Abstract
Ni-Mo supported drill cuttings were used to catalyze the hydrocracking (HDC) of Athabasca vacuum residue (AVR) in an autoclave. Drill cuttings are a common waste product that are, depending on their origin, plentiful in acidic sites. The catalyst was prepared using the wet impregnation method. HDC was carried out at both low and high H2 pressure at 400 °C. Control thermal cracking (TC) and HDC runs with and without raw drill cuttings were performed to better examine the role of the supported drill cuttings catalyst. The quality in terms of viscosity and °API gravity, and the yield of various fractions making up the product oil were used to gauge the performance of the catalyst. Similar temperature and energy profiles between TC and HDC suggested strong overlap between the two different reactions, despite H2 presence. Nevertheless, supported drill cuttings runs at high H2 pressures promoted H2 consumption to a strong extent. Consequently, the liquid yield was the highest (~75 wt.%) and the coke yield was negligible. High temperature simulated distillation results revealed a residue conversion of ~55% for both low and high pressure HDC catalytic runs. The product oil quality with respect to viscosity and °API gravity was also found to be comparable between the low and high pressure HDC catalytic runs. Accordingly, no trade-off between liquid yield and quality was incurred at high H2 pressure. Effectively the supported drill cuttings drastically reduced coke formation, while maximizing the yield of the desired liquid product.
Highlights
Heavy oil constitutes the vast majority of the proven oil reserve [1]
This study investigates the use of raw drill cuttings and Ni-Mo supported drill cuttings for HDC of Athabasca vacuum residue (AVR) in an autoclave
Drill cuttings and Ni-Mo-supported drill cuttings at 10 wt.% were compared as slurry type catalysts
Summary
Heavy oil constitutes the vast majority of the proven oil reserve [1]. the strong presence of heavy molecules such as asphaltenes poses a major recovery and upgrading problems of these reserves.exploring inexpensive processes for upgrading heavy oil into lighter fractions is essential for the resource to compete in the market [2]. Heavy oil constitutes the vast majority of the proven oil reserve [1]. The strong presence of heavy molecules such as asphaltenes poses a major recovery and upgrading problems of these reserves. Exploring inexpensive processes for upgrading heavy oil into lighter fractions is essential for the resource to compete in the market [2]. Hydrocracking (HDC) is an upgrading process that uses hydrogen in order to promote a higher H:C ratio, and a higher yield of light products [4]. HDC can utilize many different feedstocks to produce a higher quality liquid product while still maintaining a low coke yield [5]. Coke formation incurs an additional significant economic cost on the process
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