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强制循环太阳能热水系统的数值模拟

Numerical simulation of a forced circulation solar water heating system.

作者信息

Remlaoui Ahmed, Nehari Driss, Kada Benhanifia, Nasir Nor Ain Azeany Mohd, Abd-Elmonem Assmaa, Alhubieshi Neissrien, ElSeabee Fayza Abdel Aziz, Hussain Syed M

机构信息

Applied Hydrology and Environment Laboratory , University of Ain Témouchent -BELHADJ Bouchaib , 46000, Ain-Témouchent, Algeria.

Faculty of Science and Technology Laboratory of Energy in Arid Region (ENERGARID), University of Tahri Mohamed Bechar, 08000, Bechar, Algeria.

出版信息

Sci Rep. 2024 Nov 22;14(1):28999. doi: 10.1038/s41598-024-80576-y.

DOI:10.1038/s41598-024-80576-y
PMID:39578513
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11584696/
Abstract

This study presents a sophisticated numerical simulation model for a forced circulation solar water heating system (FC-SWHs), specifically designed for the unique climatic conditions of Algeria. The model aims to cater to the hot water needs of single-family houses, with a daily consumption of 246 L. Utilizing a dynamic approach based on TRNSYS modeling, the system's performance in Ain Temouchent's climate was scrutinized. The model's validation was conducted against literature results for the collector outlet temperature. Key findings include a maximum monthly average outlet temperature of 38 °C in September and a peak cumulative useful energy gain of 250 W in August. The auxiliary heating system displayed seasonal energy consumption variations, with the highest rate of 500 kJ/hr in May to maintain the water temperature at 60 °C. The energy input at the storage tank's inlet and the consistent high-level energy output at the hot water outlet were analyzed, with the former peaking at 500 W in May. The system ensured an average water tank temperature (hot, middle and bottom) and water temperature after the mixer, suitable for consumption, ranging between 55 °C and 57 °C. For applications requiring cooler water, the mixer's exit temperature was maintained at 47 °C. The study's key findings reveal that the TRNSYS model predicts equal inlet and outlet flow rates for the tank, a condition that is particularly significant when the system operates with high-temperature water, starting at 55 °C. The flow rate at this temperature is lower, at 7 kg/hr, while the water mass flow rate exiting the mixer is higher, at 10.5 kg/hr. In terms of thermal performance, the system's solar fraction (SF) and thermal efficiency were evaluated. The results indicate that the lowest average SF of 54% occurs in July, while the highest average SF of over 84% is observed in September. Throughout the other months, the SF consistently stays above 60%. The thermal efficiency of the system varies, ranging from 49 to 73% in January, 43-62% in April, 48-66% in July, and 53-69% in October. The novelty of this research lies in its climate-specific design, which addresses Algeria's solar heating needs and challenges. Major contributions include a thorough analysis of energy efficiency metrics, seasonal auxiliary heating demands, and optimal system operation for residential applications, supporting Algeria's goal of sustainable energy independence.

摘要

本研究针对强制循环太阳能热水系统(FC-SWHs)提出了一种先进的数值模拟模型,该模型是专门为阿尔及利亚独特的气候条件设计的。该模型旨在满足单户住宅的热水需求,日用水量为246升。利用基于TRNSYS建模的动态方法,对该系统在艾因泰穆申特气候条件下的性能进行了详细研究。针对集热器出口温度,对照文献结果对该模型进行了验证。主要研究结果包括:9月的最高月平均出口温度为38°C,8月的累计有用能量增益峰值为250瓦。辅助加热系统呈现出季节性能耗变化,5月维持水温在60°C时的最高能耗率为500千焦/小时。分析了储水箱进水口的能量输入以及热水出水口持续的高能量输出,前者在5月达到500瓦的峰值。该系统确保了水箱(顶部、中部和底部)的平均水温以及混合器后的水温适合使用,水温范围在55°C至57°C之间。对于需要更冷水温的应用,混合器出口温度保持在47°C。该研究的主要发现表明,TRNSYS模型预测水箱的进水和出水流量相等,当系统在55°C及以上的高温水条件下运行时,这一条件尤为重要。此温度下的流速较低,为7千克/小时,而混合器出口的水质量流速较高,为10.5千克/小时。在热性能方面,对该系统的太阳能份额(SF)和热效率进行了评估。结果表明,7月的最低平均太阳能份额为54%,而9月观察到的最高平均太阳能份额超过84%。在其他月份,太阳能份额始终保持在60%以上。该系统的热效率有所不同,1月为49%至73%,4月为43% - 62%,7月为48% - 66%,10月为53% - 69%。本研究的新颖之处在于其针对特定气候的设计,满足了阿尔及利亚的太阳能供热需求并应对了相关挑战。主要贡献包括对能源效率指标、季节性辅助供热需求以及住宅应用中系统最佳运行的全面分析,支持了阿尔及利亚实现可持续能源独立的目标。

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