储热材料热稳定性实验研究

V. Demchenko, V. Falco
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引用次数: 0

摘要

余热存储方法的优化以及相关的技术和工艺解决方案对LHTES系统的发展具有重要的影响。储存热能的新技术日益成为提供热力基础设施的传统方法的替代方案。在本文中,我们分析了储热材料的实验研究结果,以便将其进一步集成到基础设施对象的智能电网加热系统中并在M-TES中使用。所进行的文献综述表明,不同作者所研究的热守恒物质的热物性参数差异很大。我们的结论是,这是由于所研究材料的质量和实验室测量的误差。这对LHTES系统的设计产生了不利影响,并使传热过程的计算和建模变得非常复杂。正确确定TES充放电循环过程中可以获得的热量,以及积累热量的材料的寿命,这一点尤为重要。因此,本工作的目的是根据热物理性质和稳定运行时间,在0℃至115℃之间确定适合储能应用的材料,并对其进行评估。考虑到经济方面,在本研究的框架内只考虑可用的技术材料,因为材料的选择旨在在实际操作条件下使用M-TES。图1总结了蓄热物质热的加热和冷却循环的研究结果。高热功率和高导热系数对于PCM的储存效率非常重要,特别是在凝固过程中,因为在传热中主要是连续生长的固体层。然而,这两种pcm都不适合这种形式的移动储热系统。巨大的缺点是出现不同的熔点值,两种候选物的保留时间高,以及它们的价格。因此,应该进一步研究以消除这些负面影响。尽管防冻液水溶液的储热密度相对较低,但它们是本研究框架内废热传递系统的有益候选者。NaCl盐的加入实际上并不影响冷却剂的加热和冷却速度。方辉石的加入使水的热物性变差,热富集密度变小。实验证明,在……之后……4个加热和冷却循环从技术菱方石溶液,一种深黄色,不溶性沉淀形成,在操作过程中产生问题。当测试云石时,TES放电时间显著增加。所有上述物质在加热/冷却30次循环后均显示出稳定状态,并表明过冷低于熔点约30°C。三水合乙酸钠没有稳定的结果。随后,经过20次加热和冷却循环,它失去了它的性能。
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EXPERIMENTAL RESEARCH OF THERMAL STABILITY OF SUBSTANCES FOR THERMAL ENERGY STORAGE
Optimizing the storage methods for excess heat energy and associated technical and technological solutions has a significant impact on the development of LHTES systems. New technologies for storing thermal energy are increasingly an alternative to the classic methods of providing thermal infrastructure facilities. In this paper we analyze the results of experimental studies of heat-storage materials for their further integration into the Smart Grid heating system of infrastructure objects and use in the M-TES. The conducted literary review showed that the thermophysical parameters of the investigated substances for the conservation of heat from different authors are very different. We conclude that this is due to the quality of the materials being studied and the errors of laboratory measurements. This negatively affects the design of LHTES systems and greatly complicates the calculation and modeling of heat transfer processes. It is especially important to correctly determine the amount of heat that can be obtained during the charging and discharge cycles of TES, as well as the lifetime of the material that accumulates heat. Therefore, the purpose of this work is to identify the appropriate material for energy storage applications between 0 0C and 115 0C and evaluate it, depending on the thermophysical properties and the time of stable operation. Taking into account the economic aspects, only the available technical materials are considered within the framework of this study, since the choice of material is aimed at the use of M-TES in real conditions of operation. Figure 1 summarizes the results of research on heating and cooling cycles of heats of heat storage substances. High thermal power and, hence, high thermal conductivity are important for the storage efficiency of PCM, especially in the process of solidification, because in a heat transfer predominant solid layer that grows continuously. However, both PCMs are not suitable for mobile thermal storage systems in this form. The huge disadvantages are the emergence of different values ​​of the melting point, the high retention time of both candidates, as well as their prices. Therefore, further research should be directed to eliminate these negative effects. Despite the relatively low density of heat storage with aqueous solutions of antifreeze, they are beneficial candidates for waste heat transfer systems within the framework of this study. Addition of NaCl salt practically does not affect the speed of heating and cooling of the coolant. The addition of bischofite worsens the thermophysical properties of water and shows a small density of heat accumulation. It has been experimentally established that after 3 ... 4 cycles of heating and cooling from a solution of technical bischofite, a dark yellow, insoluble precipitate forms, which creates problems during the operation. Significant increase in TES discharge time was obtained when testing ozokerite. All of the above substances have shown a stable state after 30 cycles of heating / cooling and indicate overcooling below the melting point by about 30 °C. Trihydrate sodium acetate shows no stable results. Subsequently, after 20 cycles of heating and cooling, it loses its properties.
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