Process analysis of microalgae biomass thermal disruption for biofuel production
作者: Ahmed Artan , Caleb Acquah , Michael K. Danquah , Clarence M. Ongkudon
DOI: 10.1007/978-3-319-17915-5_7
关键词:
摘要: The continual usage of petroleum-sourced fuels is now widely recognized as unsustainable due to the depleting supplies, and contribution these accumulation greenhouse gases in environment. A suitable alternative utilisation renewable transport fuels. These are environmentally friendly economically sustainable. Biodiesel bioethanol derived from plant lipids carbohydrate-based crops potential alternatives petroleum In recent years, cultivation microalgae an feedstock for production biofuel has received significant attention. This a result fact that, they have fast growth rate, can accumulate high quantities carbohydrates intracellularly biodiesel bioethanol, respectively. That notwithstanding, processes involved microalgae, dewatering, biochemical extraction, conversion biofuels energy intensive undermine its full-scale application potentials. therefore necessitated need attention research order debottleneck aforementioned areas. Electroporation, High pressure homogenization (HPH), Ultrasonic Bead mills examples present cell disruption technologies. However, electroportation process which at seems more efficient than rest only been tried on lab scale, yet be experimented industrial scale capacity. this work, successful design energy-efficient technology that treat up mass 10,000 gal/annum was designed by means thermal lysis. comparative analysis with other methods reveals system significantly reliable, least fractional registered low 0.41 algal concentration 6 kg/m3.
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