Development of the design and determination of the mode characteristics of the demineralizer for sea water
Creators
- 1. Odessa National Academy of Food Technologies
- 2. Odessa State Agrarian University
- 3. Hunan University of Humanities, Science and Technology
- 4. Henan Institute of Science and Technology
- 5. Research and Design Institute for Standardization and Technology of Eco-Friendly and Organic Products
Description
The object of research is block low-temperature installations for obtaining fresh water. Investigated problem: obtaining fresh water from sea using low-temperature technologies. Main scientific results: the design is developed and the operating characteristics of the demineralizer for sea water are determined. The influence of the initial salt content of sea water on the ice formation rate is determined. With an increase in the salinity of 3.5 times, productivity on ice decreases 2.3 times. The kinetics of the salt content in the freezing solution depends on the initial concentration. With an initial salt content of 6.74 g/l, the process rate is 0.4 g/h, with a salt content of 1 g/l – 0.14 g/h With an initial salt content of 6.74 g/l, the process of separating wastewater from the ice block is more intensive. The salt content of the first portion of the effluent is 3.2 times higher than the initial concentration of the solution. A cryoscopic curve was obtained for seawater in the concentration range from 0 to 6.74 g/l. The area of practical use of the research results: studies of the quality of the obtained water showed that the content of nitrates decreases 5 times, the hardness decreases by 2 mg/dm³. The salt content is reduced from 858 mg/dm³ to 560 mg/dm³. Plants for the concentration of food liquids by the block freezing method are designed to produce environmentally friendly products that preserve the bioactive complex of raw materials as much as possible with minimal energy consumption. An innovative technological product: design and operating modes of a block freezing plant for seawater desalination. Scope of application of the innovative technological product: industrial enterprises, the technological process of which requires small volumes of fresh water; to obtain fresh water on oil platforms in the oceans; small hotels, boarding houses on the seaside.
Files
DEVELOPMENT OF THE DESIGN AND DETERMINATION OF THE MODE CHARACTERISTICS OF THE DEMINERALIZER FOR SEA WATER.pdf
Files
(862.8 kB)
Name | Size | Download all |
---|---|---|
md5:8b1b595a0061e77b8c6ee3db2e94c7c8
|
862.8 kB | Preview Download |
Additional details
References
- Lin, S., Zhao, H., Zhu, L., He, T., Chen, S., Gao, C., Zhang, L. (2021). Seawater desalination technology and engineering in China: A review. Desalination, 498, 114728. doi: http://doi.org/10.1016/j.desal.2020.114728
- Elimelech, M., Phillip, W. A. (2011). The Future of Seawater Desalination: Energy, Technology, and the Environment. Science, 333(6043), 712–717. doi: http://doi.org/10.1126/science.1200488
- Leijon, J., Boström, C. (2018). Freshwater production from the motion of ocean waves – A review. Desalination, 435, 161–171. doi: http://doi.org/10.1016/j.desal.2017.10.049
- Xie, C., Zhang, L., Liu, Y., Lv, Q., Ruan, G., Hosseini, S. S. (2018). A direct contact type ice generator for seawater freezing desalination using LNG cold energy. Desalination, 435, 293–300. doi: http://doi.org/10.1016/j.desal.2017.04.002
- Ong, C. W., Chen, C.-L. (2019). Technical and economic evaluation of seawater freezing desalination using liquefied natural gas. Energy, 181, 429–439. doi: http://doi.org/10.1016/j.energy.2019.05.193
- Liu, Y., Ming, T., Wu, Y., de Richter, R., Fang, Y., Zhou, N. (2020). Desalination of seawater by spray freezing in a natural draft tower. Desalination, 496, 114700. doi: http://doi.org/10.1016/j.desal.2020.114700
- Doornbusch, G., van der Wal, M., Tedesco, M., Post, J., Nijmeijer, K., Borneman, Z. (2021). Multistage electrodialysis for desalination of natural seawater. Desalination, 505, 114973. doi: http://doi.org/10.1016/j.desal.2021.114973
- Voutchkov, N. (2018). Energy use for membrane seawater desalination – current status and trends. Desalination, 431, 2–14. doi: http://doi.org/10.1016/j.desal.2017.10.033
- Alawad, S. M., Khalifa, A. E. (2021). Performance and energy evaluation of compact multistage air gap membrane distillation system: An experimental investigation. Separation and Purification Technology, 268, 118594. doi: http://doi.org/10.1016/j.seppur.2021.118594
- Fujiwara, M., Takahashi, K., Takagi, K. (2021). Improvement of condensation step of water vapor in solar desalination of seawater and the development of three-ply membrane system. Desalination, 508, 115051. doi: http://doi.org/10.1016/j.desal.2021.115051
- Rich, A., Mandri, Y., Mangin, D., Rivoire, A., Abderafi, S., Bebon, C. et. al. (2012). Sea water desalination by dynamic layer melt crystallization: Parametric study of the freezing and sweating steps. Journal of Crystal Growth, 342 (1), 110–116. doi: http://doi.org/10.1016/j.jcrysgro.2011.03.061
- Burdo, O. H., Reminna, L. P., Kovalenko, O. O. (2008). Pat. No. 34280 UA. Sposib otrymannia kontsentrovanykh ridkykh produktiv shliakhom vymorozhuvannia. MPK: A23L 2/08. No. u200801496; declareted: 05.02.2008; published: 11.08.2008, Bul. No. 15. Available at: https://uapatents.com/3-34280-sposib-otrimannya-koncentrovanikh-ridkikh-produktiv-shlyakhom-vimorozhuvannya.html