Open AccessBiocarbonization Process for High Quality Energy Carriers: Techno-economics
Author(s) -
Rajesh S. Kempegowda,
Øyvind Skreiberg,
KhanhQuang Tran
Publication year - 2017
Publication title -
energy procedia
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.474
H-Index - 81
ISSN - 1876-6102
DOI - 10.1016/j.egypro.2017.03.367
Subject(s) - biochar , carbonization , biomass (ecology) , biogas , environmental science , process integration , process (computing) , process engineering , work (physics) , energy carrier , waste management , heat of combustion , productivity , bioenergy , pulp and paper industry , biochemical engineering , biofuel , pyrolysis , renewable energy , engineering , materials science , computer science , chemistry , economics , agronomy , biology , composite material , operating system , scanning electron microscope , combustion , mechanical engineering , organic chemistry , macroeconomics , electrical engineering
This work deals with a process design and techno-economic analysis (TEA) of the enablement of biocarbonization processes for production of biocarbon, biocrude, biomethane, biofertilizer and heat. Three case scenarios are developed with high levels of integration: a) Biocarbonization process for maximized biocarbon and heat; b) Co-carbonization of algae and woody biomass for biocrude and biochar; and c) Combined co-carbonization and biochemical platform. The approach used here is the combination of process modelling and simulation. Depending on the market dynamics, yields of products can be optimized. Holistically, the proposed processes attempt to reduce solid residues, gaseous emissions and liquid effluents generated in the biocarbon value chain.
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