Impact of Sequential Ammonia Fiber Expansion (AFEX) Pretreatment and Pelletization on the Moisture Sorption Properties of Corn Stover |
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Authors: | Ian J Bonner David N Thompson Farzaneh Teymouri Timothy Campbell Bryan Bals Jaya Shankar Tumuluru |
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Affiliation: | 1. Biofuels &2. Renewable Energy Technologies Department, Idaho National Laboratory, Idaho Falls, Idaho, USAian.bonner@inl.gov;4. Biological &5. Chemical Processing Department, Idaho National Laboratory, Idaho Falls, Idaho, USA;6. Michigan Biotechnology Institute, Lansing, Michigan, USA;7. Renewable Energy Technologies Department, Idaho National Laboratory, Idaho Falls, Idaho, USA |
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Abstract: | Combining ammonia fiber expansion (AFEX?) pretreatment with a depot processing facility is a promising option for delivering high-value densified biomass to the emerging bioenergy industry. However, because the pretreatment process results in a high moisture material unsuitable for pelleting or storage (40% wet basis), the biomass must be immediately dried. If AFEX pretreatment results in a material that is difficult to dry, the economics of this already costly operation would be at risk. This work tests the nature of moisture sorption isotherms and thin-layer drying behavior of corn (Zea mays L.) stover at 20°C to 60°C before and after sequential AFEX pretreatment and pelletization to determine whether any negative impacts to material drying or storage may result from the AFEX process. The equilibrium moisture content to equilibrium relative humidity relationship for each of the materials was determined using dynamic vapor sorption isotherms and modeled with modified Chung-Pfost, modified Halsey, and modified Henderson temperature-dependent models as well as the Double Log Polynomial (DLP), Peleg, and Guggenheim Anderson de Boer (GAB) temperature-independent models. Drying kinetics were quantified under thin-layer laboratory testing and modeled using the Modified Page's equation. Water activity isotherms for non-pelleted biomass were best modeled with the Peleg temperature-independent equation while isotherms for the pelleted biomass were best modeled with the Double Log Polynomial equation. Thin-layer drying results were accurately modeled with the Modified Page's equation. The results of this work indicate that AFEX pretreatment results in drying properties more favorable than or equal to that of raw corn stover, and pellets of superior physical stability in storage. |
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Keywords: | AFEX pretreatment Corn stover Drying kinetics Pelletized biomass Water activity |
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