AI Article Synopsis
- Brine from desalination plants poses environmental risks, prompting increased interest in zero-liquid discharge (ZLD) systems.
- The proposed method utilizes a humidification-dehumidification (HDH) process, showing benefits like lower energy use and cost, along with decreased scaling issues.
- Experimental results indicate successful brine concentration and salt crystallization at 40 °C, achieving 56% lower energy consumption and a 58% reduction in initial plant costs compared to traditional methods.
Article Abstract
As a byproduct of desalination plants, brine is increasingly becoming a threat to the environment, and the design of zero-liquid discharge (ZLD) systems is gaining increasing attention. Existing ZLD systems are limited by a high energy intensity and high plant costs of their crystallizers. This study proposes a novel crystallization method based on the humidification-dehumidification (HDH) process, which exhibits the advantages of a low energy consumption, low component costs and a reduced scaling and fouling potential. A simple experimental setup is first designed to demonstrate the feasibility of the proposed system. Brine concentration and salt crystallization are successfully achieved with air heated to 40 °C as the heat source. Afterwards, a thermo-economic analysis is conducted for the whole system. The specific thermal energy and electricity consumption levels are found to range from 700-900 and 5-11 kJ, respectively, per kg of feed brine. The energy consumption is 56% lower than that of a conventional evaporative crystallizer, and the initial plant cost is reduced by 58%.
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| http://dx.doi.org/10.1016/j.watres.2021.117794 | DOI Listing |
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Article Synopsis
- * Results show that high-salinity wastewater droplets are 20-50% larger than those from conventional wastewater, impacting evaporation rates and dynamics.
- * Despite slower evaporation rates, higher salinity leads to shorter total evaporation durations, resulting in reduced energy consumption and creating viscous evaporation products with poor flowability.
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