Abstract
Chemical-looping combustion (CLC) is a next generation combustion technology that shows great promise as a solution for the need of high-efficiency low-cost carbon capture from fossil fueled power plants. In this paper, numerical simulations are conducted of a binary particle bed associated with a coal-direct CLC system consisting of coal (represented by plastic beads) and oxygen carrier particles and validated against an experimental riser-based carbon stripper. The detailed particle dynamics and solid-gas and solid-solid interactions are investigated using the Lagrangian particle-tracking approach known as the discrete element method coupled with the computational fluid dynamics solution for the flow field. The simulation results of the fluidization behavior and the separation ratio of the particles are in excellent agreement with the experiment. A credible simulation of a binary particle bed is of particular importance for understanding the details of the fluidization behavior; the baseline simulation established in this work can be used as a tool for designing and optimizing the performance of such systems.
Original language | English |
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Pages (from-to) | 361-367 |
Number of pages | 7 |
Journal | Powder Technology |
Volume | 325 |
DOIs | |
State | Published - Feb 1 2018 |
Keywords
- Binary particle bed
- Carbon stripper
- Chemical looping combustion
- Discrete element method
- Fluidization
- Numerical simulation