Emission and economic performance assessment of a solid oxide fuel cell micro-combined heat and power system in a domestic building

Combined heat and power (CHP) is a promising technological configuration for reducing energy consumption and increasing energy security in the domestic built environment. Fuel cells, on account of their: high electrical efficiency, low emissions and useful heat output have been identified as a key technological option for improving both building energy efficiency and reducing emissions in domestic CHP applications. The work presented in this paper builds upon results currently reported in the literature of fuel cells operating in domestic building applications, with an emission and economic performance assessment of a real, commercially available SOFC mCHP system operating in a real building; under a UK context. This paper aims to assess the emission and economic performance of a commercially available solid oxide fuel cell (SOFC) mCHP system, operating at The University of Nottingham's Creative Energy Homes. The performance assessment evaluates, over a one year period, the associated carbon (emission assessment) and operational costs (economic assessment) of the SOFC mCHP case compared to a ‘base case’ of grid electricity and a highly efficient gas boiler. Results from the annual assessment show that the SOFC mCHP system can generate annual emission reductions of up to 56% and cost reductions of 177% compared to the base case scenario. However support mechanisms such as; electrical export, feed in tariff and export tariff, are required in order to achieve this, the results are significantly less without. A net present value (NPV) analysis shows that the base case is still more profitable over a 15 year period, even though the SOFC mCHP system generates annual revenue; this is on account of the SOFC's high capital cost. In summary, grid interaction and incubator support is essential for significant annual emission and cost reductions compared to a grid electricity and gas boiler scenario. Currently capital cost is the greatest barrier to the economic viability of the system.

[1]  Viktor Dorer,et al.  Modelling and evaluation of building integrated SOFC systems , 2011 .

[2]  Adam Hawkes,et al.  Fuel cells for micro-combined heat and power generation , 2009 .

[3]  C Roselli,et al.  An Experimental and Simulation-Based Investigation of the Performance of Small-Scale Fuel Cell and Combustion-Based Cogeneration Devices Serving Residential Buildings , 2008 .

[4]  Iain Staffell,et al.  Fuel cells for domestic heat and power: are they worth it? , 2010 .

[5]  Aidong Yang,et al.  Modelling and selection of micro-CHP systems for domestic energy supply: The dimension of network-wide primary energy consumption , 2014 .

[6]  Eric S. Fraga,et al.  Modelling and Optimisation in Terms of CO2 Emissions of a Solid Oxide Fuel Cell based Micro-CHP System in a Four Bedroom House in London , 2013 .

[7]  M. Gençoglu,et al.  Design of a PEM fuel cell system for residential application , 2009 .

[8]  H. Chandra,et al.  Application of solid oxide fuel cell technology for power generation—A review , 2013 .

[9]  Alex Ferguson,et al.  An Experimental and Simulation-based Investigation of the Performance of Small-scale Fuel Cell and Combustion-based Cogeneration Devices Serving Residential Buildings: Final Report of Annex 42 of the International Energy Agency's Energy Conservation in Buildings and Community Systems Programme , 2008 .

[10]  M. Newborough,et al.  Impact of micro-CHP systems on domestic sector CO2 emissions , 2005 .

[11]  Viktor Dorer,et al.  Performance assessment of fuel cell micro-cogeneration systems for residential buildings , 2005 .

[12]  Aidan Duffy,et al.  Economic, energy and GHG emissions performance evaluation of a WhisperGen Mk IV Stirling engine μ-CHP unit in a domestic dwelling , 2014 .

[13]  Nigel M. Sammes,et al.  Small-scale fuel cells for residential applications , 2000 .