Title :
Thermal pulsed-plasma technology for hazardous waste treatment
Author :
Wald, S. ; Glocker, Ben ; Weiss, E. ; Pokryvailo, A. ; Labrune, P. ; Kempenaers, P. ; Handte, J.
Author_Institution :
Propulsion Phys. Lab., Soreq Nucl. Res. Center, Yavne, Israel
Abstract :
Summary form only given , as follows. A new, efficient, and environmentally friendly pulsed-plasma technology for hazardous waste treatment is presented. The waste material is decomposed using a high-energy pulsed-plasma jet produced in a confined discharge. Tests were successfully carried out in a modular, transportable laboratory. It comprises a pulsed power supply, confined plasma discharge injector, reactor, gas handling and monitoring systems. The 5-stage PFN designed for 5 million shots, provides up to 30 kJ, 40 kA, 0.3 ms pulses at 1 Hz. The plasma jet temperature is in the range of 2.5 to 5 eV, with a density of 10/sup -3/-10/sup -4/ g/cm/sup 3/ and velocity of about 10 km/s. The major technological challenge is the development of the repetitive plasma injector. An injector withstanding almost 1000 shots before replacement of a few consumable components has already been demonstrated. Experiments were performed using perchloroethylene and trichlroethylene as reference materials and real industrial waste comprising mono- and dichlorobenzene (30-70%). The tests were performed in several operation scenarios and under various operation parameters. It was found that complete destruction of about 2cc of waste per shot could be achieved by direct injection into the plasma injector. The energy needed was 7-9 kJ/shot-considerably below (at least by 50%) the amount of energy required in other thermal methods. It was found that the system could run without additional gas supply. The vapor pressure of the waste material was sufficient to starting the discharge while the waste itself formed the plasma. The test results proved the technical and economical feasibility of the technology. Further R&D is required in order to industrialize the components, especially the plasma injector, and to define the process for specific wastes of interest.
Keywords :
discharges (electric); plasma applications; plasma chemistry; plasma density; plasma devices; plasma jets; plasma temperature; pulsed power supplies; vapour pressure; waste disposal; 0.3 ms; 1 Hz; 10 km/s; 30 kJ; 40 kA; 7 to 9 kJ; complete destruction; confined discharge; confined plasma discharge injector; consumable components; density; dichlorobenzene; direct injection; discharge; economical feasibility; energy; environmentally friendly pulsed-plasma technology; gas handling systems; gas monitoring systems; hazardous waste treatment; high-energy pulsed-plasma jet; modular transportable laboratory; mono-chlorobenzene; operation parameters; operation scenarios; perchloroethylene; plasma injector; plasma jet temperature; pulsed power supply; reactor; real industrial waste; reference materials; repetitive plasma injector; technical feasibility; technological challenge; thermal methods; thermal pulsed-plasma technology; trichlroethylene; vapor pressure; velocity; waste; waste material; Laboratories; Plasma applications; Plasma confinement; Plasma density; Plasma materials processing; Plasma temperature; Plasma transport processes; Pulsed power supplies; Testing; Waste materials;
Conference_Titel :
Pulsed Power Plasma Science, 2001. IEEE Conference Record - Abstracts
Conference_Location :
Las Vegas, NV, USA
Print_ISBN :
0-7803-7141-0
DOI :
10.1109/PPPS.2001.961416