Preparation and characterization of magnetized GO nanoparticle enhanced microencapsulated phase change material for thermal energy storage application

IF 0.9 Q4 ENGINEERING, CHEMICAL
V. Aiswarya, Sudev Das, Satish Kumar, A. Datta
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引用次数: 1

Abstract

ABSTRACT Novel magnetized nanoparticle nickel-graphene oxide / n-octadecane/ melamine-formaldehyde (MF) composite phase change material (MnCPCM) for enhanced solar thermal energy storage(STES) is prepared via in situ polymerization. The magnetized nanoparticles in CPCM promoted the thermal energy storage capacity as well as photothermal conversion efficiency of the composite by the unidirectional heat transfer flow. For these composite PCM, the thermal conductivity is found as excellent and more than that of pure n-octadecane (0.153 W/mK) because of the presence of highly conductive magnetized GO. The role of magnetized Ni-GO nanoparticles in the structure and properties of the microencapsulated PCM is characterized by the SEM, optical microscopy, FTIR, XRD, DSC, thermogravimetric analysis and differential thermal analysis. SEM and optical microscopy reveal that the microencapsulated PCM has uniform spherical morphology. TGA and DTA results show the CPCM is stable up to a temperature of 350 °C. XRD analysis indicates highly ferromagnetic material is well composed with GO to enhance the directional heat flow. DSC analysis shows that the composite is stable up to 100 thermal cycling processes. The enhanced heat transfer flow and better leakage-preventing performance might be highly chosen for STES storage applications of the CPCM as well as heat sink integrated passive cooling. GRAPHICAL ABSTRACT
磁化GO纳米粒子增强微胶囊相变储能材料的制备与表征
摘要:采用原位聚合法制备了新型磁性纳米颗粒镍-氧化石墨烯/正十八烷/三聚氰胺-甲醛(MF)复合相变材料(MnCPCM),用于增强太阳能热储能(STES)。在CPCM中磁化的纳米颗粒通过单向传热流提高了复合材料的储热能力和光热转换效率。对于这些复合PCM,由于存在高导电性磁化的氧化石墨烯,其导热性能优异,并且优于纯正十八烷(0.153 W/mK)。通过SEM、光学显微镜、FTIR、XRD、DSC、热重分析和差热分析表征了磁化镍氧化石墨烯纳米颗粒对微胶囊化PCM结构和性能的影响。扫描电镜和光学显微镜观察表明,微胶囊化PCM具有均匀的球形形貌。热重分析(TGA)和差热分析(DTA)结果表明,CPCM在350℃温度下是稳定的。XRD分析表明,高铁磁性材料与氧化石墨烯组成良好,增强了定向热流。DSC分析表明,该复合材料在100次热循环过程中是稳定的。CPCM具有更强的传热流量和更好的防泄漏性能,可用于STES存储应用以及散热器集成被动冷却。图形抽象
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来源期刊
Indian Chemical Engineer
Indian Chemical Engineer ENGINEERING, CHEMICAL-
CiteScore
3.00
自引率
6.70%
发文量
33
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