Enhancing Efficiency and Adaptability of Double Pipe Heat Exchangers: Design and Implementation Perspectives

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Year : 2025 | Volume :12 | Issue : 01 | Page : 1-10
By
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Chetan Kumar Korde,

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Pankaj Badgaiyan,

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Tanmay Awasthi,

  1. M. Tech Scholar, Department of Mechanical Engineering, Sagar institute of research and technology, Bhopal, Madhya Pradesh, India
  2. Assistant professor, Department of Mechanical Engineering, Sagar institute of research and technology, Bhopal, Madhya Pradesh, India
  3. Assistant professor, Department of Mechanical Engineering, Sagar institute of research and technology, Bhopal, Madhya Pradesh, India

Abstract document.addEventListener(‘DOMContentLoaded’,function(){frmFrontForm.scrollToID(‘frm_container_abs_130393’);});Edit Abstract & Keyword

The present study focuses on exploring the intricacies of twin pipe heat exchangers, highlighting their versatility and efficiency in various industrial applications. Twin pipe heat exchangers consist of concentric pipes through which fluids flow in opposite directions, enabling effective heat transfer across significant temperature gradients. This design is particularly advantageous in scenarios involving low flow rates or highly viscous fluids, as well as moderate heat loads. One of the key strengths of twin pipe heat exchangers lies in their adaptability to diverse operational requirements, such as high pressures and different fluid phases. This flexibility allows them to cater to a wide range of industrial processes where heat exchange is critical. Recent advancements, such as the utilization of nanofluids, have further enhanced heat transfer rates in these exchangers. However, challenges such as pressure drops, and sedimentation remain pertinent issues that need to be addressed. Despite these challenges, twin pipe heat exchangers offer several practical benefits. They are noted for their straightforward assembly, ease of maintenance, and potential for reconfiguration as operational needs evolve. This simplicity in design and operation is particularly advantageous in industrial settings where reliability and adaptability are paramount. The specific objective of this study is to refine the design of a compact twin pipe heat exchanger suitable for applications such as cooling car engine bays. By improving upon existing designs and addressing inherent challenges, the study aims to optimize heat transfer efficiency while ensuring practical usability in real-world industrial environments. This research underscores the ongoing evolution of heat exchanger technology towards achieving greater efficiency, reliability, and applicability across diverse industrial sectors.

Keywords: Double pipe heat exchanger, Countercurrent flow, Heat transfer, Nanofluids, Industrial applications, Versatility, Twin pipe heat exchangers

[This article belongs to Recent Trends in Fluid Mechanics (rtfm)]

How to cite this article:
Chetan Kumar Korde, Pankaj Badgaiyan, Tanmay Awasthi. Enhancing Efficiency and Adaptability of Double Pipe Heat Exchangers: Design and Implementation Perspectives. Recent Trends in Fluid Mechanics. 2024; 12(01):1-10.
How to cite this URL:
Chetan Kumar Korde, Pankaj Badgaiyan, Tanmay Awasthi. Enhancing Efficiency and Adaptability of Double Pipe Heat Exchangers: Design and Implementation Perspectives. Recent Trends in Fluid Mechanics. 2024; 12(01):1-10. Available from: https://journals.stmjournals.com/rtfm/article=2024/view=0

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Regular Issue Subscription Review Article
Volume 12
Issue 01
Received 02/12/2024
Accepted 10/12/2024
Published 20/12/2024