Microwave Torrefaction and Densification of Oat Hulls for Heat and Power Production
Date
2021-02-02
Authors
Journal Title
Journal ISSN
Volume Title
Publisher
ORCID
Type
Thesis
Degree Level
Masters
Abstract
Current environmental problems are indicating that we have to opt for renewable and cleaner energy sources, however economic challenges must be addressed. The work described in this thesis investigated the effect of microwave torrefaction of oat hulls, a new technology to upgrade the physiochemical characteristics of agricultural waste for fuel use in heat or power generation.
Microwave torrefaction was carried out at temperature levels of 225, 255, and 285ºC, and residence times of 3, 6, and 9 min. It was determined that based on the temperature level or severity of torrefaction treatment, the lignocellulosic structure of the biomass, and physiochemical characteristics were modified. The higher the severity, and residence time, the higher the lignocellulosic degradation; providing an increment in the heating value and ease of grinding, but a decrease in the bulk density and binding characteristics. Moreover, the study of torrefied biomass pellet quality in means of; pellet unit density, tensile strength, heating value, and moisture adsorption determined that mild torrefaction treatments not only enhanced biomass heating values and hydrophobicity, but increased the tensile strength by allowing lignin to act as a natural binder.
These results indicate a new advantage of the microwave torrefaction, and allow knowledge contribution. Furthermore, a technoeconomic analysis of a small scale 36,900 t annum-1 microwave torrefaction pellet plant using the lab data; 255ºC for 3 min and 71% mass yield, determined the project feasibility at industrial scale. It was concluded that microwave torrefaction presents a high capital investment when compared to traditional heating methods, however such investment could be justified by the increase in production, and commercialization of liquid by-products.
This thesis shows how agricultural waste or biomass could be upgraded to produce biofuels in the province of Saskatchewan. The thesis also presented for the first time data on technoeconomic analysis of microwave equipment cost, and electricity use. The results of the investigation hope to help with knowledge contribution towards the implementation and further research of microwave torrefaction systems for biomass fuel upgrading.
Description
Keywords
Microwave torrefaction, fiber optic, pellet, biomass
Citation
Degree
Master of Science (M.Sc.)
Department
Chemical and Biological Engineering
Program
Biological Engineering