混合纳米流体与带固定环的扭带插片换热器换热性能研究。

IF 3.8 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-05-27 DOI:10.1038/s41598-025-02135-3

Younis Hamoudi Assaf, Abdulrazzak Akroot, Khaled Alnamasi, Mohamed A Ismail

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引用次数: 0

摘要

本研究使用由Al₂O₃-CuO/水组成的混合纳米流体，研究了装有特殊固定环嵌件和扭曲带元件的热交换器管的热工性能。在湍流条件下进行了模拟，雷诺数从6000到14000。系统评估了不同扭曲带扭转比（TR = 5、10和15）和混合纳米流体体积浓度（ϕ = 0.3%、0.6%和0.9%）的影响。在ANSYS Fluent中验证了CFD模型与基准数据的一致性。结果表明，在Re = 14000时，在普通管中插入一根TR = 5的扭带，与纯水相比，努塞尔数（Nu）提高36.28%，对流换热系数(h)提高36.3%。胶带促进湍流和破坏热边界层，加强对流传热。然而，这些增益会带来8.0%的压降损失（ΔP）。此外，该研究强调了纳米流体浓度在优化换热器性能中的关键作用。当体积分数为0.9%的Al₂O₃-CuO/水纳米流体加入扭转带（TR = 5）构型时，Nusselt数增加了3.2%，对流换热系数增加了18.2%。纳米流体的提升带来了6.1%的压降损失（ΔP从284.8 Pa增加到302.2 Pa），但却将热性能因子（TPF）从1.38提高到3.29。这些发现提供了一个全面的理解，如何协同被动传热方法和纳米流体可以战略性地利用，以提高工业热交换器的效率。

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Investigation of heat transfer performance in heat exchangers using hybrid nanofluids and twisted tape inserts with fixed special rings.

This study examines the thermo-hydraulic performance of a heat exchanger tube equipped with special fixed ring inserts and twisted tape elements, using a hybrid nanofluid composed of Al₂O₃-CuO/water. Simulations are carried out under turbulent flow conditions, covering Reynolds numbers from 6000 to 14,000. The impact of varying twisted tape torsion ratios (TR = 5, 10, and 15) and hybrid nanofluid volume concentrations (ϕ = 0.3%, 0.6%, and 0.9%) is systematically evaluated. A validated CFD model in ANSYS Fluent demonstrates strong agreement with benchmark data. The results show that, at Re = 14,000, inserting a twisted tape (TR = 5) into a plain tube boosts the Nusselt number (Nu) by 36.28% and the convective heat-transfer coefficient (h) by 36.3% compared to pure water. The tape promotes turbulence and disrupts the thermal boundary layer, enhancing convective heat transfer. However, these gains incur an 8.0% pressure-drop penalty (ΔP). Furthermore, the study highlights the critical role of nanofluid concentration in optimizing heat-exchanger performance. At a 0.9% volume fraction of Al₂O₃-CuO/water nanofluid added to the twisted-tape (TR = 5) configuration, the Nusselt number climbs an additional 3.2%, while the convective heat-transfer coefficient rises by 18.2%. This nanofluid boost comes with a modest 6.1% pressure-drop penalty (ΔP increases from 284.8 to 302.2 Pa) yet drives the thermal performance factor (TPF) from 1.38 to 3.29. These findings provide a comprehensive understanding of how synergistic passive heat transfer methods and nanofluids can be strategically utilized to enhance the efficiency of industrial heat exchangers.

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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