown). For example, an additional casing with a diameter of 120 mm and a wall thickness of 7 mm is installed in the casing with a diameter of 168 mm and a length of Ume fixation in the casing 6 in the range of 1726.5 m (upper end) and 1736.5 m.

The sealing unit 17 (see Fig. 4) is a device that allows hermetically disconnect and communicate as water-saturated zone 3 (see Fig. 1) of formation 2, and oil-saturated zone 5 of formation 2 (see Fig. 1 and 5) when development of an irrigated oil field.

For example, to select the residual oil during the development of an irrigated oil field, it is necessary to separate the water-saturated zone 3 (see Fig. 1) of formation 2. For this, a plug of any known construction is installed in the sealing unit (in Figs. 1, 2, 3, 4, 5, 6 is not shown), and thus cut off the water-saturated zone 3 (see Fig. 1) of formation 2.

Drilling perforation 19 (see FIG. 6) of the additional column 18 is made opposite the oil-saturated zone 5 (see FIG. 1) of formation 2. Drilling perforation is performed, for example, using a PS 112-70 drilling perforator designed to perforate wells cased by columns with a diameter of 140 .. 168 mm. The drilling puncher PS 112-70 is produced by LLC NPO Azimut (Ufa, the Republic of Bashkortostan, Russian Federation). The technological string of pipes with the pump is lowered and the oil-saturated zone 5 of formation 2 is introduced into the development (see FIGS. 1 and 6).

To enter into the development of an irrigated oil field a water-saturated zone 3 of formation 2, its message is made by means of a sealing unit 17 (see Fig. 4, 5). To this end, a technological pipe string with a pump is lowered into the well 1 (see FIG. 1) (not shown in FIGS. 1, 2, 3, 4, 5, 6), the lower end of the pipe manufacturing string being installed in the sealing unit 17 (see Fig. 4). Thus, the oil-saturated zone 5 of formation 2 is separated and the water-saturated zone 3 of formation 2 is introduced into the development of an irrigated oil field, for example, for downhole pumping of wastewater in order to maintain reservoir pressure.

Thus, in the process of developing a waterlogged oil field, oil-saturated and water-saturated zones of the formation are periodically operated.

Implementation of the proposed method will increase the efficiency of the method of developing an irrigated oil field by eliminating the annular flow in the well between the water and oil saturated zones of the formation by creating a reliable and durable screen from the insulating composition that separates the water saturated zones of the formation from oil saturated zones with the possibility of developing both an oil saturated zone and water-saturated zone of the reservoir, as well as increase the strength of the well structure by attaching the casing of the well opposite you ezannoy part of the casing.

Claims (1)

A method of developing a water-flooded oil field, including drilling it with production wells crossing the formation, consisting of water-saturated and oil-saturated zones separated by an impermeable natural layer, lowering the casing string followed by perforation of the formation, studying its oil saturation and intervals of their occurrence, the size of the impermeable natural layer, creating from an insulating composition separating the water-saturated zone of the reservoir from the oil-saturated zone, cutting out part of garden string, expanding the borehole in this interval, filling the extended interval of the borehole with an insulating composition, drilling an insulating composition in the well with leaving a screen opposite the oil-saturated zone of the formation after waiting for the insulation to solidify, perforation opposite the oil-saturated zone of the formation, well development, characterized in that placing the water-saturated zone below the oil-saturated zone of the reservoir and the thickness of the impermeable natural layer from 0.5 to 4 m in the interval of the sole is impermeable of a natural layer, a blank packer is installed, a part of the casing is cut from a blank packer to the roof of the oil-saturated zone of the formation, the wellbore is expanded in the interval of the cut-out part, the extended interval of the wellbore is filled with an insulating composition, which is used as microcement to obtain an insulating bridge, after waiting for the microcement to solidify drill an insulating bridge and a blank packer with leaving a screen opposite to an impenetrable natural layer and oil saturated formation zones with a diameter equal to the inner diameter of the casing, cut off the water-saturated zone of the formation by landing in the casing below the cut part of the stationary packer with a perforated liner with emphasis on the bottom from the bottom and the sealing unit on top, after which the cut section of the casing is fixed in the well by lowering an additional casing with its installation opposite the cut section of the casing and hermetically fixing the upper and lower ends of the additional casing in the casing above and below the cut-out portion in the well, when administered in the development of oil saturated formation zone producing boring perforations additional column opposite the oil saturated formation zone and in the development obvodnennnogo oilfield produce a periodic operation and the oil-saturated water-bearing formation zones.

Images