Seawater Desalination Process Research Articles

Enhancement of membrane distillation in seawater desalination process using inhomogeneous electric field

Enhancement of membrane distillation in seawater desalination process using inhomogeneous electric field

Literature review on the application of graphene in the field of seawater desalination

Seawater desalination technology is an important solution to global water scarcity, yet conventional methods such as reverse osmosis (RO) and distillation face challenges including high energy consumption and costly infrastructure. Graphene, as a novel nanomaterial, has demonstrated promising application prospects in desalination due to its unique physical and chemical properties. This study focuses on the applications of graphene in seawater desalination. Through comprehensive collection, organization, and analysis of relevant literature, the promotion effect of graphene on seawater desalination process in various forms such as permeable membrane and photothermal conversion membrane is analyzed and summarized. Finally, the existing research results, shortcomings and future development directions of graphene in the field of seawater desalination are summarized.

Pre-Design and Environmental Impact Analysis of Methanol Plant from Natural Gas with Dielectric Barrier Discharge Reactor

In Indonesia, the demand for methanol reaches 1.1 million tons per year, with the majority being fulfilled through imports. The formaldehyde industry is the primary consumer, using 80% of the total methanol consumption. Increasing domestic methanol production has become crucial due to dependency on imports and the presence of only one producer with a capacity of 660,000 tons per year. The preliminary design of a low-emission methanol plant is a first step toward a more environmentally friendly methanol industry in Indonesia, aiming to reduce carbon emissions and dependence on fossil fuels. Methanol production at this plant results in the lowest possible carbon emissions, using raw materials such as methane gas, purified water, and helium. The methane gas is sourced from pure liquified natural gas (LNG) from PT Badak NGL, which has been purified from CO2 and H2S under operating conditions of -162°C and 1 bar pressure. Meanwhile, the purified water is obtained through seawater desalination processes. The reaction between methane and purified water occurs in a dielectric barrier discharge (DBD) reactor at 1 bar pressure, with helium as the inert gas. The plant's production capacity reaches 500,000 tons per year, with a purity level of 99.95% and zero greenhouse gas emissions. To achieve profitability comparable to conventional methanol, a minimum methanol selling price of $970/ton is required. When the carbon credit price is $1200/tCO2, the methanol produced by this plant will be more profitable for investors compared to conventional methanol production or methanol production using carbon capture and utilization technology.

Construction of energy consumption monitoring system for energy saving equipment in seawater desalination based on whale algorithm

ABSTRACT Seawater desalination has emerged as a pivotal solution to address freshwater scarcity in coastal regions, with China being a prominent adopter of this technology. This paper compares three large-scale seawater desalination projects in China: the Six Heng Water Treatment Plant, the Caofeidian Desalination Project, and the Huaihai Yu Huan Power Plant Desalination Project. Each project employs distinct desalination technologies, including reverse osmosis and dual-membrane processes. We evaluate these systems’ operational parameters, performance indicators, and cost-effectiveness over their operational lifespans. Key considerations include seawater intake, pretreatment processes, reverse osmosis desalination, energy recovery systems, and post-treatment mineralisation. The analysis highlights these desalination plants’ efficiency, sustainability, and economic viability in addressing freshwater demands in their respective regions. Insights from this comparative study contribute to optimising seawater desalination processes, enhancing water resource management, and guiding future infrastructure development efforts in coastal areas.

Activated carbon aerogel evaporator for simultaneous salt-rejection and inhibition of phenol from entering condensed freshwater during solar-driven seawater desalination

Activated carbon aerogel evaporator for simultaneous salt-rejection and inhibition of phenol from entering condensed freshwater during solar-driven seawater desalination

A 3D Janus-like structure evaporator based on capillary force promoting efficient solar steam generation

A 3D Janus-like structure evaporator based on capillary force promoting efficient solar steam generation

Occurrence, toxicity, and control of halogenated aliphatic and phenolic disinfection byproducts in the chlorinated and chloraminated desalinated water

Occurrence, toxicity, and control of halogenated aliphatic and phenolic disinfection byproducts in the chlorinated and chloraminated desalinated water

A Review of Renewable Energy Powered Seawater Desalination Treatment Process for Zero Waste

Freshwater resources have faced serious threats in recent decades, primarily due to rapid population growth and climate change. Seawater desalination has emerged as an essential process to ensure a sustainable supply of freshwater to meet the global demand for freshwater. However, this approach has some shortcomings, such as the disposal of brines containing high levels of contaminants creating environmental problems, and the energy-intensive nature of desalination, primarily powered by fossil fuels, which contribute to greenhouse gas emissions. Consequently, as a solution, the zero liquid discharge approach has been identified by the body of research to be one of the viable methods to solve these problems. Over 90% of freshwater and reusable salts could be recovered through this approach. Adopting renewable energy-powered systems could make zero-liquid discharge desalination plants operate in an entirely environmentally friendly and sustainable manner. This review explores the integration of renewable energy-powered systems for the optimisation of seawater desalination treatment processes for zero-waste and improved productivity. The review also examines technologies and strategies that improve the efficiency and sustainability of desalination systems. By analysing recent research, we provide insights into the advancements, challenges, and prospects for optimizing renewable energy-powered seawater desalination processes aimed at achieving zero waste.

A new suggestion to marine gold extraction: Utilizing reduced graphene oxide membranes within seawater desalination processes

A new suggestion to marine gold extraction: Utilizing reduced graphene oxide membranes within seawater desalination processes

Constructing spherical-beads-on-string structure of electrospun membrane to achieve high vapor flux in membrane distillation

Constructing spherical-beads-on-string structure of electrospun membrane to achieve high vapor flux in membrane distillation

Optimization of seawater desalination processes with the ideal reverse osmosis equation

Optimization of seawater desalination processes with the ideal reverse osmosis equation

Response to discussion of “Comprehensive simulation to uncover the ideal properties of a hollow fiber forward osmosis membrane module for the seawater desalination process”

Response to discussion of “Comprehensive simulation to uncover the ideal properties of a hollow fiber forward osmosis membrane module for the seawater desalination process”

Evaluating the photochemical reactivity of disinfection byproducts formed during seawater desalination processes

Evaluating the photochemical reactivity of disinfection byproducts formed during seawater desalination processes

Scalable Carbon Black‐Enabled Membranes for Sustainable Solar Membrane Desalination

AbstractSolar energy is used worldwide for generating electricity or desalting seawater. Photothermal membrane distillation (PMD), an emerging thermal‐driven process for seawater desalination, combines interfacial heating with membrane distillation (MD) technology to address the energy consumption issues of conventional MD. However, it is still a great challenge to develop a cost‐effective and scalable membrane, which hampers the practical use of PMD. Herein, a dual‐layer carbon black (CB)/PVDF membrane is prepared via direct electrospraying on a commercial PVDF membrane. With the introduction of a functional layer, a photothermal effect is imparted to the bare membrane, thus significantly increasing the water production rate and solar utilization efficiency (SUE) during exposure to artificial sunlight (≈57% enhancement and 72% SUE under 1 sun). In addition to the outstanding photothermal properties, this functional layer also served as a passivation coating to synergistically reduce the crystallization rate and physical binding of inorganic salts on the modified membrane without adding hazardous chemicals or using laborious steps. This multifunctional coated membrane and fast‐growing solar desalination technology provides a promising solution to the water crisis, especially in off‐grid areas where energy and resources are both relatively insufficient.

RETRACTED: A Study on Life Cycle Impact Assessment of Seawater Desalination Systems: Seawater Reverse Osmosis Integrated with Bipolar-Membrane-Enhanced Electro-Dialysis Process

A lot of research has been carried out to improve the sustainability of seawater desalination. Despite progress, relatively few studies have analyzed the sustainability of seawater desalination processes integrated on two fronts, i.e., (i) process integration and (ii) energy integration. In addition, life cycle assessment studies on multi-stage flash (MSF) desalination often neglect the impact of the disposed brine by assuming that dilution of the discharged brine impacts on ecological systems less. The present study contributes to these omissions by exploring the environmental sustainability of seawater desalination systems using life cycle impact assessment (LCIA). More specifically, the LCIA of Seawater Reverse Osmosis (SWRO) integrated with (i) an Electro-Dialysis (EDBMED) process and (ii) solar photovoltaics (PV) is investigated. Life cycle analysis was used to identify pertinent indicators of the LCIA and their implications in SWRO. The comparative analysis reveals that the advantage of SWRO as compared to other technologies such as MSF is energy efficiency, at estimated levels of 75.0%. The study concludes that despite the technological challenges associated with sustainable desalination and sustainable brine management, integrating renewable energy into seawater desalination can contribute to the sustainability improvements of seawater desalination systems. The findings of this paper provide an initial assessment of the ecological footprints of seawater desalination systems.

A Lotus Seedpods-Inspired Interfacial Solar Steam Generator with Outstanding Salt Tolerance and Mechanical Properties for Efficient and Stable Seawater Desalination.

Interfacial solar steam generators (ISSGs) can capture solar energy and concentrate the heat at the gas-liquid interface, resulting in efficient water evaporation. However, traditional ISSGs have limitations in long-term seawater desalination processes, such as limited light absorption area, slow water transport speed, severe surface salt accumulation, and weak mechanical performance. Inspired by lotus seedpods, a novel ISSG (rGO-SA-PSF) is developed by treating a 3D warp-knitted spacer fabric with plasma (PSF)and combining it with sodium alginate (SA) and reduces graphene oxide (rGO). The rGO-SA-PSF utilizes a core-suction effect to achieve rapid water pumping and employs aerogel to encapsulate the plasma-treated spacer yarns to create the lotus seedpod-inspired hydrophilic stems, innovatively constructing multiple directional water transport channels. Simultaneously, the large holes of rGO-SA-PSF on the upper layer form lotus seedpod-inspired head concave holes, enabling efficient light capture. Under 1kWm-2 illumination, rGO-SA-PSF exhibits a rapid evaporation rate of 1.85kgm-2 h-1 , with an efficiency of 96.4%. Additionally, it shows superior salt tolerance (with no salt accumulation during continuous evaporation for 10 h in 10% brine) and self-desalination performance during long-term seawater desalination processes. This biomimetic ISSG offers a promising solution for efficient and stable seawater desalination and wastewater purification.

An efficient data-driven desalination approach for the element-scale forward osmosis (FO)-reverse osmosis (RO) hybrid systems

An efficient data-driven desalination approach for the element-scale forward osmosis (FO)-reverse osmosis (RO) hybrid systems

Double-photoelectrode redox desalination of seawater

High energy consumption and low salt removal rate are key barriers to realizing practical electrochemical seawater desalination processes. Here, we demonstrate a novel solar-driven redox flow desalination device with double photoelectrodes to achieve efficient desalination without electrical energy consumption. The device consists of three parts: one photoanode unit, one photocathode unit, and one redox flow desalination unit sandwiched between the two photoelectrode units. The photoelectrode units include a TiO2 photoanode and a NiO photocathode sensitized with N719 dye, triiodide/iodide redox electrolyte, and graphite paper integrated electrodes decorated with 3,4-ethylene-dioxythiophene. Two salt feeds are located between two ferro/ferricyanide redox flow chambers. Under light illumination, high-quality freshwater is obtained from brackish water containing different concentrations of NaCl from 1000 to 12,000 ppm with a high NaCl removal rate. The device can work in multiple desalination cycles without significant performance declines. Furthermore, natural seawater with an ionic conductivity of 53.45 mS cm−1 is desalinated to freshwater. This new design opens opportunities to realize efficient and practical solar-driven desalination processes.

Materials and Corrosion in Seawater Reverse Osmosis Plants: A Review

Desalination is emerging as one of the most promising solutions to extraction and increasing global demand for drinking water. A water purification process called reverse osmosis (RO), in which dissolved solids are separated from solutions by partially permeable membranes. Advances in membrane technology have resulted in the removal of up to 99% of salts in seawater. However, the process and system of seawater treatment RO are associated with many problems, such as scaling and fouling of the membranes, corrosion of the pumps, valves and piping system due to the highly concentrated salt solution and high chemical consumption. Nowadays, these problems have become very critical as they severely affect the desalination process and also massively deteriorate the performance and lifetime of the system components and materials. To ensure that the desalination process is always the best option for a low-maintenance, highly efficient and cost-effective system and process, a comprehensive study of these problems is essential. Therefore, this article addresses the characteristics of metallic materials and corrosion problems in the reverse osmosis process of seawater desalination, as well as the best solutions to focus on and evaluate for an optimal seawater desalination process, and the selection of the category of duplex stainless steels suitable for seawater desalination plants to reduce maintenance, avoid plant shutdown and ensure plant safety.

Process design and technoeconomic analysis for zero liquid discharge desalination via LiBr absorption chiller integrated HDH-MEE-MVR system

Process design and technoeconomic analysis for zero liquid discharge desalination via LiBr absorption chiller integrated HDH-MEE-MVR system