The overwhelming concerns due to over exploitation of fossil resources necessitate the utilization of alternative energy resources. Biodiesel has been considered as one of the most adaptable alternative to fossil-derived diesel with similar properties and numerous environmental benefits. Although there are various approaches for biodiesel production, development of cost-effective and robust catalyst with efficient production methods and utilization of a variety of feedstock could be the optimum solution to bring down the production cost. Considering the complexity of biodiesel production processes, process design, quantitative evaluation and optimization of the biodiesel from whole systems perspectives is essential for unlocking the complexity and enhancing the system performances. Process systems engineering offers an efficient approach to design and optimize biodiesel manufacturing systems by using a variety of tools. This review reflects state-of-the-art biodiesel research in the field of process systems engineering with a particular focus on biodiesel production including process design and simulation, sustainability evaluation, optimization and supply chain management. This review also highlights the challenges and opportunities for the development of potentially sustainable and eco-friendly enzymatic biodiesel technology.
Rapid changes in the global climate resulting from anthropogenic activities and greenhouse gas emissions from fossil resources are encouraging commercial and academic research to seek out new routes for the production of sustainable fuels. Biodiesel, as a renewable fuel, has long been recognized as one of the solutions to meet energy demand in a climate‐constrained world. Although, several routes have been devised for biodiesel production, the enzymatic route has attracted substantial research interest. Here we discuss enzymatic esterification / transesterification technology and its contribution to the green synthesis of biodiesel. This review provides a comprehensive assessment of the fundamentals of enzymatic reaction, such as the impact of different reaction components (lipase, acyl acceptor, substrate, and reaction media) on the process parameters, along with recent developments in improving enzymatic biodiesel production, such as different lipases, combinations of lipases, and two‐step methods. Kinetics and the mechanism of enzymatic reaction when lipase is used as a catalyst are also explained in greater detail. Finally, the opportunities and challenges for the development of potentially sustainable and eco‐friendly enzymatic biodiesel technology are discussed. © 2021 Society of Industrial Chemistry and John Wiley & Sons Ltd.
Hydrogen being a green fuel is rapidly gaining importance in the energy sector. Steam methane reforming is one of the most industrially important chemical reaction and a key step in the production of high purity hydrogen. Due to inherent deficiencies of conventional reforming reactors, a new concept based on fluidized bed membrane reactor is getting the focus of researchers. In this work, a nickel-based fluidized bed membrane reactor model is developed in the Aspen PLUSand#174; process simulator. A user-defined membrane module is embedded in the Aspen PLUSand#174; through its interface with Microsoftand#174; Excel. Then, a series combination of Gibbs reactors and membrane modules are used to develop a nickel-based fluidized bed membrane reactor. The model developed for nickel-based fluidized bed membrane reactor is compared with palladium-based membrane reactor in terms of methane conversion and hydrogen yield for a given panel of major operating parameters. The simulation results indicated that the model can accurately predict the behavior of a membrane reactor under different operating conditions. In addition, the model can be used to estimate the effective membrane area required for a given rate of hydrogen production.
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