مدلسازی جایگزینی دی اکسید کربن در ساختار هیدرات گازی متان

محبی, وحید; فیضی, وفا

مدلسازی جایگزینی دی اکسید کربن در ساختار هیدرات گازی متان

نوع مقاله : پژوهشی اصیل

نویسندگان

وحید محبی

وفا فیضی

دانشگاه صنعت نفت

چکیده

در این تحقیق، یک مدل سینتیکی جدید برای پدیده جایگزینی متان-کربن دیاکسید در ساختار هیدراتهای گازی پیشنهاد شده است. جایگزینی متان-کربن دیاکسید روشی پیشنهادی برای تولید از مخازن هیدرات متان است که در نتیجه آن تولید متان و ذخیره کربن دیاکسید به صورت همزمان اتفاق میافتد. این مدل بر اساس مکانیسم پیشنهادی برای پدیده جایگزینی در یک فاز دوغابی از هیدرات متان ارائه شده است. براساس این مدل، تجزیه هیدرات متان و تشکیل هیدرات کربن دیاکسید به صورت همزمان اتفاق میافتد. بنابراین پارمترهای سینتیکی تشکیل هیدرات کربن دیاکسید و تجزیه هیدرات متان به صورت آزمایشگاهی محاسبه شده و به صورت توابعی از دما و فشار برازش شدهاند. بررسی اثر شرایط عملیاتی برروی بازده جایگزینی نشان میدهد که بازده جایگزینی در فشارهای پایینتر و دماهای بالاتر بیشتر میباشد. این رفتار نشان میدهد که مکانیسم کنترل کننده سرعت برای پدیده جایگزینی در ساختار هیدرات، تجزیه هیدرات متان است، زیرا سرعت تجزیه هیدرات در دماهای بالاتر و فشارهای پایینتر بیشتر میباشد. بر اساس نتایج حاصل از این مدل در دمای 15/278 درجه کلوین با افزایش فشار از 55 بار تا 65 بار، بازده جایگزینی 78/15 تا 80/8 کاهش پیداکرده است. همچنین در دمای 15/280 در جه کلوین با افزایش فشار از 60 با تا 70 بار بازده جایگزینی از 89/26 تا 91/15 کاهش یافته است. در فشار یکسان 60 بار بازه جایگزینی در دماهای 15/280 کلوین و 15/278 کلوین به ترتیب 96/20 و 59/11 میباشد.

کلیدواژه‌ها

هیدرات گازی

متان

کربن دی‌اکسید

جایگزینی

مدل‌سازی

موضوعات

مهندسی نفت

عنوان مقاله English

Modeling of Carbon Dioxide Replacement in Methane Hydrate Structure

نویسندگان English

Vahid Mohebbi

Vafa Feizi

Petroleum University of Technology

چکیده English

Research subject:
Methane hydrate reservoirs as an unconventional resource of natural gas can secure demand of energy in the world for many years. Efficient production prom this resources is the subject of concern. CO₂-Methane replacement is a novel method for production from naturally occurring methane hydrate deposits such that methane production and CO₂ storage take occur simultaneously.

Research approach: In this study a new kinetic model is proposed for CO₂-Methane replacement in hydrate structure. This kinetic model is developed based on the mechanism proposed for replacement in the hydrate structure in the presence of excess water in a slurry phase of methane hydrate. According to this mechanism partial breakage of methane hydrate cages, methane-CO₂ substitution and formation of CO₂ hydrate proceed simultaneously. Methane hydrate dissociation and CO₂ hydrate formation kinetic parameters are evaluated experimentally and fitted on polynomials as function of pressure and temperature.

Main results: Evaluation of the effects of pressure and temperature on the replacement efficiency show that higher replacement efficiency is obtained at higher temperatures and lower pressures. It means that replacement kinetic is controlled by methane hydrate dissociation step. Since, higher temperature and lower pressure favor dissociation of methane hydrate. At 278.15 K the replacement efficiency decreased from 15.78 to 8.80 as total pressure increased from 55 bar to 65 bar, at 280.15 K it decreased from 26.98 to 15.91 by decreasing total pressure from 60 bar to 70 bar. At same pressure 60 bar for 280.15 K and 278.15 K the replacement efficiency is 20.96 and 11.59 respectively.

کلیدواژه‌ها English

Gas Hydrate

Methane

Carbon Dioxide

Replacement

Modeling

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