Numerical Simulation of a Microwave Driven Low Pressure Plasma for PET Bottle Treatment

Daniel Szeremley, Simon Steves, Peter Awakowicz, Ralf Peter Brinkmann, Mark J. Kushner, Thomas Mussenbrock

39th IEEE In­ter­na­tio­nal Con­fe­rence on Plas­ma Sci­ence 2012, Edinburgh, Scottland, Juli 08-12


Abstract

Due to a growing demand for bottles made of polyethylene terephthalate (PET) fast and efficient sterilization processes as well as barrier coating to decrease gas permeation are required. Plasma sterilization is an alternative way of sterilizing PET without using toxic ingredients (e.g. hydrogen peroxide or peracetic acid). To allow investigations in the field of plasma sterilization of PET bottles, a microwave plasma reactor has been developed. A coaxial waveguide combined with a gas-inlet, a modified plasmaline, is used for both coupling the microwave power and injecting the gas mixture into the bottle. One key parameter in the context of plasma treatment of bottles is the ion energy distribution function (IEDF) at the inner surface of the bottle. Numerical results for IEDFs performed by means of the Hybrid Plasma Equipment Model (HPEM) are presented. Plasmas with relevant gas mixtures (Ar, ArH_2 and ArO_2) at different pressures and input powers are examined. The numerical results are compared with experimentally obtained data.

Tags: Low Pressure Plasma, Microwave Driven, numerical simulation, PET Bottel Treatment