Numerical investigation on enhancement of heat transfer using rod inserts in single pipe heat exchanger

Authors

  • S. H. Raheemah Department of Mechanical Technical /Production, Al kut Technical Institution, Middle Technical University, Baghdad, Iraq
  • M. A. Ashham Department of Mechanical Technical /Production, Al kut Technical Institution, Middle Technical University, Baghdad, Iraq
  • K. Salman Department of Mechanical Technical /Production, Al kut Technical Institution, Middle Technical University, Baghdad, Iraq

DOI:

https://doi.org/10.15282/jmes.13.4.2019.24.0480

Keywords:

heat exchanger, simulation, FEM, CFD, vertical inserts

Abstract

The current study focused on statistically investigating nanofluids’ turbulent flow and rate of heat transfer in double pipe heat exchanger with rod inserts. Through the use of numerical simulation, the effects which the various kinds of nanofluids have on the enhancement of heat transfer using finite volume method (FVM) are studied. An application of homogeneous heat flux is made to the tube wall. More so, an examination of the effect of three varying slant angles of rod insert (α = 25°, 30°, 45°) was carried out at varying Reynolds number ranging from 7500 - 20000. The statistical results revealed that the coefficient of transferring heat in the tube containing rod inserts is higher than that of the smooth tube. In addition, results also showed that when rod insert are used in double pipe heat exchanger to augment the Nusselt number increases the slant angle. The max value of Nusselt number was demonstrated at the angle 45° of rod insert. Through the use of the rod inserts at (α=45°) and (S = 30mm), the coefficient of maximal skin friction was determined because of the resistance of larger flow. The maximal value of the Performance Evaluation Criteria (PEC) was mentioned in the case of min slant angle of (α = 25°) and the pitch distance of S = 30 mm.

References

Zheng N, Liu P, Shan F, Liu J, Liu Z, Liu W. Numerical studies on thermo-hydraulic characteristics of laminar flow in a heat exchanger tube fitted with vortex rods. International Journal of Thermal Sciences. 2016; 100(1): 448-456.

Fan A, Deng J, Nakayama A, Liu W. Parametric study on turbulent heat transfer and flow characteristics in a circular tube fitted with louvered strip inserts. International Journal of Heat and Mass Transfer. 2012; 55(19-20): 5205-5213

Eiamsa-ard S, Pethkool S, Thianpong C, Promvonge P. Turbulent flow heat transfer and pressure loss in a double pipe heat exchanger with louvered strip inserts. International Communications in Heat and Mass Transfer. 2008; 35(2): 120-129.

Aggrey M, Tunde BO, Josua PM. Heat transfer and thermodynamic performance of a parabolic trough receiver with centrally placed perforated plate inserts. Applied Energy. 2014; 136(2): 989–1003.

Jian G, Yuexiang Y, Wei L, Fangming J, Aiwu F. Effects of upwind area of tube inserts on heat transfer and flow resistance characteristics of turbulent flow. Experimental Thermal and Fluid Science. 2013;48(1): 147–155.

Ahmad A, Masoud D. An experimental comparison of convective heat transfer and friction factor of Al2O3 nanofluids in a tube with and without butterfly tube inserts. Journal of the Taiwan Institute of Chemical Engineers. 2015; 52(3): 31–39.

Mohammed H, Husam H, Wahid M. Heat transfer enhancement of nanofluids in a double pipe heat exchanger with louvered strip inserts. International Communications in Heat and Mass Transfer. 2013; 40(4): 36–46.

Shabanian R, Rahimi M, Shahhosseini M, Alsairafi A. CFD and experimental studies on heat transfer enhancement in an air cooler equipped with different tube inserts. International Communications in Heat and Mass Transfer. 2011; 38(3): 383-390.

Tu W, Tang Y, Zhou B, Lu L. Experimental studies on heat transfer and friction factor characteristics of turbulent flow through a circular tube with small pipe inserts. International Communications in Heat and Mass Transfer. 2014; 56(1): 1–7.

Pourramezan M, Ajam H. Modeling for thermal augmentation of turbulent flow in a circular tube fitted with twisted conical strip inserts. Applied Thermal Engineering. 2016; 105(1): 509-518.

Mashayekhi R, Khodabandeh E, Bahiraei M, Bahrami L, Toghraie D, Akbari A. Application of a novel conical strip insert to improve the efficacy of water–Ag nanofluid for utilization in thermal systems: a two-phase simulation. Energy Conversion and Management. 2017; 151(2): 573-586.

Pengxiao L, Zhichun L, Wei L, Gang C. Numerical study on heat transfer enhancement characteristics of tube inserted with centrally hollow narrow twisted tapes. International Journal of Heat and Mass Transfer. 2015; 88(1): 481–491.

Fabio K, Taye M, Gherhardt R. A new model for flow boiling heat transfer coefficient inside horizontal tubes with twisted-tape inserts. International journal of Refrigeration. 2016; 61(1): 55–68.

Erika RI , Maritza E. Cervantes-Gaxiola , Eusiel Rubio-Castro , Jos Ponce-Ortega, Marcos Gonz_alez-Llanes , Cuauht_emoc Reyes-Moreno ,Oscar M. Heat transfer analysis of a non-Newtonian fluid flowing through a circular tube with twisted tape inserts. Applied Thermal Engineering. 2015;84(3): 225-236.

Liu P, Zheng N, Shan F, Liu Z, Liu W. An experimental and numerical study on the laminar heat transfer and flow characteristics of a circular tube fitted with multiple conical strips inserts. International Journal of Heat and Mass Transfer. 2018; 117(1): 691-709.

Subhankar S, Sujoy KS. Enhancement of heat transfer of laminar flow of viscous oil through a circular tube having integral helical rib roughness and fitted with helical screw-tapes. Experimental Thermal and Fluid Science. 2013; 47(1): 81–89.

Bhuiya MMK, Ahamed JU, Chowdhury MSU, Sarkar MAR, Salam B, Saidur R, Masjuki HH, Kalam MA. Heat transfer enhancement and development of correlation for turbulent flow through a tube with triple helical tape inserts. International Communications in Heat and Mass Transfer. 2012; 39(1): 94–101

Anvari AR, Javaherdeh K, Emami-Meibodi M, Rashidi AM. Numerical and experimental investigation of heat transfer behavior in a round tube with the special conical ring inserts. Energy Conversion and Management. 2014; 88(2): 214–217.

Bodius S, Sumana B, Shuvra S, Muhammad MK . Heat transfer enhancement in a tube using rectangular-cut twisted tape Insert. Procedia Engineering. 2013; 56(1): 96–103.

Sombat T, Yingyong K, Sompol S, Pongjet P. Heat transfer enhancement in tubular heat exchanger with double V-ribbed twisted-tapes. Case Studies in Thermal Engineering. 2016; 7(2): 14–24.

Durand LB, Guimarães JC, Monteiro J, Baratieri LN. Modeling and validation of a 3D premolar for finite element analysis. Revista de Odontologia da UNESP. 2016; 45(1): 21-26.

Ghori MV, Kirar RK. Numerical analysis of tube-fin heat exchanger using fluent. International Journal on Theoretical and Applied Research in Mechanical Engineering. 2012;1(2):37-44.

Ahsan M. Prediction of gasoline yield in a fluid catalytic cracking (FCC) riser using k-epsilon turbulence and 4-lump kinetic models: A computational fluid dynamics (CFD) approach. Journal of King Saud University-Engineering Sciences. 2015;27(2):130-136.

Severo DS, Gusberti VA. modelling approach to estimate bath and metal heat transfer coefficients. In Essential Readings in Light Metals. 2016;2(1): 309-314.

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Published

2019-12-30

How to Cite

[1]
S. H. Raheemah, M. A. Ashham, and K. Salman, “Numerical investigation on enhancement of heat transfer using rod inserts in single pipe heat exchanger”, J. Mech. Eng. Sci., vol. 13, no. 4, pp. 6112–6124, Dec. 2019.

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