RU2687877C1 - Method of determining the parameters hydrocarbon saturation in reservoirs of oil and gas condensate fields and evaluation of their filtration and capacity properties in oil and gas wells, cased by a fiberglass column - Google Patents

Abstract

FIELD: measurement technology.

SUBSTANCE: use: for determination of hydrocarbon saturation parameters of strata-reservoirs of oil and gas condensate deposits. Summary of invention consists in the fact that measurement of spectral intensity of GRRC (gamma-radiation of radiation capture of neutrons) of spectrometric neutron gamma-ray logging combined with measurement of neutron flux intensity J_ss and J_ls in the region of more than 500 keV per small and large sondes neutron-neutron logging by epithermal neutrons, function of porosity F(K_p) is calculated, saturation function "far zone" F(H_f), calculating “near zone” saturation functions F(H_n), calculating the "well" saturation functions F(H_w) with cross-raft construction F(H_d) from F(K_p), F(H_n) from F(K_p), F(H_w) from F(K_p) relationships, from which saturation functions corresponding to water-saturated formations – F(H_wf), oil-saturated formations – F(H_of), and gas-saturated formations – F(H_gf); dependencies are used for calculation of oil saturation coefficients, oil and gas saturation, gas saturation, volumetric oil saturation, volumetric oil and gas saturation and volumetric gas saturation.

EFFECT: providing the possibility of increasing the information content of investigations owing to broader functional capabilities of neutron methods from probing a well borehole zone with calculation of parameters of hydrocarbon saturation with reservoirs at different distances from the wall of the fiberglass column in wells.

4 cl, 2 dwg

Description

The invention relates to the oil and gas industry and is intended to monitor the development of oil and gas condensate fields by neutron methods in wells cased with a fiberglass column.

There is a method of monitoring the oil and gas saturation, developed reservoir, using induction logging (IR) or high-frequency induction logging isometric sensing (VIKIZ) (Dvorkin VI. Geophysical monitoring of the development of oil reservoirs surrounded by fiberglass pipes. Ufa: GUP "Ufa poligrakkompkombkombkombin" 2001) and (R.Z. Imamov, N.M. Tokareva. Use of wells with fiberglass shanks to assess the dynamics of formation saturation and control development. Oil industry, 2009 ., №7, p. 90-93).

The disadvantage of the known method is a significant influence of the geological features of the reservoir structure (texture, structure, fracturing, hydrophilicity, hydrophobicity, etc.) on the calculated values of oil and gas saturation of the reservoir. The low limit of resistance measurements (200 Ω / m) does not allow this method to be used to determine the oil and gas saturation (especially carbonate reservoir rocks) with a resistance of more than 200 Ω / m. The known method is characterized by low informational content, as it allows to calculate only one parameter characterizing the relative content of hydrocarbon fluids - oil and gas saturation coefficient Kng or oil saturation coefficient - Kn and gas saturation coefficient - Kg without determining the phase state of hydrocarbons in the reservoir.

There is a method for determining the composition of hydrocarbons in reservoirs of oil and gas wells by probing the near-wellbore zone with the 3SHC + 2NNT complex of depth neutron methods (Lysenkov A.I., Danilenko V.N., Ivanov Yu.V., Sudnichnikova E.V., Borisova L. K., Egurtsov S.A. Determination of heterogeneities of the fluid composition of hydrocarbons in the near-wellbore zone by probing with a complex of neutron methods in the wells of the old stock of NTV Karotazhnik, Tver: AIS, 2015, issue 4 (250), p. 3- 6.)

The method is free from the influence of geological features of the structure of the reservoir.

A disadvantage of the known method is the significant influence of the nuclear-physical properties of chemical elements with high absorbing neutron properties on the readings of NNKt probes and gamma-emitting properties of chemical elements during the capture of thermal neutrons in a flushing or kill fluid.

In addition, the presence of a boron chemical element in a fiberglass casing, which has abnormal absorbing neutron properties for thermal neutrons (500 mbarn) and increased gamma radiation from radiation capture of 477 keV thermal neutrons with the practical absence of more hard gamma radiation, significantly reduces the informativity of the complex in determining the saturation of the pore space of the reservoir with hydrocarbon fluids.

There is a method of determining the composition of hydrocarbons in reservoirs of oil and gas wells (RF Patent No. 2439622. Lysenkov AI, Lysenkov VA, Osipov AD - №20101357221/28; declared. 26.08.2010; publ. 10.01. 2012, Bull. No. 1.), adopted for the prototype of the claimed method.

и большом

зондах метода 2ННКт, с последующим определением функции пористости

как отношения интенсивностей потоков тепловых нейтронов на малом и большом зондах

вычисляют функцию хлора «жесткая» F(Cl_ж) - спектральные интенсивности ГИРЗ в области более 2,3 МэВ, функцию хлора «мягкая»

- спектральные интенсивности ГИРЗ в области менее 2,3 МэВ, вычисляют функцию F(Cl_ннк) с использованием интенсивностей потоков тепловых нейтронов на большом и малом зондах метода 2ННКт, производят построение на кросс-плотах

зависимостей, соответствующих водонасыщенным пластам (ВП), нефтенасыщенным пластам (НП) и газонасыщенным пластам (ГП), вычисление функций массы хлора -

связанных с содержанием хлора в коллекторе, и вычисление по формулам коэффициента нефтенасыщенности

- по функции F(Cl_ж), коэффициента нефтенасыщенности

- по функции

в условиях минерализованных пластовых вод, при этом функцию

вычисляют как обратную величину произведения потоков тепловых нейтронов на большом и малом зондах с использованием метода спектрометрического нейтронного гамма-каротажа по хлору

функцию хлора «жесткая»

вычисляют как отношение квадрата спектральной интенсивности ГИРЗ в области более 2,3 МэВ - J_ж к произведению потоков интенсивностей тепловых нейтронов большого и малого зондов методом

функцию хлора «мягкая»

вычисляют как отношение квадрата спектральной интенсивности ГИРЗ в области менее 2,3 МэВ -

к произведению потоков интенсивностей тепловых нейтронов большого и малого зондов методом

In the known method, spectrometric neutron gamma-ray logging and two-probe neutron-neutron logging for thermal neutrons (SNGK + 2NNt) are used, with which they measure the intensity of thermal neutron fluxes on small

and big

2NNKt method probes, followed by determination of the porosity function

as ratios of the intensity of thermal neutron fluxes on small and large probes

calculate the function of chlorine "hard" F (Cl _W ) - the spectral intensity of GIRS in the region of more than 2.3 MeV, the function of chlorine "soft"

- spectral intensity GIRS in the region of less than 2.3 MeV, calculate the function F (Cl_NK) using the intensity of thermal neutron fluxes on the large and small probes of the 2NNt method, build on cross-rafts

dependencies corresponding to water-saturated strata (VP), oil-saturated strata (NP) and gas-saturated strata (GP), calculation of chlorine mass functions -

associated with the chlorine content in the reservoir, and the calculation of the formula for the ratio of oil saturation

- according to function F (Cl _g ), oil saturation coefficient

- by function

in conditions of mineralized formation waters, while the function

calculated as the reciprocal of the product of thermal neutron fluxes on large and small probes using the method of spectrometric neutron gamma logging for chlorine

chlorine function "hard"

is calculated as the ratio of a square Girzy spectral intensity in the range of more than 2.3 MeV - J _x to the product of the thermal neutron flux intensity large and small probes by

chlorine function "soft"

calculated as the ratio of the square of the spectral intensity of a GIRS in the region of less than 2.3 MeV -

to the product of the intensity fluxes of thermal neutrons of large and small probes by the method

The known method is suitable for estimating geological parameters in studies of cased oil and gas wells with a metal casing and becomes uninformative in wells cased with a fiberglass column, due to the fact that the presence of the chemical element of boron in a fiberglass casing with abnormal absorbing neutron properties of thermal neutrons (500 mb) ), and increased gamma radiation of radiation capture of thermal neutrons with an energy of 478 keV, with the practical absence of of the computed gamma radiation method of the SNPC method, it is not possible to reliably determine the saturation parameters of the pore space of the reservoir with hydrocarbon fluids by the 2NNKt + SNGK complex.

и

на малом и большом зондах нейтрон-нейтронного каротажа, в качестве которого применяют двухзондовый нейтрон-нейтронный каротаж по надтепловым нейтронам - 2ННКнт в комплексе с СНГК (2ННКнт+СНГК), по результатам измерения интенсивностей потоков нейтронов

и

на малом и большом зондах 2ННКнт и спектральной интенсивности ГИРЗ метода СНГК производят вычисление функции пористости

как отношения интенсивностей потоков надтепловых нейтронов на малом и большом зондах

метода, вычисляют функцию насыщения «дальней зоны»

как отношение спектральной интенсивности ГИРЗ -

в области более 500 кэВ к интенсивности потока надтепловых нейтронов большого зонда

метода

вычисляют функцию насыщения «ближней зоны»

как отношение спектральной интенсивности ГИРЗ - J_ж в области более 500 кэВ к интенсивности потока надтепловых нейтронов малого зонда -

метода

вычисляют функцию насыщения «скважина» F(H_c) как обратную величину произведения потоков надтепловых нейтронов на большом и малом зондах метода

и осуществляют построение на кросс-плотах

от

зависимостей в декартовых координатах, в условных единицах, где по оси абсцисс X назначаются аналитические параметры функции пористости

а по оси ординат Y - функции насыщения

по которым вычисляют функции насыщения, соответствующие водонасыщенным пластам -

нефтенасыщенным пластам -

и газонасыщенным пластам -

при этом функции

аппроксимируют прямой линией, перпендикулярной оси X в декартовых координатах (X-Y), где по оси X назначены функции

а по оси Y назначены функции насыщения F(H), а функции

вычисляют по результатам аппроксимации квадратичной зависимостью

точек указанного кросс-плота (X-Y) с минимальными значениями функции насыщения F(H), кроме того, геологические параметры насыщения - коэффициенты нефтенасыщенности

нефтегазонасыщенности

газонасыщенности

объемной нефтенасыщенности

объемной нефтегазонасыщенности

и объемной газонасыщенности

вычисляют по функциям насыщения:

для каждой группы кросс-плотов, получаемых в результате применения зондов комплекса СНГК+2ННКнт, обеспечивающих исследование прискважинных зон пласта-коллектора с разной глубинностью в радиальном направлении (на различном удалении) от стенки стеклопластиковой колонны нефтегазовых скважин, при этом определение геологических параметров насыщения производят с учетом фазового состояния углеводородов в поровом пространстве пласта-коллектора с низкой минерализацией пластовых вод в газовых и нефтегазовых скважинах следующим образом:The technical result achieved by the application of the claimed method of determining the saturation parameters of reservoir hydrocarbons and evaluating their reservoir properties in oil and gas-saturated wells cased with a fiberglass column, is increasing the informativeness of research by expanding the functionality of neutron methods for probing the near-well zone with calculating geological parameters saturation of reservoirs at hydrocarbons at different distances from glass wall kovoy column in oil and gas wells. This technical result is achieved by the fact that in the method of determining the saturation parameters with hydrocarbons of reservoirs of oil and gas condensate fields and assessing their reservoir properties in oil and gas wells cased with a fiberglass column, including the measurement of the spectral intensity of a GIRZ (gamma radiation from the radiation capture of neutrons), the spectrometric neutron neutron, it is a neutron neutron. SIPK in a complex with measurement of neutron flux intensities

and

on small and large probes of neutron-neutron logging, which is used as a two-probe neutron-neutron logging for epithermal neutrons - 2NKnt in combination with SNG (2NNHnt + SNG), according to the results of measurements of neutron flux intensities

and

on the small and large probes 2NKNt and the spectral intensity of the GIRS of the SNG method, the function of porosity is calculated

as ratios of fluxes of epithermal neutrons at small and large probes

method, calculate the saturation function of the "far zone"

as the ratio of the spectral intensity GIRZ -

in the region of more than 500 keV to the intensity of the flux of epithermal neutrons of a large probe

method

calculate the saturation function of the “near zone”

as the ratio of the spectral intensity GIRS - J _W in the region of more than 500 keV to the intensity of the flux of epithermal neutrons of a small probe -

method

calculate the saturation function "well" F (H _c ) as the reciprocal of the product of fluxes of epithermal neutrons on the large and small probes of the method

and build cross rafts

from

dependencies in Cartesian coordinates, in arbitrary units, where the analytical parameters of the porosity function are assigned along the X axis of the X axis.

and Y axis - saturation functions

which calculate the saturation function corresponding to the water-saturated formations -

oil reservoirs -

and gas reservoirs -

with the functions

approximate by a straight line perpendicular to the X axis in Cartesian coordinates (XY), where the X axis is assigned to the function

and on the Y axis, the saturation functions F (H) are assigned, and the functions

calculated by the results of the approximation of the quadratic dependence

points of the specified cross-float (XY) with the minimum values of the saturation function F (H), in addition, the geological parameters of saturation are the oil saturation factors

oil and gas saturation

gas saturation

bulk oil saturation

bulk oil and gas saturation

and bulk gas saturation

calculated by the saturation functions:

for each group of cross-plots, obtained as a result of using probes of the SNGK + 2NKnt complex, providing research of the near-well zones of the reservoir-reservoir with different depth in the radial direction (at different distances) from the wall of the GRP oil and gas wells, the taking into account the phase state of hydrocarbons in the pore space of a reservoir with a low salinity of formation water in gas and oil and gas wells as follows:

основанное на дефиците плотности и водородосодержания нефтегазонасыщенных и газонасыщенных пластов-коллекторов относительно водонасыщенных, производят одинаково для кросс-плотов

из расчета:definition

based on the lack of density and hydrogen content of oil-and-gas-saturated and gas-saturated reservoirs with respect to water-saturated, they are produced equally for cross-rafts

on the basis of:

Where:

- максимальные значения функции пористости водонасыщенного коллектора,

- the maximum values of the porosity function of the water-saturated collector,

- текущее значение функции пористости,

- the current value of the porosity function,

- минимальное значение функции пористости в нефтегазонасыщенном или газонасыщенном коллекторе,

- the minimum value of the function of porosity in oil or gas-saturated or gas-saturated collector,

- текущее значение функции насыщения в газонасыщенном или нефтегазонасыщенном коллекторе:

- the current value of the saturation function in a gas-saturated or oil-gas-saturated collector:

- максимальное значение функции насыщения в газонасыщенном или нефтегазонасыщенном коллекторе,

- the maximum value of the saturation function in a gas-saturated or oil-gas-saturated collector,

- принятый коэффициент нефтегазонасыщенности для нефтегазонасыщенного коллектора по табличным геологическим данным,

- adopted oil and gas saturation coefficient for oil and gas saturated reservoir based on table geological data,

- принятый коэффициент газонасыщенности для газонасыщенного коллектора по табличным геологическим данным,

- adopted gas saturation coefficient for a gas-saturated collector based on tabular geological data,

Where:

- значение функции насыщения, соответствующее водонасы-щенным коллекторам в точке текущих измерений:

- the value of the saturation function corresponding to the water-saturated collectors at the current measurement point:

- максимальное значение функции насыщения, соответствующее газонасыщенным коллекторам:

- the maximum value of the saturation function corresponding to gas-saturated collectors:

- текущие значения для функций насыщения:

- current values for saturation functions:

- принятое максимальное значение объемной нефтегазонасыщенности для нефтегазонасыщенного коллектора по табличным геологическим данным,

- the maximum value of the volume of oil and gas saturation for the oil and gas reservoir according to the table geological data,

- принятое максимальное значение объемной газонасыщенности для газонасыщенного коллектора по табличным геологическим данным.

- the adopted maximum value of volumetric gas saturation for a gas-saturated collector according to tabular geological data.

To study the complex 2NNKnt + SNG near-wellbore zones of the reservoir at different distances from the wall of the GRP oil and gas wells conventionally distinguish three zones according to the depth of research from the wall of the FRP casing: “well” - with a radius of 5-10 cm, where the readings are large and small probes 2NNKnt method, "near zone" - 10-20 cm, where readings are used small probe method recorded 2NNKnt and rigid part of the spectral intensity Girzy _w-J in the region of 500 keV and "distal zone" - 20-40 cm, where readings are used 2NNKnt large probe method and recorded rigid part of the spectral intensity Girzy - J _f in over 500 keV, with a true saturation of the reservoir are as for the "far zone".

и функции насыщения. На фиг. 2 представлены результаты интерпретации исследований комплексом 2ННКнт+СНГК.Investigations by a complex of NNKnT + SIPC methods can be performed using a multi-probe combination of these methods. FIG. 1 shows the cross-rafts:

and saturation functions. FIG. 2 presents the results of the interpretation of research complex 2NKnt + SIPK.

The essence of the method

Diagnostics of the near-wellbore zone of reservoirs for hydrocarbon fluids content and their quantitative assessment in wells cased with a fiberglass column is based on the calculation of analytical parameters closely related to the saturation of the pore space of the reservoir containing hydrocarbons with respect to saturated water reservoirs at the same level using neutron methods porosity.

The indications of any methods and modifications of stationary neutron logging (NNCT, SNG) in water-filled wells mainly depend on the total volumetric hydrogen content of the reservoir.

складывается из концентрации водорода в воде, нефти и в газе. Учитывая, что плотность жидкого флюида составляет обычно 0.7-1.2 г/см³ с нефтью или минерализованной водой, а типичная плотность газа составляет 0.005-0.04 г/см³, то плотность ядер водорода в жидком флюиде обычно в 20-100 раз превышает ядерную плотность водорода в газе, даже при его высоких давлениях. Поэтому водородосодержанием газа с точностью в несколько процентов можно пренебречь и считать, что общее водородосодержание породы

полностью определяется жидким водонефтяным флюидом, а оно приближенно выражается эквивалентным объемным водосодержанием породы W, равным:For gas sedimentary rocks with two-phase saturation

It consists of the concentration of hydrogen in water, oil and gas. Considering that the density of a liquid fluid is usually 0.7-1.2 g / cm ³ with oil or saline water, and the typical density of a gas is 0.005-0.04 g / cm ³ , the density of hydrogen nuclei in a liquid fluid is usually 20-100 times higher than the nuclear density hydrogen in a gas, even at high pressures. Therefore, the hydrogen content of a gas with an accuracy of several percent can be neglected and it is assumed that the total hydrogen content of the rock

completely determined by the liquid water-oil fluid, and it is approximately expressed by the equivalent volume water content of the rock W, equal to:

выражается в %;

- в долях единицы, a W - в %. Водородосодержание среды

линейно и в равной степени возрастает при увеличении

или уменьшении газонасыщенности

Here and below

expressed in%;

- in fractions of a unit, and W - in%. Hydrogen environment

increases linearly and equally

or reducing gas saturation

определяет влияние водорода на показания зондов нейтронного каротажа (НК), и на равной основе формируется двумя независимыми геологическими параметрами

In gas-saturated reservoirs, the total hydrogen content

determines the effect of hydrogen on the readings of neutron logging probes, and on an equal basis is formed by two independent geological parameters

которая формирует общее водородосодержание пласта

но здесьIn this regard, gas facilities are fundamentally different from oil, where the influence of hydrogen on the ND readings is determined by one geological parameter - water-saturated porosity

which forms the total hydrogen content of the reservoir

but here

Where:

- коэффициент водонасыщенности,

- coefficient of water saturation,

- коэффициент нефтенасыщенности.

- oil saturation coefficient.

и газонасыщенности

At two-phase saturation, the effect of density P decreases with increasing porosity

and gas saturation

усиливает оба дефицита, что всегда приводит к возрастанию скоростей счета любых зондов ННКнт или СНГК.Gas-saturated reservoirs of water-filled wells are simultaneously characterized by two parameters: the lack of hydrogen content - W (main) and the lack of density - P (weak). Gas saturation increase

intensifies both deficits, which always leads to an increase in the counting rates of any probes NNCT or SIPC.

The dependences of NNCT probes in gas-filled wells are pre-inverted. With increasing hydrogen content of W and density P, the readings of the probes decrease.

The presence of a fiberglass column containing boron with anomalous absorbing neutron properties of thermal neutrons (500 mbarn) and increased gamma radiation of radiation capture of thermal neutrons with energy of 478 keV with the absence of more hard gamma radiation, does not allow to use the NNKt method for research - neutron logging for thermal neutrons.

In this case, the effect of a fiberglass column can be eliminated by applying a complex of neutron methods NNCT - neutron-neutron logging for epithermal neutrons and SIPC with registration of the flux flux density factor of epithermal neutrons with energy more than 500 keV.

The environment of the neutron counters with a cadmium screen, which has anomalous absorption properties for thermal neutrons, makes it possible to record epithermal neutrons. Boron contained in the fiberglass column is also an anomalous absorber of thermal neutrons. Consequently, by registering epithermal neutrons, we get rid of the effect of boron, which is located in a fiberglass column, on the readings of counters on epithermal neutrons.

This is the difference of the claimed method from the prototype, in which the NNT-neutron-neutron logging method for thermal neutrons and spectral intensities GIRS in the region of more than 2.3 MeV are used to estimate the saturation parameters.

The depth of research in the near-wellbore zone (distance from the production casing wall) is ensured by the different depth of investigation of the neutron methods used. Small depth of research, ceteris paribus, has the 2NNKnt method, the most - the SNGK.

With an increase in the length of the probes, the depth of research increases. In the SNPC method, the depth of research increases with an increase in the gamma radiation energy of radiative capture of thermal neutrons. It follows that the depth of research can be changed using complex analytical parameters of the neutron methods SNGK + 2NNKnt. At the same time, the depth of research can be changed by using probes of various lengths and spectral intensities in different spectral gamma rays of radiative capture of thermal neutrons with energy more than 500 keV.

и

на малом и большом зондах 2ННКнт и спектральной интенсивности ГИРЗ метода СНГК производят вычисление функции пористости

как отношения интенсивностей потоков надтепловых нейтронов на малом и большом зондах:

метода 2ННКнт, вычисляют функцию насыщения «дальней зоны»

как отношение спектральной интенсивности ГИРЗ - J_ж в области более 500 кэВ к интенсивности потока надтепловых нейтронов большого зонда

метода

вычисляют функцию насыщения «ближней зоны»

как отношение спектральной интенсивности ГИРЗ-J_ж в области более 500 кэВ к интенсивности потока надтепловых нейтронов малого зонда

метода

вычисляют функцию насыщения «скважина»

как обратную величину произведения потоков надтепловых нейтронов на большом и малом зондах метода

и осуществляют построение на кросс-плотах

зависимостей в декартовых координатах, в условных единицах, где по оси абсцисс X назначаются аналитические параметры функции пористости

а по оси ординат Y - функции насыщения F(H), по которым вычисляют функции насыщения, соответствующие водонасыщенным пластам -

нефтенасыщенным пластам -

и газонасыщенным пластам -

при этом функции

аппроксимируют прямой линией, перпендикулярной оси X в декартовых координатах (X-Y), где по оси X назначены функции

а по оси Y назначены функции насыщения F(H), а функции

вычисляют по результатам аппроксимации квадратичной зависимостью

точек указанного кросс-плота (X-Y) с минимальными значениями функции насыщения F(H) (фиг. 1).When implementing the method according to the results of measuring the intensity of neutron fluxes

and

on the small and large probes 2NKNt and the spectral intensity of the GIRS of the SNG method, the function of porosity is calculated

as the ratios of the intensities of fluxes of epithermal neutrons on small and large probes:

method 2NKnnt calculate the saturation function of the "far zone"

as the ratio of the spectral intensity GIRS - J _l in the region of more than 500 keV to the intensity of the flux of epithermal neutrons of a large probe

method

calculate the saturation function of the “near zone”

as the ratio of the spectral intensity Girzy _w-J in the region of 500 keV to the flow rate of epithermal neutrons small probe

method

calculate the saturation function "well"

as the reciprocal of the product of fluxes of epithermal neutrons on the large and small probes of the method

and build cross rafts

dependencies in Cartesian coordinates, in arbitrary units, where the analytical parameters of the porosity function are assigned along the X axis of the X axis.

and on the ordinate Y - the saturation function F (H), which is used to calculate the saturation functions corresponding to water-saturated strata -

oil reservoirs -

and gas reservoirs -

with the functions

approximate by a straight line perpendicular to the X axis in Cartesian coordinates (XY), where the X axis is assigned to the function

and on the Y axis, the saturation functions F (H) are assigned, and the functions

calculated by the results of the approximation of the quadratic dependence

points of the specified cross-plot (XY) with the minimum values of the saturation function F (H) (Fig. 1).

по формулам (1-4).Further, the coefficients are calculated separately for each group of cross-floats, taking into account the phase state of hydrocarbons in the pore space of the reservoir.

according to the formulas (1-4).

по аналитическим параметрам разноглубинных модификаций нейтронных методов характеризуют насыщение прискважинной зоны коллектора на разном удалении в радиальном направлении от стенки стеклопластиковой колонны, при этом большей глубинностью характеризуются вычисленные значения геологических параметров по кросс плотам

от

средней глубинностью

малой

Calculated values

According to the analytical parameters of multi-depth modifications of neutron methods, they characterize the saturation of the near-wellbore zone of the collector at different distances in the radial direction from the wall of the fiberglass column, while the calculated values of geological parameters for cross-rafts are characterized by greater depth.

from

medium depth

small

по разным зондам комплекса СНГК+2ННКнт позволяет производить зондирование прискважинной зоны коллектора по характеру насыщения углеводородными флюидами в радиальном направлении от стенки стеклопластиковой колонны.Comparison of computed values of the same type

for different probes of the SNGK + 2NNKnt complex, it is possible to probe the near-wellbore zone of the collector according to the nature of saturation with hydrocarbon fluids in the radial direction from the wall of the fiberglass plastic column.

In studies of the 2NNKnt + SNGK complex, three zones are distinguished in depth in the radial direction from the wall of the fiberglass column: a “well” with a radius of 5-10 cm, where the indications of the large and small probes of the 2NNKnt method are used, and the “near zone” - 10-20 cm, where readings small probe method 2NNKnt apply and register a rigid part of the spectral intensity GIR3 _w-J in the region of 500 keV and "distal zone" - 20-40 cm, where readings are used large probe method recorded 2NNKnt and rigid part of the spectral intensity GIR3-J in the region of 500 keV, with a true saturation of the reservoir are as for the "far zone".

Studies using the NNKt + SNGK methods can be carried out using a multi-probe combination of these methods, for example, as part of the 2NKnt + 2SNGK, 2NNKnt + 3SNGK complexes, which allow for a more detailed exploration of the near-well zone of the reservoir according to the nature of saturation with hydrocarbon fluids.

Based on the research results, the following analytical conclusions are made:

(за истинное насыщение принимается значение, вычисленное для «дальней зоны» коллектора);- the reservoir is considered saturated with hydrocarbons, if with increasing depth of research the calculated values increase

(the value calculated for the “far zone” of the collector is taken as true saturation);

(за истинное насыщение принимается значение, вычисленное для «дальней зоны» коллектора).- the collector is considered to be water-saturated if the calculated values decrease with increasing depth of research

(the value calculated for the “far zone” of the collector is taken as true saturation).

For example, the use of 3-probe neutron-neutron logging, including methods 2NNKnt and SNGK with the subsequent calculation of complex parameters (not associated with the anomalous neutron properties of a GRP column), allows to rank the collector through density, hydrogen content associated with volumetric saturation of the pore space of the hydrocarbon column. by fes.

отражают соответственно относительное и абсолютное содержание газа в поровом пространстве коллектора. Информацию о ФЕС несет параметр

чем выше его значения, тем выше ФЕС для газонасыщенного коллектора и выше добычные характеристики скважины. Связь между ФЕС или

и добычными характеристиками устанавливают по результатам испытания скважин.Calculated saturation parameters

reflect respectively the relative and absolute gas content in the pore space of the reservoir. The FES information is parameter

the higher its value, the higher the FES for the gas-saturated reservoir and the higher the production characteristics of the well. The relationship between FES or

and mining characteristics set on the results of testing wells.

The collector is saturated with hydrocarbons, if with increasing depth of research increases the calculated values of the parameters characterizing the saturation of the reservoir with hydrocarbons.

The quantitative values of the calculated parameters characterizing the saturation of the reservoir with hydrocarbon fluids and their distribution at different distances from the production casing wall are an additional criterion in the evaluation of the FES.

и функции насыщения (прямая 2, кривая 1). На указанных кросс-плотах «а», «б», «в» функции насыщения газо-насыщенных коллекторов аппроксимированы прямой линией -

(прямая 2), перпендикулярной оси X в декартовых координатах (X-Y), где по оси X назначены функции

а по оси Y назначены функции насыщения F(H).FIG. 1 shows the dependency crossplots:

and saturation functions (straight line 2, curve 1). On the specified cross-rafts "a", "b", "c" saturation functions of gas-saturated collectors are approximated by a straight line -

(straight line 2), perpendicular to the X axis in Cartesian coordinates (XY), where functions are assigned along the X axis

and on the Y axis, the saturation functions F (H) are assigned.

на всех кросс-плотах.Gas-saturated collectors with high FES are characterized by high values of the saturation function F (H) and low values of the function of porosity

on all cross-rafts.

на всех кросс-плотах.Water-saturated reservoirs, clay and clay rocks are characterized by low values of the saturation function F (H) and high values of the function of porosity

on all cross-rafts.

(кривая 1), вычисляютSaturation functions of water-saturated reservoirs and their geological equivalents of clays and clay rocks

(curve 1), calculate

according to the results of approximation by quadratic dependence

точек указанного кросс-плота (X-Y) с минимальными значениями функции насыщения F(H).

points of the specified crossplot (XY) with the minimum values of the saturation function F (H).

FIG. 2 shows the interpretation of the results of measurements by the SIPK + 2NNKnt complexes in a gas well with low salinity of formation waters.

Water-saturated reservoirs of clay and clay rocks are distinguished by minimal values.

и низкими

Газонасыщенные коллектора со средними ФЕС выделяются высокими значениями

и средними значениями

In terms of productive sediments, gas-saturated rocks with low FES are distinguished by high values

and low

Gas-saturated collectors with average FES are characterized by high values

and mean values

и высокими значениями

по ближней и дальней зонам.Gas-saturated collectors with high FES are characterized by high values

and high values

in the near and far zones.

Thus, to analyze the saturation of the pore space of the reservoir with hydrocarbons, a diagnostic sign is used, based on a significant difference in the neutron properties of hydrocarbons in the liquid and gaseous state - density deficiency and hydrogen content of gas-saturated and oil-gas-saturated collectors relative to water-saturated collectors with the same reservoir porosity. The most sensitive to the deficit of density and hydrogen content of gas-saturated and oil-gas-saturated collectors is the NNCO method, whose readings are almost not affected by the presence of chemical elements with abnormal absorbing neutron properties in the environment. Boron, which is in the composition of fiberglass columns, has an increased gamma radiation of radiation capture of thermal neutrons with an energy of 478 keV and the practical absence of more rigid gamma radiation. To determine the saturation of the pore space of the reservoir with hydrocarbons in wells cased with a fiberglass column, the following types of interaction of neutrons with rocks opened by the well are used simultaneously: neutron scattering - NNCT, and gamma radiation of radiative capture of thermal neutrons with energy more than 500 keV - SNG using multi-probe measuring installations of type 2NNKnt + SNGK, ZNNKnt + 2 SNGK or other combinations including these methods.

Claims (23)

1. A method for determining the hydrocarbon saturation parameters of reservoir oil and gas fields and their evaluation of reservoir properties in oil and gas wells cased fiberglass column comprising a spectral measurement of gamma radiation intensity neutron radiative capture - Girzy spectrometric gamma ray neutron - SNGK in combination with the measurement of intensities neutron fluxes J _mz and J _bz on small and large probes of neutron-neutron logging, which is used as two-probe neutron-neutron logging for epithermal neutrons - 2NKnt in combination with SNGK (2NNKnt + SNGK), while the results of these measurements are used to calculate the function of porosity F (K _p ) as the intensity ratio of fluxes of epithermal neutrons on small and large probes 2НННт: F ( K _n) = J _mz: J _os, calculated saturation function "far zone» F (H _d) as the ratio of the spectral intensity Girzy - J _x in a region with an energy over 500 keV for epithermal neutron flux intensity large probe J _os method 2NNKnt - F (H _d ) = J _g : J _bz , calculate the saturation function of the “near zone” F (H _b ) as the ratio of the spectral intensity GIRS - J _f in the region with an energy of more than 500 keV to the intensity of the flux of the epithermal neutrons of the small probe - J _{m3 of} the 2NHKnt method - F (H _b ) = J _f : J _m3 , calculate the saturation function "well" F (H _с ) as the reciprocal of the product of fluxes of epithermal neutrons in the large and small probes of the method

and build on crossplots F (H _d ) from F (K _p ), F (H _b ) from F (K _p ), F (H _c ) from F (K _p ) dependencies in Cartesian coordinates, in arbitrary units, where on the abscissa X, the analytical parameters of the porosity function F (K _p ) are assigned, and on the ordinate Y - the saturation functions F (H), which calculate the saturation functions corresponding to water-saturated strata F (H _w ), to oil-saturated strata F (H _NP ) and gas-saturated layers - F (H _gp ), while the functions F (K _p ) are approximated by a straight line perpendicular to the X axis in Cartesian coordinates (XY), where x is assigned along the X axis The functions F (K _p ), and the Y-axis are assigned the saturation functions F (H), and the functions F (H _fc ) are calculated from the results of the approximation by the quadratic dependence F (H _fc ) = a ⋅F (K _p ) ² ± b⋅ F (K _p ) points of the specified crossplot (XY) with the minimum values of the saturation function F (H), in addition, the geological saturation parameters are the oil saturation factors K _n , oil and gas saturation K _ng , gas saturation K _g , bulk oil saturation K _n × K _n , hydrocarbon saturation bulk K _ng × K _p and the volume of gas saturation × K _g K _n is calculated by the saturation function: F (H _Bn), F (H _np) and F (H _n) for each group of cross-rafts obtained by applying probes complex SNGK + 2NNKnt providing research near-zones of the reservoir at different distances from the wall fiberglass column of oil and gas wells, wherein the determination of geological saturation parameters produced with the phase state of hydrocarbons in the pore space of the reservoir with low salinity of formation waters in gas and oil and gas wells as follows: determining K _ng and K _r, K _ng × K _p and K _d × K _n, based on the deficit of density and hydrogen content hydrocarbon saturation and gas saturated reservoirs relatively saturated produce same for cross-rafts F (H _d) from F (K _n ), F (H _b ) from F (K _p ), F (H _c ) from F (K _p ) from the calculation:

Where: maxF (K _p ) - the maximum values of the porosity function of the water-saturated collector, F (K _p ) _tech - the current value of the function of porosity, minF (K _p ) - the minimum value of the porosity function in an oil or gas-saturated or gas-saturated reservoir, F (H _gp ) _tech - the current value of the saturation function in a gas-saturated or oil-gas saturated collector: F (H _d ), F (H _b ), F (H _s ), maxF (H _gp ) - the maximum value of the saturation function in a gas-saturated or oil-and-gas-saturated collector, K _ng - the accepted coefficient of oil and gas _saturation for oil and gas reservoirs according to tabular geological data, K _gt - adopted gas saturation coefficient for a gas-saturated collector based on tabular geological data,

Where F (H _VP ) - the value of the saturation function corresponding to the water-saturated collectors at the point of current measurements: F (Hd), F (Hb), F (Hc), maxF (H _gp - the maximum value of the saturation function corresponding to gas-saturated collectors: F (H _d ), F (H _b ), F (H _s ), F (H) _tech - current values for saturation functions: F (H _d ), F (H _b ), F (H _s ), max K _ngt × K _p - the accepted maximum value of oil and gas _saturation for an oil and gas _saturated collector according to tabular geological data, mahK × K _{rm n} - adopted maximum value for the volume of gas saturation of a gas-saturated reservoir tabular geological data. 2. The method of determining the saturation parameters of reservoir hydrocarbons and assessing their reservoir properties in oil-gas-saturated wells cased with a fiberglass column according to claim 1, characterized in that for the investigation of the 2NKHT + SOM complex near the wellbore zones of the reservoir-reservoir at different distances from the glass-reinforced plastic columns of oil and gas wells conventionally distinguish three zones in depth of research: a “well” - with a study radius of 5–10 cm, where the indications of the large and small probes of the 2NKHK method are used t, "near zone" - 10-20 cm, where readings are used small probe method recorded 2NNKnt and rigid part of the spectral intensity Girzy - J _x in a region with an energy over 500 keV, "distal zone" - 20-40 cm, where readings are used large probe method 2NNKnt and register the hard part of the spectral intensity GIRZ - J _W in the region with an energy of more than 500 keV, while for the true saturation of the reservoir take the values for the "far zone". 3. The method of determining the saturation parameters of reservoirs with hydrocarbons and evaluating their reservoir properties in oil-gas-saturated wells cased with a fiberglass column according to claim 1, characterized in that studies with a complex of NNECt + SNGK methods can be carried out using a multi-probe combination of these methods. 4. The method of determining the saturation parameters of reservoirs with hydrocarbons and evaluating their reservoir properties in oil-gas-saturated wells cased with a fiberglass column according to claim 1, characterized in that the reservoir reservoir properties are estimated in direct proportion to changes in the calculated volumetric parameter gas saturation K _g × K _p .

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