Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
6640619 | Fuel | 2013 | 10 Pages |
Abstract
The aim of this work was to develop a detailed and practical set of kinetic equations easily applicable to further studies on simulation and experimentation at a larger scale. In addition, pyrolysis-hydrolysis tests in SCW were also conducted concluding that, in the case of IPA, these reactions do not significantly interfere with SCWO. The required experimentation was performed in a tubular reactor system at laboratory scale at a constant pressure of 25 MPa, using pure oxygen as oxidant and monitoring the efficiency of the oxidation process in terms of reduction in chemical oxygen demand (COD) and total organic carbon (TOC) versus the residence time. This study consists of two major blocks: (a) a set of experiments on SCWO of IPA under a constant excess of oxygen (=100%) and different temperatures ranging from 673 to 773 K. Two-parameter mathematical models involving two steps (a fast reaction followed by a slow reaction) were proposed to describe the IPA SCWO kinetics and to calculate the corresponding kinetic parameters, assuming a zero order for oxygen concentration; and (b) a complementary set of experiments on SCWO of IPA at a constant temperature (748 K) and different oxidant coefficients from n = 0.5 (50% of stoichiometric oxygen) to n = 2.0 (100% oxygen excess), proposing a kinetic model for oxygen concentration dependence whose parameters were determined using a Runge-Kutta-fourth-order algorithm. The kinetic models proposed allow the prediction of the COD or TOC conversion with or without respect to oxygen supply in order to optimize the SCWO operating conditions and to minimize investment and operating costs.
Related Topics
Physical Sciences and Engineering
Chemical Engineering
Chemical Engineering (General)
Authors
J. Abelleira, J. Sánchez-Oneto, J.R. Portela, E.J. MartÃnez de la Ossa,