RU2644997C2 - Method for surveying wells in cluster accommodation - Google Patents

Abstract

FIELD: oil and gas production industry.

SUBSTANCE: invention relates to the oil and gas production industry and can be used for gas-hydrodynamic survey and operation of gas, gas condensate and oil wells. Method includes measuring the flow rate, formation, bottomhole and wellhead pressures, temperatures at the wellhead of the i-th well, where i = 1, 2, 3, …, n, on each of the modes operating simultaneously into the cluster well pipeline, for each of which the coefficients of the filtration resistance A and B are determined. In this case, up to (n-1) simultaneously operating cluster wells are sequentially disconnected from one of the cluster wells selected randomly, and curves of dependence of the quadratic depression and its ratio to the production rate from the production rate are plotted for the cluster wells at different modes, along which the coefficients of the filtration resistance A and B are determined.

EFFECT: technical result of the invention consists in the expansion of functionality, which involves the ability to survey wells located in the cluster, while simultaneously working in the well pipeline, which, in turn, improves the accuracy of obtained data and extends the range of well survey, as well as reduce the period of surveying all cluster wells with increased productivity.

1 cl, 5 dwg, 6 tbl

Description

The invention relates to the oil and gas industry and can be used when conducting gas-hydrodynamic studies and operation of gas, gas condensate and oil wells.

The prior art method for gas-hydrodynamic research of wells (RF patent for the invention No. 2490449 C2, E21B 47/06, publ. 08/20/2013). The known method includes measuring pressure, temperature and fluid flow at predetermined well operating conditions, processing the results and determining the coefficient of quadratic resistance. In this case, the influence function and the coefficient of quadratic resistance are determined and the research period is set, it is divided into N time intervals, the duration of which depends on the characteristics of the well, the known properties of the influence function are set, and the equation for each interval is written. Then, the influence function and the coefficient of quadratic resistance are calculated by solving the system of equations and using the linear programming method, taking into account the specified properties of the influence function and subject to the minimum of the linear function F, determined by the corresponding formula. The disadvantage of this method is that conducting well research is accompanied by the release of products into the atmosphere, which leads to production losses. In addition, in a known manner, it is impossible to conduct studies of well clusters when they work in a train.

The prior art also knows a method for determining the productive characteristics of a gas reservoir (AS USSR No. 1104250 A1, E21B 47/00, publ. 07.23.1984). The known method includes measuring the flow rate and bottomhole pressure of the well and the subsequent determination of the coefficients of the filtration resistance of the bottomhole zone. Measurement of flow rate and bottomhole pressure in the known solution is performed once in the operating mode of operation of the well. Then determine the coefficient of the statistical relationship between the coefficients of the filtration resistance according to the results of previous measurements of flow rate and bottomhole pressure in the wells of a given formation or similar and calculate the productive characteristics of the formation. The known solution has several disadvantages:

- low productivity and accuracy of studies associated with the fact that the measurement of operating parameters is performed once in the operating mode of the well;

- release of products into the atmosphere leads to product losses;

- the impossibility of conducting research well clusters when they work in a train.

The closest in technical essence to the present invention is a method for group research of cluster gas and gas condensate wells at stationary filtration modes (RF patent for the invention No. 2338877 C1, ЕВВ 47/10, publ. 20.11.2008). The known method includes stopping the well, measuring the static pressure at the wellhead and reservoir pressure, starting the well into the gas collector and measuring the gas flow rate in several modes of operation by the method of variable differential pressure across the constriction device. Further, the method provides for: measuring dynamic pressure at the wellhead and bottomhole pressure in each mode, taking a pressure stabilization curve and pressure recovery curve, measuring gas temperature at the bottom and wellhead in each mode and determining the filtration resistance coefficients A and B. In this case, the studied wells are divided pairs with the maximum degree of overlap of the supply circuits, and each of the wells in the pair is assigned to different groups. At the same time, two groups of wells, consisting of pairs of the same name, are being examined. One group is investigated in reverse modes with a decrease in flow rate to a complete stop, and the other in forward modes with an increase in flow rate to the maximum permissible value. Then the direction of change in flow rate in both groups is reversed. At the same time, the total production rate of each pair of wells and the total production rate of the well are controlled, keeping them close to constant values for each pair of wells with an accuracy of 30%, and for a plume with an accuracy of 10%. The well-known solution has increased accuracy of the data and a shorter period for the study of all wells in the cluster. However, the known solution has disadvantages, which include: dividing the wells into pairs having a maximum degree of superposition of the power circuits; the impossibility of obtaining a full-fledged indicator characteristic while maintaining the total production in the cluster, since only two groups of wells are examined at a time when no more than three modes are carried out; in addition, for conducting studies using the known method, it is necessary to have a regulation (reduction) system at the wellhead for stepwise changing the operating modes of the studied group of wells.

The problem to which the invention is directed, is to develop a method for researching wells during cluster placement.

The technical result of the invention is the expansion of functionality, which consists in the possibility of conducting research of wells located in the cluster, while simultaneously working in a loop, which, in turn, allows to increase the accuracy of the data and expand the range of well research, as well as reduce the time required for all well wells with increased productivity.

The essence of the proposed method is as follows. According to the proposed method of researching wells at a wellhead location, they measure flow rate, formation, bottomhole and wellhead pressures, temperature at the mouth of the i-th well of the well, where i = 1, 2, 3, ..., n in each of the modes that simultaneously work in the plume of well wells , for each of the modes, the filtration resistance coefficients A and B are determined. In the well, randomly selected from one to (n-1) simultaneously working wells of the well are sequentially shut off. Then, the curves of the dependence of the quadratic depression and its relation to the flow rate from the production rate for the wells in various modes are constructed, which determine the filtration resistance coefficients A and B.

The research method can be used to control the current productive characteristics of the wells. The initial values of the coefficients of filtration resistance, reservoir pressures are determined according to standard primary studies during well development, on the basis of which a gas-dynamic model of the well is created, including models of the bottom-hole zone, well bores and their piping.

The method of researching wells during cluster placement is as follows.

Preliminary readings of the values of reservoir, bottomhole and wellhead pressures, temperatures at the wellhead and measure the flow rate at each of the wells in the bush, working in a loop. Then, at least one of the wells is closed and new readings of the values of reservoir, bottomhole and wellhead pressures, temperatures at the mouths and flow rates of operating wells are taken. At least one more well is closed or a closed well is put into operation and at least one more well is closed. Take new readings of pressure, temperature and flow rates. By closing and opening wells, the required number of values of the parameters of pressures, temperatures and flow rates of the wells are obtained. When one of the wells or several wells is stopped, a change in the regimes occurs in which there is an increase in gas production in the remaining working wells of the cluster.

Processing the research results for each individual well can be performed by known methods, it is advisable to determine the linear and quadratic coefficients of the filtration resistance or to process the results according to the known exponential dependence (see, for example, the Guide to well research, A.I. Gritsenko, Z.S. Aliev, O. M. Ermilov, V. V. Remizov, G. A. Zotov, editor-in-chief E. N. Ivakin, Moscow, Nauka, 1995, p. 186-188).

The proposed method of gas-dynamic research can be illustrated by the example of a well consisting of seven wells. The invention is illustrated in tables 1-6 and the drawings shown in FIG. 1-5, which shows graphs of the dependence of the quadratic depression and its relationship to flow rate from flow rate for randomly selected from the first to fifth wells of the bush. Table 1 shows the technological parameters of the seven wells in the cluster operating in four different modes. Tables two to six show the results of processing studies of wells 1, 2, 3, 4, 5 in the third and fourth modes. Similarly, you can get the indicator characteristics of the sixth and seventh wells, turning off, for example, wells 1 and 2 or 3 and 4. For the four modes considered in table 1, the total flow rate of all the wells in the cluster working in one loop remains unchanged (Q _cc = 5644 thousand m ³ / day), the pressure in the loop at the modes differs.

In FIG. 1-5 and in tables 1-6 the following abbreviations and designations are adopted:

Q is the gas flow rate (thousand m ³ / day);

ΔP ² = P _PL ² -P _s ² where ΔP ² is an indicator of the quadratic depression, determined by the difference between the squares of the reservoir and bottomhole pressures P (at ² );

ΔР ² / Q is the ratio of the quadratic depression indicator to the flow rate (at ² ⋅ days / thousand m ³ ).

The technological parameters of the well’s wells (Table 1) are determined on the basis of the technological report of the well’s work and the gas-dynamic model of the well. For the four modes considered (1 - operating, 2 - well No. 7 is turned off, 3 - wells No. 6 and 7 are turned off, 4 - wells No. 5, 6 and 7 are turned off), the total flow rate of all cluster wells operating in one loop is maintained unchanged (Q _kus = 5644 thousand m ³ / day), and the pressure in the loop in the modes differs.

.Referring to FIG. 1-5 graphical dependences in the coordinates ΔР ² on Q serve to determine the correction factor "C", which characterizes the influence of various factors (the presence of fluid in the well, the non-stabilization of operating modes, etc.) on the accuracy of taking points on the research modes. Correction factor C takes on a value corresponding to the quadratic depression at the intersection of the curve with the vertical axis. In our case (see Fig. 1-5), the coefficient "C" is zero. The graphical dependence in coordinates (ΔР ² ± C) / Q on Q has a plus or minus sign depending on the value of the coefficient "C". For the research, the coefficient "C" takes a zero value, therefore, the graphical dependence in the coordinates ΔР ² / Q of Q has a linear dependence (kx + b). For well No. 1, the ratio of the quadratic depression indicator to the production rate has the form ΔP ² / Q = 0,0003Q + 0.1284. Thus, the filtration resistance coefficient A (linear coefficient) characterizes the value of 0.1284 (the intersection of a straight line with the vertical axis ΔP ² ). The filtration resistance coefficient B (quadratic coefficient) characterizes the value of Q, i.e. 0.0003 (tangent of the angle of inclination of the line to the horizontal axis Q). Thus, the values of the filtration resistance coefficients are: A = 0.1284; B = 0.0003. Knowing these coefficients, one can obtain the entire productive characteristic of the well (the dependence of gas production on depression to the formation), for example, by the formula of gas inflow to the well:

.

Claims (1)

A method of researching wells during cluster placement, including measuring flow rate, formation, bottomhole and wellhead pressures, temperatures at the mouth of the i-th well, where i = 1, 2, 3, ..., n, in each of the modes simultaneously working in the plume of well wells, for each of which the filtration resistance coefficients A and B are determined, characterized in that in the well they are sequentially disconnected from one well selected to (n-1) simultaneously working wells of the well, the curves of the dependence of the quadratic depression and its relation to the flow rate are built from the flow rate for the well wells in various modes, which determine the filtration resistance coefficients A and B.

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