A. Youssfi, M. Asbik, H. Agalit, K. E. Alami, Reda Boualou
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引用次数: 0
Abstract
Latent Heat Storage (LHS) is a promising solution to overcome the intermittent nature of solar energy for concentrated solar power (CSP) plants. In fact, it matches at a relatively low cost between the electricity produced by these plants and the periods of demand. Moreover, LHS systems have higher energy density compared to Sensible Heat Storage (SHS) ones. However, their inorganic materials have low thermal conductivity, which reduces the dynamics of the storage system with respect to the limitation of operating conditions of a CSP plant. One of the effective ways to resolve this problem is the use of extending surfaces such as fins. The present work evaluates the viability of this LHS applied to the case study of a heat exchanger with and without fins. A Computational fluid dynamics (CFO) model of the studied system was built in the COMSOL-Multyphysics environment. Furthermore, it was succefully validated against the available experimental results. Overall, the obtained simulation results show a considerable enhancement of the global dynamic performances of the LHS: the charging period and the phase change duration were decreased by 30.5% and 44.64% respectively.Latent Heat Storage (LHS) is a promising solution to overcome the intermittent nature of solar energy for concentrated solar power (CSP) plants. In fact, it matches at a relatively low cost between the electricity produced by these plants and the periods of demand. Moreover, LHS systems have higher energy density compared to Sensible Heat Storage (SHS) ones. However, their inorganic materials have low thermal conductivity, which reduces the dynamics of the storage system with respect to the limitation of operating conditions of a CSP plant. One of the effective ways to resolve this problem is the use of extending surfaces such as fins. The present work evaluates the viability of this LHS applied to the case study of a heat exchanger with and without fins. A Computational fluid dynamics (CFO) model of the studied system was built in the COMSOL-Multyphysics environment. Furthermore, it was succefully validated against the available experimental results. Overall, the obtained simulation results show a consid...
潜热储存(LHS)是一种很有前途的解决方案,以克服太阳能的间歇性集中太阳能发电(CSP)电厂。事实上,它以相对较低的成本将这些发电厂生产的电力与需求时期相匹配。此外,LHS系统比显热储能系统具有更高的能量密度。然而,它们的无机材料具有低导热性,这降低了存储系统的动力学,相对于CSP工厂的操作条件的限制。解决这一问题的有效方法之一是使用延伸表面,如鳍。目前的工作评估了这种LHS应用于有翅和无翅热交换器的案例研究的可行性。在comsol - multi - physics环境下建立了系统的计算流体动力学模型。并与已有的实验结果进行了对比验证。总体而言,模拟结果表明LHS的整体动态性能得到了显著提高:充电周期和相变持续时间分别缩短了30.5%和44.64%。潜热储存(LHS)是一种很有前途的解决方案,以克服太阳能的间歇性集中太阳能发电(CSP)电厂。事实上,它以相对较低的成本将这些发电厂生产的电力与需求时期相匹配。此外,LHS系统比显热储能系统具有更高的能量密度。然而,它们的无机材料具有低导热性,这降低了存储系统的动力学,相对于CSP工厂的操作条件的限制。解决这一问题的有效方法之一是使用延伸表面,如鳍。目前的工作评估了这种LHS应用于有翅和无翅热交换器的案例研究的可行性。在comsol - multi - physics环境下建立了系统的计算流体动力学模型。并与已有的实验结果进行了对比验证。总体而言,得到的仿真结果显示了较好的结果。
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