Spherical Capsules(球形胶囊)研究综述
Spherical Capsules 球形胶囊 - To be able to further optimize the thermal performance of the storage system, a model describing the charging and discharging processes of the heat storage was developed based on a new approach for the treatment of non-spherical capsules. [1] Transmission electron microscopy results confirmed the formation of spherical capsules of PCL coating the geraniol. [2] By means of a generalized effective-field approximation, formulas are derived for the effective thermal conductivity of a three-component tribocomposite based on a phenylone matrix with spherical strengthening inclusions (alumoborosilicate glass) and inhomogeneous antifrictional inclusions (spherical capsules of glycerin in a Kapton® shell). [3] A high encapsulation efficiency (EE) (83 ± 1%) was achieved in the encapsulates and semi-spherical capsules with rough surface and mean diameter of 2. [4] Dynamic incubation showed a greater impact on the internalization of rod-shaped capsules (∼58-67% change) than on the spherical capsules (∼24-29% change). [5] In this paper, the performance of an ice bank system based on spherical capsules is experimentally analyzed and the effects of different parameters are investigated using a numerical model. [6] Basing on combinatorial properties of these codes regarding to spherical capsules, we give constructions for code codimension lifting and obtain infinite families of new surface-covering codes with codimension $$r=tR$$r=tR, $$t\ge 2$$t≥2. [7]为了能够进一步优化蓄热系统的热性能,基于一种处理非球形胶囊的新方法,开发了一个描述蓄热器充放电过程的模型。 [1] 透射电子显微镜结果证实了包被香叶醇的 PCL 球形胶囊的形成。 [2] 通过广义有效场近似,推导出基于苯基的三组分摩擦复合材料的有效热导率公式壳)。 [3] 在表面粗糙且平均直径为 2 的胶囊和半球形胶囊中实现了高封装效率 (EE) (83±1%)。 [4] 动态孵育对棒状胶囊的内化(~58-67% 变化)比对球形胶囊(~24-29% 变化)的影响更大。 [5] 在本文中,基于球形胶囊的冰库系统的性能进行了实验分析,并使用数值模型研究了不同参数的影响。 [6] 基于这些代码关于球形胶囊的组合性质,我们给出了代码余维提升的构造,并获得了无限的新表面覆盖代码族,其余维$$r=tR$$r=tR, $$t\ge 2$$ t≥2。 [7]
heat transfer fluid 传热流体
The originality of this model consists in evaluating the heat flux exchanged between the heat transfer fluid (HTF) and the spherical capsules by using experimental data (here, the temperature) and an inverse method. [1] The system consists of encapsulated spherical capsules filled with a phase change material blended with distilled water and pseudomonas (nucleating agent) and the heat transfer fluid as a combination of distilled water and Mono-ethylene glycol. [2]该模型的独创性在于通过使用实验数据(此处为温度)和逆向方法来评估传热流体 (HTF) 和球形胶囊之间交换的热通量。 [1] 该系统由封装的球形胶囊组成,其中填充有与蒸馏水和假单胞菌(成核剂)混合的相变材料,以及作为蒸馏水和单乙二醇混合物的传热流体。 [2]
self healing efficiency 自愈效率
The results of this study show that: (1) the self-healing efficiency is proportional to the diameter of the capsule; (2) the self-healing efficiency increases approximately linearly with an increase in the aspect ratio for CYL and CST capsules; (3) the self-healing efficiency may be greatly over-estimated without considering the shell thickness, especially for spherical capsules. [1]本研究结果表明:(1)自愈效率与胶囊直径成正比; (2) CYL 和 CST 胶囊的自愈效率随着长径比的增加近似线性增加; (3) 在不考虑壳厚度的情况下,自愈效率可能会被大大高估,特别是对于球形胶囊。 [1]
spherical capsules filled 填充球形胶囊
The concept of the cold accumulator was based on a 200-L-capacity cylindrical storage tank in which spherical capsules filled with water were placed. [1] The system consists of encapsulated spherical capsules filled with a phase change material blended with distilled water and pseudomonas (nucleating agent) and the heat transfer fluid as a combination of distilled water and Mono-ethylene glycol. [2] According to the proposed model, the results of calculating the temperature of the coolant after passing the storage device correlate well with the experimental data for a thermal energy storage device with spherical capsules filled with paraffin. [3] Spherical capsules filled with PCM(s) of different thermo-physical properties are used to fill the bed region, and the molten salt is used as heat transfer fluid (HTF). [4]蓄冷器的概念基于一个容量为 200 升的圆柱形储罐,其中放置了装满水的球形胶囊。 [1] 该系统由封装的球形胶囊组成,其中填充有与蒸馏水和假单胞菌(成核剂)混合的相变材料,以及作为蒸馏水和单乙二醇混合物的传热流体。 [2] 根据所提出的模型,计算通过存储装置后冷却剂温度的结果与具有填充石蜡的球形胶囊的热能存储装置的实验数据具有很好的相关性。 [3] 填充有不同热物理性质的 PCM 的球形胶囊用于填充床区,熔盐用作传热流体 (HTF)。 [4]