相变材料在太阳能聚光中心储存的热分析

Q3 Energy Journal of Energy Systems Pub Date : 2023-09-30 DOI:10.30521/jes.1082104
Sulaiman AL HASHMİ, Mingjie CHEN
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引用次数: 0

摘要

对高温相变材料(PCM)进行了热分析,考虑了不锈钢胶囊中20%的空隙和浮力驱动对流。探讨了相变引起的热膨胀和体积膨胀对能量储存和回收过程的影响。用水来填充两种不同的蜡、石蜡和硬脂酸球体之间的空隙,被认为是聚光太阳能发电的潜在PCM。在层流和湍流两种不同的边界条件下,模拟了进入和流出胶囊壁的充放料过程。应用焓-孔隙率法和流体体积法建立了计算模型,计算了PCM胶囊内部的输运现象,包括内部空气空洞。建立了包含在球内的PCM的简化二维模型,并对从固态到液态的转变进行了热分析。模拟的充电过程模式与理论模式进行了比较。实验表明,在40 ~ 60 mm无铜翅片和60 mm有铜翅片的温度分布有不同的表现。石蜡的总转化速率为0.5,比硬脂酸所需的时间短。球体的大小随着时间的推移而增加,球体的相完全改变,因为硬脂酸在过渡期间比石蜡膨胀得更多。将一个由铜制成的矩形翅片插入球中可以缩短循环时间并增加产量。
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Thermal analysis of phase change materials storage in solar concenter
Thermal analysis of high-temperature phase change materials (PCM) is conducted with the consideration of a 20% void and buoyancy-driven convection in a stainless-steel capsule. The effects of the thermal expansion and the volume expansion due to phase change on the energy storage and retrieval process are explored. The used water to fill the void between two different wax paraffin and stearic acid spheres is considered as a potential PCM for concentrated solar power. The charging/discharging process into and from the capsule wall is simulated under different boundary conditions for laminar and turbulent flows. Computational models are conducted by applying an enthalpy-porosity method and volume of fluid method to calculate the transport phenomena within the PCM capsule, including an internal air void. A simplified two-dimensional model of the PCM contained within the spheres is constructed and thermal analyses are performed for the transition from solid to liquid states. Simulated charging process modes are compared with the theory. According to experiments, the temperature distributions from 40-60 mm without and with 60 mm with copper fin have different behavior. The paraffin takes less time than stearic acid for total transformation at a rate of 0.5. The size of the sphere increases over the amount of time and the phase of the sphere to complete changes as stearic acid expands more than paraffin during the transition. Inserting a rectangular fin, that is made from copper into the ball reduces the cycle time and increases output.
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来源期刊
Journal of Energy Systems
Journal of Energy Systems Environmental Science-Management, Monitoring, Policy and Law
CiteScore
1.60
自引率
0.00%
发文量
29
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