Page 20 - Water-energy_2020
P. 20
F. Calise, et al. Energy Conversion and Management 220 (2020) 113043
References [21] Pfeifer A, Prebeg P, Duić N. Challenges and opportunities of zero emission shipping
in smart islands: A study of zero emission ferry lines. eTransportation
2020;3:100048.
[1] Calise F, et al. A novlel renewable polygeneration system for a small Mediterranean [22] Dorotić H, et al. Integration of transport and energy sectors in island communities
volcanic island for the combined production of energy and water: Dynamic simu- with 100% intermittent renewable energy sources. Renew Sustain Energy Rev
lation and economic assessment. Appl Energy 2014;135:675–93. 2019;99:109–24.
[2] Buonomano A, et al. BIPVT systems for residential applications: An energy and [23] Pfeifer A, et al. Integration of renewable energy and demand response technologies
economic analysis for European climates. Appl Energy 2016;184:1411–31. in interconnected energy systems. Energy 2018;161:447–55.
[3] Calise F, et al. Transient analysis of solar polygeneration systems including seawater [24] Alves M, Segurado R, Costa M. On the road to 100% renewable energy systems in
desalination: A comparison between linear Fresnel and evacuated solar collectors. isolated islands. Energy 2020;198:117321.
Energy 2019;172:647–60. [25] Calise F, Dentice d'Accadia M, Piacentino A. A novel solar trigeneration system
[4] Renno C, et al. Performance analysis of a CPV/T-DC integrated system adopted for integrating PVT (photovoltaic/thermal collectors) and SW (seawater) desalination:
the energy requirements of a supermarket. Appl Therm Eng 2019;149:231–48. Dynamic simulation and economic assessment. Energy 2014;67:129–48.
[5] Buonomano A, et al. Transient analysis, exergy and thermo-economic modelling of [26] Klein SA, et al. Solar Energy Laboratory, TRNSYS. A transient system simulation
façade integrated photovoltaic/thermal solar collectors. Renew Energy program. Madison: University of Wisconsin; 2006.
2019;137:109–26. [27] Calise F, et al. Thermoeconomic analysis of an integrated solar combined cycle
[6] Calise F, d’Accadia MD, Vanoli L. Design and dynamic simulation of a novel solar power plant. Energy Convers Manage 2018;171:1038–51.
trigeneration system based on hybrid photovoltaic/thermal collectors (PVT). Energy [28] Murray, M.C., et al. Live Energy Trnsys -Trnsys Simulation within Google Sketchup.
Convers Manage 2012;60:214–25. in Eleventh International IBPSA Conference. 2009. Glasgow, Scotland July 27-30.
[7] Tian L, Tang Y, Wang Y. Economic evaluation of seawater desalination for a nuclear [29] Calise F. Thermoeconomic analysis and optimization of high efficiency solar
heating reactor with multi-effect distillation. Desalination 2005;180(1):53–61.
heating and cooling systems for different Italian school buildings and climates.
[8] Calise F, et al. Economic assessment of renewable energy systems integrating
Energy Build 2010;42:992–1003.
photovoltaic panels, seawater desalination and water storage. Appl Energy
[30] Calise F, Vanoli L. Parabolic trough photovoltaic/thermal collectors: design and
2019;253:113575.
simulation model. Energies 2012;5:4186–208.
[9] Calise F, d’Accadia MD, Vicidomini M. Optimization and dynamic analysis of a
[31] C. Richardson Chemical Engineering Volume Vol 2 5th Edition, 2002 Butterworth-
novel polygeneration system producing heat, cool and fresh water. Renew Energy
Heinemann 2.
2019;143:1331–47.
[32] Wijmans JG, Baker RW. The solution-diffusion model: a review. J Membr Sci
[10] Buonomano A, et al. A novel renewable polygeneration system for hospital build-
1995;107(1):1–21.
ings: Design, simulation and thermo-economic optimization. Appl Therm Eng
[33] Dimitriou E, et al. Theoretical performance prediction of a reverse osmosis desali-
2014;67(1–2):43–60.
nation membrane element under variable operating conditions. Desalination
[11] Calise F. Thermoeconomic analysis and optimization of high efficiency solar
2017;419:70–8.
heating and cooling systems for different Italian school buildings and climates.
[34] Gils HC, et al. GIS-based assessment of the district heating potential in the USA.
Energy Build 2010;42(7):992–1003. Energy 2013;58:318–29.
[12] Calise F, et al. A novel solar-assisted heat pump driven by photovoltaic/thermal [35] Persson U, Werner S. Heat distribution and the future competitiveness of district
collectors: Dynamic simulation and thermoeconomic optimization. Energy heating. Appl Energy 2011;88(3):568–76.
2016;95:346–66. [36] Mulder M. Basic Principles of Membrane Technology. second edition Kluwer
[13] Buonomano A, et al. Adsorption chiller operation by recovering low-temperature Academic Publishers; 2020.
heat from building integrated photovoltaic thermal collectors: Modelling and si- [37] Buonomano A, et al. A hybrid renewable system based on wind and solar energy
mulation. Energy Convers Manage 2017;149:1019–36. coupled with an electrical storage: Dynamic simulation and economic assessment.
[14] Calise F, et al. Polygeneration system based on PEMFC, CPVT and electrolyzer: Energy 2018;155:174–89.
Dynamic simulation and energetic and economic analysis. Appl Energy [38] Hoek EMV, et al. Modeling the effects of fouling on full-scale reverse osmosis
2017;192:530–42. processes. J Membr Sci 2008;314(1):33–49.
[15] Kyriakarakos G, et al. Polygeneration microgrids: A viable solution in remote areas [39] https://global.aermec.com/it/. 2018.
for supplying power, potable water and hydrogen as transportation fuel. Appl [40] Bose A, et al. Co-production of power and urea from coal with CO2 capture: per-
Energy 2011;88(12):4517–26. formance assessment. Clean Techn Environ Policy 2015:1271–80.
[16] Calise F, et al. A novel solar-geothermal trigeneration system integrating water [41] Piacentino A, et al. Sustainable and cost-efficient energy supply and utilisation
desalination: Design, dynamic simulation and economic assessment. Energy 2016. through innovative concepts and technologies at regional, urban and single-user
115,;Part 3:1533–47. scales. Energy 2019;182:254–68.
[17] Calise F, et al. A novel hybrid polygeneration system supplying energy and desa- [42] http://www.bigbrandwater.com/Dow-Filmtec-SW30ULE-440i-Seawater-
linated water by renewable sources in Pantelleria Island. Energy 2017. Membrane_p_20550.html. 2019.
[18] Wang Z, et al. Optimal planning of a 100% renewable energy island supply system [43] Du Y, et al. Optimization of reverse osmosis networks with split partial second pass
based on the integration of a concentrating solar power plant and desalination design. Desalination 2015;365:365–80.
units. Int J Electr Power Energy Syst 2020;117:105707. [44] Olwig R, et al. Techno-economic analysis of combined concentrating solar power
[19] Karavas C-S, Arvanitis KG, Papadakis G. Optimal technical and economic config- and desalination plant configurations in Israel and Jordan. Desalin Water Treat
uration of photovoltaic powered reverse osmosis desalination systems operating in
2012;41:9–25.
autonomous mode. Desalination 2019;466:97–106.
[45] Soltero VM, et al. Potential of biomass district heating systems in rural areas.
[20] Mohan G, et al. A novel solar thermal polygeneration system for sustainable pro-
Energy 2018;156:132–43.
duction of cooling, clean water and domestic hot water in United Arab Emirates:
Dynamic simulation and economic evaluation. Appl Energy 2016;167:173–88.
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