RU2505802C1 - Method for quantitative determination of rock samples water-saturation using values of initial and final water-saturation - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: there performed is a core sample preparation, modelling of core sample reservoir conditions, joint filtering of salt water and oil through core sample, measurement of intermediate intensiveness of X-rays passed through the sample during filtering and determination of water-saturation by expressions. Note that the intensity of X-rays passing the sample with initial and final water-saturation is measured, the reference signal is obtained. The value of residual water-saturation is obtained after filtering experiment of water evaporation from the sample at 110-160°C. The values of initial, residual water-saturation and reference signal are used for determination of intermediate water-saturation via certain mathematical relation.

EFFECT: reduction of time for core water-saturation measurement, increase of water-saturation values determination accuracy.

3 cl, 1 dwg

Description

The invention relates to the field of the petrochemical industry and can be used in field and research laboratories for the development of technologies for increasing oil recovery and in the calculation of oil reserves, operational monitoring of the development of oil fields.

The proposed method is applicable in experiments to determine the dependence of the relative phase permeability coefficients of water and oil on water saturation under conditions close to reservoir conditions (OST 39-235-89). The relative phase permeability coefficients are used in the development of oil field exploitation projects.

A known method for determining the water saturation of a core is carried out by co-filtering mineralized water and oil through a core sample and measuring the intermediate intensity of the x-ray radiation transmitted through the sample during the filtering process, measuring the x-ray intensity at 100% water saturation, and measuring the intensity of the x-ray transmitted through dry sample and determination of water saturation by dependence (Skripkin A.G., Schemelinin Yu.A. Patent for invention No. 2315978 Method for determining dividing the water saturation of the core. The priority of invention, September 14, 2006). This method requires additional measurements of the ratio of mass absorption coefficients of x-ray radiation in oil and mineralized water, in addition, in this method it is necessary to conduct an additional scan of a dry, saturated mineralized water by 100% of the sample, which significantly increases the measurement time.

A known method for determining water saturation using a polychromatic X-ray system with the control of the saturation of the reservoir rocks with liquids for the absorption of X-rays (Kuznetsov AM Scientific and methodological foundations and studies of the influence of the properties of reservoir rocks on the efficiency of hydrocarbon extraction from the bowels, Abstract of dissertation for the degree of Doctor of Technical Sciences, M., 1998), taken as a prototype. Data on the intensity of x-ray radiation is collected during the movement of the x-ray tube, the collimator and the detector as units of a cell along the horizontal axis of the sample from the input section to the output. Model reservoir conditions. The water saturation of the core collector rocks is calculated based on Lambert’s law using the linear semi-logarithmic dependence of x-rays measured at 100% saturation of the labeled fluid sample and 100% saturation of the unlabeled fluid according to the mathematical formula, for which the intermediate (current) intensity of the x-ray radiation transmitted through the sample is measured ; X-ray intensity at 100% oil saturation; X-ray intensity at 100% water saturation. In this case, the water phase can be labeled (sodium iodide is used as a label) and oil (the label is iodoctane). This method is methodologically complex, requires time-consuming procedures for saturating a sample with 100% sequentially labeled and unlabeled liquids for calibration. In addition, a comparative analysis carried out during the filtration of labeled water shows that the addition of a label (sodium iodide, potassium iodide, etc.) leads to a significant (up to 10%) change in the permeability of the test samples in water. This phenomenon is associated with a change in the wettability of the surface of the rock sample when exposed to labeled water. Also, some iodine-containing organic substances (iodoctane, octyl iodide) partially dissolve in water.

Another disadvantage of the described method is that for various models of x-ray apparatuses, the actually set values of the voltage and current of the x-ray tube differ from the set values by the amount determined by the discreteness of the digitization of the signal (quantum noise). In this regard, during sequential scanning of water-saturated rock samples several times, the average value of the detector signal, ceteris paribus, changes. Thus, when determining core saturation using several scans of samples, a systematic error appears.

The task is to develop an express and informative method for determining the water and oil saturation of core rocks in conditions close to reservoir (high pressure and temperature).

The technical result of the method is to reduce the time taken to measure the water saturation of core rocks, as well as to increase the accuracy of determining the water saturation values.

The technical result is achieved by the fact that in the known method for determining the water saturation of a core, including preparing a core sample, modeling reservoir conditions in a core sample, co-filtering mineralized water and oil through a core sample in various ratios, measuring the intermediate intensity of x-ray radiation passing through the sample during filtration and the establishment of water saturation using mathematical formulas, it is new that before the measurement, in the core sample the initial water saturation, scan the rock sample with the initial water saturation, moreover, the measured voltage and current of the X-ray tube are used in the measurement, a reference signal is obtained by scanning a metal plate located behind the rock samples, oil with the addition of iodobenzene (C6H5I) is used for filtration, ( the value of residual water saturation is obtained after a filtration experiment by evaporation of water) from a sample at a temperature of 110-160ºС, scans are performed ue rock sample with a final water saturation, then the initial values, final water saturation and the reference signal are used to determine water saturation of intermediate mathematical relationship:

where S _VN - the value of the initial water saturation of the sample, d.ed .;

S _VK - the final water saturation of the sample, d.ed .;

- сигнал детектора при просвечивании рентгеновским излучением образца керна с начальной водонасыщенностью и опорный сигнал;I _vn ,

- the detector signal when x-rayed through a core sample with initial water saturation and a reference signal;

- сигнал детектора при просвечивании рентгеновским излучением образца керна с конечной водонасыщенностью и опорный сигнал;I _VK

- the detector signal when x-rayed through a core sample with finite water saturation and a reference signal;

I, I ^on — detector signal during X-ray transmission of a core sample with intermediate water saturation and a reference signal;

The oil saturation of the sample is determined from the condition of fullness of the pore space:

The initial water saturation is set before the filtration experiment with an error of about 1%, for example, by methods on a semi-permeable membrane, centrifugation or water displacement by oil. The final water saturation is determined after the filtration experiment by evaporating water from the sample with an error of about 2%. The use in the calculations of known and specified with great accuracy the values of the initial and final water saturations allows to increase the accuracy and reliability of determining the water saturation values.

The use of a reference signal allows to reduce the systematic measurement error, which increases the accuracy of determining the water saturation values.

The refusal to scan a sample saturated with 100% mineralized water reduces the time for measuring water saturation.

The use of lower voltage and current values of the x-ray tube can significantly increase the life of the x-ray equipment. Oil-soluble and water-insoluble iodobenzene (C6H5I) is used to increase the absorption of x-rays in its mixture with oil. This increases the signal contrast when scanning water-saturated rock samples, which in turn increases the accuracy of determining oil saturation.

The proposed method is applicable in experiments to determine the dependence of the relative phase permeability coefficients of water and oil on water saturation under conditions close to reservoir conditions (OST 39-235-89).

The figure shows a graphical dependence of the comparison of water saturations determined by the resistance method and x-ray method.

Before conducting an experiment to determine the phase permeabilities in water and oil for a cylindrical rock sample (cemented sandstone) with a diameter of 30 mm and a length of 40 mm to 70 mm, the pore volume is determined (OST 39-181-85). The core sample is extracted and dried in a heating cabinet at a temperature of 100-110 ° C to constant weight. The sample is saturated under vacuum with produced water or a model of produced water and placed in a capillary meter. Create and measure the initial water saturation. Some of the pores not occupied by water are filled with a model of oil. For this, the sample is placed in kerosene, aged 23-25 hours, then the sample is placed in a viton cuff inside an x-ray transparent core holder. Oil is added to the sample with the addition of iodobenzene and the pressure in the samples is increased to feather pressure, while mineral oil is applied to the space between the core holder wall and the cuff, which creates a sample compression pressure. Crimp pressure is increased to a value of 3-5 MPa in excess of pore pressure. The core holder with the samples is heated to reservoir temperature. A metal (copper) plate 2-3 mm thick is fixed on the core holder wall to the core sample. The plate thickness is selected in such a way that when x-rayed through the rock sample and the plate, the signal value recorded by the detector is the same. In the next step, about 5 pore volumes of oil model with iodobenzene are filtered through samples. The X-ray apparatus is turned on and a rock sample is scanned with initial water saturation and a metal plate — the core holder is illuminated with a collimated X-ray beam, the transmitted radiation intensity is measured, the carriage with the X-ray apparatus and the detector is displaced along the core sample and the metal plate with a pitch of 0.8 mm , at each step, radiation intensity is measured. The detector signal is averaged separately for the scanning section of the rock sample and the metal plate. The signal is averaged in order to obtain the average water saturation by volume of the sample. The voltage on the x-ray tube is 65-75 kV, the current is 180-195 μA. When scanning, the tube current is selected so that the signal from the detector is at least 4/5 of the upper limit of the detector measurement, the selected voltage and current value does not change throughout the experiment.

A joint filtration of mineralized water and oil is carried out in the ratios 25:75, 50:50, 75:25 and 100% water. At each ratio, a sample is scanned, and the average value of the detector I signal is measured.

The sample is removed from the core holder and placed in the chamber of the extractor (Sachs apparatus). At a temperature of 110-160 ° C, water is evaporated from the sample for 6 hours. The final water saturation is determined by the amount of condensed water in the test tube.

The found values of the initial and final water saturation S _vn and S _vk , as well as the average values of the signal from the detector when scanning a core sample with initial, final, and intermediate water saturation, are substituted into the formula

Determine the water saturation of the core sample under conditions of high pressure and temperature for each mode of joint filtration of water and oil.

A comparison of experimental data for samples of various deposits in Western Siberia is shown in the figure. On the abscissa axis, the water saturation obtained by the resistance method is plotted, and on the ordinate axis, the x-ray method. On the graph, a straight-line dependence with a unit slope is also plotted, starting from the origin.

Claims (3)

1. A method for quantitatively determining the saturation of rock samples using the initial and final water saturation values, including preparing a core sample, modeling reservoir conditions in a core sample, co-filtering mineralized water and oil through a core sample, and measuring the intermediate intensity of x-ray radiation transmitted through the filtering process the sample and the establishment of mathematical formulas of water saturation, characterized in that they measure the intensity of x-ray and of radiation passing through a sample with initial and final water saturation, receive a reference signal, the value of residual water saturation is obtained after a filtration experiment by evaporation of water from a sample at a temperature of 110-160 ° C, the values of initial, residual water saturation and reference signal are used to determine the intermediate water saturation by mathematical dependence :

where S _BH is the value of the initial water saturation of the sample, d.ed;
S _BK - value of the final water saturation of the sample, d.ed .;
I _vn ,

- the detector signal when x-rayed through a core sample with initial water saturation and a reference signal;
I _VK

- the detector signal when x-rayed through a core sample with finite water saturation and a reference signal;
I, I ^on is the detector signal during X-ray transmission of a core sample with intermediate water saturation and a reference signal. 2. The method according to claim 1, characterized in that oil is used for filtration with the addition of iodobenzene. 3. The method according to claim 1, characterized in that when conducting measurements, lower values of the voltage and current of the x-ray tube are used.