On the measurement of solids circulation rates in interconnected fluidized beds: Comparison of different experimental techniques

SFX Get it!(opens in a new window)|Full Text(opens in a new window)| Export | Download | Add to List | More... Powder Technology Volume 302, 1 November 2016, Pages 81-89 On the measurement of solids circulation rates in interconnected fluidized beds: Comparison of different experimental techniques (Article) Medrano, J.A.a, Nordio, M.ab, Manzolini, G.b, van Sint Annaland, M.a, Gallucci, F.a a Chemical Process Intensification, Department of Chemical Engineering and Chemistry, Eindhoven University of Technology, De Rondom 70, Eindhoven, Netherlands b Group of Energy Conversion Systems, Department of Energy, Politecnico di Milano, Via Lambruschini 4, Milano, Italy View references (31) Abstract Membrane assisted Chemical Looping Reforming (MA-CLR) is a novel concept recently proposed for efficient hydrogen production with integrated CO2 capture. This novel technology is based on the circulation of a solid (an oxygen and heat carrier) between two different reactors, an air reactor and a membrane assisted fuel reactor. The solids circulation rates (SCR) between the two reactors determine the oxygen and heat transfer rate and temperature difference between the reactors and hence the overall performance of the new concept. However, the prediction of the SCR is still based on empirical correlations while many different techniques have been used in the literature to measure it. In this work a comparison of three different experimental techniques for the SCR is presented. A pseudo 2D interconnected circulated fluidized bed system has been constructed and the SCR have been measured using an optical technique, a pressure difference technique and a particles extraction technique. The three methods have been compared for different experimental conditions by varying superficial gas velocities, particle diameter and particle type. Results show that the SCR can be well predicted with the pressure drop method as the results are in good agreement with both the optical technique and the particle extraction technique for both spherical particles and non-spherical particles. The fact that the optical and pressure methods are not intrusive represents the main advantage for both. However, while the optical technique gives more information on the distribution of the solids hold-up along the riser of the chemical looping system, it can only be applied to 2D systems as optical access is required. On the other hand, the pressure drop technique is much cheaper and easier to be applied and can also be used for 3D high temperature systems.