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The fuel cell and atmospheric water generator hybrid system for supplying grid-independent power and freshwater

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  • Kwan, Trevor Hocksun
  • Shen, Yongting
  • Hu, Tianxiang
  • Pei, Gang

Abstract

Despite the success of atmospheric water generators for providing drinking water to remote regions, this technology has a high specific energy consumption. This paper proposes to reuse the electrochemical water of the fuel cell for the vapor compression cycle based atmospheric water generator (VCC-AWG); After passing through an ambient heat exchanger to remove the electrochemical waste heat, the fuel cell flue gas that enters the VCC-AWG is at a higher relative humidity than natural atmospheric air, thus the freshwater yield per energy input can be significantly increased. Hence, the FC-VCC-AWG hybrid system is proposed to be a power and freshwater supply of a grid-independent home. The fuel cell model, the vapor compression cycle’s thermodynamic model, and humid air physics are coupled to analyze the overall system in terms of the fuel cell’s working condition, incoming airflow rate, compressor power consumption, and the ambient relative humidity. When RH = 0.75, adding a 2 kW fuel cell generated up to 3 kg/hr of freshwater, which is 50% higher than excluding the FC. The specific energy consumption can be 200 Wh/kg, so the VCC-AWG can be integrated with small sacrifices to the FC power output.

Suggested Citation

  • Kwan, Trevor Hocksun & Shen, Yongting & Hu, Tianxiang & Pei, Gang, 2020. "The fuel cell and atmospheric water generator hybrid system for supplying grid-independent power and freshwater," Applied Energy, Elsevier, vol. 279(C).
    • Handle: RePEc:eee:appene:v:279:y:2020:i:c:s0306261920312654
    DOI: 10.1016/j.apenergy.2020.115780
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    References listed on IDEAS

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    1. Tu, Rang & Hwang, Yunho, 2020. "Reviews of atmospheric water harvesting technologies," Energy, Elsevier, vol. 201(C).
    2. Ferreira, Rui B. & Falcão, D.S. & Oliveira, V.B. & Pinto, A.M.F.R., 2017. "1D+3D two-phase flow numerical model of a proton exchange membrane fuel cell," Applied Energy, Elsevier, vol. 203(C), pages 474-495.
    3. Bolorinos, Jose & Yu, Yang & Ajami, Newsha K. & Rajagopal, Ram, 2018. "Balancing marine ecosystem impact and freshwater consumption with water-use fees in California’s power markets: An evaluation of possibilities and trade-offs," Applied Energy, Elsevier, vol. 226(C), pages 644-654.
    4. Salehi, Ali Akbar & Ghannadi-Maragheh, Mohammad & Torab-Mostaedi, Meisam & Torkaman, Rezvan & Asadollahzadeh, Mehdi, 2020. "A review on the water-energy nexus for drinking water production from humid air," Renewable and Sustainable Energy Reviews, Elsevier, vol. 120(C).
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    Cited by:

    1. Tashtoush, Bourhan & Alshoubaki, Anas, 2023. "Atmospheric water harvesting: A review of techniques, performance, renewable energy solutions, and feasibility," Energy, Elsevier, vol. 280(C).
    2. Mengbo Zhang & Ranbin Liu & Yaxuan Li, 2022. "Diversifying Water Sources with Atmospheric Water Harvesting to Enhance Water Supply Resilience," Sustainability, MDPI, vol. 14(13), pages 1-17, June.
    3. Yao, Jing & Wu, Zhen & Wang, Huan & Yang, Fusheng & Xuan, Jin & Xing, Lei & Ren, Jianwei & Zhang, Zaoxiao, 2022. "Design and multi-objective optimization of low-temperature proton exchange membrane fuel cells with efficient water recovery and high electrochemical performance," Applied Energy, Elsevier, vol. 324(C).

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