A systematic
methodology to critically assess and screen among
early stage design alternatives was developed for the use of glycerol.
Through deterministic sensitivity analysis it was found that variations
in the product and feedstock prices, total production cost, fixed
capital investment, and discount rate, among others, have high impact
on the project’s profitability analysis. Therefore, the profitability
was tested under uncertainties by using NPV and MSP as economic metrics.
The robust ranking of solutions is presented with respect to minimum
economic risk of the project being nonprofitable (failure to achieve
a positive NPV times the consequential profit loss). It was found
that the best potential options for glycerol valorization is through
the the production of either (i) lactic acid (9 MM$ economic risk
with 63% probability of failure to achieve a positive NPV); (ii)
succinic acid (14 MM$ economic risk with 76% probability of failure
to achieve a positive NPV); or finally, (iii) 1,2-propanediol (16
MM$ economic risk with 68% probability of failure to achieve a positive
NPV). As a risk reduction strategy, a multiproduct biorefinery is
suggested which is capable of switching between the production of
lactic acid and succinic acid. This solution comes with increased
capital investment; however, it leads to more robust NPV and decreased
economic risk by approximately 20%, therefore creating a production
plant that can continuously adapt to market forces and thus optimize
profitability.
This paper presents the development
of a computer-aided decision
support tool for identifying optimal biorefinery concepts for production
of biofuels at an early design stage. To this end, a framework that
uses a superstructure-based process synthesis approach integrated
with uncertainty analysis is used. We demonstrate the application
of the tool for generating optimal biorefinery concepts for a lignocellulosic
biorefinery. In particular, we highlight the management of various
sources of data, the superstructure (integrated thermochemical and
biochemical conversion routes) needed to represent the design space,
generic but simple models describing the processing tasks, and the
formulation and solution of an MINLP problem under deterministic and
stochastic conditions to identify the optimal processing route for
multiple raw materials and products. Furthermore, we evaluate the
impact of market price uncertainties on the optimal solutions and
calculate the associated risk to enable informed and risk-aware decisions.
In this paper, eight optimal biorefi nery concepts for biofuels and biochemicals production are critically analyzed and compared in terms of their techno-economic performance and associated economic risks against historical market fl uctuations. The investigated biorefi nery concepts consider different combinations of biomass feedstock (lignocellulosic versus algal) and conversion technologies (biochemical versus thermochemical). In addition, the economic performance of each biorefi nery concept is tested assuming a sudden drop in oil prices in order to compare the fi tness/survival of each concept under extreme market disturbances. The analyses reveal amongst others that: (i) lignocellulosic bioethanol production is not economically feasible considering a drop in oil prices (a negative internal rate of return); (ii) a multi-product biorefi nery concept, where bioethanol is upgraded to higher value-added chemicals (diethyl ether and 1,3-butadiene), provides an improved resilience and robustness against market price fl uctuations by reducing economic loss by 140 MM$/a (17% IRR); (iii) the economic analysis favors biochemical conversion technologies for a small production/processing capacity, whereas the thermochemical conversion platform is favored for a relatively larger production capacity; and (iv) the microalgae-based biorefi nery concept performed worse in terms of economics compared to the others, which is largely due to the cost of algae production and harvesting. In general, we recommend that a comprehensive economic risk analysis, using for example the Monte Carlo technique, should be an integral part of the conceptual design, development, and optimization of biorefi neries to help improve their economic robustness in view of the competitive market for chemicals and fuels.
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