Study on heat transfer characteristics of flow heat coupling of horizontal spiral tube heat exchanger

Qingwen Yue, Xide Lai, Xiaoming Chen, Ping Hu

Article ID: 1516
Vol 4, Issue 2, 2021

VIEWS - 2308 (Abstract) 2523 (pdf)

Abstract


In view of the complex structural characteristics and special operating environment of the horizontal spiral tube heat exchanger of the shaft sealed nuclear main pump, the numerical simulation method of flow heat coupling is used to analyze the influence of the flow and temperature changes of the fluid on the shell side on the flow field and temperature field of the heat exchanger, explore the influence rules of the inlet parameters on the flow and heat transfer characteristics of the fluid in the heat exchanger, and analyze the enhanced heat transfer performance of the heat exchanger by using the relevant heat transfer criteria. The results show that the horizontal spiral tube fluid generates centrifugal force under the influence of curvature, forming a secondary flow which is different from the straight tube flow heat transfer, and the velocity distribution is concave arc, which will enhance the heat transfer efficiency of the heat exchanger; with the increase of shell side velocity, the degree of fluid disturbance and turbulence increases, while the pressure loss does not change significantly, and the heat transfer performance of the heat exchanger increases; under the given structure and size, the heat transfer performance curve of the heat exchanger shows that the increase of shell side flow and Reynolds number has a significant impact on the enhanced heat transfer of the spiral tube. In practical engineering applications, the heat transfer can be strengthened by appropriately increasing the shell side flow of the heat exchanger.

Keywords


Shaft Seal Nuclear Main Pump; Horizontal Spiral Tube Heat Exchanger; Coupled Heat Transfer; Numerical Simulation; Performance Analysis

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References


1. Wu Z, Xi H, Xu P. Numerical studies on geometric parametric analysis of helical-wound tube heat exchangers. Chemical Engineering 2019; 47(9): 12–17.

2. Fsadni AM, Whitty JPM. A review on the two-phase heat transfer characteristics in helically coiled tube heat exchangers. International Journal of Heat and Mass Transfer 2016; 95: 551–565.

3. Vocale P. Influence of thermal boundary conditions on local con-vective heat transfer in coiled tubes. International Journal of Thermal Sciences 2019; 145: 106039.

4. Ren Y. Numerical study on the shell-side flow and heat transfer of superheated vapor flow in spiral wound heat exchanger under rolling working conditions. International Journal of Heat and Mass Transfer 2018; 121: 691–702.

5. Lu X. Shell-side thermal-hydraulic performances of multilayer spiral wound heat exchangers under different wall thermal boundary conditions. Applied Thermal Engineering 2014; 70(2): 1216–1227.

6. Zeng M, Zhang G, Li Y, et al. Geometrical parametric analysis of flow and heat transfer in the shell side of a spiral-wound heat exchanger. Heat Transfer Engineering 2015; 36: 790–805.

7. Sun C. Experimental study on shell-side pressure drop and offshore adaptability of LNG-FPSO spiral wound heat exchanger. Experimental Thermal and Fluid Science 2019; 109: 109874.

8. Yu S. Experimental and numerical investigation of two-phase flow outside tube bundle of liquefied natural gas spiral wound heat exchangers under offshore conditions. Applied Thermal Engineering 2019; 152: 103–112.

9. Chen Z, Qin C, Dai W. Experimental research on heat transfer coefficient of spiral tube and numerical simulation of temperature field. Gas & Heat 2010; 30(1): 16–18.

10. Guo L, Chen X, Zhang M. Research on the forced convective boiling heat transfer characteristics of steam-water two-phase flow in horizontal helically coiled tubes. Journal of Xi’an Jiaotong University 1994; 28(5): 120–124.

11. Yu Q. Research on calculation method for helical wound coil tube heat exchangers [MSc thesis]. Dalian: Dalian University of Technology; 2011.

12. Naphon P. Study on the heat transfer and flow characteristics in a spiral-coil tube. International Communications in Heat and Mass Transfer 2011; 38: 69–74.

13. Zhang Z, Li Y, Wang Y, et al. Numerical simulation of fluid enhanced heat transfer in a helical tube under constant wall temperature condition. Re-frigeration and Air-Conditioning 2016; 16(2): 43–48.

14. Sharqawy MH, Saad SMI, Ahmed KK. Effect of flow configuration on the performance of spiral-wound heat exchanger. Applied Thermal Engineering 2019; 161: 114–157.

15. Elattar HF. Thermal and hydraulic numerical study for a novel multi tubes in helically coiled tube heat exchangers: Effects of operating/geometric parameters. International Journal of Thermal Sciences 2018; 128: 70–83.




DOI: https://doi.org/10.24294/tse.v4i2.1516

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