تبیین نقش متفاوت امواج تراکمی و برشی در بازتاب ویژگی‌های مخزنی سازندهای کربناته پرمین-تریاس خلیج فارس

نوع مقاله : مقاله پژوهشی

نویسندگان

دانشکده زمین‏‌شناسی، دانشکدگان علوم، دانشگاه تهران، تهران، ایران

چکیده

چاه‌پیمایی یکی از ابزارهای کلیدی در ارزیابی مخازن کربناته است و به‌ویژه داده‌های صوتی با ارائه اطلاعات ارزشمند درباره ویژگی‌های سنگ و سیال، جایگاه مهمی در مطالعات پتروفیزیکی و ژئوفیزیکی یافته‌اند. در همین راستا، این پژوهش با تمرکز بر سازندهای کنگان و دالان در خلیج فارس، به مقایسه رفتار امواج تراکمی و برشی و بررسی نقش هرکدام در ارزیابی کیفیت مخزنی پرداخته و ارتباط میان سنگ‌شناسی، نوع و میزان تخلخل، تراوایی و چگالی ماتریس با سرعت امواج را تحلیل کرده است. داده‌های به‌کاررفته شامل m ۴۱۸ مغزه، ۱۳۸۸ نمونه پلاگ و مجموعه‌ای از آنالیزهای پتروفیزیکی و زمین‌شناسی از یک چاه هدف می‌باشد. نتایج نشان می‌دهد که سنگ‌شناسی عامل اصلی کنترل‌کننده سرعت امواج است. تخلخل‌های قالبی در سنگ‌های آهکی با کاهش چگالی و ایجاد ناپیوستگی ساختاری موجب افت سرعت شده‌اند، در حالی‌که تخلخل‌های بین‌بلوری در دولومیت‌ها با حفظ پیوستگی ماتریس، سرعت بالاتری ایجاد کرده‌اند. هر دو نوع موج تراکمی و برشی در تراوایی‌های پایین‌تر از حدود mD ۵ سرعت بیشتری دارند. با افزایش تراوایی تا این مقدار، سرعت کاهش یافته و سپس روند افزایشی ملایمی مشاهده می‌شود. در تراوایی‌های پایین، پیوستگی بالای چارچوب سنگ موجب افزایش سرعت، و در تراوایی‌های بالاتر، شکل‌گیری مسیرهای جریان پیوسته موجب بازگشت تدریجی سرعت امواج می‌گردد. همچنین افزایش درصد دولومیت تا حدود ۷۰% موجب افزایش پیوسته سرعت گردید، اما پس از این آستانه اثر آن به حالت اشباع رسید. حضور انیدریت در مقادیر متوسط اثر مثبت داشت، در حالی‌که در مقادیر بالا با ایجاد ناهمگنی موجب کاهش سرعت شد. مقایسه دو نوع موج نشان داد که امواج برشی نسبت به تغییرات سنگ‌شناسی حساس‌تر هستند، در حالی‌که امواج تراکمی عمدتاً تحت تأثیر تخلخل و ترکیب سیال قرار دارند. این یافته‌ها بر اهمیت استفاده همزمان از داده‌های تراکمی و برشی در تحلیل داده‌های چاه‌پیمایی و بهبود مدل‌سازی و ارزیابی کیفی سازندهای کربناته تأکید دارد.

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Elucidating the Distinct Roles of Compressional and Shear Waves in Characterizing the Reservoir Properties of the Permian-Triassic Carbonate Formations in the Persian Gulf

نویسندگان [English]

  • Bahareh Meidani
  • Vahid Tavakoli
  • Saman Darvish Bastami
School of Geology, College of Science, University of Tehran, Iran
چکیده [English]

Well logging is one of the key tools in the evaluation of carbonate reservoirs, and acoustic data, in particular, have gained an important position in petrophysical and geophysical studies. In this regard, the present study focuses on the Kangan and Dalan formations in the Persian Gulf to compare the behavior of compressional (P) and shear (S) waves and to evaluate the role of each in assessing reservoir quality. In addition, the relationships between lithology, type and amount of porosity, permeability, and matrix density with wave velocity were analyzed. Furthermore, the dataset includes 418 m of core, 1388 plug samples, and a series of petrophysical and geological analyses from a single well. The results indicate that lithology is the main factor controlling wave velocity. Moreover, moldic porosity in limestones reduces velocity due to lower density and structural discontinuities, whereas intercrystalline porosity in dolomites results in higher velocities owing to preserved matrix continuity. Both compressional and shear waves show higher velocities at permeabilities below about 5 mD. As permeability increases up to this threshold, velocity decreases and then exhibits a gradual rise. Moreover, at low permeability, the strong framework connectivity of the rock increases velocity, while at higher permeability, the formation of continuous flow paths causes a gradual recovery of wave velocity. Furthermore, increasing dolomite content up to about 70% results in a continuous velocity increase, beyond which the effect becomes saturated. In addition, the presence of anhydrite has a positive effect at moderate amounts but reduces velocity at higher concentrations due to induced heterogeneity. Comparison of the two wave types shows that shear waves are more sensitive to lithological variations, whereas compressional waves are mainly influenced by porosity and fluid composition. These findings highlight the importance of using both P- and S-wave data simultaneously in well log analysis to improve modeling and qualitative evaluation of carbonate reservoirs.

کلیدواژه‌ها [English]

  • Carbonate Reservoirs
  • Kangan And Dalan Formations
  • Variations In Compressional And Shear Wave Velocities
  • Lithology–Velocity Relationship
  • Reservoir Characterization
  • Velocity–Porosity Correlation

مراجع

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پژوهش نفت
دوره 35، 1404-5 - شماره پیاپی 144
آذر و دی 1404
صفحه 79-113

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