Study On Temperature Distribution On Different Combination Of Liquid And Gases For Plasma Generation Using Ansys Fluent

Lam, Chee Sheng (2018) Study On Temperature Distribution On Different Combination Of Liquid And Gases For Plasma Generation Using Ansys Fluent. Project Report. Universiti Teknikal Malaysia Melaka, Melaka, Malaysia. (Submitted)

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Abstract

Study on temperature distribution on different combination of liquid and gases for in liquid plasma refers to study on the generation, use, conversion of thermal energy generated by microwave oven to the reactor. Concept of microwave heat transfer is acquired. This study focuses on heat distribution in the reactor that will lead to generation of in liquid plasma after bubble is formed through evaporation process. Different combination of liquids and gases which are H2O, Palm Oil with argon or helium gas are compared. This study also suggested ideal condition for in liquid plasma generation. Plasma is a type of ionized gas with radical species electron like OH, Hα, Hβ that generated after bubble is formed during evaporation process. Temperature distribution indicates heat transfer to the reactor will be analysed by using ANSYS software and discussion is made on temperature contour generated. Design of the simulation is by placing copper electrode on PTFE platform and put inside a glass reactor covered by Teflon. Heat wave supplied to the system is microwave at a frequency of 2.45GHz at power rating of 750W. Liquid molecule will be breakdown by radical species electron and react chemically to form hydrogen gas. It is found that combination of palm-oil and argon gas has a good potential for the formation of in liquid plasma hence increase production of hydrogen gas. Result can be explained based on thermodynamic properties of the liquid and gas respectively

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