On the cost of electrodialysis for the desalination of high salinity feeds

McGovern, Ronan Killian; Weiner, Adam Michael; Sun, Lige; Chambers, Chester; Zubair, Syed M.; Lienhard, John H.

doi:10.1016/j.apenergy.2014.09.050

Cited by 153 publications

(119 citation statements)

References 34 publications

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“…Figure 9 shows that the decreasing area and the increasing velocity result in an increase in the optimal length with the cost ratio. We note that the membrane areas and the lengths reported are the effective area and length, and that real systems usually only use 65% of the total area effectively for mass transfer [26][27][28], so we expect the physical membrane area of these systems to be approximately 50% larger than the effective values reported above. We also note that the reported cost modeling is not dependent on the fraction of the area used effectively because it uses the effective cell-pair area.…”

Section: Optimal Operating Conditions At Different Cost Ratiosmentioning

confidence: 65%

“…This minimum is limited by practical difficulties in designing sealing frames and spacers [15]. For the following results, the channel height is set to 0.5 mm, which is a thickness already used in actual systems [26]. In addition, for each system size, the velocity is set such that the total power consumption is minimized.…”

Section: Equationmentioning

confidence: 99%

“…where the subscript 's' denotes the salt, the subscript 'w' denotes the water, J is the molar flux, i is the current density, c s,C,m is the salt concentration at the membrane interface in the concentrate channel, π D,m is the osmotic pressure at the membrane interface in the diluate channel, T s is the salt transport number, [26]. Each stage is a batch system which takes the diluate from a given salinity to another set salinity.…”

Section: Appendix B2 High-salinity Brine Concentrationmentioning

confidence: 99%

“…In modeling high-salinity brine concentration, the model developed by Fidaleo and Moresi [25] is used with coefficients measured by McGovern et al [26] at high salinity. The major points of this model are summarized in Appendix B.2.…”

Section: Modeling Electrodialysismentioning

confidence: 99%

“…were measured at high salinity by McGovern et al [26]. Finally, the potential drop across the membranes is calculated as the sum of the membrane ohmic potential drops and the Donnan potential:…”

Section: Appendix B2 High-salinity Brine Concentrationmentioning

confidence: 99%

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Optimal design and operation of electrodialysis for brackish-water desalination and for high-salinity brine concentration

et al. 2017

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Electrodialysis (ED) is a desalination technology that has been deployed commercially for decades. However, few studies in the literature have looked at the optimal design and operation of these systems, especially for the concentration of high-salinity brines. In this paper, a set of constraints is defined to allow a fair comparison between different system sizes, designs, and operating conditions. The design and operation of ED are studied for the applications of brackish-water desalination and of high-salinity brine concentration for a fixed system size. The set of variables that determine the power consumption of a fixed-size system is reduced to include only the channel height and the velocity, with all the other design and operation variables depending on these two variables. After studying the minimization of power consumption for a fixed system size, the minimum costs associated with the different system sizes are studied, and the differing trends in brackish-water and high-salinity applications are compared. Finally this paper presents the effect of the cost modeling parameters on the trends of the optimal system size, current density, length, channel height, and velocity for the two applications studied.

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Section: Optimal Operating Conditions At Different Cost Ratiosmentioning

confidence: 65%

Section: Equationmentioning

confidence: 99%

Section: Appendix B2 High-salinity Brine Concentrationmentioning

confidence: 99%

Section: Modeling Electrodialysismentioning

confidence: 99%

Section: Appendix B2 High-salinity Brine Concentrationmentioning

confidence: 99%

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Optimal design and operation of electrodialysis for brackish-water desalination and for high-salinity brine concentration

et al. 2017

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Analysis and optimization of concentrated solar power plant for application in arid climate

Elbeh

Sleiti

2021

Energy Science & Engineering

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In this research study, the concentrated solar power (CSP) technology is reviewed for designing and optimizing a CSP tower plant for arid climate regions such as Qatar.A database for all CSP projects around the world is created, and a spreadsheet model for calculating the available solar irradiance is developed. Two software packages are used for analyzing and optimizing the entire solar thermal plant and its cost, SolarPILOT, and System Advisor Model (SAM). Both packages are validated using data from a recent power tower project. A thorough iterative optimization process was developed and applied to optimize the solar field parameters of a suggested CSP plant including tower optical height; heliostat structure width and height; number of heliostats; horizontal and vertical panels; receiver height and diameter; water consumption; cleaning schedule; maintenance; and total cost. The results confirmed the feasibility of a CSP plant on 0.45 km 2 of a solar field area with 2736 heliostats that produce 8 MW e with 10 hours of thermal storage and hybrid steam condensing system. It has been found that the highest production of the plant is in July, which is 3 621 950 kWh and the highest excess of electrical energy is in March, which is 2 946 965 kWh.

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