Combustion of propane with Pt and Rh catalysts in a meso-scale heat recirculating combustor

• Published in: Applied energy Vol. 130; pp. 350 - 356
• Main Authors: Wierzbicki, Teresa A., Lee, Ivan C., Gupta, Ashwani K.
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 01.10.2014; Elsevier
• Subjects: Applied sciences; Catalytic combustion; Combustion behavior; Energy; Exact sciences and technology; Heat-recirculating combustor; Meso-scale combustion; Propane oxidation; Catalytic combustion; Combustion behavior; Meso-scale combustion; Heat-recirculating combustor; Propane oxidation; Combustion chamber; Platinum; Oxidation; Catalyst; Propane
• ISSN: 0306-2619; 1872-9118
• DOI: 10.1016/j.apenergy.2014.05.069

•Compared extinction limits of catalytic and non-catalytic combustor operation.•Analyzed catalytic conversion, product selectivity/yield, and activation energy.•Results used to predict the catalytic combustor performance with liquid fuel.•Catalysts offered enhanced stable operation of combustor than without catalyst.•Rh is more suitable for liquid fuel due to higher fuel conversion and output energy. The results obtained from the combustion behavior of propane over platinum and rhodium catalysts in a meso-scale heat recirculating combustor are presented. The extinction limits, conversion, product selectivity/yield, and activation energy using the two catalysts were compared in an effort to predict their performance using a liquid fuel. The extinction limits were also compared to those of non-catalytic combustion in the same combustor. The results showed that the use of a catalyst greatly expanded the range of stable operating conditions, in terms of both extinction limits and flow rates supported. The Rh catalyst was found to exhibit a higher propane conversion rate, reaching a maximum of 90.4% at stoichiometric conditions (as compared to only 61.4% offered by the Pt catalyst under lean conditions), but the Pt catalyst had superior CO2 selectivity for most of the examined conditions, indicating more of the heat released being used for product formation as opposed to being lost to the environment. However, despite having a higher rate of heat loss, the combustion with the Rh catalyst produced an overall higher amount of enthalpy than the Pt due to its superior fuel conversion. The Pt catalyst also had a significantly smaller activation energy (13.8kJ/mol) than the Rh catalyst (74.7kJ/mol), except at equivalence ratios richer than Φ=1.75 (corresponding to catalyst temperatures below 500°C), where it abruptly changed to 211.4kJ/mol, signifying a transition from diffusion-limited reactions to kinetically limited reactions at this point. The results reveal that Rh would be a more suitable catalyst for use in liquid-fueled meso-scale combustors, as fuel conversion has been found to be a limiting factor for combustion stability in these systems, and as its higher output energy allows for greater flexibility of use.