Yankuang ceshi (Jan 2023)

Preparation of Reference Materials for Rock Evaluation of Mudstone

  • LIU Jie,
  • ZHAO Zhiming,
  • YAN Ronghui,
  • HUANG Zijian

DOI
https://doi.org/10.15898/j.cnki.11-2131/td.202201120008
Journal volume & issue
Vol. 42, no. 1
pp. 203 – 212

Abstract

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BACKGROUND As an oil and gas geochemical detection and analysis technology, rock pyrolysis is widely used in oil and gas exploration. Moreover, this technology is fast, economical, and effective in evaluating the hydrocarbon-generating potential of source rocks and identifying the oiliness of reservoir rocks. Rock pyrolysis standard materials are used for the calibration and quality monitoring of rock pyrolysis instruments, as well as being the key material basis for quantitative calculation of rock pyrolysis analysis parameters for source and reservoir rocks. At present, rock pyrolysis standard materials are relatively scarce, and most of the on-site mud logging rock pyrolysis tests use value transfer samples for instrument calibration and quality control, which brings uncertainties to data quality. At the same time, the rock pyrolysis standard material in China lacks the important parameter S4 for source rock evaluation, while the rock pyrolysis standard material in foreign countries has only one value and cannot be used for gradient calibration. Therefore, it cannot meet the application and development requirements of rock pyrolysis analysis technology in oil and gas exploration. OBJECTIVES To develop five kinds of reference materials for rock pyrolysis, with a certain gradient value of each parameter, which can satisfy the needs of conventional oil and gas testing in petroleum exploration. METHODS Candidate samples were collected from dark mudstone, oil shale and carbonaceous mudstone in the Triassic Yanchang Formation, Permian Shanxi Formation, Taiyuan Formation and Carboniferous Benxi Formation in the Ordos Basin. After impurity treatment, jaw crushing, ball mill fine grinding, powder sieving 200 mesh, mixer mixing, 60Co irradiation disinfection and sterilization, and passing the preliminary homogeneity test, the samples were packed and numbered. RESULTS For each candidate, 5×30 bottles of samples were randomly selected for uniformity testing, and the measured values of F were all less than F0.05(29, 60). There was no significant systematic difference within and between groups of samples, and the uniformity was good. Short-term stability and long-term stability were tested by the straight line fitting method, and the slope of the fitting line |b1| < t0.05·S(b1), had good stability. Eight laboratories adopted the rock pyrolysis analysis method for collaborative determination. All of the determination analysis data conformed to the normal distribution, and the determination results and corresponding uncertainties were obtained. The fixed value parameters are S2, Tmax, S4 and reference value S1, wherein the value range of S2 is 2.01-11.90mg/g, the value range of Tmax is 437-442℃, the value range of S4 is 9.5-29.9mg/g. CONCLUSIONS In accordance with the national standard material research standards and specifications, five reference materials for rock pyrolysis, GBW(E)070323, GBW(E)070324, GBW(E)070325, GBW(E)070326 and GBW(E)070327, were successfully developed. The value of each parameter presents a certain gradient, which basically covers the content range of conventional pyrolysis analysis.

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