Experimental investigation on a floating multi-effect solar still with rising seawater film

In this paper, a floating multi-effect solar still using parabolic concentrators to directly heat rising seawater film is investigated. The novel desalination device integrates solar still and two concentrators as a whole, which avoids the installation of a heat exchange pipeline and can float on the ocean to produce freshwater. The floating still consists of a front parabolic concentrator, a rear parabolic concentrator, and several embedded distillation cells. The distillation cell is composed of a hydrophilic wick, a condensing plate, and a narrow space in between. The parabolic concentrator greatly increases the solar heat to improve the temperature gradient and enhance the phase transition and diffusion process of water vapor. During desalination, the rising seawater film for evaporation is formed in the hydrophilic wick by capillary force. Through indoor steady-state experiments, some key parameters such as solar irradiance and incident angle on the temperature, water yield and gain output ratio (GOR) of the still were studied. Results indicate that the maximum temperature gradient in the 5-effect still can reach 48.5 degrees C. Under a 900 W/m(2) irradiation, the water productivity and GOR are 2.7 kg/m(2)/h and 2.2, respectively. Additionally, outdoor experiments show that the daily freshwater reaches 4.7 kg/m(2) with an average irradiation of 543 W/m(2). (C) 2022 Elsevier Ltd. All rights reserved.

Automated summary

In this paper, a floating multi-effect solar still using parabolic concentrators to directly heat rising seawater film is studied. The device integrates solar still and two concentrators, eliminating the need for a heat exchange pipeline and allowing it to float on the ocean to produce freshwater. Indoor and outdoor experiments were conducted to investigate the influence of solar irradiance and incident angle on the performance of the still. The results show that the still has high water productivity and gain output ratio under a certain irradiation.