Research articles
Calculation and analysis of sub/supercritical
methanol preheating tube for continuous production of biodiesel via
supercritical methanol transesterification
1.Engineering Research
Center of Large Scale Reactor Engineering and Technology, Ministry
of Education, State-Key Laboratory of Chemical Engineering, East China
University of Science and Technology , Shanghai 200237, China; Key
Laboratory for Green Chemical Process of Ministry of Education, Wuhan
Institute of Technology, Wuhan 430073, China; 2.Engineering Research
Center of Large Scale Reactor Engineering and Technology, Ministry
of Education, State-Key Laboratory of Chemical Engineering, East China
University of Science and Technology , Shanghai 200237, China; 3.Key Laboratory for Green
Chemical Process of Ministry of Education, Wuhan Institute of Technology,
Wuhan 430073, China;
Available online: 2009-12-05
Abstract
Biodiesel is an important renewable energy. Supercritical methanol transesterification for biodiesel has recently been concerned because of its obvious advantages. The tubular reactor is an ideal reactor for continuous preparation of biodiesel via supercritical methanol transesterification. A methanol preheating tube is necessary for the tubular reaction system because the reaction temperature for supercritical methanol transesterification is usually 520―600K. Therefore, in the range of 298―600K, changes of the density, isobaric capacity, viscosity and thermal conductivity of sub/supercritical methanol with temperature are first discussed. Then on the basis of these thermophysical properties, an integration method is adopted for the design of sub/supercritical methanol preheating tube when methanol is preheated from 298K to 600K at 16MPa and the influencing factors on the length of the preheating tube are also studied. The computational results show that the Reynolds number and the local convection heat-transfer coefficient of sub/supercritical methanol flowing in ф6mm×1.5mm preheating tube change drastically with temperature. For the local overall heat transfer coefficient and the average overall heat transfer coefficient , temperature also has an important influence on them when the inlet velocity of methanol is lower than 0.5m/s. But when the inlet velocity of methanol is higher than 0.5m/s, and almost keep invariable with temperature. Additionally, both the outlet temperature and the inlet velocity of methanol are the key affecting factors for the length of the preheating tube, especially when the outlet temperature is over the critical temperature of methanol. At the same time, the increase of tin bath’s temperature can shorten the required length of the preheating tube. At the inlet flow rate of 0.5m/s, the required length of the preheating tube is 2.0m when methanol is preheated from 298K to 590K at 16MPa with keeping the tin bath’s temperature 620K, which is in good agreement with the experimental results.