An Investigation of Controlled Oscillations in a Plasma Torch for Combustion Enhancement

Sanders, Darius Demetri

An Investigation of Controlled Oscillations in a Plasma Torch for Combustion Enhancement

dc.contributor.author	Sanders, Darius Demetri	en
dc.contributor.committeechair	O'Brien, Walter F. Jr.	en
dc.contributor.committeemember	Vlachos, Pavlos P.	en
dc.contributor.committeemember	Schetz, Joseph A.	en
dc.contributor.department	Mechanical Engineering	en
dc.date.accessioned	2014-03-14T20:47:53Z	en
dc.date.adate	2005-12-06	en
dc.date.available	2014-03-14T20:47:53Z	en
dc.date.issued	2005-11-02	en
dc.date.rdate	2006-12-06	en
dc.date.sdate	2005-11-14	en
dc.description.abstract	The oscillating plasma torch is proposed as a potential device that will produce an oscillating shock and resulting control of the supersonic combustion process. This research will capitalize on previous results [Gallimore, 1998] which indicate that the plasma torch oscillations originate from the inherent oscillations of the voltage applied to the torch. The aim of this research is to thoroughly investigate the oscillation behavior of the plasma torch with the plan of ultimately controlling the oscillation at chosen frequencies. A modulating power system used for dynamic control of the plasma torch oscillation was designed and tested in quiescent conditions (no flow), Mach 2.4 cold supersonic flow, and Mach 2 heated supersonic flow conditions. The oscillating plasma torch used nitrogen feedstock and was operated over a frequency range of 2Hz- 4kHz. A dynamic torch model using the hybrid Mayr-Cassie electric arc model was developed to predict the plasma torch electric arc response at appropriate frequencies for interaction with supersonic combustion. In quiescent conditions, the dynamic response of the plasma torch power system and plasma jet were characterized using signal processing techniques and high speed video imaging. High speed Schlieren images were used to determine the behavior of the oscillating plasma jet in Mach 2.4 cross flow and its influence on the induced shock structure. The unsteady nitrogen-fed torch was integrated with the flush walled 4-hole aerodynamic ramp injector using hydrogen and hydrocarbon fuels at the University of Virginia Aerospace Research Lab (ARL) heated Mach 2 supersonic flow. Unsteady pressure variations from the oscillating shock produced by the plasma torch were recorded using recess-mounted Kulite pressure transducers. Also, measurements of the static pressure of the combustion produced by the oscillating plasma torch were obtained. The oscillating torch system performed well over a range of different flow conditions. It will enable active control input to the combustion process. The controllable unsteady blockage might provide a type shock interaction needed to increase turbulence and mixing augmentation [Kumar, et al. 1987].	en
dc.description.degree	Master of Science	en
dc.identifier.other	etd-11142005-222336	en
dc.identifier.sourceurl	http://scholar.lib.vt.edu/theses/available/etd-11142005-222336/	en
dc.identifier.uri	http://hdl.handle.net/10919/35700	en
dc.publisher	Virginia Tech	en
dc.relation.haspart	cap0004.mpg	en
dc.relation.haspart	feedstock.avi	en
dc.relation.haspart	DariusSandersMSThesis.pdf	en
dc.relation.haspart	ShockPT_movie.avi	en
dc.relation.haspart	d0408run35.wav	en
dc.relation.haspart	d0408run46.wav	en
dc.relation.haspart	0408triangle128hz1.avi	en
dc.relation.haspart	126sin256HzVT.avi	en
dc.relation.haspart	0408sin1024hz3.avi	en
dc.rights	In Copyright	en
dc.rights.uri	http://rightsstatements.org/vocab/InC/1.0/	en
dc.subject	plasma torch	en
dc.subject	oscillation	en
dc.subject	unsteady combustion	en
dc.subject	unsteady shocks	en
dc.title	An Investigation of Controlled Oscillations in a Plasma Torch for Combustion Enhancement	en
dc.type	Thesis	en
thesis.degree.discipline	Mechanical Engineering	en
thesis.degree.grantor	Virginia Polytechnic Institute and State University	en
thesis.degree.level	masters	en
thesis.degree.name	Master of Science	en