A zero liquid discharge system integrating multi-effect distillation and evaporative crystallization for desalination brine treatment

The need for sustainable desalination arises from fast-occurring global warming and intensifying droughts due to increasing temperatures, particularly in the Middle East and North African (MENA) regions. Lack of water resources has meant that the countries in these regions have had to desalinate seawater through different sustainable technologies for food supplies and agricultural products. Greenhouses (GH) are used to protect crops from harsh climates, creating a controlled environment requiring less water. In order to have a sustainable resilient GH, a zero-liquid-discharge system (ZLD) was developed by using solar still (SS) desalination techniques, humidification-dehumidification (HDH), and rainwater harvesting. An experiment was designed and carried out by designing and manufacturing a wick type solar still, together with an HDH system, implemented into a GH. Using a pyrometer, the solar intensity was recorded, while the microclimate conditions (temperature and relative humidity) of the GH were also monitored. The GH model was tested in the UK and was shown to be a successful standalone model, providing its water requirements. In the UK, for one solar still with a surface area of 0.72 m2, maximum amount of 58 mL of distilled water was achieved per day. In Egypt, a maximum amount of 1090 mL water was collected per day, from each solar still. This difference is mainly due to the differences in the solar radiation intensity and duration in addition to the temperature variance. While dehumidification generated 7 L of distilled water, rainwater harvesting was added as another solution to the greenhouse in the UK, harvested a maximum of 7 L per day from one side (half the area of the greenhouse roof). This helped to compensate for the less distilled water from the solar stills. The results for the developed greenhouses showed how GHs in countries with different weather conditions could be standalone systems for their agricultural water requirement.

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Intensification of degradation of Sunset Yellow using packed bed in a pulsed high-voltage hybrid gas-liquid discharge system: Optimization of operating parameters, degradation mechanism and pathways

Chemical Engineering and Processing - Process Intensification ◽

10.1016/j.cep.2017.02.006 ◽

2017 ◽

Vol 115 ◽

pp. 23-33 ◽

Cited By ~ 3

Author(s):

Zhiyong Zhou ◽

Zhongrui Liang ◽

Ying Liu ◽

Yuepeng Ma ◽

Xinyan Zhu ◽

...

Keyword(s):

High Voltage ◽

Degradation Mechanism ◽

Packed Bed ◽

System Optimization ◽

Operating Parameters ◽

Sunset Yellow ◽

Discharge System ◽

Liquid Discharge

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Designing a next generation solar crystallizer for real seawater brine treatment with zero liquid discharge

Nature Communications ◽

10.1038/s41467-021-21124-4 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Chenlin Zhang ◽

Yusuf Shi ◽

Le Shi ◽

Hongxia Li ◽

Renyuan Li ◽

...

Keyword(s):

Evaporation Rate ◽

Low Cost ◽

High Water ◽

Water Evaporation ◽

Salt Crystallization ◽

Great Promise ◽

Liquid Discharge ◽

Brine Disposal ◽

Crystallization Inhibitor ◽

Brine Treatment

AbstractProper disposal of industrial brine has been a critical environmental challenge. Zero liquid discharge (ZLD) brine treatment holds great promise to the brine disposal, but its application is limited by the intensive energy consumption of its crystallization process. Here we propose a new strategy that employs an advanced solar crystallizer coupled with a salt crystallization inhibitor to eliminate highly concentrated waste brine. The rationally designed solar crystallizer exhibited a high water evaporation rate of 2.42 kg m−2 h−1 under one sun illumination when treating real concentrated seawater reverse osmosis (SWRO) brine (21.6 wt%). The solar crystallizer array showed an even higher water evaporation rate of 48.0 kg m−2 per day in the outdoor field test, suggesting a great potential for practical application. The solar crystallizer design and the salt crystallization inhibition strategy proposed and confirmed in this work provide a low-cost and sustainable solution for industrial brine disposal with ZLD.

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Renewable Thermal Energy Driven Desalination Process for a Sustainable Management of Reverse Osmosis Reject Water

Sustainability ◽

10.3390/su131910860 ◽

2021 ◽

Vol 13 (19) ◽

pp. 10860

Author(s):

Kawtar Rahaoui ◽

Hamid Khayyam ◽

Quoc Linh Ve ◽

Aliakbar Akbarzadeh ◽

Abhijit Date

Keyword(s):

Reverse Osmosis ◽

Mass Flux ◽

Sustainable Management ◽

Membrane Distillation ◽

Water Volume ◽

Feed Water ◽

Crystal Formation ◽

Discharge System ◽

Reject Water ◽

Liquid Discharge

A sustainable circular economy involves designing and promoting products with the least environmental impact. This research presents an experimental performance investigation of direct contact membrane distillation with feed approaching supersaturation salinity, which can be useful for the sustainable management of reverse osmosis reject water. Traditionally, reject water from the reverse osmosis systems is discharged in the sea or in the source water body. The reinjection of high salinity reject water into the sea has the potential to put the local sea environment at risk. This paper presents a design of a solar membrane distillation system that can achieve close to zero liquid discharge. The theoretical and experimental analysis on the performance of the lab scale close to zero liquid discharge system that produces supersaturated brine is studied. The lab-based experiments were conducted at boundary conditions, which were close to the real-world conditions where feed water temperatures ranged between 40 °C and 85 °C and the permeate water temperatures ranged between 5 °C and 20 °C. The feed water was supplied at salinity between 70,000 ppm to 110,000 ppm, similar to reject from reverse osmosis. The experimental results show that the maximum flux of 17.03 kg/m2·h was achieved at a feed temperature of 80 °C, a feed salinity of 10,000 ppm, a permeate temperature of 5 °C and at constant feed and a permeate flow rate of 4 L/min. Whereas for the same conditions, the theoretical mass flux was 18.23 kg/m2·h. Crystal formation was observed in the feed tank as the feed water volume reduced and the salinity increased, reaching close to 308,000 ppm TDS. At this condition, the mass flux approached close to zero due to crystallisation on the membrane surface. This study provides advice on the practical limitations for the use of membrane distillation to achieve close to zero liquid discharge.

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