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[4] Guan BW, Zhang T, Liu J, Liu XH*. Exergy analysis and performance improvement of liquid-desiccant deep-dehumidification system: An engineering case study. Energy, 2020, 196:117122.
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[10] Guan BW, Liu XH*, Zhang T. Energy performance analysis on segmented liquid desiccant air-conditioning system for bus spray-paint booths. Journal of Cleaner Production, 2021, 278:123898.
[11] Guan BW, Liu XH*, Zhang T. On the importance of air-solution flow rate matching in liquid-desiccant deep-dehumidification system. International Journal of Heat and Mass Transfer, 2021, 164:120614.
[12] Guan BW, Liu XH*, Zhang T. Modification of analytical solutions of coupled heat and mass transfer processes in liquid desiccant dehumidifier for deep dehumidification. International Journal of Heat and Mass Transfer, 2021, 165:120728.
[13] Guan BW, Zhang T, Liu XH*. On-site performance investigation of a desiccant wheel deep- dehumidification system applied in lithium battery manufacturing plant. Energy and Buildings, 2021, 232:110659.
[14] Guan BW, Zhang T, Liu XH*. On-site performance investigation of liquid-desiccant air-conditioning system applied in laboratory rodent room: A comparative study. Energy and Buildings, 2021, 232:110664.
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