A review of concentrated solar power hybrid technologies
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[1] Robert Pitz-Paal,et al. Trough integration into power plants : a study on the performance and economy of integrated solar combined cycle systems , 2004 .
[2] Stuart White,et al. Concentrating solar power hybrid plants – Enabling cost effective synergies , 2014 .
[3] Paul Denholm,et al. Benefits of Colocating Concentrating Solar Power and Wind , 2013, IEEE Transactions on Sustainable Energy.
[4] G. S. Miguel,et al. Environmental analysis of a Concentrated Solar Power (CSP) plant hybridised with different fossil and renewable fuels , 2015 .
[5] Fontina Petrakopoulou,et al. Simulation and evaluation of a hybrid concentrating-solar and wind power plant for energy autonomy on islands , 2016 .
[6] K. S. Reddy,et al. 4-E (Energy, Exergy, Environment, and Economic) analysis of solar thermal aided coal-fired power plants , 2010 .
[7] Shuhong Huang,et al. Coupling performance analysis of a solar aided coal-fired power plant , 2016 .
[8] Yongping Yang,et al. Research on solar aided coal-fired power generation system and performance analysis , 2008 .
[9] A. H. Shamsuddin,et al. Advances in the integration of solar thermal energy with conventional and non-conventional power plants , 2013 .
[10] Uri Fisher,et al. Gas Turbine “Solarization”-Modifications for Solar/Fuel Hybrid Operation , 2004 .
[11] Hongguang Jin,et al. Mid and low-temperature solar–coal hybridization mechanism and validation , 2014 .
[12] A. Ferrière,et al. Simulation of a hybrid solar gas-turbine cycle with storage integration , 2014 .
[13] Hongguang Jin,et al. Off-design thermodynamic performances on typical days of a 330MW solar aided coal-fired power plant in China , 2014 .
[14] José Antonio Brioso,et al. Solugas – Comprehensive analysis of the solar hybrid Brayton plant , 2016 .
[15] Prashant Baredar,et al. Status of solar wind renewable energy in India , 2013 .
[16] Yongping Yang,et al. Optimizing operation of a solar-aided coal-fired power system based on the solar contribution evaluation method , 2015 .
[17] Abraham Kribus,et al. A solar-driven combined cycle power plant , 1998 .
[18] Thorsten Denk,et al. Test and evaluation of a solar powered gas turbine system , 2006 .
[19] Tim Cockerill,et al. Life cycle GHG assessment of fossil fuel power plants with carbon capture and storage , 2008 .
[20] Mark Z. Jacobson,et al. Providing all global energy with wind, water, and solar power, Part II: Reliability, system and transmission costs, and policies , 2011 .
[21] Yongping Yang,et al. An evaluation method of solar contribution in a solar aided power generation (SAPG) system based on exergy analysis , 2016 .
[22] Carol A Boyle,et al. Comparison of life cycle carbon dioxide emissions and embodied energy in four renewable electricity generation technologies in New Zealand. , 2009, Environmental science & technology.
[23] Tianliang Yang,et al. The development of a thermo-economic evaluation method for solar aided power generation , 2016 .
[24] Abraham Kribus,et al. Performance of the solar hybrid STIG cycle with latent heat storage , 2015 .
[25] L. Suganthi,et al. Exergy analysis and annual exergetic performance evaluation of solar hybrid STIG (steam injected gas turbine) cycle for Indian conditions , 2015 .
[26] Brian Norton,et al. Technological Assessment of Different Solar-Biomass Systems for Hybrid Power Generation in Europe , 2017 .
[27] Pierre Garcia,et al. Solar Field Efficiency and Electricity Generation Estimations for a Hybrid Solar Gas Turbine Project in France , 2008 .
[28] V. Poghosyan,et al. Techno-economic assessment of substituting natural gas based heater with thermal energy storage system in parabolic trough concentrated solar power plant , 2015 .
[29] María José Montes,et al. Comparison of Heat Transfer Fluid and Direct Steam Generation technologies for Integrated Solar Combined Cycles , 2013 .
[30] Massimo Moser,et al. Concentrating solar power in a sustainable future electricity mix , 2013, Sustainability Science.
[31] Daniel Favrat,et al. CO2 Mitigation Through the Use of Hybrid Solar-Combined Cycles. , 1997 .
[32] Alessandro Franco,et al. Optimal design of binary cycle power plants for water-dominated, medium-temperature geothermal fields , 2009 .
[33] Huili Zhang,et al. Concentrated solar power plants: Review and design methodology , 2013 .
[34] Alejandro Medina,et al. Thermodynamic modeling of a hybrid solar gas-turbine power plant , 2015 .
[35] Giuseppe Franchini,et al. A comparative study between parabolic trough and solar tower technologies in Solar Rankine Cycle and Integrated Solar Combined Cycle plants , 2013 .
[36] G. C. Bakos,et al. Solar aided power generation of a 300 MW lignite fired power plant combined with line-focus parabolic trough collectors field , 2013 .
[37] T. E. Boukelia,et al. Investigation of solar parabolic trough power plants with and without integrated TES (thermal energy storage) and FBS (fuel backup system) using thermic oil and solar salt , 2015 .
[38] R. Cai,et al. Low CO2-emissions hybrid solar combined-cycle power system with methane membrane reforming , 2013 .
[39] Giovanni Manente,et al. High performance integrated solar combined cycles with minimum modifications to the combined cycle power plant design , 2016 .
[40] Philipp Blum,et al. Review on life cycle environmental effects of geothermal power generation , 2013 .
[41] T. E. Boukelia,et al. Optimization, selection and feasibility study of solar parabolic trough power plants for Algerian conditions , 2015 .
[42] Witold-Roger Poganietz,et al. Environmental and economic analysis of SolComBio concept for sustainable energy supply in remote regions , 2014 .
[43] A. Lentz,et al. Parabolic troughs to increase the geothermal wells flow enthalpy , 2006 .
[44] Shuai Deng,et al. Technical and economic analysis of integrating low-medium temperature solar energy into power plant , 2016 .
[45] Craig Turchi,et al. Co-located gas turbine/solar thermal hybrid designs for power production , 2014 .
[46] Dennis Y.C. Leung,et al. Wind energy development and its environmental impact: A review , 2012 .
[47] P. Schwarzbözl,et al. Solar gas turbine systems: Design, cost and perspectives , 2006 .
[48] Amy H. I. Lee,et al. Strategic selection of suitable projects for hybrid solar-wind power generation systems , 2010 .
[49] Gregory J. Kolb. Economic evaluation of solar-only and hybrid power towers using molten salt technology , 1996 .
[50] Rodrigo Escobar,et al. Net energy analysis for concentrated solar power plants in northern Chile , 2012 .
[51] Amos Madhlopa,et al. An integrated combined cycle system driven by a solar tower: A review , 2016 .
[52] Rodrigo Escobar,et al. Thermodynamic evaluation of solar-geothermal hybrid power plants in northern Chile , 2016 .
[53] Víctor Manuel Fernandes Mendes,et al. Bilevel approach to wind-CSP day-ahead scheduling with spinning reserve under controllable degree of trust , 2016 .
[54] Behdad Moghtaderi,et al. An in-depth assessment of hybrid solar–geothermal power generation , 2013 .
[55] Hui Hong,et al. A novel hybrid oxy-fuel power cycle utilizing solar thermal energy , 2007 .
[56] S. D. Oda,et al. A case study for three combined cycles of a solar-conventional power generation unit , 1988 .
[57] Elysia J. Sheu,et al. Optimization of a hybrid solar-fossil fuel plant: Solar steam reforming of methane in a combined cycle , 2013 .
[58] Ying Chen,et al. Life cycle assessment of solar aided coal-fired power system with and without heat storage , 2016 .
[59] Fahad A. Al-Sulaiman,et al. Exergy analysis of parabolic trough solar collectors integrated with combined steam and organic Rankine cycles , 2014 .
[60] Alexandre Szklo,et al. Potential and impacts of Concentrated Solar Power (CSP) integration in the Brazilian electric power system , 2014 .
[61] Takanobu Kosugi,et al. A CO2-capturing hybrid power-generation system with highly efficient use of solar thermal energy , 1997 .
[62] Stuart White,et al. Increasing the efficiency of parabolic trough plants using thermal oil through external superheating with biomass , 2014 .
[63] Katalin Bódis,et al. Assessing complementarity of wind and solar resources for energy production in Italy. A Monte Carlo approach , 2014 .
[64] Hongguang Jin,et al. Exergy evaluation of a typical 330 MW solar-hybrid coal-fired power plant in China , 2014 .
[65] Mario Amelio,et al. An evaluation of the performance of an integrated solar combined cycle plant provided with air-linear parabolic collectors , 2014 .
[66] Edward S. Rubin,et al. Life cycle assessment of greenhouse gas emissions, water and land use for concentrated solar power plants with different energy backup systems , 2013 .
[67] Hongguang Jin,et al. Evaluation criteria for enhanced solar–coal hybrid power plant performance , 2014 .
[68] Timothy A. Moss,et al. Adding concentrated solar power plants to wind farms to achieve a good utility electrical load match , 2013 .
[69] D. Favrat,et al. Thermoeconomic Analysis of Advanced Solar-Fossil Combined Power Plants , 2000 .
[70] Pyong Sik Pak,et al. Economic evaluation of solar thermal hybrid H2O turbine power generation systems , 2003 .
[71] Reiner Buck,et al. Analysis Of Solar Thermal Power Plants With Thermal Energy Storage And Solar-Hybrid Operation Strategy , 2011 .
[72] David Pozo-Vázquez,et al. Combining wind farms with concentrating solar plants to provide stable renewable power , 2015 .
[73] A. Kribus,et al. Solar hybrid steam injection gas turbine (STIG) cycle , 2012 .
[74] Andrea Lazzaretto,et al. Optimum choice and placement of concentrating solar power technologies in integrated solar combined cycle systems , 2016 .
[75] L. Suganthi,et al. An economic analysis of solar hybrid steam injected gas turbine (STIG) plant for Indian conditions , 2015 .
[76] Abdallah Khellaf,et al. A review of integrated solar combined cycle system (ISCCS) with a parabolic trough technology , 2014 .
[77] Martin Kaltschmitt,et al. Life cycle assessment of geothermal binary power plants using enhanced low-temperature reservoirs , 2010 .
[78] César R. Chamorro,et al. World geothermal power production status: Energy, environmental and economic study of high enthalpy technologies , 2012 .
[79] B. Corona,et al. Life cycle assessment of concentrated solar power (CSP) and the influence of hybridising with natural gas , 2014, The International Journal of Life Cycle Assessment.
[80] Martin Pehnt,et al. Dynamic life cycle assessment (LCA) of renewable energy technologies , 2006 .
[81] Riccardo Basosi,et al. Evaluation of the environmental sustainability of a micro CHP system fueled by low-temperature geothermal and solar energy , 2014 .
[82] Tangellapalli Srinivas,et al. Hybrid solar–biomass power plant without energy storage , 2014 .
[83] Germain Augsburger,et al. Thermoeconomic optimization of a combined-cycle solar tower power plant , 2012 .
[84] Rodrigo Escobar,et al. Performance model to assist solar thermal power plant siting in northern Chile based on backup fuel consumption , 2010 .
[85] S. C. Kaushik,et al. Exergetic utilization of solar energy for feed water preheating in a conventional thermal power plant , 2009 .
[86] Eckhard Lüpfert,et al. Advances in Parabolic Trough Solar Power Technology , 2002 .
[87] Prasanta Kumar Dey,et al. The feasibility of hybrid solar-biomass power plants in India , 2012 .
[88] Stuart White,et al. Concentrating solar power/alternative fuel hybrid plants: Annual electricity potential and ideal areas in Australia , 2014 .
[89] Alexander Mitsos,et al. Thermo-economic analysis of a hybrid solar-binary geothermal power plant , 2015 .
[90] E. Kakaras,et al. Combined cycle power plant with integrated low temperature heat (LOTHECO) , 2004 .
[91] H. Nezammahalleh,et al. Conceptual design and techno-economic assessment of integrated solar combined cycle system with DSG technology , 2010 .
[92] Hongguang Jin,et al. Proposal of a Solar-Coal Power Plant on Off-Design Operation , 2013 .
[93] Yongping Yang,et al. Analysis of a solar-aided coal-fired power generation system based on thermo-economic structural theory , 2016 .
[94] Dimityr Popov,et al. Innovative solar augmentation of gas turbine combined cycle plants , 2014 .
[95] Elysia J. Sheu,et al. A Review of Hybrid Solar–Fossil Fuel Power Generation Systems and Performance Metrics , 2012 .
[96] M. Belhamel,et al. Instantaneous performance of the first Integrated Solar Combined Cycle System in Algeria , 2011 .
[97] Mohamed Gadalla,et al. Thermo-economic analysis of conventional combined cycle hybridization: United Arab Emirates case study , 2016 .
[98] Ian H. Rowlands,et al. Solar and wind resource complementarity: Advancing options for renewable electricity integration in Ontario, Canada , 2011 .
[99] M. Elsayed. Solar supported steam production for power generation in Egypt , 2005 .
[100] Noam Lior,et al. Use of Low/Mid-Temperature Solar Heat for Thermochemical Upgrading of Energy, Part I: Application to a Novel Chemically-Recuperated Gas-Turbine Power Generation (SOLRGT) System , 2012 .
[101] Yongping Yang,et al. Solar thermal aided power generation , 2010 .
[102] G. Cau,et al. Performance and cost assessment of Integrated Solar Combined Cycle Systems (ISCCSs) using CO2 as heat transfer fluid , 2012 .
[103] R. Ravikrishna,et al. A novel syngas-fired hybrid heating source for solar-thermal applications: Energy and exergy analysis , 2016 .
[104] Reiner Buck,et al. Solar Upgrading of Fuels for Generation of Electricity , 2001 .
[105] Jing Yuan,et al. Performance Analysis of a Novel Cascade Integrated Solar Combined Cycle System , 2015 .
[106] María José Montes,et al. Performance analysis of an Integrated Solar Combined Cycle using Direct Steam Generation in parabolic trough collectors , 2011 .
[107] Mahmood Yaghoubi,et al. Exergoeconomic analysis and optimization of an Integrated Solar Combined Cycle System (ISCCS) using genetic algorithm , 2011 .
[108] Cheng Zhou,et al. Hybridisation of solar and geothermal energy in both subcritical and supercritical Organic Rankine Cycles , 2014 .
[109] Stuart White,et al. Hybridisation optimization of concentrating solar thermal and biomass power generation facilities , 2014 .
[110] Ennio Macchi,et al. Technical and economical analysis of a solar–geothermal hybrid plant based on an Organic Rankine Cycle , 2011 .
[111] S. Can Gülen. Second Law Analysis of Integrated Solar Combined Cycle Power Plants , 2015 .
[112] R. Trigo,et al. Spatio-temporal Complementarity between Solar and Wind Power in the Iberian Peninsula☆ , 2013 .
[113] Chemi Sugarmen,et al. Modification of Gas Turbines and Operation with Solar Produced Syngas , 2004 .
[114] Tobias Vogel,et al. Thermodynamic and economic evaluation of a solar aided sugarcane bagasse cogeneration power plant , 2016 .
[115] U. Sahoo,et al. Scope and sustainability of hybrid solar–biomass power plant with cooling, desalination in polygeneration process in India , 2015 .
[116] Masud Behnia,et al. Performance evaluation of solar thermal electric generation systems , 2003 .
[117] Peter Schwarzbözl,et al. Solar-Hybrid Gas Turbine-based Power Tower Systems (REFOS)* , 2001 .
[118] Alexandre Szklo,et al. Hybrid concentrated solar power (CSP)–biomass plants in a semiarid region: A strategy for CSP deployment in Brazil , 2015 .
[119] Alexandre Szklo,et al. Assessing incentive policies for integrating centralized solar power generation in the Brazilian electric power system , 2013 .
[120] L. Suganthi,et al. Annual performance of the solar hybrid STIG cycle , 2014 .
[121] Klaus Görner,et al. Boosting power output of a sugarcane bagasse cogeneration plant using parabolic trough collectors in a feedwater heating scheme , 2015 .
[122] Elysia J. Sheu,et al. Solar–thermal hybridization of advanced zero emissions power cycle , 2014 .
[123] Akiba Segal,et al. Optimized working temperatures of a solar central receiver , 2003 .
[124] Hongguang Jin,et al. Solar thermal power cycle with integration of methanol decomposition and middle-temperature solar thermal energy , 2005 .
[125] Jürgen Rheinländer,et al. Economic analysis of integrated solar combined cycle power plants , 2004 .
[126] Torsten Fransson,et al. Advanced Hybrid Solar Tower Combined-Cycle Power Plants , 2014 .
[127] Francis A Kulacki,et al. Utility scale hybrid wind–solar thermal electrical generation: A case study for Minnesota , 2008 .
[128] D. Popov. An option for solar thermal repowering of fossil fuel fired power plants , 2011 .
[129] Yongping Yang,et al. Thermodynamic analysis of a novel integrated solar combined cycle , 2014 .
[130] A. Sahin. Applicability of Wind?Solar Thermal Hybrid Power Systems in the Northeastern Part of the Arabian Peninsula , 2000 .
[131] M. J. Montes,et al. Performance of a direct steam generation solar thermal power plant for electricity production as a function of the solar multiple , 2009 .
[132] S. C. Kaushik,et al. Exergetic Analysis of Solar Concentrator Aided Natural Gas Fired Combined Cycle Power Plant , 2012 .
[133] Christoph Kost,et al. Fruitful symbiosis: Why an export bundled with wind energy is the most feasible option for North African concentrated solar power , 2011 .
[134] S. K. Tyagi,et al. Exergetic analysis of solar concentrator aided coal fired super critical thermal power plant (SACSCTPT) , 2012, Clean Technologies and Environmental Policy.
[135] A. Lentz,et al. Solar–geothermal hybrid system , 2006 .
[136] Yongping Yang,et al. An efficient way to use medium-or-low temperature solar heat for power generation – integration into conventional power plant , 2011 .
[137] Eric Hu,et al. The performance of a Solar Aided Power Generation plant with diverse “configuration-operation” combinations , 2016 .
[138] Yongping Yang,et al. Annual performance of a solar aided coal-fired power generation system (SACPG) with various solar field areas and thermal energy storage capacity , 2015 .
[139] Yongping Yang,et al. Evaluation of solar aided thermal power generation with various power plants , 2011 .
[140] Andrea Toffolo,et al. Thermodynamic performance of a hybrid power generation system using biomass gasification and concentrated solar thermal processes , 2015 .
[141] Yong Zhu,et al. Exergy destruction analysis of solar tower aided coal-fired power generation system using exergy and advanced exergetic methods , 2016 .
[142] Miriam Ebert,et al. Solugas – Operation Experience of the First Solar Hybrid Gas Turbine System at MW Scale , 2014 .
[143] Madjid Soltani,et al. Technical and economic assessment of the integrated solar combined cycle power plants in Iran , 2005 .
[144] Roman Adinberg. Simulation analysis of thermal storage for concentrating solar power , 2011 .
[145] Jyeshtharaj B. Joshi,et al. Solar thermal technologies as a bridge from fossil fuels to renewables , 2015 .
[146] Stuart White,et al. Solar Tower-biomass Hybrid Plants – Maximizing Plant Performance , 2014 .
[147] Mahmood Yaghoubi,et al. Exergy analysis of an integrated solar combined cycle system , 2010 .
[148] J. M. Martínez-Duart,et al. CSP electricity cost evolution and grid parities based on the IEA roadmaps , 2012 .
[149] Zhang Bai,et al. Investigation of thermodynamic performances for two solar-biomass hybrid combined cycle power generation systems , 2016 .
[150] G. Barigozzi,et al. Thermal performance prediction of a solar hybrid gas turbine , 2012 .
[151] Behdad Moghtaderi,et al. Figure of Merit Analysis of a Hybrid Solar-Geothermal Power Plant , 2013 .
[152] Sadiq J. Zarrouk,et al. Efficiency of geothermal power plants: A worldwide review , 2014 .
[153] Hasimah Abdul Rahman,et al. Historical development of concentrating solar power technologies to generate clean electricity efficiently – A review , 2015 .
[154] Pyong Sik Pak,et al. A hybrid power generation system utilizing solar thermal energy with CO2 recovery based on oxygen combustion method , 1995 .
[155] James Spelling,et al. A Thermo-Economic Study of Storage Integration in Hybrid Solar Gas-Turbine Power Plants , 2015 .
[156] Elysia J. Sheu,et al. Hybrid solar-geothermal power generation: Optimal retrofitting , 2014 .
[157] G. C. Bakos,et al. Technoeconomic assessment of an integrated solar combined cycle power plant in Greece using line-focus parabolic trough collectors , 2013 .
[158] Edward S. Rubin,et al. Economic implications of thermal energy storage for concentrated solar thermal power , 2011 .
[159] Mark Z. Jacobson,et al. Providing all global energy with wind, water, and solar power, Part I: Technologies, energy resources, quantities and areas of infrastructure, and materials , 2011 .
[160] Stuart White,et al. Concentrated solar power hybrid plants, which technologies are best suited for hybridisation? , 2013 .
[161] Mayank Gupta,et al. Development of a syngas-fired catalytic combustion system for hybrid solar-thermal applications , 2016 .
[162] A. Kouzani,et al. Multi-point and multi-level solar integration into a conventional coal-fired power plant , 2010 .
[163] Yang Yongping,et al. Performance evaluation of solar aided feedwater heating of coal-fired power generation (SAFHCPG) system under different operating conditions , 2013 .