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Title	An Investigation of Aromatic Derivatives Removal by Regenerative Combustion
Creator	Rey-Chein, Chang ; Wen-Chieh, Chen ; Wen-Chen, Chang
Publisher	Digitized by J. Willard Marriott Library, University of Utah
Date	1998
Spatial Coverage	presented at Maui, Hawaii
Abstract	Vaporised aromatic derivatives have been found in fast growing microelectronic industrial process, Taiwan EPA has classified them as the major hazardous air pollutants (HAP's) among VOC's and has recently regulated their emissions. In this presentation, an optimum bed array of honeycomb ceramic regenerator was first investigated and then proceeds design of the rotary regenerative combustion system to test destruction efficiency of VOC's. Under a range of combustion temperature from 650 to 850°C, the effect of heat recovery on destruction efficiency of aromatic derivatives were further investigated by varying the inlet concentration of process exhaust. The preliminary results show aromatic derivatives are barely destroyed at temperature below 850°C, but the destruction efficiency strongly depends on a maximized heat recovery of the exhaust gas, i.e., the heat recovery capability of honeycomb ceramic regenerator. Moreover, it seems to fasten destruction rate is subjected to those conditions is able to exhibit a higher heat recovery that inherent to cross the ignition temperature of the process exhaust, more experimental datum are needed to validate this concept and is yet under investigation.
Type	Text
Format	application/pdf
Language	eng
Rights	This material may be protected by copyright. Permission required for use in any form. For further information please contact the American Flame Research Committee.
Conversion Specifications	Original scanned with Canon EOS-1Ds Mark II, 16.7 megapixel digital camera and saved as 400 ppi uncompressed TIFF, 16 bit depth.
Scanning Technician	Cliodhna Davis
ARK	ark:/87278/s6dv1ngc
Setname	uu_afrc
ID	11570
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6dv1ngc

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Title	Page 14
Format	application/pdf
OCR Text	Show 14 Summary The diluted process exhaust preheated up to a temperature slightly cross ignition point is a criterion to fasten the combustion rate or lessen the residence time in combustion chamber. In this presentation, a rotary combustion system with ceramic honeycomb regenerators are found to exhibit highly efficient heat recovery, that seems to be the key to prevent partial oxidation occurs at higher conversion and enhance the combustion reaction. Furthermore, chlorinated aromatics are being tested to investigate the feasibility to reform dioxin derivatives, by varying the array of regenerator bed. References 1. Handbook of Organic Industrial Solvents, 5th Edition (1980) 2. OSHA/NIOSH Occupational Health Guides Chemical Hazard Acgih (TLV) (1984-1985) 3. W. Chu and H. Windawi, " Control VOC's via Catalytic Oxidation", Chem. Eng. Progress, March (1996) 4. "Air Toxics & VOC's", Mclvanine Co., (1991) , Chapter XII pp59. 5. M.S. Jenning, et. al, " Catalytic Incineration for Control of Volatile Organic Compound Emission", Noyes Publications, U.S.A. (1987) 6. J.M. Klobucar, " Choose the Best Heat-Recovery Method for Thermal Oxidizers", Chem. Eng. Progress, April (1995) 7. R. Tanaka, K. Kishimoto and T. Hasegawa, " High Efficiency Heat Transfer Method with use of High Temperature Pre-heated Air and Gas-circulation", Science and Technology, Vol. 1, No.4 (1994) (In Japanese) 8. R. Tanaka, et. al., " High Temperature Air Combustion under Development", Energy Saving, Vol. 48, No.l 0 (1996) (In Japanese) 9. Nippon Furnace Kogyo Kaisha, " High Performance Regenerator", NFK Technical Report, July (1997) (In Japanese) 10.P. N. Cheremisinoff, " Industrial Odor Control Pocket Handbook ", ppl 94, Pudvan Publishing CO., Inc. (1988)
Setname	uu_afrc
ID	11568
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6dv1ngc/11568