Tailor-Made Green Diesel Blends Design using a Decomposition-Based Computer-Aided Approach

Phoon, Li Yee; Hashim, Haslenda; Mat, Ramli; Mustaffa, Azizul Azri

doi:10.1016/b978-0-444-63577-8.50026-7

Cited by 7 publications

(2 citation statements)

References 10 publications

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“…A comprehensive methodology for computer-aided mixture design and formulation of blended products was been proposed by Gani and co-workers. − In their framework, a mixture design problem is formulated as a mixed-integer nonlinear program which is solved by means of a decomposition-based approach, i.e., the solution to the original problem is sought by considering a series of solvable subproblems and therefore by performing a sequential reduction of the number of blend candidates. This approach has been applied to a variety of case studies including the formulation of gasoline- and diesel-like fuels where the design objective has been to find optimal blend components for a so-called main ingredient, i.e., a fossil gasoline/diesel pseudocompound that must constitute the main part of all mixtures under consideration. − In the aforementioned works, fixed cost factors ($/L) assigned to the individual blend components have been the only process-related criteria explicitly included in the optimization problem. Recently, Ng and co-workers have developed a systematic methodology for mixture design in the context of integrated biorefineries that includes the identification of optimal conversion pathways via superstructure optimization once an optimal mixture has been determined based on CAMD techniques.…”

Section: Introductionmentioning

confidence: 99%

Model-Based Formulation of Biofuel Blends by Simultaneous Product and Pathway Design

Dahmen

Marquardt

2017

Energy Fuels

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Oxygenated species obtained from the selective chemo-catalytic refunctionalization of lignocellulosic materials and rationally formulated mixtures thereof can be tailored to the needs of advanced internal combustion engine concepts like low temperature compression-ignition or highly boosted spark-ignition combustion. In the present contribution, we present a framework for model-based formulation of biofuel blends with tailored properties by considering the fuel’s molecular composition as the fundamental design degree of freedom. To this end, optimization-based reaction pathway screening is combined with mathematical fuel property prediction by means of structural group contribution and quantitative structure–property relationship modeling in order to formulate and solve an integrated product and pathway design problem. The model-based approach is envisioned (i) to guide fundamental experimental investigations of the combustion behavior of blended biofuels toward the most favorable mixtures and (ii) to identify promising conversion pathways for further elaboration by means of reaction engineering and conceptual process design. The latter is ultimately needed to bridge the gap from the mass- and energy-based molecular level analysis presented here to a process level analysis addressing the economics of the involved conversion and separation steps. A case study is dedicated to the identification of promising blends and respective production routes for the spark-ignition (SI) engine. The goal here is to produce a 100% bioderived fuel with tailored properties from hexoses and pentoses of lignocellulosic biomass by utilizing renewable hydrogen from carbon-free energy sources such as wind or solar to boost the energy of fuel produced for a given quantity of biomass supplied.

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Section: Introductionmentioning

confidence: 99%

Model-Based Formulation of Biofuel Blends by Simultaneous Product and Pathway Design

Dahmen

Marquardt

2017

Energy Fuels

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“…Design methodologies can avoid expensive and time-consuming trial-and-error experimental campaigns. Similar approaches have been successfully used in several fuel development projects [4,[53][54][55][56][57][58][59][60], typically to design tailor-made molecules for fuel application. That is, molecular building blocks were computationally joined and reassembled to generate new molecules with good fuel blendstock potential.…”

Section: Considerations For Use Of the Database And The Product Desigmentioning

confidence: 99%

Identification of Promising Alternative Mono-Alcohol Fuel Blend Components for Spark Ignition Engines

2020

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Alcohols are attractive fuel blendstocks for spark ignition engines due to their high octane values and potentially positive influence on performance and emission. Although methanol, ethanol, and butanol have been widely studied, other biomass-derived alcohols may have similar or better properties. However, it is not feasible to experimentally investigate the fuel potential of every molecule. The goals of this study were to develop a methodology for rapid screening of a fuel property database for mono-alcohols and to identify alcohols with the potential of blending to produce advantaged motor gasolines. A database was developed with 13 fuel properties of all saturated C1-C10 mono-alcohols. A decision framework was used to evaluate alcohols suitable for blending in gasoline for spark ignition engines in two scenarios: low-range (up to 15 vol%) blends and high-range (greater than 40 vol%) blends. The low-range blend cases resulted in the identification of 48 alcohols. In the case of high-range blending, only six alcohols were found to be suitable. This is the first study to systematically evaluate all C1-C10 saturated alcohols for blending with gasoline using relevant fuel properties. A novel aspect of this study is the evaluation of the influence of errors in predicted property values. These scenario screenings focus attention on a smaller number of promising candidate molecules, and the approach could be modified for other classes of fuel molecules, engine types, and fuel blending goals.

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VPPD-Lab

Kalakul¹,

Cignitti²,

Zhang

et al. 2016

Computer Aided Chemical Engineering

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Tailor-Made Green Diesel Blends Design using a Decomposition-Based Computer-Aided Approach

Cited by 7 publications

References 10 publications

Model-Based Formulation of Biofuel Blends by Simultaneous Product and Pathway Design

Model-Based Formulation of Biofuel Blends by Simultaneous Product and Pathway Design

Identification of Promising Alternative Mono-Alcohol Fuel Blend Components for Spark Ignition Engines

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