Biomass Densification [electronic resource] : Systems, Particle Binding, Process Conditions, Quality Attributes, Conversion Performance, and International Standards / by Jaya Shankar Tumuluru.

Chapter 1. Bioenergy Feedstock Types and Properties -- Chapter 2. Binding Mechanism, Densification Systems, Process Variables, and Quality Attributes -- Chapter 3. Densification Process Models and Optimization -- Chapter 4. Advances in Biomass Densification and Its Impact on Cost and Quality -- Chapter 5. Biochemical and Thermochemical Conversion Performance of Densified Products for Biofuels Production -- Chapter 6. International Standards for Densified Products.

This monograph discusses the various biomass feedstocks currently available for biofuels production, as well as the mechanical preprocessing technologies that can be effectively used to reduce feedstock variability for biofuels applications. Variability in the properties of biomass-in terms of moisture, particle size distribution, and low-density-results in storage, transportation, handling, and feeding issues. Currently, biorefineries face serious particle bridging issues, uneven discharge, equipment-jamming, and transportation problems. These issues must be solved to ensure smooth operation. Mechanical preprocessing technologies, such as size reduction, densification, and moisture management using drying and dewatering, can help to overcome these issues. Many densification systems exist that will assist in converting low-density biomass to a high-density commodity type feedstock. In six chapters, the author discusses the various biomass feedstocks for biofuels production, the impact of densification process variables-such as temperature, pressure, moisture, etc.-on biomass particle agglomeration, the quality of the densified products, and the overall energy consumption of the process, as well as the various compression models for powders that can be used for biomass particles, agglomeration behavior, and optimization of the densification process using statistical and evolutionary methods. The book also discusses the novel preprocessing and dewatering technologies that can help to reduce pellet production costs. Finally, the book discusses the suitability of these densified products for biochemical and thermochemical conversion pathways, as well as the various international standards (CEN and ISO) they must adhere to. The author has worked on biomass preprocessing at Idaho National Laboratory for the last ten years. He is the principal investigator for the U.S. Department of Energy Bioenergy Technologies Office-funded "Biomass Size Reduction and Densification" project. He has developed preprocessing technologies to reduce costs and improve quality. He has published many papers and books focused on biomass preprocessing and pretreatments. Biomass process engineers and biorefinery managers can benefit from this book. Students in chemical, mechanical, biological, and environmental engineering can also use the book to understand preprocessing technologies, which greatly assist in improving biomass critical material attributes. The book can also assist policymakers and energy systems planners with the ability to understand biomass properties limitations.