Abstract
The fast pyrolysis of coffee ground for bio-crude oil production was simulated in a tilted-slide reactor. The biochemical composition was derived by an extended biomass characterization method based on the elemental analysis. The simulation was performed in a steady-state and a Lagrangian multiphase model was adopted to describe the transport of sand and biomass particles together with a multistep kinetic mechanism for fast pyrolysis. When the secondary tar cracking reactions were not considered the volatile yield increased monotonically with temperature. The inclusion of secondary reactions could improve the prediction of volatile yield which turn to decrease at higher temperature. It was found that not only the maximum volatile yield but also the corresponding reactor temperature agreed well with the experimental results. At the temperature higher than 550 °C the trend of volatile yield is similar to that of experiment while it is larger at lower reactor temperature. The individual species yields were compared at various reactor temperatures and the pyrolysis processes were analyzed by tracking the reference components when they were decomposed along the distance. It was found that the reactor temperature should be above 500 °C for effective pyrolysis of all reference components of coffee ground.
Highlights
Utilizing biomass as a renewable energy source has been widely studied to cope with the global warming issue and the depletion of fossil fuels
The fast pyrolysis of coffee ground in a tilted-slide reactor was simulated by a Lagrangian multiphase model
The biochemical composition of coffee ground was derived from the elemental analysis and the extended characterization method was adopted to account for the extractives in coffee ground
Summary
Utilizing biomass as a renewable energy source has been widely studied to cope with the global warming issue and the depletion of fossil fuels. Direct combustion of biomass in a solid form is the simplest application method as an energy source, converting biomass into a liquid fuel has advantages in storage and transportation due to the increase of energy density. Fast pyrolysis is a thermochemical process to convert biomass into liquid fuel [1,2,3,4] and this liquid product is commonly named as bio-oil or bio-crude oil. In the fast pyrolysis process, biomass is quickly decomposed into gas and solid phase in oxygen-free environment and the bio-crude oil can be obtained by quenching the gas-phase product. Scale-up and optimization of the pyrolysis reactor, it is important to understand the fast pyrolysis process in detail
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