Impacts of thermally stratified medium on transient convective heat transfer between co‐axial horizontal fixed pipes: Applications of the thermal stratification

Hossam A. Nabwey, Bakhtawar Bibi, Muhammad Ashraf, Ahmed M. Rashad, Miad Abu Hawsah
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Abstract

Thermal stratification improves coaxial pipe systems’ efficiency and stability. Thermal stratification enables accurate temperature maintenance, reduces thermal stress, optimizes heat transmission performance, and minimizes usage of energy to guarantee the system's long‐term performance. The main aim of the current study is to investigate the impacts of thermal stratification on buoyancy force flow and thermal transmission between coaxial fixed pipes. In the present research, the applications of thermally stratified medium on transient convective heat transfer between two coaxial fixed pipes are studied. A two‐dimensional mathematical formulation in terms of mutually nonlinear partial differential equations is used to analyze the unsteady flow and temperature field between the co‐axial pipes, when the internal pipe is uniformly heated and the outer wall of the external pipe is placed at infinity from the surface of the inner fixed pipe. Flow is assumed along the axial direction of the internal pipe and stationary boundary condition is assumed at the surface of the inner pipe. The coupled equations of the simulated model are solved numerically by applying the Implicit Finite Difference Technique. The computed outcomes in the form of geometrical interpretation are highlighted by using the technically advanced software TECHPLOT‐360. Comprehensive detail of the obtained results for the non‐dimensional parameters included in the flow formulation is predicted for steady state velocity, temperature distribution, time‐dependent surface shearness and time‐dependent energy shearness in results and discussion section of the manuscript. The emphasis is placed on the thermal stratification parameter in the above mentioned chief quantities. From the obtained results, it is predicted that the fluid flow pattern and thermal distribution are both reduced for rising values of the thermal stratification parameter S = 0.001, 0.03, 0.05, and 0.07. Minimum flow and thermal profile are observed at S = 0.07. Further, the amplitude of the time‐dependent surface shearness is uniformly distributed throughout the medium and the amplitude of the time‐dependent energy shearness is reduced effectively for S = 1.0, 5.0, and 10.0.
热分层介质对同轴水平固定管道间瞬态对流传热的影响:热分层的应用
热分层提高了同轴管道系统的效率和稳定性。热分层可实现精确的温度维持、减少热应力、优化热传递性能并最大限度地减少能源消耗,从而保证系统的长期性能。本研究的主要目的是探讨热分层对同轴固定管道间浮力流和热传导的影响。本研究探讨了热分层介质对两根同轴固定管道间瞬态对流传热的影响。当内部管道被均匀加热,外部管道的外壁距离内部固定管道的表面无穷远时,使用互非线性偏微分方程的二维数学公式来分析同轴管道之间的非稳态流动和温度场。假定流体沿内管轴向流动,内管表面假定有静止边界条件。模拟模型的耦合方程采用隐式有限差分技术进行数值求解。利用技术先进的软件 TECHPLOT-360 对计算结果进行了几何解释。手稿的结果和讨论部分全面详细地预测了流动公式中包含的非尺寸参数的稳态速度、温度分布、随时间变化的表面剪切力和随时间变化的能量剪切力。重点是上述主要量中的热分层参数。根据所得结果预测,当热分层参数 S = 0.001、0.03、0.05 和 0.07 的值上升时,流体流动模式和热分布都会减小。当 S = 0.07 时,流量和热分布均为最小值。此外,当 S = 1.0、5.0 和 10.0 时,随时间变化的表面剪切振幅在整个介质中均匀分布,随时间变化的能量剪切振幅有效减小。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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