About The Journal
  Aims and Scope
  Editorial Board
  Submit a Manuscript 
  Subscription Information
  Guidelines for Publication
  Ethics
Articles & Issues
  Search
  Issue
  Online First
  KJChE on
For Authors
  Instructions to Authors
  Ethical Responsibilities of
  Authors in KJChE
  Ethics in Publishing
  Peer Review Process
  Author's Checklist
  Copyright Transfer Form
Contact us
 
 
 
Issue
Korean Journal of Chemical Engineering,
Vol.39, No.7, 1729-1743, 2022
Analysis of heat transfer performance of ORC direct contact heat exchanger by GRA-VMD-LSSVM model using optimization
Zheng G, Xiao Q, Zhu S, Wang H, Geng J, Zhao S, Huang J
The relationship between heat transfer effect and influencing factors in direct contact with evaporator is studied. It is important to optimize the design and setting of direct contact heat exchangers and further improve the heat transfer process of heat exchangers by understanding the influencing factors of direct contact evaporator. The methods used are grey correlation analysis, variational mode decomposition and least square support vector machine algorithm to calculate the experimental heat transfer coefficient. The conclusions are that grey relation analysis can find the complex relationship between different influencing factors and reduce the amount of data to improve the accuracy of prediction. Hence, the novelty of this paper is to propose a simple, efficient and accurate hybrid prediction model for VHTC prediction. The place where it goes beyond previous efforts in the literature is that different influencing factors on the heat transfer performance in the direct contact heat transfer process are considered. The results show that the prediction accuracy of the heat transfer coefficient can be improved by 7% by optimizing the data only with grey correlation analysis. The prediction accuracy can be improved up to 53% after using the hybrid model.
Keywords: Direct Contact Heat Exchanger; Volumetric Heat Transfer Coefficient; Grey Relation Analysis; Variational; Mode Decomposition; Support Vector Machine
[References]
  1. Olfati M, Bahiraei M, Nazari S, Veysi F, Energy, 209, 118430, 2020
  2. Huang B, Jian Q, Luo L, Zhao J, Energy Conv. Manag., 138, 38, 2017
  3. Jiang B, Xia D, Zhang H, Pei H, Liu X, Energy, 208, 118346, 2020
  4. Atmaca A, Yumrutas R, Energy Conv. Manag., 79, 790, 2014
  5. Gutiérrez AS, Martínez JBC, Vandecasteele C, Appl. Therm. Eng., 51, 273, 2013
  6. Han Y, Sun Y, Energy, 207, 118172, 2020
  7. Hosseinzadeh K, Ganji DD, Ommi F, J. Mol. Liq., 315, 113748, 2020
  8. Wang L, Bu X, Li H, Energy, 2203, 117809, 2020
  9. Vasile M, Appl. Therm. Eng., 69, 143, 2014
  10. Nami H, Anvari-Moghaddam A, Energy, 192, 116634, 2020
  11. Hou Z, Wei X, Ma X, Meng X, J. Clean Prod., 246, 119064.1, 2020
  12. Giovannelli A, Archilei EM, Salvini C, Energies, 13, 1054, 2020
  13. Peris B, Navarro-Esbri J, Moles F, Energy, 85, 534, 2015
  14. Pili R, Martínez L, Wieland C, Hartmut S, Renew. Sust. Energ. Rev., 134, 110324, 2020
  15. Fu H, Chem. Eng. Process., 149, 107829, 2020
  16. Halkarni S, Sridharan A, Prabhu S, Int. J. Therm. Sci., 110, 340, 2016
  17. Zheng Y, Dong H, Cai J, Feng J, Zhao L, Liu J, Zhang S, Appl. Therm. Eng., 151, 335, 2019
  18. Zeng T, Zhang C, Hao D, Cao D, Chen J, Chen J, Li J, Energy, 208, 113819, 2020
  19. Sivama SPSS, Saravananb K, Harshavardhanaa N, Kumarana D, Mater. Today. Proc., 45, 1464, 2020
  20. Ppda B, Sc B, Mater. Today: Proc., 28, 568, 2020
  21. Ren S, Wang C, Xiao Y, Deng J, Tian Y, Song J, Cheng X, Sun G, Fuel, 260, 116287, 2020
  22. Hong H, Zhang Z, Guo A, Shen L, Sun H, Liang Y, Wu F, Lin H, J. Hydrol. Eng., 591, 125574, 2020
  23. Zhao Y, Zhang B, Han L, Optics Commun., 456, 124588, 2020
  24. Zhang Y, Pan G, Chen B, Han J, Zhao Y, Zhang C, Renew. Energy, 156, 1373, 2020
  25. Xiao F, Yang D, Lv Z, Guo X, Liu Z, Wang Y, Future Generation Computer Systems, 110, 1023, 2019
  26. Gyamerah S, J. of King Saud University - Computer and Information Sciences, 1319 (2020).
  27. Ms A, Am B, Hq A, Ga C, Pn D, Cr A, Energy, 205, 117986, 2020
  28. Yu Y, Shao M, Jiang L, Ke Y, Wei D, Zhang D, Jiang M, Yang Y, Optik, 237, 166759, 2021
  29. Hu R, Chen K, Chen W, Wang Q, Luo H, Waste Manage., 126, 791, 2021
  30. Amber K, Ahmad R, Aslam M, Kousar A, Usman M, Khan M, Energy, 157, 886, 2018
  31. Wang J, Hu J, Energy, 93, 41, 2015
  32. Sun H, Wu Y, Wu Z, Han F, Yang M, Wang Y, Phytochem. Lett., 43, 108, 2021
  33. Singh S, Parmar K, Makkhan S, Kaur J, Kumar J, Chaos Solitons & Fractals, 139, 110086, 2020
  34. Han H, Cui X, Fan Y, Qing H, Appl. Therm. Eng., 154, 540, 2019
  35. Thongwik S, Vorayos N, Kiatsiriroat T, Nuntaphan A, Int. Commun. Heat Mass Transf., 35, 756, 2008
  36. Huang J, Xu J, Sang X, Wang H, Wang H, Int. J. Heat Mass Transf., 75, 497, 2014
  37. Baqir A, Mahood H, Campbell A, Griffiths A, Appl. Therm. Eng., 103, 47, 2016
  38. Li J, Zhang X, Tang J, J. Appl. Geophys., 180, 104127, 2020
  39. Bavkar S, Iyer B, Deosarkar S, Probl. Biocybern. Biomed. Eng., 41, 2020
  40. Alizamir M, Kim S, Kisi O, Zounemat-Kermani M, Energy, 197, 117239, 2020
  41. Xiao C, Ye J, Rui M, Rong C, Concurrency Computation: Practice and Experience, 28, 3866, 2016
참고문헌정보(참고문헌, 인용문헌)는 화학공학소재연구정보센터에 의해 제공되고 있습니다.