SIMULATION OF ACOUSTIC ENERGY TRANSFER THROUGH A MULTILAYER SYSTEM FOR CHANGING THE RHEOLOGICAL PROPERTIES OF HYDROCARBONS

Relevance of the research is caused by the need to determine the acoustic energy level of ultrasonic exposure propagation in a multilayer system. This is required to develop the engineering project of ultrasonic devices which would modify the hydrocarbon fuel rheological properties. This, in its tur...

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Bibliographic Details
Published in:Bulletin of the Tomsk Polytechnic University Geo Assets Engineering
Main Authors: Anton V. Azin, Eugene P. Bogdanov, Sergey V. Rikkonen
Format: Article in Journal/Newspaper
Language:Russian
Published: Tomsk Polytechnic University 2023
Subjects:
Online Access:https://doi.org/10.18799/24131830/2023/3/3953
https://doaj.org/article/fb21a3a079f0408991e6a1f12452a656
Description
Summary:Relevance of the research is caused by the need to determine the acoustic energy level of ultrasonic exposure propagation in a multilayer system. This is required to develop the engineering project of ultrasonic devices which would modify the hydrocarbon fuel rheological properties. This, in its turn, could further their application in energy complex facilities in the Arctic and Antarctic environments. Aim: to develop a mathematical model for ultrasonic radiation propagation in a multilayer system with the determination of the energy at each resonance. Such a model would take into account the design-type of the ultrasound resonant emitter. Object: design-type of the ultrasound resonant emitter, multilayer system and physical model system: «ultrasonic emitter – multilayer system». Methods: mathematical modeling of ultrasonic radiation propagation within a multilayer system, considering the following impact factors: design-type of the ultrasound resonant emitter, operating mode, number of layers and material mechanical properties of the multilayer system. Experiments were based on the physical model system: «ultrasonic emitter – multilayer system». Experimental data verification proved the effectiveness of the mathematical model. Results. This mathematical model enables to determine and calculate the energy and frequency characteristics of acoustic radiation in each layer within the multilayer system itself. Ultrasonic resonant emitter operating experiments under one plexiglass-layer, two plexiglass-layer and three-plexiglass layer loads have been carried out. Estimated data are in good agreement with experiments, whereas, discrepancy does not exceed 15 %. Conclusion. Proposed and developed mathematical model enables the ultrasound resonant emitter-type to be designed, according to required power source capacity and frequency range. In this case, it could be applied for hydrocarbon fuel laboratory research.