Flexibility of a combined heat and power system with thermal energy storage for district heating

The trend towards an increased importance of distributed (renewable) energy resources characterized by intermittent operation redefines the energy landscape. The stochastic nature of the energy systems on the supply side requires increased flexibility at the demand side. We present a model that determines the theoretical maximum of flexibility of a combined heat and power system coupled to a thermal energy storage solution that can be either centralized or decentralized. Conventional central heating, to meet the heat demand at peak moments, is also available. The implications of both storage concepts are evaluated in a reference district. The amount of flexibility created in the district heating system is determined by the approach of the system through delayed or forced operation mode. It is found that the distinction between the implementation of the thermal energy storage as a central unit or as a collection of local units, has a dramatic effect on the amount of available flexibility.

[1]  Jørgen Erik Christensen,et al.  Low-energy district heating in energy-efficient building areas , 2011 .

[2]  Anders N. Andersen,et al.  Exploration of economical sizing of gas engine and thermal store for combined heat and power plants in the UK , 2008 .

[3]  Luisa F. Cabeza,et al.  Review on thermal energy storage with phase change: materials, heat transfer analysis and applications , 2003 .

[4]  Anders N. Andersen,et al.  Feasibility of CHP-plants with thermal stores in the German spot market , 2009 .

[5]  Chris Develder,et al.  LINEAR: towards a breakthrough of smart grids in Flanders , 2010 .

[6]  Fabio Polonara,et al.  State of the art of thermal storage for demand-side management , 2012 .

[7]  Marc A. Rosen,et al.  District heating and cooling: Review of technology and potential enhancements , 2012 .

[8]  Sven Werner,et al.  Profitability of sparse district heating , 2008 .

[9]  Luisa F. Cabeza,et al.  Materials used as PCM in thermal energy storage in buildings: A review , 2011 .

[10]  R. Nordman IEA Technology Roadmap - Energy-efficient Buildings : Heating and Cooling Equipment , 2011 .

[11]  Poul Alberg Østergaard,et al.  Ancillary services and the integration of substantial quantities of wind power , 2006 .

[12]  Brian Vad Mathiesen,et al.  Comparative analyses of seven technologies to facilitate the integration of fluctuating renewable energy sources , 2009 .

[13]  José María Sala,et al.  Implications of the modelling of stratified hot water storage tanks in the simulation of CHP plants , 2011 .

[14]  Christof Wittwer,et al.  Decentralised optimisation of cogeneration in virtual power plants , 2010 .

[15]  Sara Rainieri,et al.  Modeling of a thermal energy storage system coupled with combined heat and power generation for the heating requirements of a University Campus , 2010 .

[16]  Morgan Fröling,et al.  Environmental performance of district heating in suburban areas compared with heat pump and pellets furnace , 2006 .

[17]  Amar M. Khudhair,et al.  A review on phase change energy storage: materials and applications , 2004 .

[18]  Renato Lazzarin,et al.  Local or district heating by natural gas: Which is better from energetic, environmental and economic point of views? , 2006 .

[19]  Juha Kiviluoma,et al.  Influence of wind power, plug-in electric vehicles, and heat storages on power system investments , 2010 .

[20]  U. Persson,et al.  Heat distribution and the future competitiveness of district heating , 2011 .

[21]  Vittorio Verda,et al.  Primary energy savings through thermal storage in district heating networks , 2011 .

[22]  Lieve Helsen,et al.  The impact of thermal storage on the operational behaviour of residential CHP facilities and the overall CO2 emissions , 2007 .