Liquid-based high-temperature receiver technologies for next-generation concentrating solar power: A review of challenges and potential solutions

Ya-Ling HE , Wenqi WANG , Rui JIANG , Mingjia LI , Wenquan TAO

Front. Energy ›› 2023, Vol. 17 ›› Issue (1) : 16 -42.

PDF (2717KB)
Front. Energy ›› 2023, Vol. 17 ›› Issue (1) : 16 -42. DOI: 10.1007/s11708-023-0866-8
REVIEW ARTICLE
REVIEW ARTICLE

Liquid-based high-temperature receiver technologies for next-generation concentrating solar power: A review of challenges and potential solutions

Author information +
History +
PDF (2717KB)

Abstract

To reduce the levelized cost of energy for concentrating solar power (CSP), the outlet temperature of the solar receiver needs to be higher than 700 °C in the next-generation CSP. Because of extensive engineering application experience, the liquid-based receiver is an attractive receiver technology for the next-generation CSP. This review is focused on four of the most promising liquid-based receivers, including chloride salts, sodium, lead-bismuth, and tin receivers. The challenges of these receivers and corresponding solutions are comprehensively reviewed and classified. It is concluded that combining salt purification and anti-corrosion receiver materials is promising to tackle the corrosion problems of chloride salts at high temperatures. In addition, reducing energy losses of the receiver from sources and during propagation is the most effective way to improve the receiver efficiency. Moreover, resolving the sodium fire risk and material compatibility issues could promote the potential application of liquid-metal receivers. Furthermore, using multiple heat transfer fluids in one system is also a promising way for the next-generation CSP. For example, the liquid sodium is used as the heat transfer fluid while the molten chloride salt is used as the storage medium. In the end, suggestions for future studies are proposed to bridge the research gaps for > 700 °C liquid-based receivers.

Graphical abstract

Keywords

next-generation concentrating solar power / liquid-based solar receiver / molten salt / liquid metals

Cite this article

Download citation ▾
Ya-Ling HE, Wenqi WANG, Rui JIANG, Mingjia LI, Wenquan TAO. Liquid-based high-temperature receiver technologies for next-generation concentrating solar power: A review of challenges and potential solutions. Front. Energy, 2023, 17(1): 16-42 DOI:10.1007/s11708-023-0866-8

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Li M J, Zhu H H, Guo J Q. . The development technology and applications of supercritical CO2 power cycle in nuclear energy, solar energy and other energy industries. Applied Thermal Engineering, 2017, 126: 255–275

[2]

Heywood H. Solar energy: a challenge to the future. Nature, 1957, 180(4577): 115–118

[3]

Lewis N S. Toward cost-effective solar energy use. Science, 2007, 315(5813): 798–801

[4]

Kraemer D, Jie Q, McEnaney K. . Concentrating solar thermoelectric generators with a peak efficiency of 7.4%. Nature Energy, 2016, 1(11): 16153

[5]

He Y L, Wang K, Qiu Y. . Review of the solar flux distribution in concentrated solar power: Non-uniform features, challenges, and solutions. Applied Thermal Engineering, 2019, 149: 448–474

[6]

Al-Ashouri A, Köhnen E, Li B. . Monolithic perovskite/silicon tandem solar cell with > 29% efficiency by enhanced hole extraction. Science, 2020, 370(6522): 1300–1309

[7]

NREL. Life cycle greenhouse gas emissions from concentrating solar power. Technical Report, National Renewable Energy Laboratories, 2012
[8]

Khamlich I, Zeng K, Flamant G. . Technical and economic assessment of thermal energy storage in concentrated solar power plants within a spot electricity market. Renewable & Sustainable Energy Reviews, 2020, 139: 110583
[9]

Merchán R, Santos M, Medina A. . High temperature central tower plants for concentrated solar power: 2021 overview. Renewable & Sustainable Energy Reviews, 2021, 155: 111828
[10]

Lilliestam J, Labordena M, Patt A. . Empirically observed learning rates for concentrating solar power and their responses to regime change. Nature Energy, 2017, 2: 17094

[11]

Pitz-Paal R. Concentrating solar power: Still small but learning fast. Nature Energy, 2017, 2(7): 17095

[12]

Wang K, He Y L. Thermodynamic analysis and optimization of a molten salt solar power tower integrated with a recompression supercritical CO2 Brayton cycle based on integrated modeling. Energy Conversion and Management, 2017, 135: 336–350

[13]

Qiu Y, Li M J, He Y L. . Thermal performance analysis of a parabolic trough solar collector using supercritical CO2 as heat transfer fluid under non-uniform solar flux. Applied Thermal Engineering, 2017, 115: 1255–1265

[14]

He Y L, Qiu Y, Wang K. . Perspective of concentrating solar power. Energy, 2020, 198: 117373

[15]

Guo J Q, Li M J, He Y L. . A systematic review of supercritical carbon dioxide (S-CO2) power cycle for energy industries: Technologies, key issues, and potential prospects. Energy Conversion and Management, 2022, 258: 115437

[16]

GauchePShultzAStappD, . US DOE Gen3 and SunShot 2030 Concentrating Solar Power R&D: In search of $0.05/kWh autonomy and seasonal storage. Technical Report, Sandia National Laboratories, 2019
[17]

Wang K, Li M J, Zhang Z D. . Evaluation of alternative eutectic salt as heat transfer fluid for solar power tower coupling a supercritical CO2 Brayton cycle from the viewpoint of system-level analysis. Journal of Cleaner Production, 2021, 279: 123472

[18]

Ho C K, Iverson B D. Review of high-temperature central receiver designs for concentrating solar power. Renewable & Sustainable Energy Reviews, 2014, 29: 835–846

[19]

Wang W Q, Jiang R, He Y L. . Optical-thermal-mechanical analysis of high-temperature receiver integrated with gradually sparse biomimetic heliostat field layouts for the next-generation solar power tower. Solar Energy, 2022, 232: 35–51

[20]

Jiang R, Li M J, Wang W Q. . A new methodology of thermal performance improvement and numerical analysis of free-falling particle receiver. Solar Energy, 2021, 230: 1141–1155

[21]

Du S, Li M J, Ren Q L. . Pore-scale numerical simulation of fully coupled heat transfer process in porous volumetric solar receiver. Energy, 2017, 140: 1267–1275

[22]

BurgaletaJ IAriasSRamirezD. Gemasolar, the first tower thermosolar commercial plant with molten salt storage. In:17th SolarPACES Conference, Granada, Spain, 2011
[23]

PachecoJ EBradshawR WDawsonD B, . Final test and evaluation results from the solar two project. Technical Report, Sandia National Laboratories, 2022
[24]

Turchi C S, Vidal J, Bauer M. Molten salt power towers operating at 600–650 °C: Salt selection and cost benefits. Solar Energy, 2018, 164: 38–46

[25]

Pérez-Álvarez R, González-Gómez P Á, Santana D. . Preheating of solar power tower receiver tubes for a high-temperature chloride molten salt. Applied Thermal Engineering, 2022, 216: 119097

[26]

Wetzel T, Pacio J, Marocco L D. . Liquid metal technology for concentrated solar power systems: Contributions by the German research program. AIMS Energy, 2014, 2(1): 89–98

[27]

Zhang Q, Cao D, Ge Z. . Response characteristics of external receiver for concentrated solar power to disturbance during operation. Applied Energy, 2020, 278: 115709

[28]

Gomez-Vidal J C, Tirawat R. Corrosion of alloys in a chloride molten salt (NaCl-LiCl) for solar thermal technologies. Solar Energy Materials and Solar Cells, 2016, 157: 234–244

[29]

Keny S, Gupta V, Kumbhar A G. . Corrosion tests of various alloys in fluorides of lithium, sodium and potassium (FLiNaK) medium for molten salt reactors in the temperature range of 550–750 °C using electrochemical techniques. Indian Journal of Chemical Technology, 2019, 26(1): 84–88
[30]

MehosMTurchiCVidalJ, . Concentrating solar power Gen3 demonstration roadmap. Technical Report, National Renewable Energy Laboratories, 2017
[31]

Fernández A G, Gomez-Vidal J, Oró E. . Mainstreaming commercial CSP systems: A technology review. Renewable Energy, 2019, 140: 152–176

[32]

Wermac. Effects & economic impact of corrosion. 2022-1-19, available at website of Wermac
[33]

Wang K, He Y L, Zhu H H. Integration between supercritical CO2 Brayton cycles and molten salt solar power towers: A review and a comprehensive comparison of different cycle layouts. Applied Energy, 2017, 195: 819–836

[34]

WangXXuXElsentriecyH, . Investigation of properties of KCl-MgCl2 eutectic salt for heat transfer and thermal storage fluids in CSP systems. In: ASME Heat Transfer Summer Conference, Bellevue, USA, 2017
[35]

Vidal J C, Klammer N. Molten chloride technology pathway to meet the US DOE sunshot initiative with Gen3 CSP. AIP Conference Proceedings, 2019, 2126(1): 080006

[36]

Ding W, Bauer T. Progress in research and development of molten chloride salt technology for next generation concentrated solar power plants. Engineering (Beijing), 2021, 7(3): 334–347

[37]

D’Souza B, Zhuo W, Yang Q. . Impurity driven corrosion behavior of HAYNES® 230® alloy in molten chloride salt. Corrosion Science, 2021, 187: 109483

[38]

Vignarooban K, Xu X, Wang K. . Vapor pressure and corrosivity of ternary metal-chloride molten-salt based heat transfer fluids for use in concentrating solar power systems. Applied Energy, 2015, 159: 206–213

[39]

Ong T C, Sarvghad M, Lippiatt K. . Review of the solubility, monitoring, and purification of impurities in molten salts for energy storage in concentrated solar power plants. Renewable & Sustainable Energy Reviews, 2020, 131: 110006

[40]

Cho H S, Van Zee J, Shimpalee S. . Dimensionless analysis for predicting Fe-Ni-Cr alloy corrosion in molten salt systems for concentrated solar power systems. Corrosion, 2016, 72(6): 742–760

[41]

Garcia-Diaz B L, Olson L, Martinez-Rodriguez M. . High temperature electrochemical engineering and clean energy systems. Journal of the South Carolina Academy of Science, 2016, 14(1): 11–14
[42]

Sun H, Wang J Q, Tang Z. . Assessment of effects of Mg treatment on corrosivity of molten NaCl-KCl-MgCl2 salt with Raman and infrared spectra. Corrosion Science, 2020, 164: 108350

[43]

Ding W, Gomez-Vidal J, Bonk A. . Molten chloride salts for next generation CSP plants: electrolytical salt purification for reducing corrosive impurity level. Solar Energy Materials and Solar Cells, 2019, 199: 8–15

[44]

Zhang Z, Lu X, Yan Y. . The dehydration of MgCl2· 6H2O by inhibition of hydrolysis and conversion of hydrolysate. Journal of Analytical and Applied Pyrolysis, 2019, 138: 114–119

[45]

Kipouros G J, Sadoway D R. A thermochemical analysis of the production of anhydrous MgCl2. Journal of Light Metals, 2001, 1(2): 111–117

[46]

Kurley J M, Halstenberg P W, McAlister A. . Enabling chloride salts for thermal energy storage: Implications of salt purity. RSC Advances, 2019, 9(44): 25602–25608

[47]

Chen G S, Sun I W, Sienerth K D. . Removal of oxide impurities from alkali haloaluminate melts using carbon tetrachloride. Journal of the Electrochemical Society, 1993, 140(6): 1523–1526

[48]

ZhaoY. Molten chloride thermophysical properties, chemical optimization, and purification. Technical Report, National Renewable Energy Laboratories, 2020
[49]

de Bakker J, Peacey J, Davis B. Thermal decomposition studies on magnesium hydroxychlorides. Canadian Metallurgical Quarterly, 2012, 51(4): 419–423

[50]

Fernández A G, Cabeza L F. Corrosion evaluation of eutectic chloride molten salt for new generation of CSP plants. Part 1: thermal treatment assessment. Journal of Energy Storage, 2020, 27: 101125

[51]

Kashani-Nejad S, Ng K, Harris R. Preparation of MgOHCl by controlled dehydration of MgCl2·6H2O. Metallurgical and Materials Transactions B, Process Metallurgy and Materials Processing Science, 2004, 35(2): 405–406

[52]

Kipouros G J, Sadoway D R. The chemistry and electrochemistry of magnesium production. Advances in Molten Salt Chemistry, 1987, 6: 127–209
[53]

Ding W, Shi H, Jianu A. . Molten chloride salts for next generation concentrated solar power plants: Mitigation strategies against corrosion of structural materials. Solar Energy Materials and Solar Cells, 2019, 193: 298–313

[54]

Zhao Y, Klammer N, Vidal J. Purification strategy and effect of impurities on corrosivity of dehydrated carnallite for thermal solar applications. RSC Advances, 2019, 9(71): 41664–41671

[55]

Zhao Y, Vidal J. Potential scalability of a cost-effective purification method for MgCl2-containing salts for next-generation concentrating solar power technologies. Solar Energy Materials and Solar Cells, 2020, 215: 110663

[56]

AlkhamisM. Stability of metals in molten chloride salt at 800 °C. Dissertation for the Master’s Degree. Tucson: The University of Arizona, 2016
[57]

StoddardLAndrewDAdamsS, . Molten salt: Concept definition and capital cost estimate. Technical Report, Allegheny Science & Technology Corporation, 2016
[58]

HuangS YMortzheimJSamarovV, . Low cost HIP fabrication of advanced power cycle components and PM/Wrought inconel 740H weld development—Final technical report. Technical Report, GE Research, 2021
[59]

Shingledecker J, de Barbadillo J, O’Donnell D. . Materials improvements for improved economy of high-temperature components in future Gen3 CSP systems. AIP Conference Proceedings, 2019, 2126(1): 020004

[60]

Gomez-Vidal J C, Fernandez A, Tirawat R. . Corrosion resistance of alumina forming alloys against molten chlorides for energy production. II: Electrochemical impedance spectroscopy under thermal cycling conditions. Solar Energy Materials and Solar Cells, 2017, 166: 234–245

[61]

Ding W, Shi H, Xiu Y. . Hot corrosion behavior of commercial alloys in thermal energy storage material of molten MgCl2/KCl/NaCl under inert atmosphere. Solar Energy Materials and Solar Cells, 2018, 184: 22–30

[62]

Tristancho-Reyes J, Chacón-Nava J, Peña-Ballesteros D. . Hot corrosion behaviour of NiCrFeNbMoTiAl coating in molten salts at 700 °C by electrochemical techniques. International Journal of Electrochemical Science, 2011, 6: 432–441
[63]

Fernández A G, Cabeza L F. Anodic protection assessment using alumina-forming alloys in chloride molten salt for CSP plants. Coatings, 2020, 10(2): 138

[64]

Gomez-Vidal J C. Corrosion resistance of MCrAlX coatings in a molten chloride for thermal storage in concentrating solar power applications. npj Materials Degradation, 2017, 1(1): 1–9

[65]

Ding W, Bonk A, Bauer T. Molten chloride salts for next generation CSP plants: selection of promising chloride salts & study on corrosion of alloys in molten chloride salts. AIP Conference Proceedings, 2019, 2126(1): 200014

[66]

Gomez-Vidal J, Fernandez A, Tirawat R. . Corrosion resistance of alumina-forming alloys against molten chlorides for energy production. I: pre-oxidation treatment and isothermal corrosion tests. Solar Energy Materials and Solar Cells, 2017, 166: 222–233

[67]

Chavez J M, Chaza C. Testing of a porous ceramic absorber for a volumetric air receiver. Solar Energy Materials, 1991, 24(1−4): 172–181

[68]

Patil V R, Kiener F, Grylka A. . Experimental testing of a solar air cavity-receiver with reticulated porous ceramic absorbers for thermal processing at above 1000 °C. Solar Energy, 2021, 214: 72–85

[69]

Barreto G, Canhoto P, Collares-Pereira M. Parametric analysis and optimisation of porous volumetric solar receivers made of open-cell SiC ceramic foam. Energy, 2020, 200: 117476

[70]

WalkerMArmijoK MYellowhairJ, . High temperature silicon carbide receiver tubes for concentrating solar power. Technical Report, Sandia National Laboratories, 2019
[71]

Armijo K M, Walker M, Christian J. . Thermal shock resistance of multilayer silicon carbide receiver tubes for 800 °C molten salt concentrating solar power application. AIP Conference Proceedings, 2020, 2303(1): 150004
[72]

Caccia M, Tabandeh-Khorshid M, Itskos G. . Ceramic–metal composites for heat exchangers in concentrated solar power plants. Nature, 2018, 562(7727): 406–409

[73]

Xu X, Wang X, Li P. . Experimental test of properties of KCl–MgCl2 eutectic molten salt for heat transfer and thermal storage fluid in concentrated solar power systems. Journal of Solar Energy Engineering, 2018, 140(5): 051011

[74]

Wang W Q, Qiu Y, Li M J. . Coupled optical and thermal performance of a fin-like molten salt receiver for the next-generation solar power tower. Applied Energy, 2020, 272: 115079

[75]

He Y L, Xiao J, Cheng Z D. . A MCRT and FVM coupled simulation method for energy conversion process in parabolic trough solar collector. Renewable Energy, 2011, 36(3): 976–985

[76]

Qiu Y, He Y L, Li P W. . A comprehensive model for analysis of real-time optical performance of a solar power tower with a multi-tube cavity receiver. Applied Energy, 2017, 185: 589–603

[77]

HoC KMahoneyA RAmbrosiniA, . Characterization of Pyromark 2500 for high-temperature solar receivers. In: ASME International Conference on Energy Sustainability, San Diego, CA, USA, 2012
[78]

Wang W Q, Li M J, Jiang R. . Receiver with light-trapping nanostructured coating: A possible way to achieve high-efficiency solar thermal conversion for the next-generation concentrating solar power. Renewable Energy, 2022, 185: 159–171

[79]

Coventry J, Burge P. Optical properties of Pyromark 2500 coatings of variable thicknesses on a range of materials for concentrating solar thermal applications. AIP Conference Proceedings, 2017, 1850(1): 030012

[80]

Zhang K, Hao L, Du M. . A review on thermal stability and high temperature induced ageing mechanisms of solar absorber coatings. Renewable & Sustainable Energy Reviews, 2017, 67: 1282–1299

[81]

Xu K, Du M, Hao L. . A review of high-temperature selective absorbing coatings for solar thermal applications. Journal of Materiomics, 2020, 6(1): 167–182

[82]

Shah A A, Ungaro C, Gupta M C. High temperature spectral selective coatings for solar thermal systems by laser sintering. Solar Energy Materials and Solar Cells, 2015, 134: 209–214

[83]

Dan A, Barshilia H C, Chattopadhyay K. . Solar energy absorption mediated by surface plasma polaritons in spectrally selective dielectric-metal-dielectric coatings: A critical review. Renewable & Sustainable Energy Reviews, 2017, 79: 1050–1077

[84]

Zhang W, Wang B, Zhao C. Selective thermophotovoltaic emitter with a periodic multilayer structures designed by machine learning. ACS Applied Energy Materials, 2021, 4(2): 2004–2013

[85]

Barshilia H C, Kumar P, Rajam K. . Structure and optical properties of Ag–Al2O3 nanocermet solar selective coatings prepared using unbalanced magnetron sputtering. Solar Energy Materials and Solar Cells, 2011, 95(7): 1707–1715

[86]

Li P, Liu B, Ni Y. . Large-scale nanophotonic solar selective absorbers for high-efficiency solar thermal energy conversion. Advanced Materials, 2015, 27(31): 4585–4591

[87]

Yang J, Shen H, Yang Z. . Air-stability improvement of solar selective absorbers based on TiW–SiO2 cermet up to 800 °C. ACS Applied Materials & Interfaces, 2021, 13(12): 14587–14598

[88]

Wang X, Lee E, Xu C. . High-efficiency, air-stable manganese–iron oxide nanoparticle-pigmented solar selective absorber coatings toward concentrating solar power systems operating at 750 °C. Materials Today. Energy, 2021, 19: 100609

[89]

Li Y, Lin C, Wu Z. . Solution-processed all-ceramic plasmonic metamaterials for efficient solar–thermal conversion over 100–727 °C. Advanced Materials, 2021, 33(1): 2005074

[90]

Chirumamilla A, Yang Y, Salazar M H. . Spectrally selective emitters based on 3D Mo nanopillars for thermophotovoltaic energy harvesting. Materials Today Physics, 2021, 21: 100503

[91]

Garbrecht O, Al-Sibai F, Kneer R. . CFD-simulation of a new receiver design for a molten salt solar power tower. Solar Energy, 2013, 90: 94–106

[92]

GarbrechtOAl-SibaiFKneerR, . Numerical investigation of a new molten salt central receiver design. In: 18th SolarPACES Conference, Marrakech, Morocco, 2012
[93]

Slootweg M, Craig K, Meyer J P. A computational approach to simulate the optical and thermal performance of a novel complex geometry solar tower molten salt cavity receiver. Solar Energy, 2019, 187: 13–29

[94]

FriefieldJFriedmanJ. Technical report No. 1: Solar thermal power systems baded on optical transmission. Technical Report, Rocketdyne Division, Rockwell International, 1974
[95]

Ho C K, Christian J M, Ortega J D. . Reduction of radiative heat losses for solar thermal receivers. High and Low Concentrator Systems for Solar Energy Applications IX, 2014, 9175: 917506
[96]

Yellowhair J, Ho C K, Ortega J D. . Testing and optical modeling of novel concentrating solar receiver geometries to increase light trapping and effective solar absorptance. High and Low Concentrator Systems for Solar Energy Applications X, 2015, 9559: 95590A

[97]

ChristianJ MOrtegaJ DHoC K, . Design and modeling of light-trapping tubular receiver panels. In: ASME International Conference on Energy Sustainability, Charlotte, NC, USA, 2016
[98]

HoC KOrtegaJ DChristianJ M, . Fractal-like materials design with optimized radiative properties for high-efficiency solar energy conversion. Technical Report, Sandia National Laboratories, 2016
[99]

OrtegaJ DChristianJ MHoC K. Design and testing of a novel bladed receiver. In: ASME International Conference on Energy Sustainability, Charlotte, USA, 2017
[100]

Wang W Q, Qiu Y, Li M J. . Optical efficiency improvement of solar power tower by employing and optimizing novel fin-like receivers. Energy Conversion and Management, 2019, 184: 219–234

[101]

Wang W Q, He Y L, Jiang R. A multi-scale solar receiver with peak receiver efficiency over 90% at 720 °C for the next-generation solar power tower. Renewable Energy, 2022, 200: 714–723

[102]

WilliamBStineM G. Power from the sun. 2022-5-2, available at website of Power from the Sun book
[103]

Schmitz M, Schwarzbözl P, Buck R. . Assessment of the potential improvement due to multiple-apertures in central receiver systems with secondary concentrators. Solar Energy, 2006, 80(1): 111–120

[104]

Li L, Wang B, Pye J. . Optical analysis of a multi-aperture solar central receiver system for high-temperature concentrating solar applications. Optics Express, 2020, 28(25): 37654–37668

[105]

McEnaney K, Weinstein L, Kraemer D. . Aerogel-based solar thermal receivers. Nano Energy, 2017, 40: 180–186

[106]

Zhao L, Bhatia B, Yang S. . Harnessing heat beyond 200°C from unconcentrated sunlight with nonevacuated transparent aerogels. ACS Nano, 2019, 13(7): 7508–7516

[107]

Li Q, Zhang Y, Wen Z X. . An evacuated receiver partially insulated by a solar transparent aerogel for parabolic trough collector. Energy Conversion and Management, 2020, 214: 112911

[108]

Berquist Z J, Turaczy K K, Lenert A. Plasmon-enhanced greenhouse selectivity for high-temperature solar thermal energy conversion. ACS Nano, 2020, 14(10): 12605–12613

[109]

Li Y, Xu X, Wang X. . Survey and evaluation of equations for thermophysical properties of binary/ternary eutectic salts from NaCl, KCl, MgCl2, CaCl2, ZnCl2 for heat transfer and thermal storage fluids in CSP. Solar Energy, 2017, 152: 57–79

[110]

Li C J, Li P W, Wang K. . Survey of properties of key single and mixture halide salts for potential application as high temperature heat transfer fluids for concentrated solar thermal power systems. AIMS Energy, 2014, 2(2): 133–157

[111]

Wang X, Rincon J D, Li P. . Thermophysical properties experimentally tested for NaCl-KCl-MgCl2 eutectic molten salt as a next-generation high-temperature heat transfer fluids in concentrated solar power systems. Journal of Solar Energy Engineering, 2021, 143(4): 041005

[112]

Robelin C, Chartrand P, Eriksson G. A density model for multicomponent liquids based on the modified quasichemical model: Application to the NaCl-KCl-MgCl2-CaCl2 system. Metallurgical and Materials Transactions. B, Process Metallurgy and Materials Processing Science, 2007, 38(6): 869–879

[113]

Robelin C, Chartrand P. A density model based on the modified quasichemical model and applied to the NaF-AlF3-CaF2-Al2O3 electrolyte. Metallurgical and Materials Transactions. B, Process Metallurgy and Materials Processing Science, 2007, 38(6): 881–892

[114]

Ouzilleau P, Robelin C, Chartrand P. A density model based on the modified quasichemical model and applied to the (NaCl+KCl+ZnCl2) liquid. Journal of Chemical Thermodynamics, 2012, 47: 171–176

[115]

Villada C, Ding W, Bonk A. . Engineering molten MgCl2–KCl–NaCl salt for high-temperature thermal energy storage: Review on salt properties and corrosion control strategies. Solar Energy Materials and Solar Cells, 2021, 232: 111344

[116]

Yu Y S, Tao Y B, He Y L. Molecular dynamics simulation of thermophysical properties of NaCl-SiO2 based molten salt composite phase change materials. Applied Thermal Engineering, 2020, 166: 114628

[117]

Qiu Y, Li M J, Li M J. . Numerical and experimental study on heat transfer and flow features of representative molten salts for energy applications in turbulent tube flow. International Journal of Heat and Mass Transfer, 2019, 135: 732–745

[118]

Martinek J, Jape S, Turchi C S. Evaluation of external tubular configurations for a high-temperature chloride molten salt solar receiver operating above 700 °C. Solar Energy, 2021, 222: 115–128

[119]

Wang Q, Huang J, Shen Z. . Negative thermal-flux phenomenon and regional solar absorbing coating improvement strategy for the next-generation solar power tower. Energy Conversion and Management, 2021, 247: 114756

[120]

Xu L, Stein W, Kim J S. . Three-dimensional transient numerical model for the thermal performance of the solar receiver. Renewable Energy, 2018, 120: 550–566

[121]

Pacio J, Singer C, Wetzel T. . Thermodynamic evaluation of liquid metals as heat transfer fluids in concentrated solar power plants. Applied Thermal Engineering, 2013, 60(1–2): 295–302

[122]

Benoit H, Spreafico L, Gauthier D. . Review of heat transfer fluids in tube-receivers used in concentrating solar thermal systems: Properties and heat transfer coefficients. Renewable & Sustainable Energy Reviews, 2016, 55: 298–315

[123]

Fritsch A, Frantz C, Uhlig R. Techno-economic analysis of solar thermal power plants using liquid sodium as heat transfer fluid. Solar Energy, 2019, 177: 155–162

[124]

Lipiński W, Abbasi-Shavazi E, Chen J. . Progress in heat transfer research for high-temperature solar thermal applications. Applied Thermal Engineering, 2021, 184: 116137

[125]

Pacio J, Wetzel T. Assessment of liquid metal technology status and research paths for their use as efficient heat transfer fluids in solar central receiver systems. Solar Energy, 2013, 93: 11–22

[126]

Flesch J, Niedermeier K, Fritsch A. . Liquid metals for solar power systems. IOP Conference Series. Materials Science and Engineering, 2017, 228(1): 012012

[127]

Turchi C S, Libby C, Pye J. . Molten salt vs. liquid sodium receiver selection using the analytic hierarchy process. AIP Conference Proceedings, 2022, 2445: 110016

[128]

TurchiCGageSMartinekJ, . CSP Gen3: Liquid-phase pathway to SunShot. Renewable Energy Laboratories Technical Report, 2021
[129]

SNL. Final report sodium solar receiver experiment. Sandia National Laboratories Technical Report, 1982
[130]

KesselringPSelvageC S. The IEA/SSPS solar thermal power plants volume1: Central receiver system. Springer, Berlin, Germany, 1986
[131]

CasalF G. Solar thermal power plants: achievements and lessons learned exemplified by the SSPS project in Almeria/Spain. Springer Science & Business Media, 2012
[132]

Heinzel A, Hering W, Konys J. . Liquid metals as efficient high-temperature heat-transport fluids. Energy Technology (Weinheim), 2017, 5(7): 1026–1036

[133]

BartosNFisherJWantA. Experiences from using molten sodium metal as heat transfer fluid in concentrating solar thermal power systems. Proceedings of Asia-Pacific Solar Research Conference, Brisbane, Australia, 2015
[134]

Coventry J, Andraka C, Pye J. . A review of sodium receiver technologies for central receiver solar power plants. Solar Energy, 2015, 122: 749–762

[135]

Deguchi Y, Muranaka R, Kamimoto T. . Reaction path and product analysis of sodium-water chemical reactions using laser diagnostics. Applied Thermal Engineering, 2017, 114: 1319–1324

[136]

Armijo K M, Andraka C E. Phenomenological studies on sodium for CSP applications: A safety review. AIP Conference Proceedings, 2016, 1734(1): 040001

[137]

Guo Q, Chen Z, Mao L. . Preliminary source term and consequence assessment of primary cover gas leakage accident for CLEAR-I. Progress in Nuclear Energy, 2015, 78: 136–140

[138]

BraidTHarperHWilsonR. Operation of cover-gas system during SLSF tests. Argonne National Laboratories Technical Report, 1982
[139]

Nur K, Laurent B, Thierry G. . The role of powder physicochemical properties on the extinction performance of an extinguishing powder for sodium fires. Nuclear Engineering and Design, 2019, 346: 24–34

[140]

Chikazawa Y, Katoh A, Yamamoto T. . Secondary sodium fire measures in JSFR. Nuclear Technology, 2016, 196(1): 61–73

[141]

MaletJ. Ignition and combustion of sodium, fire consequences, extinguishment and prevention. In: International Atomic Energy Agency, International Working Group on Fast Reactors, Vienna, Austria, 1996
[142]

Sarvghad M, Delkasar Maher S, Collard D. . Materials compatibility for the next generation of concentrated solar power plants. Energy Storage Materials, 2018, 14: 179–198

[143]

LaiG Y. High-temperature corrosion and materials applications. In: ASM international, Ohio, US, 2007
[144]

Conroy T, Collins M N, Grimes R. A review of steady-state thermal and mechanical modelling on tubular solar receivers. Renewable & Sustainable Energy Reviews, 2020, 119: 109591

[145]

Zhang J, Kapernick R. Oxygen chemistry in liquid sodium–potassium systems. Progress in Nuclear Energy, 2009, 51(4−5): 614–623

[146]

Mangus D, Napora A, Briggs S. . Design and demonstration of a laboratory-scale oxygen controlled liquid sodium facility. Nuclear Engineering and Design, 2021, 378: 111093

[147]

Hemanath M, Meikandamurthy C, Kumar A A. . Theoretical and experimental performance analysis for cold trap design. Nuclear Engineering and Design, 2010, 240(10): 2737–2744

[148]

Onea A, Hering W, Lux M. . Numerical optimization of cold trap designs for the Karlsruhe Sodium Laboratory. International Journal of Heat and Mass Transfer, 2017, 113: 984–999

[149]

Onea A, Lux M, Hering W. . Design, optimization and layout of a compact cold trap with high efficient heat recovery by a helical coil for the Karlsruhe Sodium Laboratory. International Journal of Heat and Mass Transfer, 2017, 113: 1000–1011

[150]

YvonP. Structural Materials for Generation IV Nuclear Reactors. Woodhead Publishing, 2016
[151]

Hering W, Onea A, Jianu A. . Liquid metals, materials and safety measures to progress to CSP 2.0. AIP Conference Proceedings, 2019, 2126(1): 080002

[152]

Deng Y, Jiang Y, Liu J. Liquid metal technology in solar power generation-basics and applications. Solar Energy Materials and Solar Cells, 2021, 222: 110925

[153]

Müller-Trefzer F, Niedermeier K, Fellmoser F. . Experimental results from a high heat flux solar furnace with a molten metal-cooled receiver SOMMER. Solar Energy, 2021, 221: 176–184

[154]

Flesch J, Fritsch A, Cammi G. . Construction of a test facility for demonstration of a liquid lead-bismuth-cooled 10 kW thermal receiver in a solar furnace arrangement-SOMMER. Energy Procedia, 2015, 69: 1259–1268

[155]

Alchagirov B B, Shamparov T M, Mozgovoi A G. Experimental investigation of the density of molten lead–bismuth eutectic. High Temperature, 2003, 41(2): 210–215

[156]

Mwesigye A, Yılmaz İ H. Thermal and thermodynamic benchmarking of liquid heat transfer fluids in a high concentration ratio parabolic trough solar collector system. Journal of Molecular Liquids, 2020, 319: 114151

[157]

Conroy T, Collins M N, Fisher J. . Thermohydraulic analysis of single phase heat transfer fluids in CSP solar receivers. Renewable Energy, 2018, 129: 150–167

[158]

Flesch J, Marocco L, Fritsch A. . Entropy generation minimization analysis of solar salt, sodium, and lead–bismuth eutectic as high temperature heat transfer fluids. Journal of Heat Transfer, 2020, 142(4): 042103

[159]

Ho C K. Advances in central receivers for concentrating solar applications. Solar Energy, 2017, 152: 38–56

[160]

Zhang J. A review of steel corrosion by liquid lead and lead–bismuth. Corrosion Science, 2009, 51(6): 1207–1227

[161]

Ilinčev G. Research results on the corrosion effects of liquid heavy metals Pb, Bi and Pb–Bi on structural materials with and without corrosion inhibitors. Nuclear Engineering and Design, 2002, 217(1−2): 167–177

[162]

Frazer D, Stergar E, Cionea C. . Liquid metal as a heat transport fluid for thermal solar power applications. Energy Procedia, 2014, 49: 627–636

[163]

Lorenzin N, Abanades A. A review on the application of liquid metals as heat transfer fluid in Concentrated Solar Power technologies. International Journal of Hydrogen Energy, 2016, 41(17): 6990–6995

[164]

Weisenburger A, Müller G, Heinzel A. . Corrosion, Al containing corrosion barriers and mechanical properties of steels foreseen as structural materials in liquid lead alloy cooled nuclear systems. Nuclear Engineering and Design, 2011, 241(5): 1329–1334

[165]

Shi H, Jianu A, Weisenburger A. . Corrosion resistance and microstructural stability of austenitic Fe–Cr–Al–Ni model alloys exposed to oxygen-containing molten lead. Journal of Nuclear Materials, 2019, 524: 177–190

[166]

Wei X, Jin J, Jiang Z. . FeCrMoWCBY metallic glass with high corrosion resistance in molten lead–bismuth eutectic alloy. Corrosion Science, 2021, 190: 109688

[167]

Fetzer R, Weisenburger A, Jianu A. . Oxide scale formation of modified FeCrAl coatings exposed to liquid lead. Corrosion Science, 2012, 55: 213–218

[168]

Ban N, Kamihori T, Takamuku H. A study of the behavior of volatiles in the float process. Journal of Non-Crystalline Solids, 2004, (345−346): 777–781

[169]

Li L Y, Lin H J, Han J J. . Influence of spout lip set-height on flow behavior during the glass float process. Journal of Non-Crystalline Solids, 2017, 472: 46–54

[170]

Shou P, Hongcan R, Xin C. . Continuous forming of ultrathin glass by float process. International Journal of Applied Glass Science, 2019, 10(3): 275–286

[171]

DeAngelis F, Seyf H R, Berman R. . Design of a high temperature (1350 °C) solar receiver based on a liquid metal heat transfer fluid: Sensitivity analysis. Solar Energy, 2018, 164: 200–209

[172]

Zhang Y, Cai Y, Hwang S. . Containment materials for liquid tin at 1350 °C as a heat transfer fluid for high temperature concentrated solar power. Solar Energy, 2018, 164: 47–57

[173]

Amy C, Budenstein D, Bagepalli M. . Pumping liquid metal at high temperatures up to 1673 Kelvin. Nature, 2017, 550(7675): 199–203

[174]

FinkJLeibowitzL. Thermodynamic and transport properties of sodium liquid and vapor. Argonne National Laboratories Technical Report, 1995
[175]

Sobolev V. Thermophysical properties of lead and lead–bismuth eutectic. Journal of Nuclear Materials, 2007, 362(2–3): 235–247

[176]

Assael M J, Kalyva A E, Antoniadis K D. . Reference data for the density and viscosity of liquid copper and liquid tin. Journal of Physical and Chemical Reference Data, 2010, 39(3): 033105

[177]

Humrickhouse P W. An equation of state and compendium of thermophysical properties of liquid tin, a prospective plasma-facing material. IEEE Transactions on Plasma Science, 2019, 47(7): 3374–3379

[178]

Chapman T W. The heat capacity of liquid metals. Materials Science and Engineering, 1966, 1(1): 65–69

[179]

Savchenko I V, Stankus S V, Agadjanov A S. Measurement of liquid tin heat transfer coefficients within the temperature range of 506–1170 K. High Temperature, 2011, 49(4): 506–511

RIGHTS & PERMISSIONS

Higher Education Press

AI Summary AI Mindmap
PDF (2717KB)

6464

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/