郭永庆,张通,陈来军,司杨,陈晓弢,梅生伟

• 1:青海大学新能源光伏产业研究中心青海省清洁能源高效利用重点实验室
• 2:清华大学电力系统及发电设备控制和仿真国家重点实验室

摘要(Abstract)：

作为一种可实现大规模太阳能热利用的储热技术,盐梯度太阳池受到了国内外能源领域众多学者的广泛关注。首先简要介绍了盐梯度太阳池的基本结构、工作原理及主要性能评价指标,梳理了影响盐梯度太阳池综合性能的关键因素;在此基础上,总结了提升盐梯度太阳池性能的技术方向和具体措施,并介绍了盐梯度太阳池的典型应用场景;最后,总结了国内外盐梯度太阳池实验系统和工程应用的发展现状。以期通过对盐梯度太阳池关键技术的现状综述和工程技术的进展介绍,为后续相关领域的研究提供指导和借鉴。

关键词(KeyWords)： 盐梯度太阳池;提热;影响因素;增效;应用

Abstract:

Keywords:

基金项目(Foundation): 青海省科技计划项目(2018-ZJ-774)

作者(Author): 郭永庆,张通,陈来军,司杨,陈晓弢,梅生伟

参考文献(References)：

• [1]卢斯煜,周保荣,饶宏,等.高比例光伏发电并网条件下中国远景电源结构探讨[J].中国电机工程学报, 2018,38(S1):39-44.
• [2]王新赫,杜轩成,魏进家.不同太阳能热化学储能体系的研究进展[J].科学通报, 2017, 62(31):3631-3642.
• [3]高春娟,曹冬梅,张雨山.太阳池技术研究进展[J].盐业与化工, 2012, 41(5):14-19.
• [4]SAYER A H, AL-HUSSAINI H, CAMPBELL A N. New comprehensive investigation on the feasibility of the gel solar pond and a comparison with the salinity gradient solar pond[J]. Applied thermal engineering, 2018, 130:672-683.
• [5]SATHISH D, JEGADHEESWARAN S. Effective study of thermal behavior on membrane stratified portable solar pond[J]. Materials today proceedings, 2020, 27:23-25.
• [6]于文娟.自然静水蓄热保温供暖技术研究[D].哈尔滨:哈尔滨工业大学, 2013.
• [7]李楠.盐梯度太阳池水体研究及表层结冰对太阳池性能的影响[D].大连:大连理工大学, 2013.
• [8]NJOKUA H O, AGASHIA B E, ONYEGEGBU S O.A numerical study to predict the energy and exergy performances of a salinity gradient solar pond with thermal extraction[J]. Solar energy, 2017, 157:44-761.
• [9]ALIABADI M K, FEIZABADI A. Employing wavy structure to enhance thermal efficiency of spiral-coil utilized in solar ponds[J]. Solar energy, 2020, 199:552-569.
• [10]ARAMESH M, POURFAYAZ F, KASAEIAN A. Numerical investigation of the nanofluid effects on the heat extraction process of solar ponds in the transient step[J]. Solar energy,2017, 157:869-879.
• [11]GANGULY S, DATE A, AKBARZADEH A. Heat recovery from ground below the solar pond[J]. Solar energy, 2017,155:1254-1260.
• [12]EL MANSOURI A, HASNAOUI M, AMAHMID A, et al.Transient theoretical model for the assessment of three heat exchanger designs in a large-scale salt gradient solar pond:Energy and exergy analysis[J]. Energy conversion and management, 2018, 167:45-62.
• [13]KHALILIAN M, POURMOKHTAR H, ROSHAN A. Effect of heat extraction mode on the overall energy and exergy efficiencies of the solar ponds:A transient study[J]. Energy,2018, 154:27-37.
• [14]李楠,苗晶玉,张亮,等.盐梯度太阳池双扩散模型及热盐变化规律数值模拟[J].太阳能学报, 2017, 38(7):1749-1754.
• [15]RGHIF Y, ZEGHMATI B, BAHRAOUI F. Modeling of a salt gradient solar pond under Moroccan climate taking into account double-diffusive convection[J]. Materials today proceedings, 2020, 30:883-888.
• [16]MONTALàM, CORTINA J L, AKBARZADEHD A, et al. Stability analysis of an industrial salinity gradient solar pond[J]. Solar energy, 2019, 180:216-225.
• [17]EL MANSOURI A, HASNAOUIA M, AMAHMID A, et al. Transient modeling of a salt gradient solar pond using a hybrid Finite-Volume and Cascaded Lattice-Boltzmann method:Thermal characteristics and stability analysis[J].Energy conversion and management, 2018, 158:416-429.
• [18]刘宏升,姜霖松,吴丹,等.基于二维数值模拟的梯形太阳池特性分析[J].太阳能学报, 2017, 38(1):148-155.
• [19]姜霖松,刘宏升,吴丹,等.梯形太阳池热性能与影响因素分析[J].大连理工大学学报, 2016, 56(1):1-6.
• [20]王丹.盐梯度太阳池热性能与储能应用研究[D].沈阳:沈阳建筑大学, 2016.
• [21]BERKANIM, SISSAOUIH, ABDELLIA, et al.Comparison of three solar ponds with different salts through bi-dimensional modeling[J]. Solar energy, 2015, 116:56-68.
• [22]BOZKURT I, DENIZS, KARAKILCIKM, et al.Performance assessment of a magnesium chloride saturated solar pond[J]. Renewable energy, 2015, 78:35-41.
• [23]王广乐,祝永强,徐贵钰,等.基于盐湖卤水储热性能的太阳池研究[J].化学世界, 2019, 50(8):514-518.
• [24]赵启文,杨林,屠兰英,等.以纯碱蒸氨废液为工作介质的太阳池试验研究[J].青海大学学报(自然科学版),2015(1):46-49, 61.
• [25]VERMA S, DAS R. Wall profile optimisation of a salt gradient solar pond using a generalized model[J]. Solar energy, 2019, 184:356-371.
• [26]DEHGHAN A A, MOVAHEDI A, MAZIDI M.Experimental investigation of energy and exergy performance of square and circular solar ponds[J]. Solar energy, 2013, 97:273-284.
• [27]张敏,吴志跃,张国栋,等.非对流层数对太阳池性能的影响[J].可再生能源, 2015, 33(12):1778-1785.
• [28]KADI K E, ELAGROUDY S, JANAJREH I, et al. Flow simulation and assessment of a salinity gradient solar pond development[J]. Energy procedia, 2019, 158:911-917.
• [29]BEIKI H, SOUKHTANLOU E. Determination of optimum insulation thicknesses for salinity gradient solar pond’s bottom wall under different climate conditions[J]. Sn applied ences, 2020, 2(7):1-12.
• [30]SAYER A H, AL-HUSSAINI H, CAMPBELL A N.Experimental analysis of the temperature and concentration profiles in a salinity gradient solar pond with and without a liquid cover to suppress evaporation[J]. Solar energy, 2017,155:1354-1365.
• [31]RUSKOWITZ J A, SUAREZ F, TYLER S W, et al.Evaporation suppression and solar energy collection in a salt-gradient solar pond[J]. Solar energy, 2014, 99:36-46.
• [32]ARAMESH M, KASAEIAN A, POURFAYAZ F, et al.Energy analysis and shadow modeling of a rectangular type salt gradient solar pond[J]. Solar energy, 2017, 146:161-171.
• [33]KHALILIAN M. Assessment of the overall energy and exergy efficiencies of the salinity gradient solar pond with shading effect[J]. Solar energy, 2017, 158:311-320.
• [34]KARAKILCIK M, DINCER I, BOZKURT I, et al.Performance assessment of a solar pond with and without shading effect[J]. Energy conversion and management,2013, 65:98-107.
• [35]葛少成,孙文策,解茂昭.浊度和池底反射率对太阳池热性能的影响[J].太阳能学报, 2005, 26(5):732-736.
• [36]李楠,孙文策,张财红,等.不同浊度分布下太阳池热性能模拟[J].热科学与技术, 2010, 9(2):119-125.
• [37]ATIZ A, BOZKURT I, KARAKILCIK M, et al.Investigation of turbidity effect on exergetic performance of solar ponds[J]. Energy conversion and management, 2014,87:351-358.
• [38]SOGUKPINAR H, BOZKURT I, KARAKILCIK M.Performance comparison of aboveground and underground solar ponds[J]. Thermal science, 2018, 22(2):953-961.
• [39]肖树阳,孟庆芬,董亚萍,等.温棚太阳池模拟实验研究[J].盐湖研究, 2013, 21(1):57-61.
• [40]ANAGNOSTOPOULOS A, DANIEL S, CAMPBELL A N,et al. Finite element modelling of the thermal performance of salinity gradient solar ponds[J]. Energy, 2020, 203:117861.
• [41]BASO N F, GUNADIN I C, YUSRAN. Solar pond potential as a new renewable energy in South Sulawesi[J]. Journal of physics conference series, 2018, 979:012039.
• [42]MANSOURI A E, HASNAOUI M, BENNACER R, et al. Transient thermal performances of a salt gradient solar pond under semi-arid Moroccan climate using a 2D doublediffusive convection model[J]. Energy conversion and management, 2017, 151:199-208.
• [43]BOZKURT I, MANTARM S, KARAKILCIK M. A new performance model to determine energy storage efficiencies of a solar pond[J]. Heat and mass transfer, 2015, 51(1):39-48.
• [44]WANG H, YU X L, SHEN F L, et al. A Laboratory experimental study on effect of porous medium on salt diffusion of salt gradient solar pond[J]. Solar energy, 2015,122:630-639.
• [45]吴丹,刘宏升,孙文策.采用多孔介质材料增强太阳池性能的实验研究[J].太阳能学报, 2013, 34(8):1323-1328.
• [46]史玉凤.多孔介质对太阳池性能影响的研究[D].大连:大连理工大学, 2011.
• [47]张刘钢.相变材料对盐梯度太阳池热性能影响的实验和理论研究[D].焦作:河南理工大学, 2018.
• [48]BEIKA A J G, ASSARI M R, TABRIZI H B. Transient modeling for the prediction of the temperature distribution with phase change material in a salt-gradient solar pond and comparison with experimental data[J]. Journal of energy storage, 2019, 26:101011.
• [49]ASSARI M R, TABRIZI H B, BEIK A J G. Experimental studies on the effect of using phase change material in salinity-gradient solar pond[J]. Solar energy, 2015, 122:204-214.
• [50]BEIKI H, SOUKHTANLOU E. Improvement of salt gradient solar ponds’performance using nanoparticles inside the storage layer[J]. Applied nanoscience, 2019,9(2):243-254.
• [51]吴丹.以耦合辅助措施增强太阳池热性能实验和数值模拟研究[D].大连:大连理工大学, 2015.
• [52]ALCARAZ A, MONTALàM, VALDERRAMA C, et al.Increasing the storage capacity of a solar pond by using solar thermal collectors:Heat extraction and heat supply processes using in-pond heat exchangers[J]. Solar energy,2018, 171:112-121.
• [53]李楠,薛占一,刘华,等.配合集热器的盐梯度太阳池热性能实验与分析[J].热科学与技术, 2017, 16(5):392-397.
• [54]张学林,张通,薛小代,等.盐梯度太阳池Kalina循环发电系统性能研究[J].可再生能源, 2020, 38(6):738-744.
• [55]李楠,张超,张财红,等.盐梯度太阳池有机朗肯循环发电系统热力性能分析[J].热能动力工程, 2018, 33(5):7-12.
• [56]GHAEBI H, ROSTAMZADEH H. Performance comparison of two new cogeneration systems for freshwater and power production based on organic Rankine and Kalina cycles driven by salinity-gradient solar pond[J]. Renewable energy,2020, 156:748-767.
• [57]ZIAPOUR B M, SHOKRNIA M. Exergoeconomic analysis of the salinity-gradient solar pond power plants using two-phase closed thermosyphon:A comparative study[J].Applied thermal engineering, 2017, 115:123-133.
• [58]DING L C, AKBARZADEH A, DATE A, et al. Electric power generation via plate type power generation unit from solar pond using thermoelectric cells[J]. Applied energy,2016, 183:61-76.
• [59]薛占一.盐梯度太阳池热性能分析及热发电实验研究[D].秦皇岛:燕山大学, 2017.
• [60]TUNDEE S, SRIHAJONG N, CHARMONGKOLPRADIT S, et al. Electric power generation from solar pond using combination of thermosyphon and thermoelectric modules[J]. Energy procedia, 2014, 48:453-463.
• [61]APPADURAI M, VELMURUGAN V. Performance analysis of fin type solar still integrated with fin type mini solar pond[J]. Sustainable energy technologies and assessments,2015, 9:30-36.
• [62]BISHT S, DHINDSA G S, Sehgal S S, et al. Augmentation of diurnal and nocturnal distillate of solar still having wicks in the basin and integrated with solar pond[J]. Materials today proceedings, 2020, 33(3):1615-1619.
• [63]SUáREZ F, RUSKOWITZ J A, TYLER S W, et al. Renewable water direct contact membrane distillation coupled with solar ponds[J]. Applied energy, 2015, 158:532-539.
• [64]NAKOA K, RAHAOUI K, DATE A, et al. Sustainable zero liquid discharge desalination(SZLDD)[J]. Solar energy,2016, 135:337-347.
• [65]曹国建.太阳池集热的太阳能海水淡化系统性能研究[D].大连:大连理工大学, 2012.
• [66]赵广斌.太阳能海水淡化系统经济性对比研究[D].大连:大连理工大学, 2013.
• [67]KANANA S, DEWSBURYA J, SERFF G F L. Simulation of solar air-conditioning system with salinity gradient solar pond[J]. Energy procedia, 2015, 79:746-751.
• [68]ATIZ A, KARAKILCIK H, ERDEN M, et al. Assessment of electricity and hydrogen production performance of evacuated tube solar collectors[J]. International journal of hydrogen energy, 2019, 44(27):14137-14144.
• [69]KARAKILCIK M, ERDEN M, CILOGULLARI M, et al.Investigation of hydrogen production performance of a reactor assisted by a solar pond via photoelectrochemical process[J]. International journal of hydrogen energy, 2018,43(23):10549-10554.
• [70]吴志跃,张敏,程芳琴,等.太阳池辅热下污泥厌氧消化产沼气研究[J].山西农业科学, 2016, 44(5):629-634.
• [71]余疆江,郑绵平,唐力君,等.碳酸盐型卤水实验室模拟提锂和太阳池提锂的对比[J].化工进展, 2013, 32(6):1248-1252, 1260.
• [72]王品.太阳池富钾机理及其在大浪滩盐湖的应用技术研究[D].天津:天津科技大学, 2015.
• [73]ALCARAZ A, MONTALàM, CORTINA J L, et al. Design construction and operation of the first industrial salinitygradient solar pond in Europe:An efficiency analysis perspective[J]. Solar energy, 2018, 164:316-326.
• [74]ABDULLAH A A, FALLATAH H M, LINDSAY K A, et al.Measurements of the performance of the experimental salt-gradient solar pond at Makkah one year after commissioning[J]. Solar energy, 2017, 150:212-219.
• [75]高春娟,董泽亮,蔡荣华,等.盐梯度太阳池的建立及运行实验研究[J].盐业与化工, 2015, 44(10):34-36.
• [76]ASSARIMR, TABRIZIHB, PARVAR M, etal.Experiment and optimization of mixed medium effect on small-scale salt gradient solar pond[J]. Solar energy, 2017,151:102-109.
• [77]SUáREZ F, RUSKOWITZ J A, CHILDRESS A E, etal.Understanding the expected performance of large-scale solar ponds from laboratory-scale observations and numerical modeling[J]. Applied energy, 2014, 117:1-10.
• [78]FAQEHA H, BAWAHAB M, Vet Q L, etal. A n experimental study to establish a salt gradient solar pond(SGSP)[J]. Energy procedia, 2019, 160:239-245.
• [79]刘宏升,姜霖松,吴丹,等.梯形盐水太阳池的实验与模拟研究[J].太阳能学报, 2016, 37(5):1227-1234.
• [80]史玉凤,孙文策,刘宏升,等.太阳池底部加设多孔介质实验与模拟研究[J].大连理工大学学报, 2012, 52(1):16-22.
• [81]KHALILIAN M. Energetic performance analysis of solar pond with and without shading effect[J]. Solar energy, 2017,157:860-868.
• [82]WANG H, WU Q, MEI Y Y, et al. A study on exergetic performance of using porous media in the salt gradient solar pond[J]. Applied thermal engineering, 2018, 136:301-308.