Comparison of heat transfer performances of helix baffled heat exchangers with different baffle configurations

doi:10.1016/j.cjche.2014.10.014

Chin.J.Chem.Eng. ›› 2015, Vol. 23 ›› Issue (1): 255-261.DOI: 10.1016/j.cjche.2014.10.014

• ENERGY, RESOURCES AND ENVIRONMENTAL TECHNOLOGY • Previous Articles Next Articles

Comparison of heat transfer performances of helix baffled heat exchangers with different baffle configurations

Cong Dong^1,2, Yaping Chen¹, Jiafeng Wu¹

1 School of Energy and Environment, Southeast University, Nanjing 210096, China;
2 School of Light Industry, Zhejiang University of Science and Technology, Hangzhou 310023, China

Received:2013-05-20 Revised:2014-03-31 Online:2015-01-24 Published:2015-01-28
Contact: Yaping Chen
Supported by:
Supported by the National Natural Science Foundation of China (50976022, 51276035) and the Provincial Science and Technology Innovation and Transformation of Achievements of Special Fund Project of Jiangsu Province (BY2011155).

Comparison of heat transfer performances of helix baffled heat exchangers with different baffle configurations

Cong Dong^1,2, Yaping Chen¹, Jiafeng Wu¹

1 School of Energy and Environment, Southeast University, Nanjing 210096, China;
2 School of Light Industry, Zhejiang University of Science and Technology, Hangzhou 310023, China

通讯作者: Yaping Chen
基金资助:
Supported by the National Natural Science Foundation of China (50976022, 51276035) and the Provincial Science and Technology Innovation and Transformation of Achievements of Special Fund Project of Jiangsu Province (BY2011155).

Abstract

Abstract: Numerical simulations were performed on flow and heat transfer performances of heat exchangers having six helical baffles of different baffle shapes and assembly configurations, i.e., two trisection baffle schemes, two quadrant baffle schemes, and two continuous helical baffle schemes. The temperature contour or the pressure contour and velocity contour plots with superimposed velocity vectors on meridian, transverse and unfolded concentric hexagonal slices are presented to obtain a full angular view. For the six helix baffled heat exchangers, the different patterns of the single vortex secondary flow and the shortcut leakage flow were depicted as well as the heat transfer properties were compared. The results show that the optimum scheme among the six configurations is a circumferential overlap trisection helix baffled heat exchanger with a baffle incline angle of 20° (20°TCO) scheme with an anti-shortcut baffle structure, which exhibits the second highest pressure drop Δp_o, the highest overall heat transfer coefficient K, shell-side heat transfer coefficient h_o and shell-side average comprehensive index h_o/Δp_o.

Key words: Helix baffled heat exchanger, Trisection baffle, Quadrant baffle, Continuous baffle, Circumferential overlap baffle, Secondary flow, Heat transfer, Numerical simulation

摘要： Numerical simulations were performed on flow and heat transfer performances of heat exchangers having six helical baffles of different baffle shapes and assembly configurations, i.e., two trisection baffle schemes, two quadrant baffle schemes, and two continuous helical baffle schemes. The temperature contour or the pressure contour and velocity contour plots with superimposed velocity vectors on meridian, transverse and unfolded concentric hexagonal slices are presented to obtain a full angular view. For the six helix baffled heat exchangers, the different patterns of the single vortex secondary flow and the shortcut leakage flow were depicted as well as the heat transfer properties were compared. The results show that the optimum scheme among the six configurations is a circumferential overlap trisection helix baffled heat exchanger with a baffle incline angle of 20° (20°TCO) scheme with an anti-shortcut baffle structure, which exhibits the second highest pressure drop Δp_o, the highest overall heat transfer coefficient K, shell-side heat transfer coefficient h_o and shell-side average comprehensive index h_o/Δp_o.

关键词: Helix baffled heat exchanger, Trisection baffle, Quadrant baffle, Continuous baffle, Circumferential overlap baffle, Secondary flow, Heat transfer, Numerical simulation

Cong Dong, Yaping Chen, Jiafeng Wu . Comparison of heat transfer performances of helix baffled heat exchangers with different baffle configurations[J]. Chin.J.Chem.Eng., 2015, 23(1): 255-261.

Cong Dong, Yaping Chen, Jiafeng Wu . Comparison of heat transfer performances of helix baffled heat exchangers with different baffle configurations[J]. Chinese Journal of Chemical Engineering, 2015, 23(1): 255-261.

References

[1] J. Lutcha, J. Nemcansky, Performance improvement of tubular heat exchangers by helical baffles, Chem. Eng. Res. Des. 68 (3) (1990) 263-270.

[2] P. Stehlik, J. Nemcansky, D. Kral, L.W. Swanson, Comparison of correction factors for shell-and-tube heat exchangers with segmental or helical baffles, Heat Transfer Eng. 15 (1) (1994) 55-65.

[3] M.J. Andrews, B.I. Master, Three-dimensional modeling of a helixchanger heat exchanger using CFD, Heat Transfer Eng. 26 (6) (2005) 22-31.

[4] J.F. Zhang, B. Li, W.J. Huang, Y.G. Lei, Y.L. He, W.Q. Tao, Experimental performance comparison of shell-side heat transfer for shell-and-tube heat exchangers with middle-overlapped helical baffles and segmental baffles, Chem. Eng. Sci. 64 (8) (2009) 1643-1653.

[5] J.F. Zhang, Y.L. He, W.Q. Tao, 3D numerical simulation on shell-and-tube heat exchangers with middle-overlapped helical baffles and continuous baffles—Part II: Simulation results of periodic model and comparison between continuous and noncontinuous helical baffles, Int. J. Heat Mass Transfer 52 (23-24) (2009) 5381-5389.

[6] Y.P. Chen, A novel helix baffled heat exchanger suitable for tube bundle arrangement with equilateral triangles, Petrol. Chem. Eq. 37 (6) (2008) 1-5 (in Chinese).

[7] X. Cao,W.J. Du, S. Ji, Effects of baffle connectionmanner on shell-side performance of heat exchanger with helical baffles, CIESC J. 62 (12) (2011) 3367-3372 (in Chinese).

[8] X.P. Song, Z.Z. Pei, Shell and tube heat exchanger with anti-short circuit spiral baffle plate, Petrol. Chem. Eq. Technol. 28 (3) (2007) 13-17 (in Chinese).

[9] B. Peng, Q.W.Wang, C. Zhang, G.N. Xie, L.Q. Luo, Q.Y. Chen, M. Zeng, An experimental study of shell-and-tube heat exchangers with continuous helical baffles, J. Heat Transfer 129 (10) (2007) 1425-1431.

[10] Y.P. Chen, R.B. Cao, J.F.Wu, C. Dong, Y.J. Sheng, Experimental study on shell side heat transfer performance of circumferential overlap trisection helical baffle heat exchangers, Proceedings of the ASME 2011 International Mechanical Engineering Congress and Exposition, Denver, 2011, pp. 27-33.

[11] C. Dong, Y.P. Chen, J.F.Wu, R.B. Cao,Water to water heat transfer on shell-side of trisection helical baffle heat exchangers, CIESC J. 63 (3) (2012) 721-727 (in Chinese).

[12] Y.P. Chen, Y.J. Sheng, J.F.Wu, C. Dong, Numerical simulation on flow field in circumferential overlap trisection helical baffle heat exchanger, Appl. Therm. Eng. 50 (1) (2013) 1035-1104.

[13] C. Wang, J.G. Zhu, Z.F. Sang, Experimental studies on thermal performance and flow resistance of heat exchangers with helical baffles, Heat Transfer Eng. 30 (5) (2009) 353-358.

[14] N.T. Farhad, Z.M. Sirous, R.Z. Kazem, T.A. Reza, Baffle space impact on the performance of helical baffle shell and tube heat exchangers, Appl. Therm. Eng. 44 (2012) 143-149.

[15] Z.G. Zhang, D.B. Ma, X.M. Fang, X.N. Gao, Experimental and numerical heat transfer in a helically baffled heat exchanger combined with one three-dimensional finned tube, Chem. Eng. Process. 47 (9-10) (2008) 1738-1743.

[16] Y.G. Lei, Y.L. He, Pa Chu, R. Li, Design and optimization of heat exchangers with helical baffles, Chem. Eng. Process. 63 (17) (2008) 4386-4395.

[17] Z.G. Zhang, T. Xu, X.M. Fang, Experimental study on heat transfer enhancement of a helically baffled heat exchanger combined with three-dimensional finned tubes, Appl. Therm. Eng. 24 (14-15) (2004) 2293-2300.

[18] M.R. Jafari Nasr, A. Shafeghat, Fluid flow analysis and extension of rapid design algorithm for helical baffle heat exchangers, Appl. Therm. Eng. 28 (11-12) (2008) 1324-1332.

[19] G.D. Chen, Q. Gao, M. Zeng, Q.W. Wang, Numerical studies on shell-side performance of shell-and-tube evaporators with continuous helical baffles, J. Eng. Thermophys. 32 (1) (2011) 104-106.

[20] S. Eiamsa-ard, P. Promvonge, Influence of double-sided delta-wing tape insert with alternate-axes on flow and heat transfer characteristics in a heat exchanger tube, Chin. J. Chem. Eng. 19 (3) (2011) 410-423.

[21] X.Y. Tang, D.S. Zhu, Experimental and numerical study on heat transfer enhancement of a rectangular channel with discontinuous crossed ribs and grooves, Chin. J. Chem. Eng. 20 (2) (2012) 220-230.

Comparison of heat transfer performances of helix baffled heat exchangers with different baffle configurations

Comparison of heat transfer performances of helix baffled heat exchangers with different baffle configurations

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