Influence of the heat storage size on the plant performance in a Smart User case study
暂无分享,去创建一个
Giovanni Ferrara | Andrea Chesi | Lorenzo Ferrari | Fabio Tarani | Sandro Magnani | L. Ferrari | G. Ferrara | A. Chesi | F. Tarani | S. Magnani
[1] Paul Denholm,et al. Grid flexibility and storage required to achieve very high penetration of variable renewable electricity , 2011 .
[2] Antonio Piacentino,et al. An original multi-objective criterion for the design of small-scale polygeneration systems based on realistic operating conditions , 2008 .
[3] Min Dai,et al. Integration of Green and Renewable Energy in Electric Power Systems , 2009 .
[4] Antonio Piacentino,et al. A methodology for sizing a trigeneration plant in mediterranean areas , 2003 .
[5] V. I. Ugursal,et al. Residential cogeneration systems: Review of the current technology , 2006 .
[6] M. Newborough,et al. Impact of micro-CHP systems on domestic sector CO2 emissions , 2005 .
[7] M. L. Baughman,et al. Optimizing combined cogeneration and thermal storage systems , 1989 .
[8] José María Sala,et al. Implications of the modelling of stratified hot water storage tanks in the simulation of CHP plants , 2011 .
[9] Lieve Helsen,et al. The impact of thermal storage on the operational behaviour of residential CHP facilities and the overall CO2 emissions , 2007 .
[10] Peter Tzscheutschler,et al. Performance of Residential Cogeneration Systems in Germany. A Report of Subtask C of FC+COGEN-SIM The Simulation of Building-Integrated Fuel Cell and Other Cogeneration Systems. Annex 42 of the International Energy Agency Energy Conservation in Buildings and Community Systems Programme , 2008 .
[11] Jeffrey M. Gordon,et al. A general thermodynamic model for absorption chillers: Theory and experiment , 1995 .
[12] Wan-Chen Lu,et al. An evaluation of empirically-based models for predicting energy performance of vapor-compression water chillers , 2010 .
[13] Tomasz M. Mróz. Thermodynamic and economic performance of the LiBr–H2O single stage absorption water chiller , 2006 .
[14] Hongbo Ren,et al. Economic and environmental evaluation of micro CHP systems with different operating modes for residential buildings in Japan , 2010 .
[15] Paulien M. Herder,et al. Uncertainties in the design and operation of distributed energy resources: The case of micro-CHP systems , 2008 .
[16] P. R. Spina,et al. Analysis of innovative micro-CHP systems to meet household energy demands , 2012 .
[17] Ruzhu Wang,et al. COMBINED COOLING, HEATING AND POWER: A REVIEW , 2006 .
[18] Laura Vanoli,et al. Micro-combined heat and power in residential and light commercial applications , 2003 .
[19] Barbara Praetorius,et al. Micro Cogeneration: Towards Decentralized Energy Systems , 2005 .
[20] Azharul Karim,et al. Experimental investigation of a stratified chilled-water thermal storage system , 2011 .
[21] Neil Hewitt,et al. An investigation of a household size trigeneration running with hydrogen , 2011 .
[22] A. Fragaki,et al. Conditions for aggregation of CHP plants in the UK electricity market and exploration of plant size , 2011 .
[23] Xu Rong,et al. A review on distributed energy resources and MicroGrid , 2008 .
[24] K. Khan,et al. Energy conservation in buildings: cogeneration and cogeneration coupled with thermal energy storage , 2004 .
[25] S. P. Chowdhury,et al. Microgrids: Energy management by strategic deployment of DERs—A comprehensive survey , 2011 .
[26] Sourena Sattari,et al. Technical and economic feasibility study of using Micro CHP in the different climate zones of Iran , 2011 .
[27] Adam Hawkes,et al. Cost-effective operating strategy for residential micro-combined heat and power , 2007 .
[28] Jiacong Cao,et al. Optimization of Thermal Storage Based on Load Graph of Thermal Energy System , 2000 .
[29] 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 .
[30] Giuliano Dall'O',et al. Comparison between predicted and actual energy performance for summer cooling in high-performance residential buildings in the Lombardy region (Italy) , 2012 .
[31] Martin L. Baughman,et al. Optimizing Combined Cogeneration and Thermal Storage Systems: An Engineering Economics Approach , 1989, IEEE Power Engineering Review.
[32] Massimiliano Manfren,et al. Paradigm shift in urban energy systems through distributed generation: Methods and models , 2011 .
[33] Sau Man Lai,et al. Integration of trigeneration system and thermal storage under demand uncertainties , 2010 .
[34] Behnam Mohammadi-ivatloo,et al. Stochastic risk-constrained short-term scheduling of industrial cogeneration systems in the presence of demand response programs , 2014 .
[35] Francesco Melino,et al. Influence of the thermal energy storage on the profitability of micro-CHP systems for residential building applications , 2012 .
[36] T.C. Green,et al. Fuel consumption minimization of a microgrid , 2005, IEEE Transactions on Industry Applications.
[37] Hans Müller-Steinhagen,et al. A new method of characterization for stratified thermal energy stores , 2007 .
[38] Željko Bogdan,et al. Improvement of the cogeneration plant economy by using heat accumulator , 2006 .
[39] Ian Paul Knight,et al. Residential cogeneration systems: A review of the current technologies. A report of subtask A of FC+COGEN-SIM: The simulation of building-integrated fuel cell and other cogeneration systems , 2005 .
[40] Lin Lu,et al. Investigation on wind power potential on Hong Kong islands—an analysis of wind power and wind turbine characteristics , 2002 .
[41] S. Chowdhury,et al. Microgrids and Active Distribution Networks , 2009 .
[42] Ryohei Yokoyama,et al. Optimal unit sizing of cogeneration systems in consideration of uncertain energy demands as continuous random variables , 2002 .
[43] Andrea De Pascale,et al. Guidelines for residential micro-CHP systems design , 2012 .
[44] O. Alsayegh,et al. Grid-connected renewable energy source systems: Challenges and proposed management schemes , 2010 .