Reaction Rate of the Production of Dimethyl Carbonate Directly from the Supercritical CO_2 and Methanol
スポンサーリンク
概要
- 論文の詳細を見る
The reaction rate of the dimethyl carbonate (DMC) synthesis directly from carbon dioxide and methanol at a supercritical homogeneous state with a tin liquid catalyst is studied. Since the experimental time course for the reaction scheme has been already reported, the rate for the reverse reaction is obtained by a semi-batch reactor in this study. Together with previously reported data, the rate equations for the forward and the reverse reactions are modeled to express the dehydration effect. With the rate equation proposed, the overall reaction rate is fairly predicted. The rate equation is also applied to a flow type reactor with a simplified model. The reaction simulation shows that 90% dehydration for the reaction mixture makes the DMC yields three times larger than that for no dehydration. In addition, the pressure effect on the yield is investigated. On the contrary to linear pressure dependence of the DMC yield in the semi-batch reactor, the amount of DMC product from the flow type reactor changes slightly with the pressure. It suggests that the reaction pressure for the flow type reactor can be less than that for semi-batch reactor, showing the possibility of the industrialization of the process.
- 社団法人 化学工学会の論文
- 2005-12-01
著者
-
IWAKABE Koichi
Department of Chemical Engineering, Graduate School of Science and Engineering, Tokyo Institute of T
-
NAKAIWA Masaru
Energy-Efficient Chemical Systems Group, Research Institute for Innovation in Sustainable Chemistry,
-
Nakaiwa Masaru
Energy-efficient Chemical Systems Group Research Institute For Innovation In Sustainable Chemistry N
-
Nakaiwa Masaru
Energy-efficient Chemical Systems Group Research Institute For Innovation In Sustainable Chemistry N
-
Iwakabe Koichi
Department Of Chemical Engineering Graduate School Of Science And Engineering Tokyo Institute Of Tec
-
Choi Jun-chul
Molecular Catalysis Group Research Institute For Innovation In Sustainable Chemistry National Instit
-
Takahashi Toshikazu
Molecular Catalysis Group Research Institute For Innovation In Sustainable Chemistry National Instit
-
SAKAKURA Toshiyasu
Molecular Catalysis Group, Research Institute for Innovation in Sustainable Chemistry, National Inst
-
YASUDA Hiroyuki
Molecular Catalysis Group, Research Institute for Innovation in Sustainable Chemistry, National Inst
-
OOSHIMA Yoshihiro
Department of Applied Chemistry, Faculty of Science and Engineering, Chuo University
-
Ooshima Yoshihiro
Department Of Applied Chemistry Faculty Of Science And Engineering Chuo University
-
Sakakura Toshiyasu
Molecular Catalysis Group Research Institute For Innovation In Sustainable Chemistry National Instit
-
Yasuda Hiroyuki
Molecular Catalysis Group Research Institute For Innovation In Sustainable Chemistry National Instit
関連論文
- Performance of an Internally Heat-Integrated Distillation Column (HIDiC) in Separation of Ternary Mixtures
- New System for Electric Power Generation by Wet Oxidation of Biomass Ethanol
- On the Startup of Ideal Heat Integrated Distillation Columns (HIDiC)
- Identification and Internal Model Control of an Ideal Heat Integrated Distillation Column(HIDiC)
- 理想的内部熱交換型蒸留塔(HIDiC) の性能評価
- DYNAMICS OF IDEAL HEAT INTEGRATED DISTILLATION COLUMNS
- A NUMERICAL CONSIDERATION ON DYNAMIC MODELING AND CONTROL OF IDEAL HEAT INTEGRATED DISTILLATION COLUMNS
- Reaction Rate of the Production of Dimethyl Carbonate Directly from the Supercritical CO_2 and Methanol
- Interpreting Design of an Ideal Heat-Integrated Distillation Column through Exergy Analysis
- Choosing More Controllable Configuration for an Internally Heat-Integrated Distillation Column
- Graphical Synthesis of an Internally Heat-Integrated Distillation Column
- The Influences of Pressure Distribution on an Ideal Heat-Integrated Distillation Column (HIDiC)
- A Simple Method for Modeling Process Asymmetry
- Brownian Dynamics Simulation Study of Self-Diffusion of a Charged Particle in Swollen Counter-Charged Hydrogel Modeled as Cubic Lattice
- Energy Saving Characteristics of the Internally Heat Integrated Distillation Column (HIDiC) Pilot Plant for Multicomponent Petroleum Distillation
- Recent Advances in Internally Heat-Integrated Distillation Columns (HIDiC) for Sustainable Development