Production of Microstructure Materials from Incinerator Ashes Using Thermal Plasma Technology

碩士 === 國立臺北科技大學 === 材料及資源工程系碩士班 === 92 === Due to the population density was higher and rising quickly, the suitable place for traditional landfill was getting difficulty to find in Taiwan. Therefore, there are 30 MSW incinerators under construction and will be completed before end of 2005. It is es...

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Main Authors: Chih-Chien Tu, 杜志謙
Other Authors: Ta-Wui Cheng
Format: Others
Language:zh-TW
Published: 2004
Online Access:http://ndltd.ncl.edu.tw/handle/80321122320915481915
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spelling ndltd-TW-092TIT006810142016-06-15T04:16:50Z http://ndltd.ncl.edu.tw/handle/80321122320915481915 Production of Microstructure Materials from Incinerator Ashes Using Thermal Plasma Technology 焚化灰渣電漿熔融製成微晶材料之研究 Chih-Chien Tu 杜志謙 碩士 國立臺北科技大學 材料及資源工程系碩士班 92 Due to the population density was higher and rising quickly, the suitable place for traditional landfill was getting difficulty to find in Taiwan. Therefore, there are 30 MSW incinerators under construction and will be completed before end of 2005. It is estimated that over 1.5 to 2.0 million tones of incinerator ashes will be generated annually. These incinerated ashes contain large amount of hazardous materials such as heavy metals and Dioxins. If these hazardous materials cannot be carefully treated, it can be endanger the ecological environment. This research work applied the thermal plasma melting and vitrification technology to treat incinerator ashes. The melted slag can be produced the microstructure materials via sintering and heat treatment procedure. The experiment results showed that large amount of heavy metals, such as, Pb, Cd and Cu, evaporated into gas phase during melting, but Cr still remained in the incinerator ashes based slag. The activation energy of the crystallization for quenched slag were around 600-670 kJmol-1 by using non-isothermal method. During the lab-scale plasma molten system, the characterizations of the microstructure materials from slag-13 were better than that of fabricated form slag-31. When using the pilot-scale plasma molten system, the melting was quenching into water in order to obtain the glassiness slag. The properties of the microstructure materials from quenched slag were better than that of manufactured by slowly cooled slag. The best physical/mechanical and chemical resistance properties of the microstructure materials were produced at 1100-1150℃ for 2 hours heat treatment. Diopside and gehlenite were formed as the major crystalline phases. These microstructure materials have great potential for reutilization as non-porous or water permeable materials. Ta-Wui Cheng 鄭大偉 2004 學位論文 ; thesis 163 zh-TW
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language zh-TW
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sources NDLTD
description 碩士 === 國立臺北科技大學 === 材料及資源工程系碩士班 === 92 === Due to the population density was higher and rising quickly, the suitable place for traditional landfill was getting difficulty to find in Taiwan. Therefore, there are 30 MSW incinerators under construction and will be completed before end of 2005. It is estimated that over 1.5 to 2.0 million tones of incinerator ashes will be generated annually. These incinerated ashes contain large amount of hazardous materials such as heavy metals and Dioxins. If these hazardous materials cannot be carefully treated, it can be endanger the ecological environment. This research work applied the thermal plasma melting and vitrification technology to treat incinerator ashes. The melted slag can be produced the microstructure materials via sintering and heat treatment procedure. The experiment results showed that large amount of heavy metals, such as, Pb, Cd and Cu, evaporated into gas phase during melting, but Cr still remained in the incinerator ashes based slag. The activation energy of the crystallization for quenched slag were around 600-670 kJmol-1 by using non-isothermal method. During the lab-scale plasma molten system, the characterizations of the microstructure materials from slag-13 were better than that of fabricated form slag-31. When using the pilot-scale plasma molten system, the melting was quenching into water in order to obtain the glassiness slag. The properties of the microstructure materials from quenched slag were better than that of manufactured by slowly cooled slag. The best physical/mechanical and chemical resistance properties of the microstructure materials were produced at 1100-1150℃ for 2 hours heat treatment. Diopside and gehlenite were formed as the major crystalline phases. These microstructure materials have great potential for reutilization as non-porous or water permeable materials.
author2 Ta-Wui Cheng
author_facet Ta-Wui Cheng
Chih-Chien Tu
杜志謙
author Chih-Chien Tu
杜志謙
spellingShingle Chih-Chien Tu
杜志謙
Production of Microstructure Materials from Incinerator Ashes Using Thermal Plasma Technology
author_sort Chih-Chien Tu
title Production of Microstructure Materials from Incinerator Ashes Using Thermal Plasma Technology
title_short Production of Microstructure Materials from Incinerator Ashes Using Thermal Plasma Technology
title_full Production of Microstructure Materials from Incinerator Ashes Using Thermal Plasma Technology
title_fullStr Production of Microstructure Materials from Incinerator Ashes Using Thermal Plasma Technology
title_full_unstemmed Production of Microstructure Materials from Incinerator Ashes Using Thermal Plasma Technology
title_sort production of microstructure materials from incinerator ashes using thermal plasma technology
publishDate 2004
url http://ndltd.ncl.edu.tw/handle/80321122320915481915
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