Thermal decomposition of chrysotile-containing wastes in a water vapor atmosphere
スポンサーリンク
概要
- 論文の詳細を見る
A simple thermal decomposition technique to convert asbestos-containing wastes (ACWs) into non-asbestos products has been developed by heating ACWs in a water vapor atmosphere. It was confirmed that cement slates containing 18 mass % chrysotile were converted into non-asbestos products by the thermal treatment in a water vapor atmosphere at 800°C for 2 h. In contrast, the thermal treatments in air required temperatures as high as 900°C to convert the cement slates into non-asbestos products. It should be noted that any chrysotile particles were not detected by the phase-contrast microscopic observation in the products after the thermal treatments in a water vapor atmosphere at temperatures beyond 800°C but three or less chrysotile particles remained after the thermal treatments in air at high temperatures beyond 900°C. In a water vapor atmosphere, ACWs were successfully converted into non-asbestos products at low temperatures below 800°C for 2 h by accelerated solid-state reactions between decomposed products of chrysotile and cement components to form calcium magnesium silicates. This technique may contribute to large-scale decomposition of ACWs with low energy consumption in comparison with the traditional melting method.
- 公益社団法人 日本セラミックス協会の論文
著者
-
Yanagisawa Kazumichi
Research Laboratory Of Hydrothermal Chemistry Faculty Of Science Kochi University
-
KOZAWA Takahiro
Research Laboratory of hydrothermal Chemistry, Faculty of Science, Kochi University
-
ONDA Ayumu
Research Laboratory of hydrothermal Chemistry, Faculty of Science, Kochi University
-
CHIBA Osamu
Technical Research Institute, Toda Co.
-
ISHIWATA Hiroyuki
Technical Research Institute, Nishimatsu Construction Co., Ltd.
-
TAKANAMI Tetsuro
Division of Environmental Engineering, Daioh Shinyo Co., Ltd.
関連論文
- Synthesis of Lithiophorite with Sandwich Layered Structure by Hydrothermal Soft Chemical Process
- Topotactic Preparation of Preferentially Oriented BaTiO_3 and TiO_2 Thin Films on Polycrystalline Substrate
- Hydrothermal Soft Chemical Synthesis of Ni(OH)_2-Birnessite Sandwich Layered Compound and Layered LiNi_Mn_O_2
- Growth of Barium Chlorapatite Crystals from a Sodium Chloride Flux
- Hydrothermal Crystal Growth of Lamthanum-Modified Lead Zirconate Titanate
- Crystal Growth of Lead Zirconate Titanate with Additives under Hydrothermal Conditions
- Occurrence and lithofacies of shungite : early Proterozoic carbon-rich rocks from Karelia, northwestern Russia
- Salt-assisted Solid-state Chemical Reaction. Synthesis of ZnO Nanocrystals
- Growth of Strontium Chlorapatite Crystals from a Sodium Chloride Flux
- Solvothermal Preparation and Control of Phase Composition of Nanosized Rhodium Sulfide Particles
- Hierarchically Structured Snowflakelike WO_3・0.33H_2O Particles Prepared by a Facile, Green, and Microwave-assisted Method
- LOW TEMPERATURE SINTERING OF SEPIOLITE BY HYDROTERMAL HOT-PRESSING TECHNIQUE
- Immobilization of Radioactive Wastes in Hydrothermal Synthetic Rock : Lithification of Silica Powder
- Hydrothermal Preparation of Ceramic Powders with Controlled Morphology
- Thermal decomposition of chrysotile-containing wastes in a water vapor atmosphere
- Accelerated Formation of β-Dicalcium Silicate by Solid-state Reaction in Water Vapor Atmosphere
- Spin-coating Preparation of High Quality Mesoporous Titania Nanofilms
- Immobilization of Radioactive Wastes in Hydrothermal Synthetic Rock, (III) : Properties of Waste Form Containing Simulated High-Level Radioactive Waste
- Hydrothermal Synthesis of ZnO Long Fibers
- Occurrence and lithofacies of shungite: early Proterozoic carbon-rich rocks from Karelia, northwestern Russia
- Immobilization of radioactive wastes in hydrothermal synthetic rock, (II) Hydrothermal synthesis of pollucite.:Hydrothermal Synthesis of Pollucite
- Immobilization of cesium into pollucite structure by hydrothermal hot-pressing.
- Hydrothermal Synthesis of Boehmite Plate Crystals