Oxidative torrefaction for cleaner utilization of biomass for soil amendment

Sonal K Thengane,C Jim Lim,Kevin S Kung,Ahmed F Ghoniem,Ankita Gupta,Daniel L Sanchez,Mohamed Ateia,Sanjay M Mahajani,Shahabaddine Sokhansanj

doi:10.1016/j.clet.2020.100033

Abstract

Growing concerns of emissions from wildfires and burning of crop residues demand cleaner and efficient technologies to convert and utilize this residual biomass. The present study demonstrates a pilot scale moving bed biomass torrefaction reactor operating in oxidative medium to produce biochar for soil amendment. A series of experiments are conducted on pine shavings and rice husk, at conditions corresponding to different values of index of torrefaction ( I torr ), ratio of higher heating value of torrefied biomass (i.e. biochar) to that of raw biomass. Air-biomass equivalence ratio dominantly governs the operating temperature and affects torrefaction more than the residence time. Product yields of scaled-up reactor differed from those of a smaller bench-top reactor, primarily because of differences in heat transfer within reactor and losses to the surrounding. A relatively linear relationship of I torr is observed with biochar properties such as specific surface area, water retention capacity, bulk density, and electrical conductivity. When tested for soil amendment, the raw biomass and biochar treatments reduced soil pH by 0.2–0.3 in a season, with lowest pH values in case of pine shavings. Estimated nitrogen release and organic matter decreased with increasing I torr , but most amendments had no significant effect on seed germination and the number of green shoots. Comparatively, heavy torrefied biomass treatments showed highest shoot heights and crop yield followed by light torrefied or raw biomass and control. Successful demonstration of a pilot scale reactor and encouraging effects on soil and plant growth suggest that commercial-scale oxidative torrefaction of various residual biomass is possible for soil amendment application. • Demonstrated pilot scale oxidative moving bed reactor for biomass torrefaction. • Product yields for scaled-up reactor differed from those of a bench-top reactor. • Analyzed biochar properties showed linear relationship with index of torrefaction. • Amendments reduced soil pH but did not affect seed germination and leaf count. • Heavy torrefied pine shavings positively impacted soil quality and crop yield.

Highlights

Biomass has gained significant interest among renewable energy sources, in the sectors of energy, food, and water
Three residence time ranges of 15–20 min, 20–25 min, and 25–30 min correspond to average residence times of 17.5 min, 22.5 min, and 27.5 min
Oxidative torrefaction is proposed as a cleaner technology for converting residual biomass to biochar for soil amendment application

Summary

Introduction

Biomass has gained significant interest among renewable energy sources, in the sectors of energy, food, and water. Concerns have increased over the emissions and ecological losses because of wildfires and open burning of crop residues in different parts of world. For such residual biomass from agriculture and forestry, thermochemical processes such as gasification and different types of pyrolysis are widely applied. Torrefaction or mild pyrolysis is a thermochemical process that occurs in the range of 200–300 C often at atmospheric pressure in limited or no oxygen presence. Torrefied biomass is known for its properties such as improved hydrophobicity and grindability, high energy density and friability, and resistance to biodegradation, making it suitable for a range of applications (Bourgois and Guyonnet, 1988)

Methods

Results

Conclusion