The impact of particle size of cellulosic residue and solid loadings on enzymatic hydrolysis with a mass balance

• Published in: Fuel (Guildford) Vol. 245; pp. 514 - 520
• Main Authors: Kapoor, Manali, Semwal, Surbhi, Satlewal, Alok, Christopher, Jayaraj, Gupta, Ravi P., Kumar, Ravindra, Puri, Suresh K., Ramakumar, S.S.V.
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 01.06.2019; Elsevier BV
• Subjects: Acids; Biodegradation; Biomass; Commercialization; Degradation products; Dilute acid pretreatment; Dilution; Enzymes; Ethanol; Glucan; Glucan hydrolysis; Hydrolysis; IR spectroscopy; Mass balance; Particle size; Polysaccharides; Pretreatment; Recovery; Rice straw; Saccharides; Size reduction; Straw; Sugar; Particle size; Glucan hydrolysis; IR spectroscopy; Dilute acid pretreatment; Rice straw
• ISSN: 0016-2361; 1873-7153
• DOI: 10.1016/j.fuel.2019.02.094

•Impact of biomass particle size on glucan conversion was studied.•Maximum glucan conversion was obtained for 10 mm particle size.•Increasing the enzyme dosages results in 14% higher glucan conversion.•In the current set of parameters 10 mm particle size was found to be optimum.•Lower LOI and higher S/G ratio leading to higher overall sugar recovery. Rice straw has a great potential for ethanol production due to its richness in polysaccharides and abundant availability, however, for efficient utilization of these polysaccharides, size reduction is a prerequisite step. Therefore, biomass particle size plays a vital role for cellulosic ethanol commercialization. In this study, the effects of rice straw particle size on dilute acid pretreatment efficiency and enzymatic hydrolysis are investigated. Different sizes; 5, 10 and 20 mm were subjected to dilute acid pretreatment in a continuous pilot scale system with a horizontal screw feeder reactor followed by enzymatic hydrolysis at varying solids (10 and 15%) and enzyme dosages (5 and 10 FPU/g of pretreated residue). The glucan hydrolysis for 5, 10 and 20 mm are 65.6, 80.0 and 60.0% using 5 FPU and 79.5, 93.4 and 72.8% using 10 FPU/g pretreated residue respectively at 10% loading, whereas, at 15% it is significantly lower in respective experiment. Overall sugar recovery with 10 mm is 63.8 and 72.9% with 5 and 10 FPU respectively. RS with 10 mm biomass particle size at both solid loadings and enzyme dosages resulted in much higher enzymatic hydrolysis than others and in turn the overall sugar recovery and this was found to be due to the variation in the degradation products and pseudolignin contents in the pretreated biomass. The insight into the structural intricacies of biomass after pretreatment are studied using FT-IR and SEM revealing significant changes in biomass properties responsible for improved sugar recovery.