IJBTT

Exploring the Novel Design and Control of Shell and Tube-in-Tube Heat Exchanger

Exploring the Novel Design and Control of Shell and Tube-in-Tube Heat Exchanger
	© 2024 by IJETT Journal
	Volume-72 Issue-6
	Year of Publication : 2024
	Author : Surendran Thangavelan Jeyarajah, Gnanaseelan Joselin Retna Kumar
	DOI : 10.14445/22315381/IJETT-V72I6P117

How to Cite?

Surendran Thangavelan Jeyarajah, Gnanaseelan Joselin Retna Kumar, "Exploring the Novel Design and Control of Shell and Tube-in-Tube Heat Exchanger," International Journal of Engineering Trends and Technology, vol. 72, no. 6, pp. 159-169, 2024. Crossref, https://doi.org/10.14445/22315381/IJETT-V72I6P117

Abstract
The Shell and Tube-in-Tube (S&TinT) heat exchanger is a superior solution compared to conventional counterparts, boasting an innovative design that includes three heat-transfer elements for three fluid paths. This paper initially addresses the challenges in traditional heat exchanger designs and further, considering the drawbacks, a novel design of S&TinT heat exchanger is proposed, which provides dynamic control over heat transfer performance, facilitating rapid changes to meet specific operational requirements. Multiple advantages make the S&TinT heat exchanger a promising solution for industries demanding high efficiency and adaptability in their heat transfer processes. Secondly, the Logarithmic Mean Temperature Difference (LMTD) algorithm was chosen to calculate the necessary parameters, which modified the standard LMTD algorithm to accommodate heat transfer dynamics between the three fluids. The modified LMTD algorithm ensures the accuracy of the design process and contributes to a deeper understanding of the complex heat transfer mechanisms in multi-fluid systems. Finally, Controlling the parameters of the designed S&TinT heat exchanger is performed by a Model Predictive Controller (MPC) as it can handle multi-input, multi-output systems. Along with this, a comparative analysis with a conventional Proportional-Integral-Derivative (PID) controller is studied and it reveals considerable insights. The error analysis further confirms the superior performance of the MPC controller, establishing it as an effective and effective control technique for advanced heat transfer systems such as the S&TinT heat exchanger.

Keywords
Heat exchanger, CAD, S&TinT, LMTD, MPC.

References
[1] Aparna Kaleru, Sriram Venkatesh, and Narasimha Kumar, “Numerical and Experimental Study of a Shell and Tube Heat Exchanger for Different Baffles,” Heat Transfer, vol. 52, no. 3, pp. 2186-2206, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[2] Ravi Gugulothu, and Narsimhulu Sanke, “Experimental Investigation of Heat Transfer Characteristics for a Shell and Tube Heat Exchanger,” Energy Harvesting and Systems, vol. 11, no. 1, pp. 1-11, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[3] S.A. Marzouk et al., “A Comprehensive Review of Methods of Heat Transfer Enhancement in Shell and Tube Heat Exchangers,” Journal of Thermal Analysis and Calorimetry, vol. 148, pp. 7539-7578, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[4] N.C. Damasceno, and O.G. Filho, “PI Controller Optimization for a Heat Exchanger through Metaheuristic Bat Algorithm, Particle Swarm Optimization, Flower Pollination Algorithm and Cuckoo Search Algorithm,” IEEE Latin America Transactions, vol. 15, no. 9, pp. 18011807, 2017.
[CrossRef] [Google Scholar] [Publisher Link]
[5] Md. Farhad Ismail, “Effects of Perforations on the Thermal and Fluid Dynamic Performance of a Heat Exchanger,” IEEE Transactions on Components, Packaging and Manufacturing Technology, vol. 3, no. 7, pp. 1178-1185, 2013.
[CrossRef] [Google Scholar] [Publisher Link]
[6] Tianyi Gao et al., “Cross Flow Heat Exchanger Modeling of Transient Temperature Input Conditions,” IEEE Transactions on Components, Packaging and Manufacturing Technology, vol. 4, no. 11, pp. 1796-1807, 2014.
[CrossRef] [Google Scholar] [Publisher Link]
[7] J.A. Vazquez et al., “Robust Control System Design using Eigenstructure Assignment with Uncertain Parameters for a Double-Pipe Heat Exchanger,” IEEE Latin America Transactions, vol. 16, no. 3, pp. 851-858, 2018.
[CrossRef] [Google Scholar] [Publisher Link]
[8] Mohammed A. Almeshaal, and Karim Choubani, “Using the Log Mean Temperature Difference (LMTD) and ε-NTU Methods to Analyze Heat and Mass Transfer in Direct Contact Membrane Distillation,” Membranes, vol. 13, no. 6, pp. 1-15, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[9] Jie Lian et al., “Thermal and Mechanical Performance of a Hybrid Printed Circuit Heat Exchanger Used for Supercritical Carbon Dioxide Brayton Cycle,” Energy Conversion and Management, vol. 245, 2021.
[CrossRef] [Google Scholar] [Publisher Link]
[10] D. Vinoth Kumar, S. Vijayaraghavan, and Praveen Thakur, “Analytical and Experimental Investigation on Heat Transfer and Flow Parameters of Multichannel Louvered Fin Cross Flow Heat Exchanger Using Iterative LMTD and ∊-NTU Method,” Materials Today: Proceedings, vol. 52, pp. 1240-1248, 2022.
[CrossRef] [Google Scholar] [Publisher Link]
[11] Samuel J.M. Cartaxo, and Fabiano A.N. Fernandes, “Counterflow Logarithmic Mean Temperature Difference is Actually the Upper Bound: A Demonstration,” Applied Thermal Engineering, vol. 31, no. 6-7, pp. 1172-1175, 2011.
[CrossRef] [Google Scholar] [Publisher Link]
[12] Miten Mistry, and Ruth Misener, “Optimising Heat Exchanger Network Synthesis using Convexity Properties of the Logarithmic Mean Temperature Difference,” Computers & Chemical Engineering, vol. 94, pp. 1-17, 2016.
[CrossRef] [Google Scholar] [Publisher Link]
[13] X. Cui et al., “Fundamental Formulation of a Modified LMTD Method to Study Indirect Evaporative Heat Exchangers,” Energy Conversion and Management, vol. 88, pp. 372-381, 2014.
[CrossRef] [Google Scholar] [Publisher Link]
[14] Ankush D. Tharkar, and Shripad P. Mahulikar, “The Mean Temperature Difference Method for Micro Heat Exchanger Analysis Considering Property Variation,” Heat Transfer Engineering, vol. 40, no. 8, pp. 605-615, 2019.
[CrossRef] [Google Scholar] [Publisher Link]
[15] Ahmad Fakheri, “Determining Log Mean Temperature Difference Correction Factor and Number of Shells of Shell and Tube Heat Exchangers,” Journal of Enhanced Heat Transfer, vol. 24, no. 1-6, pp. 387-402, 2017.
[CrossRef] [Google Scholar] [Publisher Link]
[16] Ruomei Qi et al., “Design of the PID Temperature Controller for an Alkaline Electrolysis System with Time Delays,” International Journal of Hydrogen Energy, vol. 48, no. 50, pp. 19008-19021, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[17] Vatia Fahrunisa Rahmadini, Alfian Ma'arif, and Nur Syuhadah Abu, “Design of Water Heater Temperature Control System using PID Control,” Control Systems and Optimization Letters, vol. 1, no. 2, pp. 111-117, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[18] Haoran Liu et al., “Temperature Control Algorithm for Polymerase Chain Reaction (PCR) Instrumentation Based upon Improved Hybrid Fuzzy Proportional Integral Derivative (PID) Control,” Instrumentation Science & Technology, vol. 51, no. 2, pp. 109-131, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[19] Prabhu Kaliappan et al., “Temperature Control Design with Differential Evolution Based Improved Adaptive-Fuzzy-PID Techniques,” Intelligent Automation & Soft Computing, vol. 36, no. 1, pp. 781-801, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[20] Yuan Gao, Shohei Miyata, and Yasunori Akashi, “Energy Saving and Indoor Temperature Control for an Office Building Using TubeBased Robust Model Predictive Control,” Applied Energy, vol. 341, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[21] Farhat Mahmood et al., “Data-Driven Robust Model Predictive Control for Greenhouse Temperature Control and Energy Utilisation Assessment,” Applied Energy, vol. 343, pp. 1-17, 2023.
[CrossRef] [Google Scholar] [Publisher Link]
[22] Xi Chen et al., “Temperature and Voltage Dynamic Control of PEMFC Stack Using MPC Method,” Energy Reports, vol. 8, pp. 798-808, 2022.
[CrossRef] [Google Scholar] [Publisher Link]
[23] Xiaoming Li, and Xinghuo Yu, “Robust Regulation for Superheated Steam Temperature Control Based on Data-Driven Feedback Compensation,” Applied Energy, vol. 325, 2022.
[CrossRef] [Google Scholar] [Publisher Link]
[24] Dennis Kibalama et al., “Model Predictive Control for Automotive Climate Control Systems via Value Function Approximation,” IEEE Control Systems Letters, vol. 6, pp. 1820-1825, 2021.
[CrossRef] [Google Scholar] [Publisher Link]