RU2654348C2 - Methodology of research of the chemical reagents on related technologies negative influence - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: invention relates to the petroleum industry and can be used to conduct studies to assess the chemical reagent influence on the wells production properties. Proposed is a method for assessing of the chemical reagents negative effect on related technologies, including oil sampling, preparation of the artificial water-oil emulsion, preparation of the finished chemical reagent working solution, determination of the artificial water-oil emulsion density before and after the free water separation, determination of the samples dispersity before and after the free water separation, determination of the artificial water-oil emulsion stability, determination of the separated from the artificial water-oil emulsion water pH, determination of the mechanical impurities in water granulometric composition, analysis of the obtained data, the finished chemical reagent generalized assessment by the complex of properties. At that, during the finished chemical reagent selection for the wells operation and repair, in addition to direct assessment of the application effectiveness in the technological process, for the artificial water-oil emulsion preparation, as an aqueous phase water is used, with possibility of the well conditions simulation. Finished chemical reagent effect on the oil colloidal stability is assessed using optical methods of investigation with the study of optical properties of the control oil sample upper and lower layers and the oil sample with the finished chemical reagent, and settling the samples for 24 hours. Then, the upper and lower layers optical properties are re-examined to determine the colloidal stability degree. Wherein, on the basis of microscopic studies, an increase in the emulsion with the finished chemical reagent dispersion was established, which allows to determine the stable water-oil emulsions formation ability.

EFFECT: technical result is an increase in the efficiency of chemical reagent selection for the wells operation and repair technological processes, which does not have a negative side effect on the oil colloidal stability and on the water-oil emulsions formation.

1 cl, 5 dwg

Description

The invention relates to the oil industry and can be used to conduct studies to assess the influence of a chemical reagent (hereinafter XP) on the properties of well products.

The mechanism of XP is complex and not fully understood. An important problem that needs to be resolved remains the compatibility of the applied technologies for stimulating the formation and well, mainly of a chemical nature. The density of the technologies used is sometimes such that the negative side effect of one “dampens” the effectiveness of the other.

Currently, various methods are used to evaluate the effectiveness of XP.

Method 1. When implementing the method, a model mixture is prepared that simulates formation water, placed in a two-electrode electrochemical cell, the working electrode in which is a sample of structural material that simulates a part of the downhole equipment, and the auxiliary electrode is made of inert metal, the cell is thermostated at a temperature of 20-80 ° C, then they affect the mixture with an electromagnetic field at different frequencies, while measuring in time the reactive C and active R components of the electrochemical of the cell impedance, and determine the optimal frequency for a given model mixture, at which the values of the impedance components change in time by at least 3 times compared to the original. Then, at the optimum frequency, the impedance components are measured in time for the mixture with an inhibitor introduced into it, the ratio of the reactive and active components is found, a graphical dependence of this ratio on the time of exposure to the electromagnetic field is constructed at the optimal frequency for the mixture with and without the inhibitor, according to which determine the exposure time corresponding to the maximum value of the ratio C / R, set the difference between the mentioned exposure time for a mixture with an inhibitor and without it, which judge the comparative effectiveness of inhibitors. The larger the difference, the more effective the inhibitor (Rakitin A.R., Kichigin V.I., Fofanov B.V. "Method for selecting effective scaling inhibitors", RF patent No. 2327029, IPC ЕВВ 37/06, publ. 20.06 .2008).

Method 2. Determining the effectiveness of a scale inhibitor. Essence: the inhibitor is forced through a model of a porous medium of a geometrically regular shape with a chemically neutral surface; the dependences of specific adsorption on contact time, the maximum number of pore volumes and the tangent of the angle between the tangent to the desorption curve and the ordinate axis on the flow rate of the inhibitor are measured. The maximum values of specific adsorption of the maximum number of pore volumes and the tangent of the angle judge the effectiveness of the inhibitor. Quartz beads are used as a porous medium (Antipin Yu.V., Tselikovsky OI, Islanov Sh. G. "Method for determining the effectiveness of a scale inhibitor", RF patent No. 2056040, IPC G01N 5/04, publ. 03/10/1996) .

The disadvantage of these methods is that they do not allow to determine the effectiveness of the use of XP in a consistent application of technology. In this connection, the results obtained on the basis of these methods often do not correspond to the results of field trials.

Almost all studies on the selection of optimal XP are based on the study of the effect of the composition of XP on the kinetics of dissolution of deposits depending on the composition of the deposits. This does not take into account the properties of deposits, structure and their possible changes as a result of exposure to previously applied technologies.

The process of selecting solvents should include the stage of conducting studies to assess the effect of XP on the stability of the oil disperse system, since when mixed with XP, it is possible to decrease the viscosity of the oil disperse system and, as a result, decrease colloidal stability, accelerate sedimentation processes. This leads to the destruction of the oil disperse system and a decrease in effective oil production.

In this regard, an important and urgent task is to develop a new method for a comprehensive analysis of the effect of XP on the properties of oil.

The purpose of the invention is the selection of effective ready-made XP for the technological processes of operation and repair of wells that do not have a negative side effect on the colloidal stability of oil and on the formation of water-oil emulsions.

This goal is achieved by the fact that in the methodology for assessing the negative impact of chemicals on related technologies, oil sampling, preparation of an artificial oil-water emulsion (hereinafter referred to as emulsion), preparation of a working solution of the finished chemical reagent, determination of the density of the emulsion before and after separation of free water are carried out, determination of the dispersion of samples before and after separation of free water, determination of the stability of the emulsion, determination of the pH of the separated water from the emulsion, determination of particle size distribution Skog composition of solids in water; analysis of the data obtained, a generalized assessment of the finished chemical reagent by a set of properties.

What is new is that when choosing ready-made XP for operation and repair of wells, in addition to directly assessing the effectiveness of application in the technological process, produced water is used as the aqueous phase to prepare the emulsion, which allows simulating well conditions, and the impact of the prepared XP on the colloidal stability of oil is assessed using optical research methods with the study of the optical properties of the upper and lower layers of a control oil sample and an oil sample with a finished chemical reaction ntom, sedimentation of samples within 24 hours, then re-study the optical properties of the upper and lower layers to determine colloidal stability; and on the basis of microscopic studies, an increase in the dispersion of the emulsion with the finished chemical reagent was established, which allows us to determine the ability to form stable water-oil emulsions.

To assess the effect of finished XP on colloidal stability of oil, a comprehensive analysis technique has been developed that provides optical and microscopic studies of oil before and after application of finished XP.

In this work, as an example of a specific implementation of the methodology for studying the negative effect of chemical reagents on related technologies, the results of studies of finished HRP SNPCH-5314 using oil samples of the Devonian horizon of the North Almetyevsk area of the Romashkinskoye field of PJSC Tatneft are presented.

The methodology for studying the negative impact of finished XP on related technologies is illustrated by the following drawings: where

in FIG. 1 shows the dependence of K _sp on the wavelength of oil from the top layer of the emulsion with a water cut of 40%;

in FIG. 2 shows the dependence of K _cn on the wavelength of oil from the lower layer of the emulsion with a water cut of 40%;

in FIG. 3 presents the results of laboratory studies of the optical properties of emulsions with a water cut of 40% after the onset of sedimentation;

in FIG. 4 shows microphotographs of an emulsion with a water cut of 20% without the finished chemical reagent (a) and with the finished chemical reagent (b);

in FIG. 5 presents the results of microscopic studies of an emulsion with a water cut of 20% without a ready-made chemical reagent and with a ready-made chemical reagent.

The spectrophotometric method of analysis consists in determining the degree of absorption by the substance of light rays of various wavelengths - the light absorption coefficient (K _sp ). Due to the fact that absorption at a certain wavelength is an individual characteristic of a substance, the concentration of a given substance in a sample can be judged by the magnitude of absorption.

If you build a continuous curve of the optical density of the oil sample depending on the wavelength, you can notice the individual maxima and minima corresponding to the absorption of light by individual oil components.

Laboratory studies of changes in the optical properties of oil were carried out on a ShimadzuUV-1800 spectrophotometer. The research methodology provided for the following: the optical properties of the upper and lower layers of the control oil sample and the oil sample with the finished chemical reagent were studied, then the samples were settled for 24 hours, after which the optical properties of the upper and lower layers were re-studied. The research results are presented in FIG. 1 and FIG. 2.

Laboratory studies of determining the density of the emulsion before and after separation of free water were carried out using the analytical instrument “Vibration density meter VIP-2M”, which allows you to most accurately determine the density indicator of the emulsion before and after separation of free water.

It was revealed that when oil comes into contact with finished XP, the light absorption coefficient of the upper and lower layers of oil changes, which indicates the effect of finished XP on the colloidal stability of oil.

Then, microscopic studies of emulsions were carried out on a Leica DM 750 R Microscope. Microphotographs were obtained (Fig. 4) and a disperse analysis was performed. It was found that emulsions without a finished chemical reagent have a lower degree of dispersion than an emulsion with a finished XP.

As an example in FIG. 5 shows the results of microscopic studies of an emulsion with a water cut of 20% without a ready-made chemical reagent and with a ready-made chemical reagent.

The use of research methods for the negative impact of finished chemicals on related technologies has shown that:

- chemical reagent SNPCH-5314 increases the stability of emulsions. It was found that at a water content of 20%, the sedimentation stability of an emulsion with a ready-made chemical reagent increases by 2 times;

- when oil comes into contact with finished XP, the light absorption coefficient of the upper and lower layers of oil changes. So, the CSP of the upper layer decreased by 792 units, and the CSP of the lower layer increased by 924 (Fig. 3). Based on the research data, it can be assumed that the finished chemical reagent SNPCH-5314 affects the colloidal stability of oil;

- with microscopic studies performed on a “Leica DM 750 R microscope”, an increase in the dispersion of an emulsion with a ready-made XP water cut of 20% by 35% was established.

It is necessary to continue research on finished XP for related technological processes. For research, the use of the proposed methods may be recommended. In addition to the standard assessment of the effectiveness of finished XP, it is necessary to evaluate the effect of finished XP on the colloidal stability of oil and on the formation of emulsions.

Comparison of the impact indicators of ready-made XP allows you to rank them both for a specific and for a generalized criterion.

The technological and economic effect of the use of ready-made XP can be obtained not only by preventing the deposition of salts, but their competent use, avoiding all possible consequences after their use.

Claims (1)

A method for assessing the negative impact of chemical reagents on related technologies, including oil sampling, preparation of an artificial water-oil emulsion, preparation of a working solution of a finished chemical reagent, determination of the density of an artificial oil-water emulsion before and after separation of free water, determination of the dispersion of samples before and after separation of free water, determination stability of the artificial water-oil emulsion, determination of the pH of the separated water from the artificial water-oil emulsion, determination particle size distribution of mechanical impurities in water; analysis of the obtained data, a generalized assessment of the finished chemical reagent by a set of properties, characterized in that when choosing a finished chemical reagent for operation and repair of wells, in addition to directly assessing the effectiveness of the application in the process, for the preparation of an artificial oil-water emulsion, formation water is used as the aqueous phase with the ability to simulate downhole conditions, assess the impact of the finished chemical reagent on the colloidal stability of oil using optical research methods with the study of the optical properties of the upper and lower layers of a control oil sample and an oil sample with a finished chemical reagent, sedimentation of samples for 24 hours, then repeated studies of the optical properties of the upper and lower layers to determine the degree of colloidal stability, and based on microscopic studies an increase in the dispersion of the emulsion with the finished chemical reagent was established, which allows us to determine the ability to form stable water-oil oil Pulse.

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