4 Papers
4 Citations
Ganesh Sharma is an academic researcher from National Environmental Engineering Research Institute. The author has contributed to research in topics: Biogas & Population. The author has an hindex of 3, co-authored 4 publications.
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Papers
Evaluation, applicability and optimization of advanced oxidation process for pretreatment of rice straw and its effect on cellulose digestibility
TL;DR: In this paper, an advanced oxidation process, i.e. Alkaline Wet Air Oxidation (AWAO), was used as a pretreatment for rice straw and scrutinizes the effect of operation parameters on cellulose recovery, hemicellulose solubilization and lignin removal through Response Surface Methodology (RSM).
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Performance evaluation of methanogenic digester using kitchen waste for validation of optimized hydrolysis conditions for reduction in ammonia accumulation
Nidhi Sahu,Ganesh Sharma,B. Chandrashekhar,Niti B. Jadeja,Atya Kapley,R.A. Pandey,Abhinav Sharma +6 more
TL;DR: In this paper, a biphasic system (hydrolysis and methanogenesis) was evaluated for validation of previously optimized hydrolysis conditions [pH 7.2-7.5, Aeration 0.19-0.22 vvm (volume of air per unit volume of media per minute), Temperature 44 - 48°C] for reduction in ammonia accumulation in the methanogenic digester.
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Evaluation of biogas production potential of kitchen waste in the presence of spices.
Nidhi Sahu,Abhinav Sharma,Priyanka Mishra,B. Chandrashekhar,Ganesh Sharma,Atya Kapley,R.A. Pandey +6 more
TL;DR: In this article, the effect of spices (garlic, red chili, cinnamon, coriander, clove, turmeric, cardamom, black pepper) on anaerobic digestion of kitchen waste for biogas production is investigated.
Optimization of hydrolysis conditions for minimizing ammonia accumulation in two-stage biogas production process using kitchen waste for sustainable process development
TL;DR: In this article, an optimization of hydrolysis for minimum ammonia accumulation by controlling the physico-chemical conditions viz. temperature, pH, and aeration is presented, which leads to reduction in ammonia accumulation up to 66% operated under optimized hydrolyisation conditions compared to other operating condition in methanogenic phase.