使用专业学术语言翻译下面的句子：面向工业固废资源化利用和规模化消纳需求针对煤气化灰渣、粉煤灰、煤矸石等煤基固废反应活性差、高值化处置困难、综合利用率低等难题本项目提出微尺度化工与声场激励协同的微通道过程强化煤基固废资源高值化梯级利用新方法：通过构建微通道连续流反应器开发煤基固废微尺度高效混合化工工艺提高活化反应效率；通过集成超声波换能器元件调控微通道内多相流动及能质传递特性实现煤基固废多物理场耦合

This project proposes a new method for the high-value utilization of coal-based solid waste through the synergy of micro-scale chemical processes and acoustic field stimulation, targeting the challenges of poor reaction activity, difficult disposal of high-value utilization, and low comprehensive utilization rate of coal gasification ash, fly ash, and coal gangue. By constructing a microchannel continuous flow reactor and developing a micro-scale efficient mixing chemical process for coal-based solid waste, the activation reaction efficiency is improved. By integrating ultrasonic transducer elements, the characteristics of multiphase flow and energy-mass transfer in microchannels are regulated to achieve high-value disposal of coal-based solid waste through multiple physical field coupling. The ultrasonic microchemical production system is used to achieve the cascade transformation of silicon, aluminum, calcium, iron, and carbon resources, and to improve the comprehensive utilization rate of coal-based solid waste. This project will focus on the research of microchannel chemical reactor continuous flow and ultrasound transducer-assisted stimulation to enhance the high-value utilization of coal-based solid waste. Different types of coal-based solid waste will be studied to elucidate the decomposition and reconstruction mechanism of the silicon, aluminum, calcium, iron, and carbon chemical network structure, reveal the evolution of waste component structure under multiple physical field conditions and its impact on material properties, and clarify the structure-performance relationship of products, providing technical support and theoretical basis for the high-value, large-scale, and clean cascade utilization of coal-based solid waste