Affiliation:
1. Engineering Research Center of Resource Utilization of Carbon‐containing Waste with Carbon Neutrality of Ministry of Education, National Energy Coal Gasification Technology Research and Development Center, Shanghai Engineering Research Center of Coal Gasification East China University of Science and Technology Shanghai China
Abstract
AbstractUnderstanding the collective flow of nanoparticles is important for handling the storing, dosing, and conveying of nanoparticles. We experimentally studied the discharge characteristics of nanoparticles from the hopper through a microchannel under ultrasonic vibration. Results show that ultrasonic vibration can effectively trigger the flow of jammed nanoparticles, which flows in the form of aggregates at a controllable discharge rate as low as 0.1 mg/s. The aggregate properties were obtained from high‐speed image processing technology. The multi‐stage flow mechanism was revealed: particle re‐arrangement at low amplitude and wall slip at high amplitude. Given this, the discharge rate model was developed by introducing an exponential function G(Fr) into the traditional Beverloo equation. The modified model describes both the self‐organized behavior at low amplitudes and velocity scaling caused by acceleration at high amplitudes, successfully predicting the discharge rate within ± 10% errors.
Funder
National Natural Science Foundation of China