Abstract
Transition from hydrocarbon to renewable era has already started, but not everywhere around the world and not at the same pace. The gap between supply and demand of renewables has to be closed for providing uninterrupted and secure energy. Reaching 100% renewable target in urban areas can only be attainable with energy storage. More cost-effective energy storage options will increase exploitation of renewable potential. Energy storage can be used in several ways and points in the energy value chain. Energy end-users can benefit from storage technologies to meet their electrical, heat and cold demands. Energy storage technologies vary in terms of maturity and services they can provide. Using energy storage with different concepts such as sector coupling may increase its value and widen its users and benefits. Buildings are the focus of 100% renewable energy urban areas. Increasing net-zero energy buildings will accelerate transition to ultimate goal of 100% renewables target. There are several ways of using energy storage in buildings for using renewables and also preventing urban heat island effects. This chapter will give an overview on energy storage and its current applications in urban areas. The roles of energy storage with a special focus on 100% renewable urban areas are discussed.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Agalit H, Zari N, Maaroufi M (2017) Thermophysical and chemical characterization of induction furnace slags for high temperature thermal energy storage in solar power plants. Sol Energy Mater Sol Cells 172:168–176
Allen KG (2010) Performence characteristics of packed bed thermal energy storage for solar thermal power plants, University of Stellenbosch Department of Mechanical and Mechatronic Engineering, Master of Science Thesis
Alva G, Liu L, Huang X, Fang G (2017) Thermal energy storage materials and systems for solar energy applications. Renew Sustain Energ Rev 68:693–706
Alva G, Lin Y, Fang G (2018) An overview of thermal energy storage systems. Energy 144:341–378
Argyrou MC, Christodoulides P, Kalogirou SA (2018) Energy storage for electricity generation and related processes: technologies appraisal and grid scale applications. Renew Sustain Energy Rev 94:804–821
Aringhoff R, Geyer M, Herrmann U, Kistner R, Nava P, Osuna R (2002) AndaSol-50 MW solar plants with 9 hour storage for Southern spain. In: Steinfeld A (ed) Proceedings of 11th solar PACES international symposium on concentrated solar power and chemical energy technologies. 4–6 Sept 2002, Zurich, Switzerland, pp 37–42. ISBN: 39521409-3-7
Ataer OE (2006) Storage of thermal energy, in energy storage systems in Encyclopedia of Life Support Systems (EOLSS), Developed under the Auspices of the UNESCO. Eolss Publishers, Oxford
Athienitis AK, Liu C, Hawes D, Banu D, Feldman D (1997) Investigation of the thermal performance of a passive solar test-room with wall latent heat storage. Build Environ 32(5):405–410
Bruch A, Fourmigue JF, Coutirier R (2014) Experimental and numerical investigation of a pilot-scale thermal oil packed bed thermal storage system for CSP power plant. Solar Enery 105:116–125
Brunet Y (2013) Energy storage: applications to the electricity vector. Low Emission Power Gener Technol Energy Manage, 1–49
Bruno F, Belusko M, Liu M, Tay NHS (2015) Using solid-liquid phase change materials (PCMs) in thermal energy storage systems. In: Advances in thermal energy storage systems. Woodhead Publishing, pp 201–246
Cabeza LF, Castell A, Barreneche C, de Gracia A, Fernández AI (2011) Materials used as PCM in thermal energy storage in buildings: a review. Renew Sustain Energy Rev 15(3):1675–1695
Cascetta M, Cau G, Puddu P, Serra F (2015) Experimental investigation of a packed bed thermal energy storage system. In: Journal of Physics: Conference Series, vol. 655, no. 1. IOP Publishing, p 012018
Cellat K, Beyhan B, Konuklu Y, Dündar C, Karahan O, Güngör C, Paksoy H (2019) 2 years of monitoring results from passive solar energy storage in test cabins with phase change materials. Solar Energy
Dincer I (2002) Thermal energy storage systems as a key technology in energy conservation. Int J Energy Res 26(7):567–588
Dincer I, Rosen MA (2010) Thermal energy storage: systems and applications, 2nd edn. Wiley, UK. ISBN: 978-0-470-74706-3
Drissi S, Ling TC, Mo KH, Eddhahak A (2019) A review of microencapsulated and composite phase change materials: alteration of strength and thermal properties of cement-based materials. Renew Sustain Energy Rev 110:467–484
Ferg EE, Schuldt F, Schmidt J (2019) The challenges of a Li-ion starter lighting and ignition battery: a review from cradle to grave. J Power Sources 423:380–403
Fernández AI, Barreneche C, Miró L, Brückner S, Cabeza LF (2015) Thermal energy storage (TES) systems using heat from waste. In: Advances in thermal energy storage systems. Woodhead Publishing, pp 479–492
González Roubaud E, Pérez Osorio D, Prieto C (2017) Review of commercial thermal energy storage in concentrated solar power plants: steam versus molten salts. Renew Sustain Energy Rev 80:133–148
Grosu Y, Fernández I, Fernández L, Nithiyanantham U, Baba Y, Mers A, Faik A (2018a) Natural and by-product materials for thermocline-based thermal energy storage system at CSP plant: structural and thermophysical properties. Appl Therm Eng 136:185–193
Grosu Y, Ortega-Fernández I, López del Amo JM, Faik A (2018b) Natural and by-product materials for thermocline-based thermal energy storage system at CSP plant: compatibility with mineral oil and molten nitrate salt. Appl Therm Eng 136:657–665
Guelpa E, Verda V (2019) Thermal energy storage in district heating and cooling systems: a review. Appl Energy 252:113474
IEA-ETSAP and IRENA (2013) https://www.irena.org/publications/2013/Jan/IRENA-IEA-ETSAP-Technology-Briefs, https://iea-etsap.org/
Jankowski NR, McCluskey FP (2014) A review of phase change materials for vehicle component thermal buffering. Appl Energy 113:1525–1561
Jaguemont J, Omar N, Van den Bossche P, Mierlo J (2018) Phase-change materials (PCM) for automotive applications: a review. Appl Therm Eng 132:308–320
Kenisarin M, Mahkamov K (2007) Solar energy storage using phase change materials. Renew Sustain Energy Rev 11(9):1913–1965
Koçak B, Paksoy H (2018) Sensible thermal energy storage in packed bed for industrial solar applications. In: Häberle A (ed) Proceedings of the ISES EuroSun 2018 conference—12th international conference on solar energy for buildings and industry, 10–13 Sept 2018
Koçak B, Paksoy H (2019) Using demolition wastes from urban regeneration as sensible thermal energy storage material. Int J Energy Res 1–7. https://doi.org/10.1002/er.4471
Konuklu Y, Sahan N, Paksoy H (2018) Comprehensive energy systems, Dicer I (ed) Elsevier, Jan 2018
Koohi-Fayegh S, Rosen MA (2020) A review of energy storage types, applications and recent developments. J Energy Storage 27:101047
Krese G, Butala V, Stritih U (2018) Thermochemical seasonal solar energy storage for heating and cooling of buildings. Energy Buildings 164:239–253
Kusama Y, Ishidoya Y (2017) Thermal effects of a novel phase change material (PCM) plaster under different insulation and heating scenarios. Energy Build 141:226–237
Kuznik F, Johannes K, David D (2015) Integrating phase change materials (PCMs) in thermal energy storage systems for buildings. In: Cabeza LF (ed) Advances in thermal energy storage systems. Woodhead Publishing, Methods and Applications, pp 325–347
MacCracken M (2006) Ice thermal storage and LEED Gold. In: ECOSTOCK, 10th international thermal energy storage conference, New Jersey, USA, 31 May–2 June
Mangold D, Deschaintre L (2019) Task 45 large systems, seasonal thermal energy storage, SHC. http://www.solarthermalworld.org/sites/gstec/files/news/file/2016–07-27/task45_b_saisenal_storages.pdf
Medrano M, Gil A, Martorell I, Potau X, Cabeza LF (2010) State of the art on high-temperature thermal energy storage for power generation. Part 2—case studies. Renew Sustain Energy Rev 14(1):56–72
Miró L, Navarro ME, Suresh P, Gil A, Fernández AI, Cabeza LF (2014) Experimental characterization of a solid industrial by-product as material for high temperature sensible thermal energy storage (TES). Appl Energy 113:1261–1268
Motte F, Falcoz Q, Veron E, Py X (2015) Compatibility tests between solar salt and thermal storage ceramics from inorganic industrial wastes. Appl Energy 155:14–22
Nash AL, Badithela A, Jain N (2017) Dynamic modeling of a sensible thermal energy storage tank with an immersed coil heat exchanger under three operation modes. Appl Energy 195:877–889
Navarro ME, Martı´nez M, Gil A, Fernandez AI, Cabeza LF, Olives R, PY X (2012) Selection and characterization of recycled materials for sensible thermal energy storage. Solar Energy Mater Solar Cells 107:131–135
Ochs F, Nußbicker-Lux J, Marx R, Koch H, Heidemann W, Muller-Steinhagen H (2008) Solar assisted district heating system with seasonal thermal energy in Eggenstein-Leopoldshafen, Eurosun 2008, Lisboa
Paksoy H, Evliya H, Bozdağ S, Mazman M, Konuklu Y, Turgut B, Gök Ö, Yılmaz M, Yılmaz S, Beyhan B (2009) CO2 mitigation with thermal energy storage. Int J Glob Warm 1(1/2/3)
Panayiotou GP, Kalogirou SA, Tassou SA (2016) Evaluation of the application of Phase Change Materials (PCM) on the envelope of a typical dwelling in the Mediterranean region. Renew Energy 97:24–32
Pandey AK, Tyagi HVV, Rahim NA, Selvaraj JAL, Sari A (2018) Novel approaches and recent developments on potential applications of phase change materials in solar energy. Renew Sustain Energy Rev 82, 281–323
Prasad JS, Muthukumar P, Desai F, Basu DN, Rahman MM (2019) A critical review of high-temperature reversible thermochemical energy storage systems. Appl Energy 254:113733
Py X, Calvet N, Olivès R, Echegut P, Bessada C, Jay F (2009) Thermal storage for solar power plants based on low cost recycled material. In: EFFSTOCK, the 11th international conference on thermal energy storage, 14–17 June 2009, Stockholm, Sweden
Py X, Calvet N, Olives R, Meffre A, Echegut P, Bessada C, Veron E, Ory S (2011) Recycled material for sensible heat based thermal energy storage to be used in concentrated solar thermal power plants. J Sol Energy Eng 133:031008
Rathore PKS, Shukla SK, Gupta NK (2019) Potential of microencapsulated PCM for energy savings in buildings: a critical review. Sustain Cities Soc 225:723–744
Ravikumar M, Srinivasan PSS (2012) Analysis of heat transfer across phase change material filled reinforced cement concrete roof for thermal management. Proc Inst Mech Eng, Part C: J Mech Eng Sci 226(12):2933–2940
Ryu HW, Hong SA, Shin BC, Kim SD (1991) Heat transfer characteristics of cool-thermal storage systems. Energy 16:727–737
Sakai H (2000) Application of ice storage system to cold air distribution system. In: IEA ECES Annex 14 cooling in all climates with thermal energy storage workshop, Tokyo, Japan, 10 Nov
Schlipf D, Schicktanz P, Maier H, Schneider G (2015) Using sand and other small grained materials as heat storage medium in a packed bed HTTESS. Energy Procedia 69:1029–1038
Schmidt T, Mangold D, Muller-Steinhage H (2004) Central solar heating plants with seasonal storage in Germany. Sol Energy 76:165–174
Sharif MA, Al-Abidi AA, Mat S, Sopian K, Ruslan MH, Sulaiman MY, Rosli MAM (2015) Review of the application of phase change material for heating and domestic hot water systems. Renew Sustain Energy Rev 42:557–568
Soares N, Costa JJ, Gaspar AR, Santos P (2013) Review of passive PCM latent heat thermal energy storage systems towards buildings’ energy efficiency. Energy Buildings 59:82–103
Song M, Niu F, Mao N, Hu Y, Deng S (2018) Review on building energy performance improvement using phase change materials. Energy Build 158:776–793
Souayfane F, Fardoun F, Biwole PH (2016) Phase change materials (PCM) for cooling applications in buildings: a review. Energy Buildings 129:396–431
Stritih U, Charvat P, Klimes L, Osterman E, Ostry M, Butala V (2018) PCM thermal energy storage in solar heating of ventilation air—experimental and numerical investigations. Sustain Cities Soc 37:104–115
STS-med (2018) http://www.stsmed.eu/
Sun X, Gou Z, Lau SSY (2018) Cost-effectiveness of active and passive design strategies for existing building retrofits in tropical climate: case study of a zero-energy building. J Clean Prod 183:35–45
Tyagi VV, Buddhi D (2007) PCM thermal storage in buildings: A state of art. Renew Sustain Energy Rev 11(6):1146–1166
Xu B, Li P, Chan C (2015) Application of phase change materials for thermal energy storage in concentrated solar thermal power plants: a review to recent developments. Appl Energy 160:286–307
Zhou Q, Du D, Lu C, He Q, Liu W (2019) A review of thermal energy storage in compressed air energy storage system. Energy 188:115993
Zhu N, Li S, Hu P, Wei S, Deng R, Lei F (2018) A review on applications of shape-stabilized phase change materials embedded in building enclosure in recent ten years. Sustain Cities Soc 43:251–264
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2020 Springer Nature Switzerland AG
About this chapter
Cite this chapter
Paksoy, H., Şahan, N., Koçak, B. (2020). Role of Energy Storage in 100% Renewable Urban Areas. In: Uyar, T. (eds) Accelerating the Transition to a 100% Renewable Energy Era. Lecture Notes in Energy, vol 74. Springer, Cham. https://doi.org/10.1007/978-3-030-40738-4_19
Download citation
DOI: https://doi.org/10.1007/978-3-030-40738-4_19
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-40737-7
Online ISBN: 978-3-030-40738-4
eBook Packages: EnergyEnergy (R0)