Fluid Flow Analysis of Concentric Heat Exchanger with Different Nano Fluids and Mass Flow Rates

Authors

  • G Kondaiah Associate Professor, Department of Mechanical Engineering, Pace Institute of Technology and Sciences (Autonomous), Andhra Pradesh, India Author
  • G E Babu Associate Professor, Department of Mechanical Engineering, Pace Institute of Technology and Sciences (Autonomous), Andhra Pradesh, India Author
  • K Venkateswarlu Associate Professor, Department of Mechanical Engineering, Pace Institute of Technology and Sciences (Autonomous), Andhra Pradesh, India Author

Keywords:

CFD, NANO FLUID, CATIA

Abstract

 In this article, the overall performance of  water and other nano fluids mixed with base fluid water in a  twin pipe warmth exchanger is investigated. At quantity  fractions of 0.35 percentage, the nano fluids are Silicon  Oxide and silver nano fluid. The traits of nano fluids are  decided the usage of theoretical calculations, which can be  then utilised as inputs for analysis. CATIA parametric  software program is used to create a 3D model of the dual  pipe heat exchanger (plain and coil insert tube). CFD  research of a dual pipe warmth exchanger with water,  silicon oxide, and silver nano particle at diverse mass float  fees of zero.32, zero. Fifty two, 0.72,zero.Ninety two, and  1.12 kg/sec is performed. Theoretical calculations on the  twin pipe warmness exchanger had been additionally  finished. 

Downloads

Download data is not yet available.

References

Z.Said, S.M.A. Rahman, M. El Haj Assad, Abdul HaiAlami, (2019), “Heat transfer enhancement and life cycle analysis of a Shell-and-Tube Heat Exchanger using stable CuO/water nanofluid” Sustainable Energy Technologies and Assessments, Vol.31, PP.306-317.

Kevin J. Albrecht, Clifford K. Ho, (2019), “Design and operating considerations for a shell-and-plate, moving packed bed, particle-to-sCO2 heat exchanger”, Solar Energy, Vol.178, PP.331-340.

Uttam Roy, MrinmoyMajumder, (2019), “Evaluating heat transfer analysis in heat exchanger using NN with IGWO algorithm”, Vacuum, Vol.161, PP.186-193.

Xuen Chen, Chuang Sun, Xinlin Xia, Rongqiang Liu, Fuqiang Wang, “Conjugated heat analysisof a foam filled double pipe heat exchanger for high temperature application”, International Journal of Heat and Mass Transfer, 134 1003- 1013 (2019)

Sheikholeslami, M. and Ganji, D.D., 2016. Heat transfer improvement in a double pipe heat exchanger by means of perforated turbulators. Energy conversion and management, 127, pp.112-123, 2019

M.H. Bahmani, G. Sheikhzadeh, M. Zarringhalam, O.A. Akbari, A.A Alrashed, G.A.S. Shabani, and M. Goodarzi, Investigation of turbulent heat transfer and nanofluid flow in a double pipe heat exchanger. Advanced Powder Technology, 29(2), pp.273-282, 2018.

M.M. Heyhat, A. Abdi and A. Jafarzad, Performance evaluation and exergy analysis of a double pipe heat exchanger under air bubble injection. Applied Thermal Engineering, 143, pp.582-593, 2018.

Marwa A.W. Ali, Wael M. El Maghlany, Yehia A. Eldrainy, Abdelhamid Attia. ”Heat Transfer enhancement of double pipe heat exchanger using rotating of variable eccentricity inner pipe”, Alexandria Engineering Journal, 57, 3709 3725 (2018).

Shuyong Liu, Ming Jin, KefengLyu, Tao Zhou, Zhumin Zhao, (2018), “Flow and heat transfer behaviors for doublewalled straight-tube heat exchanger of HLM loop”, Annals of Nuclear Energy, Vol.120, PP.604-610.

SoheilSoleimanikutanaeia, C.X. Lina, DexinWangb, (2018), “Modeling and simulation of cross-flow transport membrane condenser heat exchangers”, International Communications in Heat and Mass Transfer, Vol.95, PP.92-97.

Han Xiaoxing, Wang Yaxiong, (2018), “Experimental investigation of the thermal performance of a novel concentric tube heat pipe heat exchanger” International Journal of Heat and Mass Transfer, Vol.127, PP.1338-1342.

N.Piroozfam, A. HosseinpourShafaghi, S.E. Razavi, (2018), “Numerical investigation of three methods for improving heat transfer in counter-flow heat exchangers”, International Journal of Thermal Sciences, Vol.133, PP.230-239.

R.Whalley, K.M. Ebrahimi, (2018), “Heat Exchanger Dynamic Analysis”, Applied Mathematical Modelling. [14] Anas El Maakoul, Azzeddine Laknizi, Said Saadeddine, Abdellatif Ben Abdellah, Mohamed Meziane, Mustapha El Metoui, “Numerical deisgn and investigation of heat transfer enhancement and performance for an annulus with continuous helical baffles in a double pipe heat exchanger”, Energy Conversion and Management, 133 76-86 (2017).

Kamlel Milani Shirvan, Soroush Mirzakhanlari, Soteris A. Kalogirous, Hakan F. Oztop, Mojtaba Mamourian,” Heat Transfer and Sensitivity Analysis in a Double Pipe Heat Exchanger Filled with Porous Medium”, International Journal of Thermal Sciences 121 124-137 (2017)

MohamadOmidi, MousaFarhadi, MohamadJafari, (2017), “A comprehensive review on double pipe heat exchangers”, Applied thermal Engineering, Vol.110, PP.1075-1090.

SuxinQian, Jianlin Yu, Gang Yan, (2017), “A review of regenerative heat exchange methods for various cooling technologies”, Renewable and Sustainable Energy Reviews, Vol.69, PP.535-550.

T.N. Verma, P. Nashine, D.V. Singh, T.S. Singh, D. Panwar, (2017), “ANN: Prediction of an experimental heat transfer analysis of concentric tube heat exchanger with corrugated inner tubes” Applied Thermal Engineering.

M. Sheikholeslami, D.D. Ganji, (2016), “Heat transfer improvement in a double pipe heat exchanger by means of perforated turbulators”, Energy Conversion and Management, Vol.127, PP.112-123.

A.Bejan, M. Alalaimi, S. Lorente, A.S. Sabau, J.W. Klett, (2016), “Counterflow heat exchanger with core and plenums at both ends” International Journal of Heat and Mass Transfer, Vol.99, PP.622-629.

Downloads

Published

2022-10-30

Issue

Vol. 9 No. 5 (2022): International Journal of Innovative Research in Engineering & Management (Oct) 2022

Section

Articles

How to Cite

Fluid Flow Analysis of Concentric Heat Exchanger with Different Nano Fluids and Mass Flow Rates . (2022). International Journal of Innovative Research in Engineering & Management, 9(5), 201–209. Retrieved from https://acspublisher.com/journals/index.php/ijirem/article/view/10752