A review of available methods and development on energy storage; Technology update

Renewable and Sustainable Energy Reviews

Volumn 33, Issue , 2014, Pages 532-545

  Mahlia, T M I ^a,b   Saktisahdan, T J ^a   Jannifar, A ^c   Hasan, M H ^c   Matseelar, H S C ^c  

^a Universiti Tenaga Nasional   (Malaysia)

^b SYIAH KUALA UNIVERSITY   (Indonesia)

^c UNIVERSITY OF MALAYA   (Malaysia)

Author keywords

Electricity; Energy savings; Energy storage; Renewable energy

Indexed keywords

COMPRESSED AIR; ELECTRICITY; ENERGY CONSERVATION; ENERGY STORAGE; HEAT STORAGE; SYNTHETIC FUELS;

BATTERY ENERGY STORAGES (BES); COMPRESSED AIR ENERGY STORAGE; FLYWHEEL ENERGY STORAGE; HYDROGEN ENERGY STORAGES; PUMPED-HYDRO ENERGY STORAGES; RENEWABLE ENERGIES; SUPER CAPACITOR ENERGY STORAGES; SUPERCONDUCTING MAGNETIC ENERGY STORAGES;

ELECTRIC ENERGY STORAGE;

EID: 84896382257     PISSN: 13640321     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.rser.2014.01.068     Document Type: Review

References (121)

1. L. ZhiDong An econometric study on China's economy, energy and environment to the year 2030 Energy Policy 31 2003 1137 1150
2. A.C. Fisher Energy and environment in the long term Energy Policy 17 1989 84 87
3. O. Benestad, L. Brinck, L. Emborg, B. Juul-Kristensen, A. Kristiansen, and N.I. Meyer et al. Energy and environment: Nordic energy scenarios for 2010 and 2030 Energy Policy 21 1993 1225 1236
4. A.M. Omer Energy, environment and sustainable development Renew Sustain Energy Rev 12 2008 2265 2300
5. Seo DH, Krarti M. Evaluation of energy savings by optimization control in thermal energy storage system. In: Proceedings of the ASME International Solar Energy Conference. 2007. p. 433-40, 710.
6. M. Cheralathan, R. Velraj, and S. Renganarayanan Performance analysis on industrial refrigeration system integrated with encapsulated PCM-based cool thermal energy storage system Int J Energy Res 31 2007 1398 1413
7. E.A. Abdelaziz, R. Saidur, and S. Mekhilef A review on energy saving strategies in industrial sector Renew Sustain Energy Rev 15 2011 150 168
8. S. Mekhilef, S. Siga, and R. Saidur A review on palm oil biodiesel as a source of renewable fuel Renew Sustain Energy Rev 15 2011 1937 1949
9. R. Saidur, A. Atabani, and S. Mekhilef A review on electrical and thermal energy for industries Renew Sustain Energy Rev 15 2011 2073 2086
10. W.T. Chong, M.S. Naghavi, S.C. Poh, T.M.I. Mahlia, and K.C. Pan Techno-economic analysis of a wind-solar hybrid renewable energy system with rainwater collection feature for urban high-rise application Appl Energy 88 2011 4067 4077
11. T.M.I. Mahlia, M.Z. Abdulmuin, T.M.I. Alamsyah, and D. Mukhlishien An alternative energy source from palm wastes industry for Malaysia and Indonesia Energy Convers Manage 42 2001 2109 2118
12. T.M.I. Mahlia, H.H. Masjuki, and I.A. Choudhury Potential electricity savings by implementing energy labels for room air conditioner in Malaysia Energy Convers Manage 43 2002 2225 2233
13. R. Domański, M. Jaworski, and M. Rebow Thermal energy storage problems J Power Technol 1995 79
14. EPRI. Electricity Energy Storage Technology Options. 2010.
15. D.A. Connolly Review of Energy Storage Technologies 2009 University of Limerick Ireland
16. C. Naish, I. McCubbin, O. Edberg, and M. Harfoot Outlook of energy storage technologies 2007 Policy department economic and scientific policy Brussel
17. European Commision. Energy storage: a key for decentrelized power, power quality and clean transport. 2001.
18. EIA World energy outlook - 2009 2009 International Energy Agency Paris
19. A. Gonzalez, B. Gallachóir, E. McKeogh, and K. Lynch Study of electricity storage technologies and their potential to address wind energy intermittency in Ireland Sustain Energy Irel 2004
20. 2 emissions from fuel combustion 2009 International Energy Agency Paris
21. ClimateTechWiki. Energy storage: compressed air (CAES). Available from: 〈http://climatetechwiki.org/technology/jiqweb- caesâŒ[acessed 22.05.12].
22. A. Cavallo Controllable and affordable utility-scale electricity from intermittent wind resources and compressed air energy storage (CAES) Energy 32 2007 120 127
23. P. Holden, D. Moen, M. De Corso, and J. Howard Alabama electric cooperative compressed air energy storage (CAES) Plant Improv 2000 8 11
24. Nyserda. Final report: compressed air energy storage engineering and economic study. 2009.
25. 2 benefits). Available from: 〈http://www.espcinc.com/library/EPRI-Paper- on-CAES-Technology.pdfâŒ.
26. Takeshima KI, Sagara K, Yamanaka T, Kotani H. Simulation study on estimation method for flow rate in air-conditioning system with water thermal energy storage. In: Proceedings of the building simulation 2007, vols 1-3; 2007. p. 1334-40, 2006.
27. Argonne National Laboratory. Compressed air energy storage (CAES) in Salt Caverns. 2009.
28. EPRI. Handbook for energy storage for transmission or distribution applications. report no. 1007189. Technical update December 2002. Document can be found at: www.epri.com2002.
29. I. Arsie, V. Marano, M. Moran, G. Rizzo, and G. Savino Optimal management of a wind/CAES power plant by means of neural network wind speed forecast European Wind Energy Conference and Exhibition, The European Wind Energy Association (EWEA), Milan, May 7. 10 2007
30. C. Bullough AA-CAES 2004 Integration of Wind Energy Alstom Power Technology Centre United Kingdom
31. Sohn CW, Fuchs J, Gruber M. Chilled water storage cooling system for an army installation. In: Proceedings of ASHRAE annual meeting. Seattle, WA; 1999. p. 1126-33.
32. RWE. ADELE - Adiabatic compressed-air energy storage (CAES) for electricity supply.
33. Nakhamkin M. Compress air energy storage. Energy storage power corporation. 〈http://www.espcinc.com/âŒ.
34. EPRI. Handbook for energy storage for transmission or distribution applications. report no. 1007189. Technical update December 2002
35. Iowa stored energy park project terminated, Iowa stored energy plant agency press release; July 28, 2011.
36. Schulte RH, Critelli N, Holst K, Huff G. Lessons from Iowa: development of a 270 MW compressed air energy storage project in midwest independent system operator. Sandia report. 2012.
37. N.M. Jubeh, and Y.S.H. Najjar Power augmentation with CAES (compressed air energy storage) by air injection or supercharging makes environment greener Energy 38 2012 228 235
38. N. Hartmann, O. Vöhringer, C. Kruck, and L. Eltrop Simulation and analysis of different adiabatic compressed air energy storage plant configurations Appl Energy 2011
39. Y. Kim, D. Shin, and D. Favrat Operating characteristics of constant-pressure compressed air energy storage (CAES) system combined with pumped hydro storage based on energy and exergy analysis Energy 36 2011 6220 6233
40. Y. Kim, and D. Favrat Energy and exergy analysis of a micro-compressed air energy storage and air cycle heating and cooling system Energy 35 2010 213 220
41. H. Ibrahim, R. Younès, A. Ilinca, M. Dimitrova, and J. Perron Study and design of a hybrid wind-diesel-compressed air energy storage system for remote areas Appl Energy 87 2010 1749 1762
42. H. Ibrahim, A. Ilinca, R. Younes, J. Perron, and T. Basbous Study of a hybrid wind-diesel system with compressed air energy storage IEEE 2007 320 325
43. T. Basbous, R. Younes, A. Ilinca, and J. Perron Pneumatic hybridization of a diesel engine using compressed air storage for wind-diesel energy generation Energy 38 2012 264 275
44. H.M. Kim, J. Rutqvist, D.W. Ryu, B.H. Choi, C. Sunwoo, and W.K. Song Exploring the concept of compressed air energy storage (CAES) in lined rock caverns at shallow depth: a modeling study of air tightness and energy balance Appl Energy 92 2012 653 667
45. J.B. Greenblatt, S. Succar, D.C. Denkenberger, R.H. Williams, and R.H. Socolow Baseload wind energy: modeling the competition between gas turbines and compressed air energy storage for supplemental generation Energy Policy 35 2007 1474 1492
46. V. Marano, G. Rizzo, and F.A. Tiano Application of dynamic programming to the optimal management of a hybrid power plant with wind turbines, photovoltaic panels and compressed air energy storage Appl Energy 97 2012 849 859
47. R. Madlener, and J. Latz Economics of centralized and decentralized compressed air energy storage for enhanced grid integration of wind power Appl Energy 101 2013 299 309
48. E. Fertig, and J. Apt Economics of compressed air energy storage to integrate wind power: a case study in ERCOT Energy Policy 39 2011 2330 2342
49. H. Lund, G. Salgi, B. Elmegaard, and A.N. Andersen Optimal operation strategies of compressed air energy storage (CAES) on electricity spot markets with fluctuating prices Appl Therm Eng 29 2009 799 806
50. G. Salgi, and H. Lund System behaviour of compressed-air energy-storage in Denmark with a high penetration of renewable energy sources Appl Energy 85 2008 182 189
51. H. Lund, and G. Salgi The role of compressed air energy storage (CAES) in future sustainable energy systems Energy Convers Manage 50 2009 1172 1179
52. S. Succar, D.C. Denkenberger, and R.H. Williams Optimization of specific rating for wind turbine arrays coupled to compressed air energy storage Appl Energy 96 2012 222 234
53. E. Drury, P. Denholm, and R. Sioshansi The value of compressed air energy storage in energy and reserve markets Energy 36 2011 4959 4973
54. P. Denholm, and R. Sioshansi The value of compressed air energy storage with wind in transmission-constrained electric power systems Energy Policy 37 2009 3149 3158
55. O.M. Al-Rabghi, and M.M. Akyurt A survey of energy efficient strategies for effective air conditioning Energy Convers Manage 45 2004 1643 1654
56. W.P. Bahnfleth, and J. Song Constant flow rate charging characteristics of a full-scale stratified chilled water storage tank with double-ring slotted pipe diffusers Appl Therm Eng 25 2005 3067 3082
57. Baxter R. Energy storage: an expanding role as distributed resources. 2003.
58. K.Y.C. Cheung, S.T.H. Cheung, R.G.N. De Silva, M.P.T. Juvonen, R. Singh, and J.J. Woo Large-scale energy storage systems 2003 Imperial College London, ISE2 England
59. R. Baxter Energy storage - a nontechnical guide 2006 PennWell Corporation Oklahoma
60. H. Liu, and J. Jiang Flywheel energy storage-an upswing technology for energy sustainability Energy Build 39 2007 599 604
61. Z. Kohari, and I. Vajda Losses of flywheel energy storages and joint operation with solar cells J Mater Process Tech 161 2005 62 65
62. L. Truong, F. Wolff, N. Dravid, and P. Li Simulation of the interaction between flywheel energy storage and battery energy storage on the international space station IEEE vol. 2 2000 848 854
63. T.J. Pieronek, D.K. Decker, and V.A. Spector Spacecraft flywheel systems-benefits, and issues IEEE 2 1997 589 593
64. G. Ries, and H.W. Neumueller Comparison of energy storage in flywheels and SMES Physica C: Supercond 357 2001 1306 1310
65. B. Bolund, H. Bernhoff, and M. Leijon Flywheel energy and power storage systems Renew Sustain Energy Rev 11 2007 235 258
66. T.M. Mulcahy, J.R. Hull, K.L. Uherka, R.C. Niemann, R.G. Abboud, and J.P. Juna et al. Flywheel energy storage advances using HTS bearings IEEE Trans Appl Supercond 9 1999 297 300
67. I. Vajda, Z. Kohari, T. Porjesz, L. Benko, V. Meerovich, and W. Gawalek Operational characteristics of energy storage high temperature superconducting flywheels considering time dependent processes Physica C: Supercond 372 2002 1500 1505
68. (de) R. Andrade, A. Ferreira, G. Sotelo, W. Suemitsu, L. Rolim, and J. Silva Neto et al. A superconducting high-speed flywheel energy storage system Physica C: Supercond 408 2004 930 931
69. Guo CX, Wei XL, Wang DB. Heat transfer enhancement and parametric study on the cold thermal energy storage system. In: Proceedings of Cryogenics and Refrigeration. 2008. p. 797-801, 999.
70. S.M. Hasnain, and N.M. Alabbadi Need for thermal-storage air-conditioning in Saudi Arabia Appl Energy 65 2000 153 164
71. MS-196. Project all electric vehicle (AEV). RTP 16.02 inom WEAG. Technical report no. 1; Nov-Dec 2001.
72. Sahin F, Vandenput A. Design considerations of the flywheel-mounted axial-flux permanent-magnet machine for a hybrid electric vehicle. 1999.
73. P. Mellor, N. Schofield, and D. Howe Flywheel and supercapacitor peak power buffer technologies IET 2000 8/1 8/5
74. I. Iglesias, L. Garcia-Tabares, A. Agudo, I. Cruz, and L. Arribas Design and simulation of a stand-alone wind-diesel generator with a flywheel energy storage system to supply the required active and reactive power IEEE vol. 3 2000 1381 1386
75. H. Kan, K. Chau, and M. Cheng Development of doubly salient permanent magnet motor flywheel energy storage for building integrated photovoltaic system IEEE 1 2001 314 320
76. Y.H. Kim, K.H. Lee, Y.H. Cho, and Y.K. Hong Comparison of harmonic compensation based on wound/squirrel-cage rotor type induction motors with flywheel IEEE vol. 2 2000 531 536
77. J. Zhang, Z. Chen, L. Cai, and Y. Zhao Flywheel energy storage system design for distribution network IEEE vol. 4 2000 2619 2623
78. G. Reiner, and N. Wehlau Concept of a 50 MW/650 MJ power source based on industry-established MDS flywheel IEEE vol. 1 2001 187 190
79. T. Richard, R. Belhomme, N. Buchheit, and F. Gorgette Power quality improvement case study of the connection of four 1.6 MVA flywheel dynamic UPS systems to a medium voltage distribution network IEEE vol. 1 2001 253 258
80. L.V. Truong, F.J. Wolff, and N.V. Dravid Simulation of flywheel electrical system for aerospace applications IEEE vol. 1 2000 601 608
81. T. Aanstoos, J. Kajs, W. Brinkman, H. Liu, A. Ouroua, and R. Hayes et al. High voltage stator for a flywheel energy storage system IEEE Trans Magn 37 2001 242 247
82. F. Aghbalou, F. Badia, and J. Illa Exergetic optimization of solar collector and thermal energy storage system Int J Heat Mass Tran 49 2006 1255 1263
83. Fehrenbacher K. Pumped hydro energy storage: it takes a heck of a long time. 2010.
84. E. Ingram Balancing the grid with pumped storage Renewable energy world.com 2010
85. Schoppe C.Wind and pumped-hydro power storage: determining optimal commitment policies with knowledge gradient non-parametric estimation. 2010.
86. D.A. Anthony New energy storage option Gravity Power 2011 Available from: 〈 http://gigaom.com/2011/01/19/a-new-energy-storage-option- gravity-power/ âŒ
87. PIER program. 2020 Strategic analysis of energy storage in California. University of California.
88. R.A. Huggins Energy storage 2010 Springer-Verlag GmbH
89. Electropaedia. Battery and energy technologies: lead acid battery. Available from: 〈http://www.mpoweruk.com/leadacid. htmâŒ.
90. C.P. Zhang, S.M. Sharkh, X. Li, F.C. Walsh, C.N. Zhang, and J.C. Jiang The performance of a soluble lead-acid flow battery and its comparison to a static lead-acid battery Energy Convers Manage 52 2011 3391 3398
91. F.C. Walsh Electrochemical technology for environmental treatment and clean energy conversion Pure Appl Chem 73 2001 1819 1837
92. C.P. De Léon, A. Frías-Ferrer, J. González-Garcia, D.A. Szánto, and F.C. Walsh Redox flow cells for energy conversion J Power Sources 160 2006 716 732
93. C.B. Beggs, and I.C. Ward Ice storage: design study of the factors effecting installations Build Serv Eng Res Technol 13 1992 49 59
94. L.T. Lam, and R. Louey Development of ultra-battery for hybrid-electric vehicle applications J Power Sources 158 2006 1140 1148
95. Energy storage technology primer: a summary. Available from: 〈http://www.nrf.gov.sg/NRF/uploadedFiles/National-Innovation- Challenge/Energy%20Storage.pdfâŒ.
96. B.G. Pollet, I. Staffell, and J.L. Shang Current status of hybrid, battery and fuel cell electric vehicles: from electrochemistry to market prospects Electrochim Acta 84 2012 235 249
97. M. Kamibayashi, and K. Tanaka Recent sodium sulfur battery applications IEEE 2 2001 1169 1173
98. X.T. Ren, L.K. Zeng, P. Liu, and H. Wang Thermal energy storage system of sulfate/fiber matrix composite Key Eng Mat 368-372 2008 1077 1079 (948)
99. Y.H. Yau, and S.K. Lee Feasibility study of an ice slurry-cooling coil for HVAC and R systems in a tropical building Appl Energy 87 2010 2699 2711
100. J.S. Lee, S. Tai Kim, R. Cao, N.S. Choi, M. Liu, and K.T. Lee et al. Metal-air batteries with high energy density: Li-air versus Zn-air Adv Energy Mater 1 2011 34 50
101. K.F. Blurton, and A.F. Sammells Metal/air batteries: their status and potential-a review J Power Sources 4 1979 263 279
102. T. Nguyen, and R.F. Savinell Flow batteries Electrochem Soc Interface 2011 54 56
103. M. Ferrier Stockage d'energie dans un enroulement supraconducteur Low Temp Electr Power 1970 425 432
104. M. Zukowski Mathematical modeling and numerical simulation of a short term thermal energy storage system using phase change material for heating applications Energy Convers Manage 48 2007 155 165
105. Tixador P. Superconducting magnetic energy storage: Status and perspective. 2008.
106. ASHRAE Thermal storage. ASHRAE Handbook: HVAC Applications 2007 American Society of Heating, Refrigerating and Air Conditioning Engineers (ASHRAE), Inc. Atlanta, GA
107. K.S. Lee, and S.J. Jeong Numerical modeling on the performance of aquifer thermal energy storage system under cyclic flow regime Int J Green Energy 5 2008 1 14
108. Banks G. Graphene-based supercapacitor hits new energy storage high. Gizmag. 2010, Available from: 〈 http://www.gizmag.com/ graphene-supercapacitor-energy-density-record/17188/ âŒ.
109. B. Rismanchi, R. Saidur, G. BoroumandJazi, and S. Ahmed Energy, exergy and environmental analysis of cold thermal energy storage (CTES) systems Renew Sustain Energy Rev 16 2012 5741 5746
110. Y.H. Yau, and B. Rismanchi A review on cool thermal storage technologies and operating strategies Renew Sustain Energy Rev 16 2012 787 797
111. A. Sharma, V. Tyagi, C. Chen, and D. Buddhi Review on thermal energy storage with phase change materials and applications Renew Sustaine Energy Rev 13 2009 318 345
112. KHIN MYAMYA. Encapsulation of phase change materials for heat storage. 2003.
113. M.M. Farid, A.M. Khudhair, S.A.K. Razack, and S. Al-Hallaj A review on phase change energy storage: materials and applications Energy Convers Manage 45 2004 1597 1615
114. A.I. Fernandez, M. Martinez, M. Segarra, I. Martorell, and L.F. Cabeza Selection of materials with potential in sensible thermal energy storage Sol Energy Mater Sol Cells 2010 1723 94
115. Senjyu T, Shimabukuro K, Uezato KF, Funabashi T. A technique for thermal and energy storage system unit commitment. In: Proceedings of the 2004 IEEE power engineering society general meeting, vols. 1 and 2. 2004. p. 601-6, 2358.
116. Solar heat storage: latent heat materials. In: Lane G, editor. Boca Raton, Florida: CRC Press, Inc.; 1986.
117. B. Zalba, J.M. Marin, L.F. Cabeza, and H. Mehling Review on thermal energy storage with phase change: materials, heat transfer analysis and applications Appl Therm Eng 23 2003 251 283
118. A.H. Abedin, and M.A. Rosen Closed and open thermochemical energy storage: energy- and exergy-based comparisons Energy 41 2012 83 92
119. Visscher K,Veldhuid JBJ. Comparison of candidate material for seasonal storage of solar heat through dynamic simulation of building and renewable energy system. In: Proceedings of the ninth international IBPSA conference, Montreal, Canada. 2005. p. 1285-92.
120. Elkind EN. The power of energy storage: how to increase deployment in California to reduce greenhouse gas emissions. 2010.
121. S.M. Kaplan Electric power storage Congr Res Serv 2009