This
work presents a novel multiobjective optimization model for
bitumen upgrading operations. The proposed model considers five basic
upgrading stages; which are the base of any bitumen/heavy oil upgrading
operation. These stages include: primary distillation, vacuum distillation,
cracking, hydrotreating, and blending. The model includes different
processing units per upgrading stage. Each unit includes a set of
operating modes; which are defined in terms of particular products
yield and energy requirements. The proposed model takes into account
two competing objective functions that must be minimized: 1) operating
energy costs, and 2) associated CO2 emissions. The optimization
approach seeks for the optimal bitumen upgrading configuration by
selecting the most suitable upgrading steps based on their corresponding
unit’s operating modes. This is done to obtain a particular
type of synthetic crude oil (SCO) blend according to composition specifications.
The problem was modeled as a mixed-integer nonlinear program (MINLP)
using the GAMS modeling system. The model was validated using historical
data of the Canadian heavy oil industry. The results show that the
proposed model is a practical tool to (1) select and plan the most
suitable bitumen upgrading configuration according to product specifications,
(2) determine the upgrading energy costs, (3) and mitigate CO2 emissions.
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