传热
流量(数学)
流体力学
计算流体力学
机械
计算机科学
物理
热力学
机械工程
工程类
作者
Anant Sidhappa Kurhade,Gulab Dattrao Siraskar,Parimal Sharad Bhambare,G. Murali,Sushil Deshpande,Pushparaj Warke,Shital Yashwant Waware
出处
期刊:International Journal of Modern Physics C
[World Scientific]
日期:2025-01-10
卷期号:36 (12)
被引量:15
标识
DOI:10.1142/s0129183125500433
摘要
Heat exchangers play a vital role in industrial applications by facilitating efficient thermal energy exchange between two distinct fluid streams. These fluids are separated by a solid barrier, which prevents mixing, conserves energy and reduces operational costs. To enhance the efficiency of heat exchangers, wire inserts are often incorporated into the fluid paths. These inserts increase turbulence, improve fluid mixing, and boost heat transfer rates, making the system more effective. In this study, a counter-flow helical double-pipe heat exchanger was analyzed using Computational Fluid Dynamics (CFD) through the simulation software Ansys CFX. The simulations were conducted for cold fluid temperatures ranging from 12°C to 22°C and hot fluid temperatures between 32°C and 52°C, with Reynolds numbers varying from [Formula: see text] to [Formula: see text] to capture a broad spectrum of flow behaviors. The CFD model demonstrated excellent agreement with experimental results, achieving high correlation coefficients of 0.96 for the hot fluid and 0.95 for the cold fluid. This high level of accuracy validates the robustness of the model in predicting real-world heat transfer dynamics. The inclusion of wire inserts within the cold fluid flow path played a critical role in enhancing heat exchanger performance. By inducing turbulence, the wire inserts disrupted the thermal boundary layer, allowing for greater heat transfer between the hot and cold streams. This resulted in a substantial improvement in heat transfer rates, reaching a 25% increase under optimized conditions. This also led to an improved temperature difference between the fluid at the inlet and outlet, optimizing the thermal performance of the exchanger. Alternative materials such as aluminum or titanium could also be considered for wire inserts, potentially improving thermal efficiency at varying costs.
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