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Science and Technology for the Built Environment Volume 25, 2019 - Issue 1
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Original Articles

Experimental study on the active enhancement mechanisms of heat and mass transfer in an absorption chiller (RP-1462)

Peng WangSchool of Civil Engineering, Dalian University of Technology, Dalian City, Liaoning Province, China;Durham School of Architectural Engineering and Construction, University of Nebraska–Lincoln, PKI-104F, 1110 S 67th Street, Omaha, NE, 68182, USAView further author information
,
Sungmin YoonDurham School of Architectural Engineering and Construction, University of Nebraska–Lincoln, PKI-104F, 1110 S 67th Street, Omaha, NE, 68182, USAView further author information
,
Yuebin YuDurham School of Architectural Engineering and Construction, University of Nebraska–Lincoln, PKI-104F, 1110 S 67th Street, Omaha, NE, 68182, USACorrespondence[email protected]
View further author information
&
Ziqi ShenDurham School of Architectural Engineering and Construction, University of Nebraska–Lincoln, PKI-104F, 1110 S 67th Street, Omaha, NE, 68182, USAView further author information
Pages 58-68 | Received 26 Jul 2017, Accepted 20 Jun 2018, Published online: 08 Oct 2018

References

  • Ali Aroon, M., and M.A. Khansary. 2017. Generalized similarity transformation method applied to partial differential equations (PDEs) in falling film mass transfer. Computers & Chemical Engineering 101:73–80.
  • Aoune, A., and C. Ramshaw. 1999. Process intensification: Heat and mass transfer characteristics of liquid films on rotating discs. International Journal of Heat and Mass Transfer 42(14):2543–56.
  • Barrera, M.A., R. Best, V.H. Gómez, O. García-Valladares, N. Velázquez, and J. Chan. 2012. Analysis of the performance of a GAX hybrid (Solar-LPG) absorption refrigeration system operating with temperatures from solar heating sources. Energy Procedia 30:884–92.
  • Bergles, A.E., and R.M. Manglik. 2013. Current progress and new developments in enhanced heat and mass transfer. Journal of Enhanced Heat Transfer 20(1):1–15.
  • Bo, S., X. Ma, Z. Lan, H. Chen, and J. Chen. 2012. Numerical simulation on wave behaviour and flow dynamics of laminar–wavy falling films: Effect of surface tension and viscosity. Canadian Journal of Chemical Engineering 90(1):61–68.
  • Chen, R.-H., Y.-J. Lin, and C.-M. Lai. 2013. The influence of horizontal longitudinal vibrations and the condensation section temperature on the heat transfer performance of a heat pipe. Heat Transfer Engineering 34(1):45–53.
  • Cheng, L., T. Luan, W. Du, and M. Xu. 2009. Heat transfer enhancement by flow-induced vibration in heat exchangers. International Journal of Heat and Mass Transfer 52(3):1053–57.
  • Gao, H., B. Liu, and Y. Yan. 2017. Numerical simulation of bubbles motion in lifting pipe of bubble pump for lithium bromide absorption chillers. Applied Thermal Engineering 115:1398–406.
  • Gilani, S.I.-u.-H., and M.S.M.S. Ahmed. 2015. Solution crystallization detection for double-effect LiBr–H2O steam absorption chiller. Energy Procedia 75:1522–28.
  • Gomri, R. 2010. Investigation of the potential of application of single effect and multiple effect absorption cooling systems. Energy Conversion and Management 51(8):1629–36.
  • Hoffmann, L., I. Greiter, A. Wagner, V. Weiss, and G. Alefeld. 1996. Experimental investigation of heat transfer in a horizontal tube falling film absorber with aqueous solutions of LiBr with and without surfactants. International Journal of Refrigeration 19(5):331–41.
  • Hosseinnia, S.M., M. Naghashzadegan, and R. Kouhikamali. 2017. Numerical study of falling film absorption process in a vertical tube absorber including Soret and Dufour effects. International Journal of Thermal Sciences 114:123–38.
  • Jayasekara, S., and S.K. Halgamuge. 2013. Mathematical modeling and experimental verification of an absorption chiller including three dimensional temperature and concentration distributions. Applied Energy 106:232–42.
  • Kiani, H., D.W. Sun, and Z. Zhang. 2012. The effect of ultrasound irradiation on the convective heat transfer rate during immersion cooling of a stationary sphere. Ultrasonics Sonochemistry 19(6):1238–45.
  • Lazrak, A., F. Boudehenn, S. Bonnot, G. Fraisse, A. Leconte, P. Papillon, and B. Souyri. 2016. Development of a dynamic artificial neural network model of an absorption chiller and its experimental validation. Renewable Energy 86:1009–22.
  • Li, Z., L. Liu, and J. Liu. 2016. Variation and design criterion of heat load ratio of generator for air cooled lithium bromide–water double effect absorption chiller. Applied Thermal Engineering 96:481–89.
  • Liu, Y.-l., S.-m. Xu, and W. Han. 2004. Experimental study of falling film absorption in a swaying tube using TFE/NMP as working fluid. Journal–Dalian University of Technology 44(1):65–69.
  • Liu, Y.-l., S. Xu, W. Han, and B. Wang. 2004. Experimental study of falling film absorption in a swaying tube using TFE/NMP as working fluid. Journal of Dalian University of Technology 1:015.
  • Monroy Melendez, D. 2010. Effect of ultrasonic vibration on the mass transfer coefficient in a sieve plate scrubber. Clemson University, Clemson, SC.
  • Mortazavi, M., and S. Moghaddam. 2016. Laplace transform solution of conjugate heat and mass transfer in falling film absorption process. International Journal of Refrigeration 66:93–104.
  • Mortazavi, M., R. Nasr Isfahani, S. Bigham, and S. Moghaddam. 2015. Absorption characteristics of falling film LiBr (lithium bromide) solution over a finned structure. Energy 87:270–78.
  • Nabil, B.H., C. Bechir, and G. Slimane. 2014. Global modeling of heat and mass transfers in spiral tubular absorber of a water–lithium bromide absorption chiller. International Journal of Refrigeration 38:323.
  • Park, C.W., H.C. Cho, and Y.T. Kang. 2004. The effect of heat transfer additive and surface roughness of micro-scale hatched tubes on absorption performance. International Journal of Refrigeration 27(3):264–70.
  • Schmid, F., and K. Spindler. 2016. Experimental investigation of the auxiliary gas circuit of a diffusion absorption chiller with natural and forced circulation. International Journal of Refrigeration 70:84–92.
  • Shen, Z., Y. Yu, and J. Lau. 2016. Experimental setup and methodology on active mechanisms for enhancing heat and mass transfer in sorption fluids. ASHRAE Transactions 122(2):122–133..
  • Shirazi, A., R.A. Taylor, S.D. White, and G.L. Morrison. 2016. A systematic parametric study and feasibility assessment of solar-assisted single-effect, double-effect, and triple-effect absorption chillers for heating and cooling applications. Energy Conversion and Management 114:258–77.
  • Thangavelu, S.R., A. Myat, and A. Khambadkone. 2017. Energy optimization methodology of multi-chiller plant in commercial buildings. Energy 123:64–76.
  • Tsuda, H., and H. Perez-Blanco. 2001. An experimental study of a vibrating screen as means of absorption enhancement. International Journal of Heat and Mass Transfer 44(21):4087–94.
  • Wang, J., J. Wu, and H. Wang. 2015. Experimental investigation of a dual-source powered absorption chiller based on gas engine waste heat and solar thermal energy. Energy 88:680–89.
  • Xu, Y.-j., S.-j. Zhang, and Y.-h. Xiao. 2016. Modeling the dynamic simulation and control of a single effect LiBr–H2O absorption chiller. Applied Thermal Engineering 107:1183–91.
  • Yang, L., K. Du, X. Niu, Y. Zhang, and Y. Li. 2014. Numerical investigation of ammonia falling film absorption outside vertical tube with nanofluids. International Journal of Heat and Mass Transfer 79:241–π50.

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