RU2138625C1 - Method for development of water-oil deposit - Google Patents

Abstract

FIELD: oil production industry. SUBSTANCE: method can be used in working of deposits with bottom water. According to method, after drilling up of deposit and recovery of product from producing wells, pressure in bed is maintained at level of values ensuring setting of static level in well head zone of producing well. After that, oil is periodically recovered from well head zone. Application of aforesaid method increases oil recovery due to larger embracing of bed by flooding with simultaneous reduced recovery of associated water. EFFECT: higher efficiency. 3 dwg

Description

 The invention relates to the field of development of oil deposits and may find application in the operation of deposits with bottom water.

 There is a method of developing an oil reservoir underlain with bottom water, which consists in changing the fluid flows in the reservoir and selecting products from production wells [see M.L. Surguchev Secondary and tertiary methods of increasing oil recovery.-M.: Nedra, 1985.-p 85.]. The disadvantages of the method are the low oil recovery coefficient and a large selection of associated water caused by the formation of bottom water cones during operation of the wells.

 The closest technical solution to the proposed one is the method described in the book "Geology and development of the largest and unique oil and gas fields in Russia" / Abdulmazitov RG, Baimukhametov KS, Victorin V.D. and others. "M .: VNIIOENG, 1996. - T.1. -s.67.

 The method includes drilling production and injection wells; selection of products from producing wells; creation of a system for monitoring and regulating pressure between the oil and aquifer parts of the reservoir.

 A significant drawback of this method is that during the operation of the producing well, oil is not displaced from the roof of the formation, since the forces pushing the oil out of the formation into the well are much less hydrodynamic. Filtration resistance of the formation for oil exceeds than for water. Water flows from the water-saturated (washed) part of the formation into the well without displacing oil. This reduces reservoir coverage by water flooding and leads to the withdrawal of large volumes of water.

 The aim of the invention is to increase oil recovery by increasing the coverage of the formation by water flooding while reducing the selection of associated water.

 This goal is achieved by the described method, including drilling production and injection wells, selection of products from production wells, the creation of a system for monitoring and regulating the pressure between the oil and aquifer parts of the reservoir.

 New is that the pressure in the reservoir is maintained at a level that ensures the establishment of a static level in the estuary zone of the producing well, and oil is periodically taken from this zone.

 Figure 1 shows the section of the reservoir, which is at a late stage, when the well is flooded due to the formation of a bottom water cone.

 In FIG. 2 is the same as in FIG. 1, in the mode when the well is stopped for gravitational separation of oil and water.

 In FIG. 3 is the same as in FIG. 2, in the mode of oil selection from the wellhead zone.

 The method is carried out in the following sequence.

 A section of the reservoir having a waterlogged formation with residual oil reserves concentrated in the roofing part of the structure is operated by a producing well. The site was exploited in the initial and subsequent stages of development at a reservoir pressure close to the initial one, i.e. equal hydrostatic, mechanized way with the descent of the deep pump into the bottom of the well.

 In the process of drilling and operating wells, wells are examined, the parameters of the formation and the fluids saturating them are determined. Measure formation pressure. Well production samples are taken. The method is applicable when the specific gravity of the oil is less than the specific gravity of the bottom water.

 As the development of the deposit, the water cut of the producing wells increases and reaches 90-99%. In the selection of products, hydrodynamic forces exceed gravity, so plantar water, displacing only part of the oil, enters the well. A bottom water cone forms, which prevents oil from entering the well. Plantar water due to lower filtration resistances of the washed part of the reservoir enters the well. The well selects products with a large percentage of water. The process of exploitation of the reservoir becomes ineffective.

 According to the results of the study, they begin to implement the method.

 The well is stopped and a static level is measured. If the well overflows, then the injection of water into the injection wells is limited. At a low static level, increase injection volumes. If there is a connection with the marginal region and the energy characteristic of the formation allows you to maintain a static level in the wellhead, then there is no need to control the injection volumes.

 Having established a static level in the wellhead zone, it stops at gravitational phase redistribution in the well-formation system. Previously, the underground equipment (pump) for production is dismantled from the well, filling fluid is removed from the wellbore, the reservoir is mastered with a swab on the rope.

 Due to the greater specific gravity, the bottom water located in the wellbore and in the cone will tend to occupy the lower part of the formation, and the oil will “float” and advance to the selection zone. The flow of water into the bottom of the formation creates a force that squeezes the oil into the well. It is known that buoyancy forces equal to the product of the difference between the specific gravities of water and oil and the height of the column of water in the wellbore act on oil in the bottom-hole zone of the well.

 Having a lower specific gravity, oil in the well also floats due to gravitational forces and occupies its upper part, i.e. I bring it to the mouth. The establishment of a static level in the immediate vicinity of the mouth is associated with greater potential energy for the gravitational separation of oil and water. Using the wellbore from the mouth as a reservoir for sludge and accumulation of oil allows you to select anhydrous oil with low energy costs for its pumping and use non-metal-intensive equipment for production.

 The well is transferred to periodic work. The time required for the accumulation of oil depends on the reservoir and physico-chemical properties of the reservoir and oils, the ratio of the specific gravities of oil and water. To accelerate the separation of oil and water, it is possible to use downhole and bottom-hole formation treatment with demulsifiers and chemical reagents used in oil production. The specific amount of oil accumulation time is determined in the field. The well is equipped with a sensor for measuring the oil-water section in the well. After the oil-water section in the well reaches a certain level, oil is pumped out until water appears. The method of oil production depends on the rate of oil accumulation; therefore, various types of oil extraction can be used: swab on a rope, pump, etc. Oil produced can be transported by fuel trucks, pumped to an oil pipeline line, etc. After oil extraction, bottom water is again pulled to the well. The well stops at the accumulation of oil. Plantar water enters the roof of the formation and displaces oil into the producing well. Then the cycles of selection and accumulation of oil are repeated. Waterflood coverage increases without associated water withdrawal.

An example of a specific implementation. The section of oil deposits with bottom water (see Fig. 1) is operated by a producing well. Products are selected from a carbonate formation with a total thickness of 45 m, incl. oil saturated 15 m, water saturated 30 m. According to the well survey, it was found that the oil reservoir is confined to the anticline with the formation roof marks in the well of 900 m.The reservoir has an active marginal area, therefore it is developed under natural water pressure conditions. During the drilling process, a core was selected. According to the results of the core study, the formation parameters were determined by which the oil reserves were calculated. In the area of this well is concentrated - 240 thousand tons of balance reserves. An oil sample was taken. Oil has a low gas content. The specific gravity of oil is 850 kg / m ³ , water - 130 kg / m ³ .

 The deposit was developed without maintaining reservoir pressure in a mechanized way. The static level is at the level of 80 m from the wellhead. After the selection of 48 thousand tons of oil, the current water cut of the production of production wells reached 99.8%. The results of a well study showed that the residual reserves are confined to the roofing part of the formation and most of them are associated with low-amplitude elevations of the structure.

 The development of the deposit has reached the limit of cost-effective operation. The oil production rate of the well is 0.05 t / s, and the fluid rate is 25 t / s.

For gravitational separation of oil and water in the well-formation system, the well was stopped. Pumping equipment raised to the surface. We lowered the tubing, pumped the filling fluid with a swab on the rope, that is, mastered the formation. The well was equipped with a controller to determine the rate of gravity redistribution of oil in water and its accumulation in the well. Measurements were taken to beat the oil-water section. For three days, a 250 m high oil column was installed in the well, which at a 6 '' production casing amounted to 4.5 m ³ (Fig. 2). Based on the results of the study, the depth of descent of the combined pump was determined and a well operation program was established for pumping anhydrous oil. A pump was lowered into the well to a depth of 300 meters (Fig. 3). Made a selection of oil. During the year, 100 oil pumping cycles were performed, which amounted to 450 tons. Over the entire life of the reservoir, 58 thousand tons of oil were taken, which led to an increase in oil recovery by 4% (table).

 40 million rubles were spent on the annual selection of additional oil. The value of additional oil amounted to 0.43 million rubles / t • 450 tons = 193 million rubles. The economic effect for 1 year per well amounted to 153 million rubles.

Claims (1)

 A method of developing a water-oil deposit, including drilling production and injection wells, selecting products from production wells, creating a system for monitoring and regulating the pressure between the oil and aquifer parts of the formation, characterized in that the pressure in the formation is maintained at a level that ensures the establishment of a static level in the wellhead zone of the producing well, and oil is periodically taken from this zone.

Images