RU2258137C1 - Survey performing and survey result interpretation method for well opened-up oil-and-gas bed - Google Patents

Abstract

FIELD: oil production industry, particularly to determine initial data necessary for 3D computer oil-and-gas bed development modeling.

SUBSTANCE: method involves drilling vertical, horizontal or inclined well; opening oil-saturated interval of oil-and-gas bed; performing well survey in unsteady regime along with providing oil extraction regime with minimal possible well pressure, which results in artificial gas pollution and watering of extracted product. Well survey is performed under control of well pressure dynamics and oil, water and gas discharge of the well. Fluid saturation along well bore within the limits of opened interval is also measured. The obtained data are used to determine permeability index in longitudinal and transversal bedding directions, porosity, skin-factor, oil, water and gas mobility edge, powers of functional dependence of oil, gas and water relative permeability. Method is performed along with periodical well shutdown and following well starting-up is carried out under minimal possible well pressure.

EFFECT: increased accuracy and reliability of bed parameters, relative permeability for oil, gas and water determination.

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Description

The present invention relates to the oil and gas industry, in particular to the definition of the source data necessary for the design of the development of the oil and gas reservoir.

A known method of researching an oil well under unsteady filtration conditions, including operating the well for a long time with constant oil production and shutting it down to remove the bottomhole pressure recovery curve, which is used to determine reservoir properties of the formation (see Basniev K.S., Kochina I .N., Maksimov V.M .: Underground hydromechanics. Ed. Nedra, 1993, p.156-159).

The disadvantages of this method are the following:

- the method is applicable in the absence of a gas cap and bottom water;

- allows you to determine a limited number of parameters, as it is based on the theory of single-phase, one-dimensional filtration.

Closest to the proposed is a method for investigating a well that has discovered an oil and gas reservoir, including investigating a well under steady-state filtration conditions (see I. Zakirov, Combined inflow of gas, oil, and bottom water to a well. Oil industry, No. 2, 1988, p. 39 -42) in order to obtain indicator charts for oil, gas and water.

The disadvantages inherent in this method are

- hard-to-reach in practice steady-state inflows of oil, gas and bottom water to the well;

- the proximity of the mathematical formulation of the problem, which does not allow to determine the formation parameters necessary for the design of the development of the oil and gas reservoir.

The present invention is based on the task of creating a method for researching and interpreting the results of a well study that has uncovered an oil and gas reservoir, which allows finding reservoir parameters necessary for designing a development. In this case, the well may be vertical, horizontal, inclined in design.

The fulfillment of the task is achieved by the fact that in the method of researching a vertical, horizontal, deviated well that uncovered an oil and gas reservoir, an oil production mode is created at the lowest possible bottomhole pressure, leading to artificial and accelerated gas contamination and watering of the recoverable products, i.e. the implementation of near-well multiphase, multidimensional (3D) filtration of formation fluids, as well as the fact that

- in the process of well research, they monitor the dynamics of bottomhole pressure, oil flow rates for oil, water and gas, measure fluid saturation along the wellbore within the opened interval;

- the theory of multiphase, multidimensional filtration is used to describe the filtration processes in the reservoir; the inverse problem of identifying reservoir properties based on the results of a well study is formulated in an optimization statement and numerical methods and methods of optimal control theory are used to solve it;

- to increase the degree of reliability of the identified parameters, the well is shut down and the studies are repeated at the lowest possible bottomhole pressure.

The method is as follows.

After drilling the well, lowering the production casing, cementing and perforating it, and developing the well, a depth gauge is lowered to its bottom. The wellhead is tied in such a way that it is possible to continuously measure the flow rates of the well in oil, gas and water.

The well is put into operation at the lowest possible bottomhole pressure. As a result, the extraction of oil with dissolved gas begins, and then the extracted products are gassed with gas from the gas cap and flooded with bottom water. As you know, this is a consequence of the formation of gas and water cones.

From the moment the well is put into operation at the lowest possible bottomhole pressure, the initial reservoir pressure, current bottomhole pressure, and oil, gas and water flow rates are measured at different times. Using methods of field geophysics, the intervals of formation fluid inflow are monitored and the fluid saturation profiles are taken at different time points.

The results of the artificially created multiphase, multidimensional filtration flow carry extensive information on reservoir properties of the formation in three-dimensional (3D) space, including phase permeabilities important for theory and practice of development for oil, gas, and water, as well as information on the anisotropy of reservoir properties.

A three-dimensional (3D) gas-hydrodynamic model of the reservoir is created for the zone around the investigated well. This means that all a priori known data are specified about the features of the geological structure of the considered element of the formation, its filtration and capacitive parameters, relative phase permeabilities (RPP) for oil, gas and water, initial pressure and temperature, as well as the dependences of the properties of oil, gas and water from pressure. The 3D model of the reservoir element also incorporates the design characteristics of the well, including its tracing in 3D space. The dimensions of the formation element are selected so that the disturbance from the start-up of the well does not reach its boundaries.

The created 3D gas-hydrodynamic model of the formation is approximate. For it was created with unreliable parameters of the reservoir and RPP for oil, gas and water. Now this 3D model is undergoing a procedure of adaptation to the actual data of well exploration. This means that identification of the formation parameters and RPP for oil, gas and water are subject to minimization of the quality functional. The search for the desired parameters and RPT is performed using numerical methods and gradient procedures. Moreover, the methods of the theory of optimal control allow us to determine the values of functional derivatives, i.e. derivatives of the quality functional in the required parameters. For this, it is necessary to solve not only the direct 3D multiphase problem as applied to the considered element of the formation and the well under study, but also the 3D problem of the same phase coupled to it.

Finding the desired parameters and dependencies is based on

- Actual data on pressures, flow rates, saturations obtained as a result of research work at the well;

- solving an adequate inverse problem of the theory of filtration.

As a result of solving the inverse problem, it is necessary to find the value of the permeability of the formation along (k) and across the bed (k ₂ ), the porosity coefficient (m), the oil saturation coefficient (S _H ), the skin factor (S), the reservoir elastic coefficient (β ^* ) for oil saturated zone, relative phase permeabilities for oil (k _H ^* ), water (k _B ^* ) and gas (k ^* _g ), including threshold saturation values for oil (S ^* _H ), water (S _B ^* ) and gas (S _g ^* ).

Due to the large number of parameters and dependencies sought, the inverse problem is formulated as an optimization one. As a minimized functional, the following

Here P _with - bottomhole pressure in the well; Q _B - well flow rate in water; q _{g is the} gas production rate of the well; α ₁ , α ₂ , α ₃ , α ₄ - normalization and weight coefficients; t is the time; T - time study wells.

It is accepted that multidimensional, multiphase filtration of formation fluids is described by a system of partial differential equations known in underground gas-hydrodynamics. To solve this system of equations, initial and boundary conditions are specified. The initial conditions characterize the unperturbed state of the formation at t = 0 and they reflect the initial vertical and vertical distribution of pressure and fluid saturation. The boundary conditions at the boundaries of the distinguished element of the reservoir reflects, for example, the fact of the impermeability of these boundaries. As the boundary condition at the well, the measured dependence q _n = q _n (t) is set.

The statement and the algorithm for solving such inverse problems are described in the monograph: ES Zakirov: Three-dimensional multiphase problems of forecasting, analysis and regulation of oil and gas field development. Ed. Grail, 2001, 302 pp.

In this way, a directed search is performed for the required parameters and RPP, which best approximate the actual measured and calculated dependences of the time variation of the characteristic parameters of the well research process.

In order to increase the degree of reliability of the determined parameters and dependencies, periodic shutdowns of the well are carried out. At the next start-up of the well, the minimum possible bottomhole pressure is again set.

Thus, for the first time, a high-tech method of researching a well that has discovered an oil and gas reservoir is proposed, which allows one to find all the initial parameters and dependencies necessary for drawing up a development project. High technology is determined

- deliberate creation of a three-dimensional, multiphase filtration flow near and at the bottom of the well;

- conducting extensive monitoring of the flow of three fluids to the well;

- determination of the whole complex of initial parameters and dependencies based on the solution of the inverse 3D multiphase problem of the theory of filtration in an optimization formulation using numerical methods and methods of the optimal control theory.

An example implementation of the proposed method

The reliability and legitimacy of new approaches to the study of wells and reservoirs is established by adequate mathematical experiments. This approach was adopted by the authors to prove the validity of the proposed method for researching wells. To this end, the following results of a mathematical experiment are presented.

Figure 1 presents one quarter of the element of the reservoir oil and gas deposits. Element dimensions along the OX, OY, OZ axes are 500 m × 500 m × 50 m. Gas, oil and water saturated formation thicknesses are 20, 10, 20 m, respectively. The porosity coefficient is 20%, the permeability coefficients along the OX, OY, OZ axes are 500, 500, and 50 ppm respectively. The initial viscosity of oil, gas and water in reservoir conditions are 0.44, 0.024, 0.34 cP, respectively. The accepted dependences of the RPT for oil, gas, and water are shown in FIGS. 2-5 in the form of solid lines.

In these figures, the dependences of the RPT for oil, gas, and water taken as initial in the identification problem are presented in the form of lines with circles. The actual and revised RPTs for oil, gas and water in FIGS. 2-5 are given as solid lines and triangular icons, respectively. At the same time, with high accuracy (with an error of not more than 1%), all other desired parameters of the reservoir were also determined, which were initially set from a priori data and representations.

Thus, the results of the above and other mathematical experiments testify to the validity and reliability of the proposed technology for researching a well that uncovered an oil and gas deposit, and an algorithm for solving the problem of identifying research results in order to find the desired parameters of the formation and RPP for oil, gas and water.

Claims (3)

1. The method of research and interpretation of the results of a study of a well that has discovered an oil and gas reservoir, including drilling a vertical, horizontal or inclined well, opening an oil-saturated interval of a reservoir of an oil and gas reservoir, conducting a well study in an unsteady mode, characterized in that they create a mode of oil production at the lowest possible bottom hole pressure , leading to artificial gas contamination and watering of recoverable products, in the process of exploring the well, control the dyne bottom hole pressure, oil flow rates, oil and water and gas measurements of fluid saturation along the wellbore within the opened interval, use the data to determine permeability coefficients along and across the bedding, porosity, skin factor, mobility thresholds for oil, gas and water , degrees of functional dependences of relative phase permeabilities for oil, gas and water. 2. The method according to claim 1, characterized in that, in order to increase the degree of reliability of the determined parameters and dependencies, periodic shutdowns of the well are carried out, and the next time the well is put into operation, the lowest possible bottomhole pressure is set again. 3. The method according to claim 1 or 2, characterized in that the determination of all the required parameters is carried out on the basis of solving a 3D multiphase identification problem in an optimization statement using an iterative procedure, numerical methods and methods of optimal control theory.

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