Potential Analysis of Atmospheric Water Harvesting Technologies from the Perspective of “Trading-in Energy for Water”

Houjun, Li; Cheng, Longdi; Sun, Peng; Li, Fang‐Fang; Qiu, Jun

doi:10.3390/w15050878

Cited by 5 publications

(3 citation statements)

References 59 publications

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“…This topographical challenge leads to additional energy consumption and costs associated with lifting the reclaimed condensed water to these high locations. Moreover, the fluctuating quantity of condensed water due to humidity levels does not appeal to cooling tower operators [50][51][52]. Additionally, the term "grey water" has deterred direct application of condensed water [53,54].…”

Section: Discussionmentioning

confidence: 99%

Carbon Footprint Reduction by Reclaiming Condensed Water

Leung,

Cheng

2024

Sustainability

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Everyday activity incurs carbon footprints, which are classified as personal, production, organizational and national, and may be assessed by input–output analysis (IOA), life-cycle assessment (LCA), or the combination of LCA and IOA methods. Notwithstanding international standards, like ISO 14064 and Publicly Available Specification (PAS) released for standardization, carbon footprint results can vary and sometimes lack consistency that due to variations in data sources, crossover boundary definitions, and operational boundaries for indirect emissions. The novelty of this study is the direct utilization of condensed water in an existing cooling water system, without the need for prior wastewater treatment, as typically required for greywater. The lack of practical case studies exploring the water–energy nexus in the context of reclaiming condensed water for evaporative cooling tower systems makes this research particularly significant. This highlights that condensed water can be a straightforward and cost-effective solution for both water conservation and energy savings. This case study highlights the benefits of reclaiming condensed water as supplementary cooling water, which proved effective in water quality treatment and dilution augmentation, considering that a higher cycle of concentration (CoC) was achieved, leading to reduced bleed-off that resulted in a water saving of 44% for make-up and 80% for bleed-off water, and energy savings from 6.9% to 13.1% per degree Celsius of condensing refrigerant temperature (CRT). The analytical assessment revealed that reclaiming condensed water is a promising answer for green building and is a by-product of condensation without extra power demands, avoiding the generation of an increased carbon footprint and exacerbation of greenhouse gas (GHG) emissions from freshwater resource extraction, and for the production of energy-efficient devices or substitutions. By eliminating the need for wastewater treatment, this research enhances the practicality and feasibility of direct use of condensed water in various applications. This approach not only promotes sustainability by conserving water and energy but also renews interest among proponents of green building practices. It has the potential to accelerate the adoption of this method and integrate it into green building designs.

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Section: Discussionmentioning

confidence: 99%

Carbon Footprint Reduction by Reclaiming Condensed Water

Leung,

Cheng

2024

Sustainability

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“…With that said, a new benchmark of water production efficiency can be accounted in L kW À1 h À1 for this proposed hybrid SSG system as this calculation has been applied in different type of atmospheric water harvesting systems. 95,96…”

Section: Device Designmentioning

confidence: 99%

Updated perspective on solar steam generation application

Onggowarsito,

Mao,

Zhang

et al. 2024

Energy Environ. Sci.

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“…Water stability: In the process of moisture absorption, moisture absorbent will inevitably be in the environment containing a large amount of water. High water stability is the inevitable requirement of moisture absorbent [91]. High stability can maintain the pore structure and other properties of the hygroscopic agent, which is conducive to maintaining efficient hygroscopic performance and structural design.…”

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confidence: 99%

Research Progress on Hygroscopic Agents for Atmospheric Water Harvesting Systems

Bai,

Zhou,

Cui

et al. 2024

Materials

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Adsorptive atmospheric water harvesting systems (AWHs) represent an innovative approach to collecting freshwater resources from the atmosphere, with a hygroscopic agent at their core. This method has garnered significant attention due to its broad applicability, strong recycling capacity, and sustainability. It is being positioned as a key technology to address global freshwater scarcity. The core agent’s hygroscopic properties play a crucial role in determining the performance of the AWHs. This article provides a comprehensive review of the latest advancements in hygroscopic agents, including their adsorption mechanisms and classifications. This study of hygroscopic agents analyzes the performance and characteristics of relevant porous material composite polymer composites and plant composites. It also evaluates the design and preparation of these materials. Aiming at the problems of low moisture adsorption and desorption difficulty of the hygroscopic agent, the factors affecting the water vapor adsorption performance and the method of enhancing the hygroscopic performance of the material are summarized and put forward. For the effect of hygroscopic agents on the volume of water catchment devices, the difference in density before and after hygroscopicity is proposed as part of the evaluation criteria. Moisture absorption per unit volume is added as a performance evaluation criterion to assess the effect of hygroscopic agents on the volume of water collection equipment. The article identifies areas that require further research and development for moisture absorbers, exploring their potential applications in other fields and anticipating the future development direction and opportunities of moisture-absorbing materials. The goal is to promote the early realization of adsorptive atmospheric water harvesting technology for large-scale industrial applications.

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Potential Analysis of Atmospheric Water Harvesting Technologies from the Perspective of “Trading-in Energy for Water”

Cited by 5 publications

References 59 publications

Carbon Footprint Reduction by Reclaiming Condensed Water

Carbon Footprint Reduction by Reclaiming Condensed Water

Updated perspective on solar steam generation application

Research Progress on Hygroscopic Agents for Atmospheric Water Harvesting Systems

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