Title :
Direct Decomposition of Anesthetic Gas Exhaust Using Atmospheric Pressure Multigas Inductively Coupled Plasma
Author :
Tamura, Toshiyuki ; Kaburaki, Yuki ; Sasaki, Ryota ; Miyahara, Hidekazu ; Okino, Akitoshi
Author_Institution :
Dept. of Energy Sci., Tokyo Inst. of Technol., Yokohama, Japan
Abstract :
In our research group, an atmospheric multigas inductively coupled plasma (ICP) source was developed for industrial plasma processing and elemental analysis. The plasma source can stably generate atmospheric thermal plasma not only by Ar but also by He, O2, N2, CO2, air, and their mixture gas. In this paper, the plasma source was applied for anesthetic gas decomposition including N2O, which is a kind of global warming gases. Atmospheric thermal plasma was generated by mixture gas of N2O, O2, and air. It corresponds to actual gas composition for up to three surgery exhaust. Spectroscopic characteristics of generated plasma and composition of treated gas were investigated. By using optimally shaped ICP torch, 99.9% of decomposition rate and 942 g/kWh of high energy efficiency were achieved. However, around 3% of NOx was generated as by-products due to high gas temperature.
Keywords :
plasma diagnostics; plasma pressure; plasma sources; plasma temperature; plasma torches; N2O global warming gases; anesthetic gas exhaust; atmospheric pressure; atmospheric thermal plasma; decomposition rate; direct decomposition; elemental analysis; high gas temperature; industrial plasma processing; multigas inductively coupled plasma; optimally shaped ICP torch; plasma source; pressure 1 atm; spectroscopic characteristics; three surgery exhaust; treated gas composition; Iterative closest point algorithm; Plasma measurements; Plasma temperature; Radio frequency; Surgery; Temperature measurement; Atmospheric pressure thermal plasma; nitrous oxide; plasma applications; waste gas treatment;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2011.2155103
