Material Selection and Fluid Flow Analysis of Parallel Flow Heat Exchanger

EngRN: Chemical Engineering Pub Date : 2016-12-01 DOI:10.9734/acri/2016/30239

C. E. Okafor, Alex Dubem Tagbo, O. Obiafudo, E. Nwadike

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引用次数: 0

Abstract

Aims: To select appropriate material and undertake fluid flow analysis of parallel flow heat exchanger. Methodology: Dynamic simulation study was performed to evaluate conditions of heat transfer of water through heat exchanger using ASPEN HYSYS. Cambridge Education Selector (CES) Granta software was used to select the suitable candidate materials for the heat exchanger. The properties of the selected materials and fluid characteristics were implemented in Computational Fluid Dynamics (CFD) to solve and analyze the fluid flow. Results: For inner pipe, low alloy steel having maximum thermal conductivity of 55(W/m°C) and specific heat capacity of 530 (J/kg°C) respectively was selected and used. For the outer pipe, cast iron, gray having thermal conductivity of 72 (W/m°C) and specific heat capacity of 495(J/kg°C) passed the selection criteria and was used.The total heat transfer surface area and hydraulic diameter was determined as 0.1341634m2 and 0.481m respectively while the velocity of flow (V) for hot and cold fluid was established as 0.00014518 m/sec and 0.000196817 m/sec respectively. Conclusion: The material-process decision on a parallel flow heat exchanger design was reduced to trade-off between performance and cost. The data obtained from the experimental record are well matched with computational fluid dynamics simulated values at different mass flow rate.

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平行流换热器的材料选择与流体流动分析

目的:选择合适的材料，对并联换热器进行流体流动分析。方法:采用ASPEN HYSYS软件对水通过换热器的换热条件进行动态模拟研究。使用剑桥教育选择器(CES) Granta软件选择合适的候选材料作为换热器。利用计算流体动力学(CFD)对所选材料的性质和流体特性进行求解和分析。结果:内管选用最大导热系数为55(W/m°C)、比热容为530 (J/kg°C)的低合金钢。外管选用导热系数为72 (W/m°C)、比热容为495(J/kg°C)的灰铸铁，符合选用标准。总换热表面积和水力直径分别为0.1341634m2和0.481m，热流体和冷流体的流速V分别为0.00014518 m/sec和0.000196817 m/sec。结论:平行流换热器设计的材料-工艺决策简化为性能与成本之间的权衡。实验数据与不同质量流量下的计算流体力学模拟值吻合较好。

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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EngRN: Chemical Engineering

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