The counter hollow fiber membrane-based humidifier is used for air humidification, which avoids the problem of liquid droplets carryover in traditional liquid humidification technology. In this study, an experimental rig was established for the hollow fiber membrane humidification system. The effects of air mass flow rate, air temperature, air relative humidity, water mass flow rate, water temperature on air humidity ratio increase, air temperature difference, power consumption per unit of humidification, humidification efficiency, energy efficiency, exergy destruction and exergy efficiency were experimentally investigated using the energy and exergy method. The results reveal the enhancement of the exergy efficiency with the increase in inlet air relative humidity, inlet air dry bulb temperature, air mass flow rate, and water mass flow rate. The results show that the humidification performance of the system is strongly influenced by the water temperature, while the humidification effect is more significant for the low temperature and low air humidity. It was found that as the relative humidity and dry bulb temperature of the air increased, the exergy destruction decreased significantly and the exergy efficiency increased. Increasing the air mass flow rate and water flow temperature resulted in an increase in both exergy destruction and exergy efficiency, while increasing the water flow rate had little effect on exergy destruction and fire efficiency. The exergy efficiency of the system ranged from 0.37 to 0.71. The maximum exergy destruction was 3.74 W, which occurred at air RHa,1=30%, air temperature Ta,1=30°C, water temperature Tw,1=28°C, and air and water flow rates of 32 kg/h and 7 kg/h, respectively. The humidification efficiency of the system ranged from 0.712 to 0.925, and the power consumption per unit of humidification ranged from 0.94 g/(h•W) to 12.50 g/(h•W).
| Published in | International Journal of Energy and Power Engineering (Volume 9, Issue 6) |
| DOI | 10.11648/j.ijepe.20200906.12 |
| Page(s) | 95-107 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Hollow Fiber Membrane, Air Humidification, Exergy Efficiency, Mass Transfer
| [1] | KNEIFEL, K.; NOWAK, S.; ALBRECHT, W.; HILKE, R.; JUST, R.; PEINEMANN, K., Hollow fiber membrane contactor for air humidity control: Modules and membranes. J Membrane Sci 2006, 276, (1-2), 241-251. |
| [2] | Cahalan, T.; Rehfeldt, S.; Bauer, M.; Becker, M.; Klein, H., Experimental set-up for analysis of membranes used in external membrane humidification of PEM fuel cells. Int J Hydrogen Energ 2016, 41, (31), 13666-13677. |
| [3] | Dijkink, B. H.; Tomassen, M. M.; Willemsen, J. H. A.; van Doorn, W. G., Humidity control during bell pepper storage, using a hollow fiber membrane contactor system. Postharvest Biol Tec 2004, 32, (3), 311-320. |
| [4] | Li, G.; Qi, R.; Zhang, L., Performance study of a solar-assisted hollow-fiber-membrane-based air humidification - dehumidification desalination system: Effects of membrane properties. Chem Eng Sci 2019, 206, 164-179. |
| [5] | ASHRAE, ANSI/ASHRAE Standard 55-2017: Thermal Environmental Conditions for Human Occupancy. In 1041-2336, SSPC, Ed ASHRAE: Atlanta, 2017. |
| [6] | Wolkoff, P., Indoor air humidity, air quality, and health – An overview. Int J Hyg Envir Heal 2018, 221, (3), 376-390. |
| [7] | Jesswein, I.; Hirth, T.; Schiestel, T., Continuous dip coating of PVDF hollow fiber membranes with PVA for humidification. J Membrane Sci 2017, 541, 281-290. |
| [8] | Golinko, I.; Drevetskiy, V., Mathematical Model of Heat-and-Mass Transfer for Steam Humidifier. Modeling, Control and Information Technologies 2019, (3), 35-36. |
| [9] | Feng, Z.; Zhou, X.; Xu, S.; Ding, J.; Cao, S., Impacts of humidification process on indoor thermal comfort and air quality using portable ultrasonic humidifier. Build Environ 2018, 133, 62-72. |
| [10] | Chen, J.; Han, D.; He, W.; Liu, Y.; Gu, J., Theoretical and experimental analysis of the thermodynamic and economic performance for a packed bed humidifier. Energ Convers Manage 2020, 206, 112497. |
| [11] | Eder, E.; Preißinger, M., Experimental analysis of the humidification of air in bubble columns for thermal water treatment systems. Exp Therm Fluid Sci 2020, 115, 110063. |
| [12] | Xu, Z.; Xiao, Y.; Wang, Y., Experimental and theoretical studies on air humidification by a water spray at elevated pressure. Appl Therm Eng 2007, 27, (14-15), 2549-2558. |
| [13] | Bazhenov, S. D.; Bildyukevich, A. V.; Volkov, A. V., Gas-Liquid Hollow Fiber Membrane Contactors for Different Applications. Fibers 2018, 6, (4), 76. |
| [14] | Zhang, L., Coupled heat and mass transfer in an application-scale cross-flow hollow fiber membrane module for air humidification. Int J Heat Mass Tran 2012, 55, (21-22), 5861-5869. |
| [15] | Johnson, D. W.; Yavuzturk, C.; Pruis, J., Analysis of heat and mass transfer phenomena in hollow fiber membranes used for evaporative cooling. J Membrane Sci 2003, 227, (1-2), 159-171. |
| [16] | Pandey, R.; Lele, A., Modelling of water-to-gas hollow fiber membrane humidifier. Chem Eng Sci 2018, 192, 955-971. |
| [17] | Chiari, A., Air humidification with membrane contactors: experimental and theoretical results. International journal of ambient energy 2000, 21, (4), 187-195. |
| [18] | Bergero, S.; Chiari, A., Experimental and theoretical analysis of air humidification/dehumidification processes using hydrophobic capillary contactors. Appl Therm Eng 2001, 21, (11), 1119-1135. |
| [19] | Zhang, L.; Huang, S., Coupled heat and mass transfer in a counter flow hollow fiber membrane module for air humidification. Int J Heat Mass Tran 2011, 54, (5-6), 1055-1063. |
| [20] | Zhang, L.; Li, Z.; Zhong, T.; Pei, L., Flow maldistribution and performance deteriorations in a cross flow hollow fiber membrane module for air humidification. J Membrane Sci 2013, 427, 1-9. |
| [21] | Huang, S.; Yang, M., Longitudinal fluid flow and heat transfer between an elliptical hollow fiber membrane tube bank used for air humidification. Appl Energ 2013, 112, 75-82. |
| [22] | Bakeri, G.; Naeimifard, S.; Matsuura, T.; Ismail, A. F., A porous polyethersulfone hollow fiber membrane in a gas humidification process. Rsc Adv 2015, 5, (19), 14448-14457. |
| [23] | Bakeri, G., A Comparative Study on the Application of Porous PES and PEI Hollow Fiber Membranes in Gas Humidification Process. Journal of Membrane Science & Research 2019, 5, 11-19. |
| [24] | Banat, F.; Jwaied, N., Exergy analysis of desalination by solar-powered membrane distillation units. Desalination 2008, 230, (1-3), 27-40. |
| [25] | Ni, M.; Leung, M. K. H.; Leung, D. Y. C., Energy and exergy analysis of hydrogen production by a proton exchange membrane (PEM) electrolyzer plant. Energ Convers Manage 2008, 49, (10), 2748-2756. |
| [26] | Al-Sulaiman, F. A., Assessment of next generation refrigerants for air conditioning systems integrated with air-membrane heat and mass exchangers. Energ Convers Manage 2017, 154, 344-353. |
| [27] | Huang, S.; Li, N.; Low, E.; Xiao, L.; Liang, C., Entropy and exergy analysis of a liquid-liquid air-gap hollow fiber membrane contactor. Int J Therm Sci 2020, 158, 106543. |
| [28] | Liu, G.; Qin, Y.; Yin, Y.; Bian, X.; Kuang, C., Thermodynamic modeling and exergy analysis of proton exchange membrane fuel cell power system. Int J Hydrogen Energ 2020, 45, (54), 29799-29811. |
| [29] | Liang, C.; Li, N.; Huang, S., Entropy and exergy analysis of an internally-cooled membrane liquid desiccant dehumidifier. Energy 2020, 192, 116681. |
| [30] | Liang, C.; Zeng, S., Multi-Objective Design Optimization of Hollow Fiber Membrane-Based Liquid Desiccant Module Using Particle Swarm Optimization Algorithm. Heat Transfer Eng 2017, 1-11. |
| [31] | J. R, T.; W, T., An Introduction to Error Analysis: The Study of Uncertainties in Physical Measurements, 2nd ed. University Science Books 1997. |
| [32] | Dincer, I.; Rosen, M. A., Exergy Analysis of Heating, Refrigerating, and Air Conditioning. Elsevier: 2015; p 1-42. |
| [33] | Chengqin, R.; Nianping, L.; Guangfa, T., Principles of exergy analysis in HVAC and evaluation of evaporative cooling schemes. Build Environ 2002, 37, (11), 1045-1055. |
| [34] | Kanoglu, M.; Dincer, I.; Rosen, M., Exergy analysis of psychrometric processes for HVAC&R applications, ASHRAE Trans 113 part 2. 2007; p 172-180. |
| [35] | Ratlamwala, T. A. H.; Dincer, I., Efficiency assessment of key psychometric processes. International Journal of Refrigeration 2013, 36, (3), 1142-1153. |
| [36] | Martínez, P.; Ruiz, J.; Martínez, P. J.; Kaiser, A. S.; Lucas, M., Experimental study of the energy and exergy performance of a plastic mesh evaporative pad used in air conditioning applications. Appl Therm Eng 2018, 138, 675-685. |
| [37] | Nada, S. A.; Fouda, A.; Mahmoud, M. A.; Elattar, H. F., Experimental investigation of energy and exergy performance of a direct evaporative cooler using a new pad type. Energ Buildings 2019, 203, 109449. |
| [38] | Abohorlu Doğramacı, P.; Riffat, S.; Gan, G.; Aydın, D., Experimental study of the potential of eucalyptus fibres for evaporative cooling. Renew Energ 2019, 131, 250-260. |
| [39] | Gunhan, T.; Demir, V.; Yagcioglu, A. K., Evaluation of the Suitability of Some Local Materials as Cooling Pads. Biosyst Eng 2007, 96, (3), 369-377. |
| [40] | Yang, M.; Huang, S.; Yang, X., Experimental investigations of a quasi-counter flow parallel-plate membrane contactor used for air humidification. Energ Buildings 2014, 80, 640-644. |
| [41] | Chen, X.; Su, Y.; Aydin, D.; Zhang, X.; Ding, Y.; Reay, D.; Law, R.; Riffat, S., Experimental investigations of polymer hollow fibre integrated evaporative cooling system with the fibre bundles in a spindle shape. Energ Buildings 2017, 154. |
APA Style
Zhipeng He, Caihang Liang. (2020). Experimental Study on Energy and Exergy Analysis of a Counter Hollow Fiber Membrane-based Humidifier. International Journal of Energy and Power Engineering, 9(6), 95-107. https://doi.org/10.11648/j.ijepe.20200906.12
ACS Style
Zhipeng He; Caihang Liang. Experimental Study on Energy and Exergy Analysis of a Counter Hollow Fiber Membrane-based Humidifier. Int. J. Energy Power Eng. 2020, 9(6), 95-107. doi: 10.11648/j.ijepe.20200906.12
AMA Style
Zhipeng He, Caihang Liang. Experimental Study on Energy and Exergy Analysis of a Counter Hollow Fiber Membrane-based Humidifier. Int J Energy Power Eng. 2020;9(6):95-107. doi: 10.11648/j.ijepe.20200906.12
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Download@article{10.11648/j.ijepe.20200906.12,
author = {Zhipeng He and Caihang Liang},
title = {Experimental Study on Energy and Exergy Analysis of a Counter Hollow Fiber Membrane-based Humidifier},
journal = {International Journal of Energy and Power Engineering},
volume = {9},
number = {6},
pages = {95-107},
doi = {10.11648/j.ijepe.20200906.12},
url = {https://doi.org/10.11648/j.ijepe.20200906.12},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijepe.20200906.12},
abstract = {The counter hollow fiber membrane-based humidifier is used for air humidification, which avoids the problem of liquid droplets carryover in traditional liquid humidification technology. In this study, an experimental rig was established for the hollow fiber membrane humidification system. The effects of air mass flow rate, air temperature, air relative humidity, water mass flow rate, water temperature on air humidity ratio increase, air temperature difference, power consumption per unit of humidification, humidification efficiency, energy efficiency, exergy destruction and exergy efficiency were experimentally investigated using the energy and exergy method. The results reveal the enhancement of the exergy efficiency with the increase in inlet air relative humidity, inlet air dry bulb temperature, air mass flow rate, and water mass flow rate. The results show that the humidification performance of the system is strongly influenced by the water temperature, while the humidification effect is more significant for the low temperature and low air humidity. It was found that as the relative humidity and dry bulb temperature of the air increased, the exergy destruction decreased significantly and the exergy efficiency increased. Increasing the air mass flow rate and water flow temperature resulted in an increase in both exergy destruction and exergy efficiency, while increasing the water flow rate had little effect on exergy destruction and fire efficiency. The exergy efficiency of the system ranged from 0.37 to 0.71. The maximum exergy destruction was 3.74 W, which occurred at air RHa,1=30%, air temperature Ta,1=30°C, water temperature Tw,1=28°C, and air and water flow rates of 32 kg/h and 7 kg/h, respectively. The humidification efficiency of the system ranged from 0.712 to 0.925, and the power consumption per unit of humidification ranged from 0.94 g/(h•W) to 12.50 g/(h•W).},
year = {2020}
}
TY - JOUR T1 - Experimental Study on Energy and Exergy Analysis of a Counter Hollow Fiber Membrane-based Humidifier AU - Zhipeng He AU - Caihang Liang Y1 - 2020/12/16 PY - 2020 N1 - https://doi.org/10.11648/j.ijepe.20200906.12 DO - 10.11648/j.ijepe.20200906.12 T2 - International Journal of Energy and Power Engineering JF - International Journal of Energy and Power Engineering JO - International Journal of Energy and Power Engineering SP - 95 EP - 107 PB - Science Publishing Group SN - 2326-960X UR - https://doi.org/10.11648/j.ijepe.20200906.12 AB - The counter hollow fiber membrane-based humidifier is used for air humidification, which avoids the problem of liquid droplets carryover in traditional liquid humidification technology. In this study, an experimental rig was established for the hollow fiber membrane humidification system. The effects of air mass flow rate, air temperature, air relative humidity, water mass flow rate, water temperature on air humidity ratio increase, air temperature difference, power consumption per unit of humidification, humidification efficiency, energy efficiency, exergy destruction and exergy efficiency were experimentally investigated using the energy and exergy method. The results reveal the enhancement of the exergy efficiency with the increase in inlet air relative humidity, inlet air dry bulb temperature, air mass flow rate, and water mass flow rate. The results show that the humidification performance of the system is strongly influenced by the water temperature, while the humidification effect is more significant for the low temperature and low air humidity. It was found that as the relative humidity and dry bulb temperature of the air increased, the exergy destruction decreased significantly and the exergy efficiency increased. Increasing the air mass flow rate and water flow temperature resulted in an increase in both exergy destruction and exergy efficiency, while increasing the water flow rate had little effect on exergy destruction and fire efficiency. The exergy efficiency of the system ranged from 0.37 to 0.71. The maximum exergy destruction was 3.74 W, which occurred at air RHa,1=30%, air temperature Ta,1=30°C, water temperature Tw,1=28°C, and air and water flow rates of 32 kg/h and 7 kg/h, respectively. The humidification efficiency of the system ranged from 0.712 to 0.925, and the power consumption per unit of humidification ranged from 0.94 g/(h•W) to 12.50 g/(h•W). VL - 9 IS - 6 ER -
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