In recent years, the problems of traffic congestion, energy crisis, and environmental pollution in the traditional transport modes have severely restricted the sustainable development of both economics and ecological environmental.The tube-contained raw material pipeline hydraulic transportation is a transport method with both energy saving and environmental protection, which overcomes the shortcomings of traditional transport modes.In order to analyze the hydraulic characteristics of vibrational transport of a piped carriage within a pipeline, the fluid-solid coupling solution between fluid domain of the flow field and the solid domain of the piped carriage within the pipeline was given, and simulated results were compared with experimental results.The results show that the instantaneous translational speed and instantaneous rotational angular speed of the piped carriage are in fluctuating state, and the motion of the piped carriage is regarded as vibrational transport.The increase in the placement angle of the guide vane causes both the translational speed and the rotational angular speed of the piped carriage to increase.The annular gap flow and the pipe fluid mixed with each other, causes the pressure at the downstream flow field of the piped carriage to first decrease and then increase.The velocity distributions of vibrational transport of the piped carriage are unified, while the pressure distributions shows a descending trend.The increase in the placement angle of the guide vane causes the average pressure drop coefficient to first decrease and then increase, and when the placement angle is set to 24°, the average pressure drop coefficient reaches the minimum.This paper provides a theoretical basis for practical application of the tube-contained raw material pipeline hydraulic transportation.
Key words
fluid-structure interaction /
piped carriage /
hydraulic characteristics /
guide vane /
vibrational transport
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