RU2672783C1 - Complex spectrometric equipment for neutron logging - Google Patents

Abstract

FIELD: measurement technology; mining.SUBSTANCE: using for diagnosis of near-well zones of reservoirs. Summary of Invention is that neutron logging equipment comprises common source of neutrons installed in a protective casing along its axis, two gamma-radiation detectors for radiative capture of thermal neutrons of a spectrometric neutron gamma-ray logging (SNGL), two thermal neutron detectors that form small and large neutron-neutron logging for thermal neutrons (NNLt), and additionally contains two detectors of epithermal neutrons, forming small and large probes of neutron-neutron logging for epithermal neutrons (NNLet), SNGL detectors are separated from each other by a lead shield and placed in a common cadmium converter screen, while NNLt probe detectors are placed in cadmium screens and separated from NNLet probe detectors by polyamide screens, and the gaps between screens are impregnated with a high-temperature silicone sealant, with all the SNGL, NNLt and NNLet probes located on one side of the neutron source.EFFECT: extending the functionality of neutron methods, which allow to investigate the near-wellbore zone of the reservoir with increased reliability on the fluid composition of hydrocarbons and content of formation waters in the pore space of the reservoir and their distribution in the radial direction from the borehole wall (col).5 cl, 1 dwg

Description

The invention relates to the field of geophysical research of wells by methods of deep neutron logging and can be used to diagnose near-wellbore zones of reservoirs of gas, oil and gas and oil wells.

Known equipment SPRK (spectrometric radioactive logging tool), which implemented - spectrometric modification of the OGC method (neutron gamma-ray logging) to chlorine - SNGK-C1, as well as the 2NNKt method - two-probe neutron-neutron logging by thermal neutrons (Lysenkov A.I. Chlorine logging based on stationary neutron sources // NTV “Logging”. - Tver: Publishing House AIS, 2006. Issue 7-8 (148-149). - P. 109-128).

The device allows you to determine the mass content of sodium chloride M (Cl) in produced water, which reflects the water-saturated porosity in the oil reservoir, and the porosity coefficient, determined by the results of 2NNct, by which the oil saturation coefficient is calculated.

Known complex spectrometric neutron logging equipment, including a common stationary neutron source, probes with two spectrometric detectors of gamma radiation of radiation capture of thermal neutrons (SSC), probes containing thermal neutron detectors (NNCT) located on one side of the neutron source, while large LPG probe, small and large probes of NNCt thermal neutron detectors are rotated along the axis in opposite directions relative to the neutron source (RF Patent No. 127487, G01V 5/00, April 27, 2013. ) Taken as a prototype of the claimed device.

A disadvantage of known probe devices is the partial use of the analytical capabilities of neutron methods to determine the saturation of reservoirs, based on the absorption of thermal neutrons and gamma radiation of thermal neutron capture by elements that are part of the fluids, or the phase state of a hydrocarbon fluid that saturates the pore space of the reservoir. Another disadvantage is that due to the location of the LPG and NNCT neutron probes on different sides of the neutron source, the results of processing their readings are strongly influenced by transients when the formation boundaries are crossed by probes of different depth neutron methods, while the reliability of the results is reduced and is difficult their interpretation, for example, under conditions of a thin-layered section with strongly changing reservoir properties and reservoirs, and with horizontal drilling of oil and gas wells Azhin adds the uncertainty of the position of the boundaries of the layers relative to the probe installation.

The technical result achieved by the use of the inventive integrated spectrometric neutron logging equipment is the expansion of the functionality of neutron methods, allowing with increased reliability to study the borehole zone of the reservoir according to the fluid composition of hydrocarbons and the content of formation water in the pore space of the reservoir and their radial distribution from the well wall (columns ) based on the use of almost all basic neutron nuclear-physical nature the source of rocks and fluids saturating them associated with processes of suprathermal neutron deceleration (2NNCnt), thermal neutron absorption (2NNCnt) and gamma radiation of thermal neutron capture (2СНГК).

The specified technical result is achieved by the fact that the claimed complex spectrometric neutron logging equipment, including a common neutron source installed in the guard along its axis, a gamma radiation detector of thermal neutron capture of a small probe spectrometric neutron gamma ray log (GIS) and a gamma radiation detector of thermal neutron capture a large LPG probe, which are protected by lead shields from the accompanying gamma radiation coming from a neutron source the gamma radiation of radiation capture of thermal neutrons from chemical elements in the fluids that fill the well, two thermal neutron detectors forming small and large neutron-neutron thermal neutron logging probes (NNCt), in contrast to the known one, additionally contains two epithermal neutron detectors that form small and large neutron-neutron logging tools for epithermal neutrons (NNCnt), CIS detectors are separated by a lead screen and placed in a common cadmium converter screen for calibration and calibration of the energy scale of gamma radiation from radiation capture of thermal neutrons by cadmium of the LPG method, and epithermal neutron detectors of NNCt probes are placed on cadmium screens and separated from thermal neutron detectors of NNCt probes by polyamide screens, and the gaps between the screens are impregnated with high-temperature silicone sealant, while SNKK, NNKt and NNKnt probes are located on one side of the neutron source in the following order: small NNKnt probe, small NNKt probe, large NNKnt probe, large NNKt probe, m a small CISC probe, a large CISC probe, as a result of which the detectors of the small probe of NNCnt form screens that reduce the effect of direct radiation from the neutron source on the readings of the probes of NNCt, while the detector of the small probe NNCnt serves as a screen for the detector of a small probe NNCt and the queue serves as a screen for the detector of a large probe NNKt.

In addition, helium neutron epithermal neutron counters with increased helium pressure were used as detectors of NNCnt probes.

Scintillation detectors can be used as LPG detectors placed in a common converter screen.

When researching wells while drilling, scintillation detectors of LPG probes can be replaced by gas-discharge counters placed in a common converter screen that record the integral neutron gamma-ray flux.

As a common neutron source, a controlled (pulsed) neutron source or a stationary (chemical) neutron source can be used.

The attached figure shows a schematic arrangement of probes for complex spectrometric neutron logging equipment.

In the guard casing 1 along its axis there is a common neutron source 2, on one side of which there is a detector 3 of gamma radiation of radiation capture of thermal neutrons of a small probe (MSSNGK) and detector 4 of gamma radiation of radiation capture of thermal neutrons of a large probe (BSSNGK) of spectrometric neutron gamma-ray logging (2СНГК), two thermal neutron detectors 5 and 6, forming a small probe (MSCNT) and a large neutron neutron neutron-neutron logging probe (BSCNCt) (2ННКт), two 7 and 8 epithermal neutron detectors, for transmitting a small probe (MZNKnt) and a large probe (BZNKnt) neutron-neutron logging by epithermal neutrons (2NNKnt). Detectors 3 and 4 of LPG probes are separated by a lead screen 9 and placed into a common cadmium converter screen 10 to form the energy scale of gamma radiation from radiation capture of thermal neutrons by cadmium and to set the scale of the energy scale of the LPG method, and to increase the sensitivity of the method to collector porosity The detectors 7 and 8 of the suprathermal neutrons of the NNCt probes are placed in cadmium screens 11 and 12 and are separated from the thermal neutron detectors of the NNCt probes by polyamide 13 and 14 screens, and the gaps between the indicated screens s impregnated with a high temperature silicone sealant 15. The neutron source 2 is enclosed in a shield 16 made of polyamide.

The probes are located on one side of the center of the neutron source in the following sequence: a small probe of NNCt, a small probe of NNCt, a large probe of NNCt, a large probe of NNCt, a small probe of the LPA, a large probe of the LPA.

In addition, helium neutron epithermal neutron counters with increased helium pressure were used as detectors 7 and 8 of the NNCnt probes.

Scintillation detectors can be used as detectors 3 and 4 of LPG probes placed in a common converter screen.

When researching wells while drilling, scintillation detectors 3 and 4 of the LPG can be replaced by gas-discharge counters placed in a common converter screen 10, which record the integral flux of neutron gamma radiation.

As a common neutron source, a controlled (pulsed) neutron source or a stationary (chemical) neutron source can be used.

In the protective casing 1 also have an electronic unit for recording and transmitting data to the surface (not shown).

The protective casing 1 is equipped with a clamping device and is lowered into the well on the cable (not shown in the drawing).

During the lifting of the equipment, multi-probe multi-depth neutron logging (ND) of the near-borehole space is carried out by 2NKNt + 2NNKt + 2SNGK probe complexes.

NK is based on irradiation of the near-wellbore space with neutrons from a stationary or controlled neutron generator 2 and measurement of flux densities of epithermal and thermal neutrons with detectors 5, 6 and 7, 8 of 2NKnt and 2NNKt probes.

Spectrometric detectors 3, 4 of 2СНГК probes record the spectral distribution of gamma radiation of thermal neutron capture (GIRZ) by energy generated as a result of nuclear reactions during the capture of thermal neutrons.

These three types of neutron interaction with the rock and its saturating fluids are performed using measuring probes (MZSNGK, BZSNGK, BZNNKt, MZNNKt, BZNNKnt, MZNNKnt), marked by arrows in the drawing.

In this case, lithological separation of sections is carried out, rock porosity, gas-liquid and oil-water contacts are determined, gas saturation, oil saturation and volume saturation and oil saturation coefficients in the near-well part of the reservoir are determined.

Areas of effective application of ND are lithological section partitioning, determination of porosity (Kp) and geological parameters of saturation of oil saturation coefficients, gas saturation Кн, Кg and volumetric oil saturation Кп * Кн and volumetric gas saturation Кп * Кг:

- for the 2NNKnt + 2SNGK complex - a reservoir with medium and high salinity of produced water (Spl) and flushing fluid (SZh) with low shaft torsion in gas, oil and gas and oil wells;

- for the 2NNKt + 2SNGK complex - a reservoir with medium and high porosity, but low Spl and Sv in gas, oil and gas and oil wells;

- for the complex 2NKt + 2NKnt - reservoir with low porosity in gas and oil and gas wells with a low value of Spl and Sp.

The different depths of studies of the near-wellbore zone (removal from the wall of the well (column) is provided by different depths of research of the neutron methods used. The depth of research, ceteris paribus, has the method of NNCnt, medium - NNCt, more - CISK.

During operation of the complex device, the light flashes of the detectors are converted into current pulse amplitudes proportional to the energy of gamma quanta by means of photoelectronic multipliers (PMTs) and the neutron flux is converted into current pulse amplitudes by means of a neutron counter. Next, amplification and amplitude digitization of the pulses coming from the PMT and digitization of the pulses from the neutron counters and transmission of the accumulated information through the logging cable to the logger and then to the logging station computer (not shown).

Screens 9 ... 12 provide for detectors 3 ... 8 a reduction in the influence of interfering geological and technical factors complicating the relationship between the recorded readings of neutron methods and geological parameters of saturation.

Detectors 7 and 8 of suprathermal neutrons of NKNT probes are placed in cadmium screens 11 and 12 and are separated from detectors 5 and 6 of thermal neutrons of NKNt probes by polyamide screens 13 and 14, and the gaps between these screens are impregnated with high-temperature silicone sealant 15, which provides more reliable screening of the detectors NNCt from direct radiation of a neutron source and a stream of thermal neutrons coming from the side of the wellbore. Since the probes of the equipment are located on one side of the center of the neutron source in the following sequence: MZNKnt, MZNKnt, BZNKnt, BZ NNKt, the detector MZNKnt serves as an additional screen for the detector MZNKnt, and the detector BZNKnt, in turn, serves as a screen for the detector BZNKnt, which reduces the effect of direct radiation from a neutron source to the readings of NKt probes.

The cadmium converter screen 10, in which the detectors 3 and 4 of the LPG probes are placed, provides the conversion of the thermal neutron flux coming from the rocks into the gamma radiation flux due to the abnormally high absorption properties of cadmium by thermal neutrons, followed by the emission of wide gamma quanta energy spectrum, which are used to calibrate the energy scale of the scintillation detector and significantly increase the differentiation of rocks by water content.

When researching wells while drilling, scintillation detectors 3 and 4 of the LPG probes can be replaced by gas-discharge counters that record the integrated neutron gamma-ray flux with minimal energy consumption, which is an advantage for use in stand-alone devices.

Thus, to analyze the saturation of the pore space of the reservoir with hydrocarbons at different distances from the borehole wall (columns), the main types of neutron interaction with rocks exposed by the borehole are simultaneously used, neutron scattering - NNCnt, neutron absorption - NNCt, gamma radiation of thermal neutron capture - LPG using multi-probe measuring devices of the type 2NNKt + 2NNKnt + 2SNGK.

The use of 2NNKt + 2NNKnt + 2СНГК for the deep-well complex for studying wells improves the reliability of the results obtained, expands the possibilities of qualitative and quantitative analysis of neutron logging readings and simplifies their interpretation.

Claims (5)

1. Integrated neutron logging spectrometric equipment, including a common neutron source installed in the guard along its axis, a gamma radiation detector for radiation capture of thermal neutrons from a small probe, spectrometric neutron gamma ray logger - LPG and a gamma radiation detector for radiation capture of thermal neutrons from a large LPG probe, which are protected by lead shields from concomitant gamma radiation coming from a neutron source and gamma radiation of thermal neutron capture from x of thermal elements in the fluid filling the well, two thermal neutron detectors forming small and large neutron-neutron logging probes based on thermal neutrons - NNCT, characterized in that it additionally contains two epithermal neutron detectors forming small and large neutron-neutron logging probes epithermal neutrons-NNCnt, CIS detectors are separated by a lead screen and placed in a common cadmium converter screen to form and calibrate the energy scale of gamma radiation from rad cadmium capture of thermal neutrons by the LPG method, and epithermal neutron detectors of NKNT probes are placed in cadmium screens and separated from the thermal neutron detectors of NKN probes by polyamide screens, the gaps between the screens are impregnated with high-temperature silicone sealant, while all the CISK, NNKt and NNKt probes are located to the side of the neutron source, in the following order, a small probe of the NKNT, a small probe of the NKnt, a large probe of the NKnt, a large probe of the NKnt, a small probe of the SSC, a large probe of the SSC, so that NNCNTs form screens that reduce the effect of direct radiation from a neutron source on the readings of NNCt probes, while the NNCnt small probe detector serves as a screen for the NNCt small probe detector, and the NNCnt large probe detector, in turn, serves as a screen for the detector of a large NNCt probe. 2. Integrated neutron logging spectrometric equipment according to claim 1, characterized in that helium neutron counters of epithermal neutrons with increased helium pressure are used as detectors of NNCnt probes. 3. Integrated neutron logging spectrometric equipment according to claim 1, characterized in that scintillation detectors can be used as LPG detectors placed in a common converter screen. 4. Integrated neutron logging spectrometric equipment according to Claims 1 and 3, characterized in that when studying wells during drilling, the scintillation detectors of LPG probes can be replaced by gas-discharge counters that record the integral gamma-ray neutron flux placed in a common converter screen. 5. Complex spectrometric neutron logging equipment according to claim 1, characterized in that a pulsed neutron source or a stationary neutron source can be used as a common neutron source.

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