Project Number: 6034-41000-016-00
Start Date: Dec 09, 2010
End Date: Dec 08, 2015
Commercial success for development and recovery of byproducts from citrus waste streams depends on the ability to economically recover sufficient quantities to meet market demands, favorable recovery costs and market value. Integration of processes to separate and recover limonene, fermentable sugars, pectin and other polysaccharides, flavonoids and other components to produce multiple high value co-products will be investigated. Recovery of pectin or modified pectin along with other polysaccharides after water extraction of fermentable sugars will be investigated for utilization in industrial applications and integrated with a steam stripping treatment for recovery of volatile terpenes. Hydrolysis of citrus peel waste utilizing commercial enzyme products and subsequent fermentation of released sugars will be evaluated for efficacy in liquefaction, conversion of cellulose to glucose, ethanol production, and cost. This will be compared to extraction, concentration and utilization of isolated sugar and pectin/polysaccharide fractions. Separation, concentration and recovery schemes to separate fermentable sugars from non-fermentable components will include residue hydrolysis, use of ion-exchange and absorbent resins, ultrafiltration, nanofiltration, reverse osmosis, water/solvent extractions and selective precipitation. Mass balances and extraction efficiencies will be determined for major byproduct components Pectin is a major component of citrus peel with extensive functionality and the degree of methylesterification has a very strong influence on functionality. Techniques to reliably produce novel, non-random patterns of methylesterification in pectin molecules and accurately characterize their distribution will be investigated. Fractions containing pectin or other polysaccharides from citrus processing waste will be characterized for macromolecular and nanostructural properties. They will then be treated with pectin modifying enzymes at varying pH, temperature, and salt concentrations and the resulting changes in functionality and nanostructure determined. Chemical modifications will be performed using nucleophilic reagents to modify functionality alone or in combination with enzymatic treatments. Materials generated will be tested for biosorption properties as amorphous powdered materials and after conversion via chemical crosslinking. In addition, water holding capacity, viscosity, and other rheological functional properties such as yield point will be determined along with changes in fragmentation size, molecular weight distribution, degree of polymerization, degree of substitution of added groups, as well as thermal and pH tolerance. Materials with appropriate properties will then be tested in applications such as drilling fluids, dry strength additives for paper, cement additives, and absorbents for spill applications. The economics of producing newly developed by-products will be evaluated and compared with those products currently utilized for targeted applications. Economic information will include raw materials, consumable, and energy costs, fixed capitol investment cost, and a breakdown of operating and capital cost estimates.