Chinese

Journal of Thermal Science

热科学学报

Journal of Thermal Science >

2023 , Vol. 32 >Issue 4: 1684 - 1696

DOI: https://doi.org/10.1007/s11630-023-1725-y

Experimental and Theoretical Study of an Internally Cooled Liquid Desiccant Dehumidifier

Expand
  • 1. Key Laboratory of Advanced Energy and Power, Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing 100190, China
    2. Research Center for Clean Energy and Power, Chinese Academy of Sciences, Lianyungang 222069, China
    3. University of Chinese Academy of Sciences, Beijing 100049, China

Online published: 2023-11-27

Supported by

This work was supported by National Science and Technology Major Project (No. 2017-I-0009-0010).

Copyright

Science Press, Institute of Engineering Thermophysics, CAS and Springer-Verlag GmbH Germany, part of Springer Nature 2023
Fold

Abstract

Liquid desiccant dehumidifiers are useful for simultaneously recovering heat and water from flue gas. Internally cooled dehumidifiers are generally superior to adiabatic dehumidifiers in terms of the consumption of the desiccant and the size of the equipment required. This study examines the performance of a counter-flow dehumidifier through experiments and simulations under different operating conditions, and analyzes the moisture effectiveness and enthalpy effectiveness as performance indices. By applying correlations from the literature, the theoretical model can predict the performance of the dehumidifier within an acceptable range of accuracy. According to the experimental results, droplets were visible at a low desiccant flow rate when the velocity of the gas was above 4.88 m/s. Moreover, a higher cooling ratio and a higher temperature of the solution enhanced the effectiveness of the dehumidification. A temperature cross occurred between the gas and the solution when the mass transfer was sufficiently high, which reflects better heat transfer performance than the conventional convective heat exchanger.

Key words: flue gas; recovery; water; heat; internal cooling; calcium chloride

Cite this article

ZHENG Xin, LU Yuan, WANG Bo, ZHAO Lifeng, XIAO Yunhan . Experimental and Theoretical Study of an Internally Cooled Liquid Desiccant Dehumidifier[J]. Journal of Thermal Science, 2023 , 32(4) : 1684 -1696 . DOI: 10.1007/s11630-023-1725-y

References

[1] Black J., Cost and performance baseline for fossil energy plants Volume 1: Bituminous coal and natural gas to electricity. Final report (2nd ed), National Energy Technology Laboratory (2010 Nov.) Report No: DOE20101397, 2010.
[2] Zhang C., Yang Y., Fan L., et al., Numerical study on operating characteristics of self-driven total heat recovery system for wet-hot flue gas. Applied Thermal Engineering, 2020, 173: 115223.
[3] Cheng Y.F., Zheng G.J., Wei C., et al., Reactive nitrogen chemistry in aerosol water as a source of sulfate during haze events in China. Science Advances, 2016, 2(12): e1601530.
[4] Wu W., Li X., You T., Advances in waste heat and renewable energy utilization. Absorption Heating Technologies, Springer, 2019, pp. 237–259.
[5] Ostrowski P., Szelejewski F., Estimation of the coal fired heat plant energy efficiency increase after heat recovery from flue gas cooling down below the dew point. E3S Web of Conferences, EDP Sciences, 2019, 82: 01003.
[6] Yang B., Jiang Y., Fu L., et al., Full-open absorption heat pump for total heat recovery of flue gas. Journal of Southeast University (Natural Science Edition), 2018, 48(5): 789–793.
[7] Elberry M.F., Elsayed A.A., Teamah M.A., et al., Performance improvement of power plants using absorption cooling system. Alexandria Engineering Journal, 2018, 57(4): 2679–2686.
[8] Fan W., Theoretical analysis of open cycle absorption heat transfer and experiment on absorber and generator. Institute of Engineering Thermophysics, Chinese Academy of Sciences, China, 2008.
[9] Copen J., Sullivan T., Folkedahl B., Principles of flue gas water recovery system. The Power-Gen International Conference, December 6–8, Las Vagas NV, 2005.
[10] Ibarra-Bahena J., Romero R.J., Performance of different experimental absorber designs in absorption heat pump cycle technologies: A review. Energies, 2014, 7(2): 751–766.
[11] Ren C.Q., Tu M., Wang H.H., An analytical model for heat and mass transfer processes in internally cooled or heated liquid desiccant-air contact units. International Journal of Heat and Mass Transfer, 2007, 50(17): 3545–3555.
[12] Khan A.Y., Cooling and dehumidification performance analysis of internally-cooled liquid desiccant absorbers. Applied Thermal Engineering, 1998, 18(5): 265–281.
[13] Wang X., Cai W., Lu J., et al., A hybrid dehumidifier model for real-time performance monitoring, control and optimization in liquid desiccant dehumidification system. Applied Energy, 2013, 111: 449–455.
[14] Zhang L., Hihara E., Saikawa M., Combination of air-source heat pumps with liquid desiccant dehumidification of air. Energy Conversion and Management, 2012, 57: 107–116.
[15] Ge G., Xiao F., Xu X., Model-based optimal control of a dedicated outdoor air-chilled ceiling system using liquid desiccant and membrane-based total heat recovery. Applied Energy, 2011, 88(11): 4180–4190.
[16] Bansal P., Jain S., Moon C., Performance comparison of an adiabatic and an internally cooled structured packed-bed dehumidifier. Applied Thermal Engineering, 2011, 31(1): 14–19.
[17] Khan A.Y., Martinez J.L., Modelling and parametric analysis of heat and mass transfer performance of a hybrid liquid desiccant absorber. Energy Conversion and Management, 1998, 39(10): 1095–1112.
[18] Gommed K., Grossman G., Ziegler F., Experimental investigation of a LiCl-water open absorption system for cooling and dehumidification. Journal of Solar Energy Engineering, 2004, 126(2): 710–715.
[19] Chen X., Su Y., Reay D., et al., Recent research developments in polymer heat exchangers–A review. Renewable and Sustainable Energy Reviews, 2016, 60(1): 1367–1386.
[20] Gandhidasan P., Ullah M.R., Kettleborough C., Analysis of heat and mass transfer between a desiccant-air system in a packed tower. Journal of Solar Energy Engineering, 1987, 109(2): 89–93.
[21] Islam M.R., Wijeysundera N., Ho J., Simplified models for coupled heat and mass transfer in falling-film absorbers. International Journal of Heat and Mass Transfer, 2004, 47(2): 395–406.
[22] Yoon J.-I., Phan T.-T., Moon C.-G., et al., Numerical study on heat and mass transfer characteristic of plate absorber. Applied Thermal Engineering, 2005, 25(14–15): 2219–2235.
[23] Chilton T.H., Colburn A.P., Mass transfer (absorption) coefficients prediction from data on heat transfer and fluid friction. Industrial & Engineering Chemistry, 1934, 26(11): 1183–1187.
[24] Serth R.W., Lestina T.G., 5-Design of shell-and-tube heat exchangers. Serth R.W., Lestina T.G., Process Heat Transfer (Second Edition). Boston, Academic Press, 2014, pp. 151–197.
[25] Yih S.-M., Chen K.-Y., Gas absorption into wavy and turbulent falling liquid films in a wetted-wall column. Chemical Engineering Communications, 1982, 17(1–6): 123–136.
[26] Shah R.K., London A.L. Chapter V - Circular duct. Laminar flow forced convection in ducts. Academic Press, 1978, pp. 78–152.
[27] Siddig-Mohammed B., Watson F., Holland F., Study of the operating characteristics of a reversed absorption heat pump system (heat transformer). Chemical Engineering Research and Design, 1983, 61: 283–289.
[28] Yin Y., Zheng B., Chen T., et al., Investigation on coupled heat and mass transfer coefficients between compressed air and liquid desiccant in a packed dryer. International Journal of Heat and Mass Transfer, 2016, 93: 1218– 1226.
Options
Outlines

/

Wechat

Sponsored by: Institute of Engineering Thermophysics, Chinese Academy of Sciences Publisher: Science Press

Copyright © 2023 Journal of Thermal Science