Dezembro 2024 vol. 11 num. 2 - X Simpósio Internacional de Inovação e Tecnologia

Full Article - Open Access.

Idioma principal | Segundo idioma

CASCADE-TYPE SOLAR DISTILLER FOR BRACKISH WATER POTABILIZATION

CASCADE-TYPE SOLAR DISTILLER FOR BRACKISH WATER POTABILIZATION

Lima, Carlos Antônio Pereira de ; Silva, Camylla Barbosa ; Silva, Karyna Steffane da ; Medeiros, Keila Machado de ;

Full Article:

"Solar distillers are excellent means of obtaining fresh water and this studypresents the results of using a cascade-type solar distiller to remove salts andimpurities from groundwater. Using this model, a maximum hourly productivity of269.23 mL.m-2and an accumulated productivity per distillation unit area of 3,025.40mL.m-2.day-1 were achieved. Furthermore, all the physical-chemical parametersanalyzed showed significant reductions, falling below the maximum values permittedby national and international legislation. Therefore, the model presents itself as agood alternative for obtaining fresh water for isolated communities, with low cost,easy operation and high yield."

Full Article:

"Solar distillers are excellent means of obtaining fresh water and this studypresents the results of using a cascade-type solar distiller to remove salts andimpurities from groundwater. Using this model, a maximum hourly productivity of269.23 mL.m-2and an accumulated productivity per distillation unit area of 3,025.40mL.m-2.day-1 were achieved. Furthermore, all the physical-chemical parametersanalyzed showed significant reductions, falling below the maximum values permittedby national and international legislation. Therefore, the model presents itself as agood alternative for obtaining fresh water for isolated communities, with low cost,easy operation and high yield."

Download (PDF)

Palavras-chave: Solar distillation, Salt removal, Fresh water,

Palavras-chave: Solar distillation, Salt removal, Fresh water,

DOI: 10.5151/siintec2024-393207

Referências bibliográficas
  • [1] "1ALMAJALI, T. A. H.; ISMAIL, F. B.; KAZEM, H. A.; GUNNASEGARAN, P. A. L.;
  • [2] SHURAFA, S. M. Al; AL-MUHSEN, N. F. O. Enhanced water production and
  • [3] improving solar water distillation efficiency of double-slope solar stills: modeling and
  • [4] validation. Thermal Science And Engineering Progress, v. 53, p. 102712, 202
  • [5] http://dx.doi.org/10.1016/j.tsep.2024.102712.
  • [6] 2NEGI, A.; RANAKOTI, L.; BHANDARI, P.; KHARGOTRA, R.; SINGH, T. Thermophysical characteristics and storage material compatibility in nano-enhanced phase
  • [7] change materials for solar distillation applications: a critical assessment. Solar
  • [8] Energy Materials And Solar Cells, v. 271, p. 112870, 2024.
  • [9] http://dx.doi.org/10.1016/j.solmat.2024.112870.
  • [10] 3SUN, W.; LIU, Z.; LIU, Y.; WANG, Z. Enhancing freshwater production with a highperformance solar interface evaporator and in low-vacuum environment: a solardriven low-vacuum interfacial distillation system. Desalination, v. 568, p. 117014,
  • [11] 2023. http://dx.doi.org/10.1016/j.desal.2023.117014.
  • [12] 4
  • [13] TIAN, S.; LI, X.; REN, J.; ZHOU, Z.; WANG, F.; SHI, K.; XU, J.; GU, T.; SHON, H.
  • [14] Emerging heat-localized solar distillation systems: solar interfacial distillation vs
  • [15] photothermal membrane distillation. Desalination, v. 572, p. 117147, 2024.
  • [16] http://dx.doi.org/10.1016/j.desal.2023.117147. 5
  • [17] FANG, S.; TU, W.; LU, W. Artificial intelligence vision technology application in
  • [18] sustainability evaluation of solar-driven distillation device. Environmental
  • [19] Technology & Innovation, v. 36, p. 103731, 2024.
  • [20] http://dx.doi.org/10.1016/j.eti.2024.103731.
  • [21] 6BOUZAID, M.; ANSARI, O.; TAHA-JANAN, M.; MOUHSIN, N.; OUBREK, M.
  • [22] Numerical Analysis of Thermal Performances for a Novel Cascade Solar
  • [23] Desalination Still Design. Energy Procedia, v. 157, p. 1071-1082, 2019.
  • [24] http://dx.doi.org/10.1016/j.egypro.2018.11.274.
  • [25] 7SHARSHIR, S. W.; OMARA, M. A.; ELSISI, G.; JOSEPH, A.; KANDEAL, A. W.; ALI,
  • [26] A.; BEDAIR, G. Thermo-economic performance improvement of hemispherical solar
  • [27] still using wick material with V-corrugated basin and two different energy storage
  • [28] materials. Solar Energy, v. 249, p. 336-352, 2023.
  • [29] http://dx.doi.org/10.1016/j.solener.2022.11.038.
  • [30] 8RAMOS, R. O.; LIMA, C. A. P.; CAVALCANTE, G. G.; MEDEIROS, K. M. Multianalysis Integrated System with Connectivity and Datalogger Function for Monitoring
  • [31] Solar Desalination Stations and Other Water and Effluent Treatment Systems (2021).
  • [32] Patent: Privilege of Innovation. Depositor: State University of Paraíba. Registration
  • [33] number: BR1020210075996. Registration institution: INPI - National Institute of
  • [34] Industrial Property. Brazil.
  • [35] 9BAIRD, R. B.; EATON, A. D.; RICE, E. W. Standard Methods for the Examination
  • [36] of Water and Wastewater. 1496 p. 23th edition. Washington, USA: American Public
  • [37] Health Association, 2017.
  • [38] 10ESFE, M. H.; ESFANDEH, S.; KAMYAB, M. H.; TOGHRAIE, D. Simulation of the
  • [39] impact of solar radiation intensity on the performance of economical solar water
  • [40] desalination still in Semnan province. Case Studies in Thermal Engineering, v. 28,
  • [41] 101471, 2021. https://doi.org/10.1016/j.csite.2021.101471.
  • [42] 11HAFS, H.; ANSARI, O.; BAH, A. Impact of wind-driven mixed convection on the
  • [43] performance of passive solar desalination with PCM heat storage in varied Moroccan
  • [44] climates. Ecological Frontiers, v. 44, n. 1, p. 73-83, 2024.
  • [45] http://dx.doi.org/10.1016/j.chnaes.2023.07.001.
  • [46] 12
  • [47] TOOSI, S. S. A.; GOSHAYESHI, H. R.; ZAHMATKESH, I.; NEJATI, V.
  • [48] Experimental assessment of new designed stepped solar still with Fe3O4 + graphene
  • [49] oxide + paraffin as nanofluid under constant magnetic field. Journal of Energy
  • [50] Storage, v. 62, 106795, 2023. https://doi.org/10.1016/j.solener.2024.112385.
  • [51] 13SAHA, S.; SARKER, M. R. I.; KADER, M. A.; AHMED, M. A.; TULY, S. S.;
  • [52] MUSTAFT. Development of a vacuum double-slope solar still for Enhanced
  • [53] freshwater productivity. Solar Energy, v. 270, 112385, 2024.
  • [54] https://doi.org/10.1016/j.solener.2024.112385.
  • [55] 14BRAZIL, Official Gazette of the Union. Ministry of Health/Minister's Office 2021.
  • [56] ORDINANCE GM/MS No. 888, of May 4, 2021.
  • [57] 15WHO Guidelines for drinking-water quality: fourth edition incorporating the first
  • [58] addendum 2017. Geneva: World Health Organization; Licence: CC BY-NC-SA 3.0
  • [59] IGO."
Como citar:

Lima, Carlos Antônio Pereira de; Silva, Camylla Barbosa; Silva, Karyna Steffane da; Medeiros, Keila Machado de; "CASCADE-TYPE SOLAR DISTILLER FOR BRACKISH WATER POTABILIZATION", p. 864-871 . In: . São Paulo: Blucher, 2024.
ISSN 2357-7592, DOI 10.5151/siintec2024-393207

últimos 30 dias | último ano | desde a publicação


downloads


visualizações


indexações