RU2179239C2 - Method of well completion - Google Patents

Abstract

FIELD: methods of mineral recovery. SUBSTANCE: method includes perforation of well walls and creation of differential pressure. Preliminarily, mechanical properties of formation ground samples are tested, and rated value of differential pressure required for changing the ground structure to increase its permeability in well surroundings is determined. During perforation or after it, differential pressure is built up with value not less than raised one and maintained said value until well is changed to operating conditions. Preferably differential pressure shall be maintained within rated value until cessation of fluid output. Proposed method is used for recovery of oil, water, gas-condensate, etc., in well completion. EFFECT: higher efficiency of well production rate increase. 2 cl, 4 ex

Description

 The invention relates to methods for extracting minerals and can be used to extract oil, water, gas condensate, etc. from the earth's crust. in the development of deposits.

 A well-known method of development and overhaul of wells, aimed at increasing the flow of fluid, including the descent into the well of equipment that allows perforation and stimulation of productive zones by increasing the pressure before breaking the surface of the well, and performing appropriate operations using this equipment (see the description of the patent U.S. N 5615739, 166-306, 1997 [1]).

 A disadvantage of the known method is its low efficiency, since its implementation does not take into account the mechanical properties of the soil in the reservoir and situations are possible where perforation and the proposed method of stimulation of the reservoir zones will not increase the flow of fluid or provide only a slight short-term increase.

 A known method of processing the bottom-hole formation zone (PZP), used to increase the flow of fluid (see the description of the patent of the Russian Federation N 2029078, E 21 In 43/25, 1995 [2]). The known method provides for repeated cycles of "depression - repression" with the injection of an acid solution in the PPP. The disadvantage of this method is the limited application, since it is effective only in carbonate reservoirs. In addition, the use of acidic environments leads to accelerated corrosion of downhole equipment.

 Closest to the claimed in its technical essence is a method of well development, known from the description of the patent of the Russian Federation N 1572084, E 21 In 43/11, 1996 [3]. The known method provides for perforation of a well during depression created by a jet pump, and exposure to the formation by alternating pressure by successively creating depression and repression on the formation. Moreover, if depression is created using a jet pump, then repression is achieved by pumping the working fluid into the under-packer zone through the insert of the jet pump with the check valve open. The disadvantage of this method is the complexity of the implementation, because it requires repeated cycles of processing the PPP and recording the pressure recovery curve after each of them, limited use (only for unstable plastic formations in the context), low efficiency, because the choice of the magnitude of depression is not justified by a preliminary study of the mechanical properties of the soil of the reservoir to determine the magnitude of the depression at which structural changes in the soil of the bottomhole formation zone occur, leading to an increase in its permeability. The purpose of the method is only to clean the bottomhole zone from solid particles and liquids that penetrated into the bottomhole zone during the construction of the well and worsen its filtration properties.

 The inventive method is aimed at increasing the efficiency of increasing the flow rate of wells.

 The specified result is achieved by the fact that the method of well development includes perforation of the walls of the well and the creation of depression, while preliminary investigating the mechanical properties of soil samples from the formation and determining the amount of depression necessary to change the structure of the soil, leading to an increase in its permeability in the vicinity of the well, during perforation or after it, a depression is created no less than calculated and maintained as such until the fluid production rate increases, and then the depression is reduced to operational values.

 The indicated result is also achieved by the fact that the value of depression no less than calculated is maintained until the increase in the flow rate of the fluid ceases.

Distinctive features of the proposed method are:
- a preliminary study of the mechanical properties of soil samples from the reservoir and determining the magnitude of the depression necessary to change the structure of the soil, leading to an increase in its permeability in the PPP;
- the creation in the process of perforation or after it of the magnitude of the depression is not less than the calculated, obtained on the basis of the study of soil samples;
- maintaining depression not less than calculated until the fluid production rate increases;
- maintaining depression at the same level until the cessation of the increase in fluid production.

 A preliminary study of the mechanical properties of soil samples from the formation and determining the amount of depression necessary to change the structure of the soil, leading to an increase in its permeability in the bottomhole formation zone, reduces the complexity of the method and ensures high efficiency, since the parameters of the impact on the formation are determined in advance in the laboratory, leading to an increase in flow rate, instead of repeatedly repeating these effects directly at the well until a result is achieved at, as provided for in the known method [3].

 The creation in the process of perforation or after it of a depression value no less than calculated, the value of which is obtained on the basis of the study of soil samples, allows us to achieve the desired result, since with the calculated values of depression structural changes in the soil will already occur in the PPP, as a result of which its permeability and therefore, fluid influx, and with depressions no less than calculated, these changes will occur for sure.

 Maintaining depression at a level equal to or greater than the calculated one, before increasing the flow rate of the fluid, is necessary to ensure the passage of structural transformations in the soil, leading to an increase in its permeability. An increase in fluid flow rate will mean that these changes in the soil have already occurred. Moreover, it was experimentally established that, when modeling conditions in the bottom-hole zone for samples with depression of a certain level, in some cases, structural changes leading to an increase in soil permeability were associated with the destruction of samples, for example, for rocks such as oil-bearing sandstones of Lovinsky, Symoryakhsky, Tevlino-Russkinskoye deposits (NK LUKOIL), carbonates of the North-Dolginsky structure of the Timan-Pechersk basin (Gazprom), and in some cases there was a sharp increase in the permeability of the sample during Anenii its solidity, for example, carbonates Tengiz (Kazakhstan).

 Since, depending on the properties of the soil, structural changes in the PPP with established depression can occur from a few minutes to several hours, it is advisable to maintain the depression at a level equal to or higher than the calculated one in particular cases until the increase ceases fluid flow rate. The cessation of the increase in fluid flow rate means that all possible changes in the soil of the bottomhole zone have already occurred and further maintenance of depression at a given level loses its meaning.

 The essence of the proposed method is illustrated by examples of its implementation.

 Example 1. In the General case, the method of well development is implemented as follows.

 Samples in the form of cubes were made from cores extracted during the drilling of this or an adjacent well from the reservoir area to study their mechanical and filtration properties. The studies were carried out on a hydraulic press, which provides modeling of conditions in the bottomhole zone by independent triaxial loading with strain measurements along three axes. Simultaneously with the loading of the sample, air was supplied through its two opposite faces at a pressure not exceeding 1 atm, its flow rate was measured, and rock permeability was calculated. The loading of the sample was carried out in such a way that stresses arising in the rock corresponded to the conditions in the BCP with increasing depression in the well. By a sharp increase in the rate of deformation of the sample or a sharp increase in air flow, the moment of change in the structural characteristics of the soil, which increase the permeability, was established, and the value of the depression leading to such a change was established. The well was equipped with well-known means to maintain the pressure at the bottom of the well below the reservoir oil pressure. In special cases of implementation, a jet pump was used as such a means. A perforator was lowered into the well to carry out the perforation procedure. The necessary depression was created in the well either immediately before perforation, or after perforation. Then, the set value of the depression was kept approximately constant when monitoring the well flow rate until the flow rate increased or its growth stopped.

 This method is applicable for well development for both open-hole and cased wells. Perforation can be carried out using any known means.

 The perforation intended to establish a hydrodynamic connection between the cased well and the formation and transfer the depression to the formation in the open hole stimulates the onset of the process of structural changes in the bottomhole formation zone.

 The nature of the perforation is the density of the holes, their size, shape, etc. - can be determined by calculation based on the properties of the soil.

 Example 2. The method of well development was implemented at well N 7192 K-35 of the Symoryakhskaya area, mastered by the Uraineftegaz TPP. The well is cased and cemented to the bottom at a depth of 2450 m.

 Samples in the form of a cube with a face size of 50 mm were made from cores extracted from the productive formation of the neighboring well N 7172, while one of the cube axes coincided with the core axis, and the other two were oriented randomly. In the process of examining the samples in a hydraulic press, it was found that when the samples were uniaxially compressed, corresponding to the conditions on the borehole wall with a depression of about 100 at, they begin to deform intensively, and deformation is accompanied by a change in the structure of the rock, its disintegration, and increased permeability. The samples eventually crumbled.

In the interval of the reservoir 2404 - 2442.5 m perforation was performed. Using the UGIS-5 jet pump installed in well N 7192, a depression was created at the bottom of the well, the value of which was constantly monitored using a depth gauge. At the same time, the volume of fluid obtained from the well was measured, and its flow rate was determined. In order to verify the correctness of the data on the magnitude of the necessary depression previously obtained on the basis of the study of soil samples, its value was increased stepwise. Three modes were sequentially worked out for three hours each: with a depression of 30 at, a flow rate of 0.514 m ³ / day was obtained, with a depression of 60 at - 1.371 m ³ / day, with a depression of 100 at, the production rate increased during the development of the regime, the average production rate over 3 hours amounted to 11.314 m ³ / day, which became evidence of the correctness of the selected value of depression. After three hours, the jet pump was turned off and the well was put into production mode.

Example 3. The method is implemented at well N 7172 of the Symoryakhskaya area, which is located at a distance of about 1 km from well N 7192. Well 7172 was equipped in the same way as well N 7192, and all actions were carried out on it, as indicated in example 3 , except that the depression of 100 atm was kept constant for 5 hours. It was found that the flow rate of the fluid increased during the first four hours and ultimately amounted to 24.647 m ³ / day. Since there was no increase in flow rate in the next hour, it was decided to turn off the jet pump and put the well into production mode.

 Thus, the proposed method allows to cause an increased flow of fluid due to changes in the structure of the soil and therefore is applicable to any type of fluid.

Claims (2)

 1. The method of well development, including perforation of the walls of the well, creating depression and measuring flow rate, characterized in that the mechanical properties of the soil samples from the formation are preliminarily examined and the estimated amount of depression necessary to change the structure of the soil, leading to an increase in its permeability in the bottomhole formation zone, is determined , during or after perforation, a depression of at least calculated is created and maintained before the well is put into operation.  2. The method according to p. 1, characterized in that the magnitude of the depression is not less than the calculated support until the termination of the increase in fluid flow rate.