Development and combustion characteristics of microwave plasma-assisted fluidized bed combustor

A novel waste treatment method that can efficiently decompose waste, suppress by-product generation, and operate at a low cost is urgently required. Herein, a microwave plasma-assisted combustor was developed and its combustion characteristics were investigated for application in solid waste treatment. The experimental conditions for obtaining good states of fluidization, mixing, and plasma formation were examined prior to the combustion experiments. Subsequently, the optimal experimental conditions, such as the filling amount of bed particles, bed particle diameter, microwave irradiation position, and microwave output, required for good combustion were achieved. Combustion experiments based on these conditions revealed that a good fluidization state is required to obtain a good combustion state in this device, although the combustion condition does not necessarily depend on the system pressure at each O2 flow rate. Comparison of the conditions with similar fluidization states at O2 flow rates of 1-4 L/min revealed a maximum fuel conversion ratio at 4 L/min owing to the combustion promotion caused by increased O2 partial pressure. The fuel did not remain in the fluidized bed combustor after the combustion experiments. & COPY; 2023 The Society of Powder Technology Japan. Published by Elsevier BV and The Society of Powder Technology Japan. All rights reserved.

Automated summary

An efficient waste treatment method is urgently needed to decompose waste, suppress by-product generation, and minimize costs. This study investigated a microwave plasma-assisted combustor for solid waste treatment and identified the optimal experimental conditions. The combustion experiments revealed the importance of a good fluidization state for achieving successful combustion in this device.