ABSTRACT
Chemical-looping combustion is a technology with inherent separation of the greenhouse gas CO₂. The technique uses an oxygen carrier made up of particulate metal oxide to transfer oxygen from combustion air to fuel. In this work, an oxygen carrier consisting of 60% NiO and 40 % NiAl₂O₄ was used in a 10 kW CLC reactor system for 160 hours of operation with fuel. The first three hours of fuel operation excepted, the test series was accomplished with the same batch of oxygen carrier particles. The fuel used in the experiments was natural gas, and a fuel conversion to CO₂ of more than 99% was accomplished. Combustion conditions were very stable during the test period, except for the operation at sub-stoichiometric conditions. It was shown that the methane fraction in the fuel reactor exit gas was dependent upon the rate of solids circulation, with higher circulation leading to more unconverted methane. The carbon monoxide fraction was found to follow the thermodynamical equilibrium for all investigated fuel reactor temperatures, 660°C – 950°C. Thermal analysis of the fuel reactor at stable conditions enabled calculation of the particle circulation which was found to be approximately 4 kg/s,MW. The loss of fines, i.e. elutriated oxygen carrier particles with diameter < 45 μm, decreased during the entire test period. After 160 h of operation the fractional loss of fines was 0.00022/h, corresponding to a particle life time of 4500 h.