用于中高温热能储存的碱酸盐离子液体:合成与热物理特性分析

IF 5.3 2区 化学 Q2 CHEMISTRY, PHYSICAL Journal of Molecular Liquids Pub Date : 2024-09-01 DOI:10.1016/j.molliq.2024.125912
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There are already some solid–liquid phase change materials working in this range of temperature e.g., sugar alcohols, aromatic organic compound, inorganic salts, or blend of inorganic salts but all of them present different drawbacks, such as vapor pressure, degradation, low thermal conductivity, corrosion, etc. In consequence, there is a need to explore new PCM materials in this range of temperature applications. In this context, ionic liquids could play a key role in the development of novel PCMs due to their intrinsic properties. Indeed, ILs are gaining increased attention in the field of thermal energy storage in the last years but mainly in the low temperature range (&lt;150 °C) remaining their application in the mid-to-high temperature range in between 150 °C and 350 °C underestimated. 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引用次数: 0

摘要

近年来,热能储存备受关注,并呈现出蓬勃发展的势头。从这个意义上说,以潜热形式储存热能具有能量密度高、能量损耗低和能源效率高等特点,因此特别受到关注。要以潜热形式储存热能,就需要相变材料(PCM)的存在,而相变材料的性能则是在热能储存(TES)系统中实施相变的关键,相变发生的温度,低温(150 °C)或高温(150 °C),将决定特定 PCM 的应用。在这种情况下,开发可在 150 °C 至 350 °C 之间的中高温环境中储存潜热的 PCM 材料就显得尤为重要,例如在太阳能聚光发电或热回收领域。目前已经有一些固液相变材料可以在这个温度范围内工作,如糖醇、芳香族有机化合物、无机盐或无机盐混合物,但它们都存在不同的缺点,如蒸汽压、降解、导热率低、腐蚀等。因此,有必要在这一温度范围内探索新的 PCM 材料。在这种情况下,离子液体因其固有特性,可在新型 PCM 的开发中发挥关键作用。事实上,近年来,离子液体在热能储存领域越来越受到关注,但主要是在低温范围(150 °C),而在 150 °C至 350 °C的中高温范围内的应用却被低估了。在这项工作中,我们通过将所需的甲氧基羧酸甲酯与 NaOH 或 KOH 直接反应,制备了六种不同的碱基烷酸酯离子液体,即[Na][MeOC2]、[K][MeOC2]、[Na][MeOC3]、[K][MeOC3]、[Na][MeOC4]和[K][MeOC4]。对制备的离子液体进行了结构表征和热物理性质评估。其中五种离子液体([K][MeOC3]除外)显示出良好的焓值,范围在 119 J/g 至 197 J/g 之间,四种离子液体([Na][MeOC2]、[K][MeOC2]、[Na][MeOC4]和[K][MeOC4])在 380 °C 以上显示出优异的热稳定性。此外,这四种离子液体还成功通过了循环性测试,表明在 50 次加热/冷却循环后没有明显的焓损失(最小值为 0%,最大值为 7%),符合 RAL-GZ 896(质量协会 PCM)的循环类别 F。总之,这些制备的离子液体在循环性和热稳定性方面都超过了糖醇,在所研究的中高温(150-350 °C)范围内可与无机盐(如 NaNO3)相媲美。
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Alkali alkanoate ionic liquids for thermal energy storage at mid-to-high temperature: Synthesis and thermal–physical characterization

Thermal energy storage is gaining much attention and experiencing a renascence in last years. In this sense, storing thermal energy in form of latent heat is of special interest due higher energy density, lower energy losses and higher energy efficiency. To store thermal energy as latent heat the presence of a phase change material (PCM) is needed and its performance the key for its implementation in a thermal energy storage (TES) system and the temperature at which the phase change takes place, low (<150 °C) or high (>150 °C) temperature, will condition the application of a given PCM. In this context, the development of PCM materials to store latent heat at mid-to-high temperature in between 150 °C and 350 °C is of special interest e.g., in the field of concentrated solar power or heat recovery. There are already some solid–liquid phase change materials working in this range of temperature e.g., sugar alcohols, aromatic organic compound, inorganic salts, or blend of inorganic salts but all of them present different drawbacks, such as vapor pressure, degradation, low thermal conductivity, corrosion, etc. In consequence, there is a need to explore new PCM materials in this range of temperature applications. In this context, ionic liquids could play a key role in the development of novel PCMs due to their intrinsic properties. Indeed, ILs are gaining increased attention in the field of thermal energy storage in the last years but mainly in the low temperature range (<150 °C) remaining their application in the mid-to-high temperature range in between 150 °C and 350 °C underestimated. In this work, we prepared six different alkali alkanoate ionic liquids, namely [Na][MeOC2], [K][MeOC2], [Na][MeOC3], [K][MeOC3], [Na][MeOC4] and, [K][MeOC4] by direct reaction between the desired methyl methoxycarboxylate ester with NaOH or KOH. The prepared ionic liquids were structurally characterized, and their thermal–physical properties evaluated. Five of them but [K][MeOC3] showed good enthalpy values ranging from 119 J/g to 197 J/g and four of them [Na][MeOC2], [K][MeOC2], [Na][MeOC4] and, [K][MeOC4] have showed excellent thermal stability above 380 °C. In addition, these four ionic liquids have successfully passed the cyclability test showing no significant enthalpy losses (between 0 % minimum and 7 % maximum) after 50 heating/cooling cycles compiling with the cycling category F of the RAL-GZ 896 (Quality Association PCM). All in all, these prepared ionic liquids surpass sugar alcohols in terms of cyclability and thermal stability and are comparable with the inorganic salts e.g. NaNO3 employed in the studied range of mid-to-high temperature (150–350 °C).

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来源期刊
Journal of Molecular Liquids
Journal of Molecular Liquids 化学-物理:原子、分子和化学物理
CiteScore
10.30
自引率
16.70%
发文量
2597
审稿时长
78 days
期刊介绍: The journal includes papers in the following areas: – Simple organic liquids and mixtures – Ionic liquids – Surfactant solutions (including micelles and vesicles) and liquid interfaces – Colloidal solutions and nanoparticles – Thermotropic and lyotropic liquid crystals – Ferrofluids – Water, aqueous solutions and other hydrogen-bonded liquids – Lubricants, polymer solutions and melts – Molten metals and salts – Phase transitions and critical phenomena in liquids and confined fluids – Self assembly in complex liquids.– Biomolecules in solution The emphasis is on the molecular (or microscopic) understanding of particular liquids or liquid systems, especially concerning structure, dynamics and intermolecular forces. The experimental techniques used may include: – Conventional spectroscopy (mid-IR and far-IR, Raman, NMR, etc.) – Non-linear optics and time resolved spectroscopy (psec, fsec, asec, ISRS, etc.) – Light scattering (Rayleigh, Brillouin, PCS, etc.) – Dielectric relaxation – X-ray and neutron scattering and diffraction. Experimental studies, computer simulations (MD or MC) and analytical theory will be considered for publication; papers just reporting experimental results that do not contribute to the understanding of the fundamentals of molecular and ionic liquids will not be accepted. Only papers of a non-routine nature and advancing the field will be considered for publication.
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