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Capacitive Mixing for Extracting Concentration Gradient Energy
KTH, School of Engineering Sciences in Chemistry, Biotechnology and Health (CBH), Chemical Engineering.ORCID iD: 0000-0002-1781-4399
2022 (English)Doctoral thesis, comprehensive summary (Other academic)
Abstract [en]

Capacitive mixing (CapMix) is a renewable method of extracting energy from the salinity gradient energy (SGE) between seawater and freshwater. The classical CapMix systems using solid electrodes generate electricity by periodically circulating seawater and freshwater into the CapMix system. The major limitation of classical CapMix is intermittent energy production. Therefore, the development of a new CapMix system to solve this limitation is highly desired. This thesis aims to develope an innovative CapMix system for continuous energy production. All the work is based on four papers and can be divided into the following parts.

In Chapter 1, a brief introduction to the SGE and CapMix is presented. 

In Chapter 2, a comparative study on the four classical CapMix systems, namely, capacitive energy extraction based on double layer expansion (CDLE), capacitive energy extraction based on the Donnan potential (CDP), and CDP with additional charging of constant voltage (CDP-CV) and constant current (CDP-CC)., is discussed. The influences of experimental parameters, e.g., applied voltage, applied current, accumulated charge, and the external load on the system performance, were systematically investigated and presented. A comprehensive comparison between these four classical CapMix systems is also given in this chapter.

Chapter 3 and Chapter 4 describe two novel CapMix systems based on flow electrode (F-CapMix) configuration which were developed to realize continuous energy production. The first one is a two-cell F-CapMix system, in which the flow electrode slurry was circulated between the two cells. The second is a one-cell F-CapMix system with cross chambers, in which there are two chambers between one pair of plates in parallel; the flow electrode slurry was circulated within the two graphite plates of the cell. The feasibility of these two F-CapMix systems was examined. The effect of the experimental parameters, e.g., activated carbon loading, carbon black amount, external resistance, feedwater flow rate, and flow electrode flow rate, on the system performance were systematically investigated and presented. 

In Chapter 5, a thorough study of the theoretical models related to the thermodynamic properties of the electric double layer at equilibrium, e.g., the Gouy-Chapman-Stern (GCS), Modified Poisson-Boltzmann-Stern (MPBS), modified Donnan (mD) and improved modified Donnan (i-mD) models is presented. The rationality and the physical interpretation of the parameters used in these models were detailed investigated and presented.

Abstract [sv]

Kapacitiv blandning (CapMix) är en förnybar metod för att utvinna energi från salthaltsgradientenergin (SGE) mellan havsvatten och sötvatten. De klassiska CapMix-systemen som använder solida elektroder genererar elektricitet genom att periodiskt strömma havsvatten och sötvatten in i CapMix-systemet. Den största begränsningen för klassisk CapMix är den intermittenta energiproduktionen. Därför är utvecklingen av ett nytt CapMix-system för att lösa denna begränsning mycket önskvärt. Detta examensarbete syftar till att utveckla ett innovativt CapMix-system för kontinuerlig energiproduktion. Allt arbete bygger på fyra papper och kan delas upp i följande delar. 

I kapitel 1 presenteras en kort introduktion till SGE och CapMix. 

I kapitel 2, en jämförande studie av de fyra klassiska CapMix-systemen, nämligen kapacitiv energiextraktion baserad på dubbelskiktsexpansion (CDLE), kapacitiv energiextraktion baserad på Donnan-potentialen (CDP) och CDP med ytterligare laddning av konstant spänning (CDP) -CV) och konstant ström (CDP-CC). Inverkan av experimentella parametrar, t.ex. pålagd spänning, pålagd ström, ackumulerad laddning samt extern belastning på systemets prestanda undersöktes och presenterades systematiskt. Den omfattande jämförelsen mellan dessa fyra klassiska CapMix-system ges också i detta kapitel. 

I kapitel 3 och kapitel 4 utvecklades två nya CapMix-system baserade på flödeselektrodkonfiguration (F-CapMix) för att realisera kontinuerlig energiproduktion. Den första är ett F-CapMix-system med två celler, i vilket flödeselektrodsuspensionen cirkulerade mellan de två cellerna. Den andra är en encell med tvärkammare F-CapMix-system, i vilket det finns två kammare mellan ett par plattor parallellt, flödeselektrodsuspensionen cirkulerades inom cellens två grafitplattor. Genomförbarheten av dessa två F-CapMix-system undersöktes. Effekten av de experimentella parametrarna, t.ex. aktivt kol, mängd kimrök, externt motstånd, matarvattenflöde och flödeselektrodflödeshastighet på systemets prestanda undersöktes och presenterades systematiskt.

I kapitel 5, en grundlig studie av de teoretiska modellerna som relaterade till de termodynamiska egenskaperna hos det elektriska dubbelskiktet vid jämvikt, t.ex. Gouy-Chapman-Stern (GCS), Modified Poisson-Boltzmann-Stern (MPBS), modifierad Donnan (mD) och förbättrade modifierade Donnan (i-mD) modeller gavs. Rationaliteten och den fysiska tolkningen av parametrarna som används i dessa modeller undersöktes och presenterades i detalj.

Place, publisher, year, edition, pages
Stockholm: KTH Royal Institute of Technology, 2022. , p. 74
Series
TRITA-CBH-FOU ; 2022:50
Keywords [en]
capacitive mixing, salinity gradient energy, salt difference energy, electric double layer, flow electrode CapMix
Keywords [sv]
kapacitiv blandning, salthaltsgradientenergi, saltskillnadsenergi, elektriskt dubbelskikt, flödeselektrod CapMix.
National Category
Chemical Engineering
Research subject
Chemical Engineering
Identifiers
URN: urn:nbn:se:kth:diva-319620ISBN: 978-91-8040-365-8 (print)OAI: oai:DiVA.org:kth-319620DiVA, id: diva2:1701031
Public defence
2022-11-03, F3, Kollegiesalen, Brinellvägen 8, via Zoom: https://kth-se.zoom.us/meeting/register/u5Apdu6gqj4qH9JEeQ2pGyUr3U_E1A8jLWY9, Stockholm, 10:00 (English)
Opponent
Supervisors
Note

Online defense

Available from: 2022-10-04 Created: 2022-10-04 Last updated: 2022-10-24Bibliographically approved
List of papers
1. Applicability of different double‐layer models for the performance assessment of the capacitive energy extraction based on double layer expansion (Cdle) technique
Open this publication in new window or tab >>Applicability of different double‐layer models for the performance assessment of the capacitive energy extraction based on double layer expansion (Cdle) technique
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2021 (English)In: Energies, E-ISSN 1996-1073, Vol. 14, no 18, p. 5828-, article id 5828Article in journal (Refereed) Published
Abstract [en]

Capacitive energy extraction based on double layer expansion (CDLE) is a renewable method of harvesting energy from the salinity difference between seawater and freshwater. It is based on the change in properties of the electric double layer (EDL) formed at the electrode surface when the concentration of the solution is changed. Many theoretical models have been developed to describe the structural and thermodynamic properties of the EDL at equilibrium, e.g., the Gouy– Chapman–Stern (GCS), Modified Poisson–Boltzmann–Stern (MPBS), modified Donnan (mD) and improved modified Donnan (i‐mD) models. To evaluate the applicability of these models, especially the rationality and the physical interpretation of the parameters that were used in these models, a series of single‐pass and full‐cycle experiments were performed. The experimental results were compared with the numerical simulations of different EDL models. The analysis suggested that, with optimized parameters, all the EDL models we examined can well explain the equilibrium charge–voltage relation of the single‐pass experiment. The GCS and MPBS models involve, how-ever, the use of physically unreasonable parameter values. By comparison, the i‐mD model is the most recommended one because of its accuracy in the results and the meaning of the parameters. Nonetheless, the i‐mD model alone failed to simulate the energy production of the full‐cycle CDLE experiments. Future research regarding the i‐mD model is required to understand the process of the CDLE technique better.

Place, publisher, year, edition, pages
MDPI AG, 2021
Keywords
CapMix, CDLE, Electric double layer, Modified donnan, Salinity difference energy, Thermodynamic properties, Electrode surfaces, Energy extraction, Energy productions, Harvesting energies, Optimized parameter, Performance assessment, Physical interpretation, Extraction
National Category
Physical Chemistry
Identifiers
urn:nbn:se:kth:diva-311757 (URN)10.3390/en14185828 (DOI)000700230700001 ()2-s2.0-85115172557 (Scopus ID)
Note

QC 20220504

Available from: 2022-05-04 Created: 2022-05-04 Last updated: 2023-08-28Bibliographically approved
2. Comparative study on the performance of capacitive mixing under different operational modes
Open this publication in new window or tab >>Comparative study on the performance of capacitive mixing under different operational modes
2022 (English)In: Energy Reports, E-ISSN 2352-4847, Vol. 8, p. 7325-7335Article in journal (Refereed) Published
Abstract [en]

Capacitive mixing (CapMix) is a renewable method of extracting energy from the salinity difference between seawater and freshwater. In this study, we systematically investigate the system behavior and performance of the CapMix system under four operational modes namely, capacitive energy extraction based on double layer expansion (CDLE), capacitive energy extraction based on the Donnan potential (CDP), and CDP with additional charging of constant voltage (CDP-CV) and constant current (CDPCC). The results indicate that the application of additional charging in the CDP technique can break the limits of the Donnan potential and significantly improve the system's performance. Accordingly, in terms of energy production and average power density, CDP-CC and CDP-CV are the two superior operational modes, followed by CDP and CDLE. In addition, our results reveal that CDP-CC is determined by the accumulated charge and applied current. CDLE is dependent on the applied voltage, while CDPCV is not sensitive to the applied voltage. Increasing the external load can considerably increase the energy production of both CDLE and CDP. In summary, the findings in this study provide practical information for the optimization and application of CapMix technologies.

Place, publisher, year, edition, pages
Elsevier BV, 2022
Keywords
Salinity gradient energy, Capacitive energy extraction, Double layer expansion, CDLE, CDP
National Category
Other Engineering and Technologies not elsewhere specified Renewable Bioenergy Research Energy Engineering
Identifiers
urn:nbn:se:kth:diva-316716 (URN)10.1016/j.egyr.2022.05.245 (DOI)000836288000008 ()2-s2.0-85131397909 (Scopus ID)
Note

QC 20220830

Available from: 2022-08-30 Created: 2022-08-30 Last updated: 2022-11-29Bibliographically approved
3. Comparative study on the performance of a two-cell system of Flow Electrode Capacitive Mixing (F-CapMix) for continuous energy production
Open this publication in new window or tab >>Comparative study on the performance of a two-cell system of Flow Electrode Capacitive Mixing (F-CapMix) for continuous energy production
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(English)Manuscript (preprint) (Other academic)
Abstract [en]

Capacitive mixing (CapMix), one of the most recent techniques that extract salinity gradient energy from the salt difference between seawater and freshwater, has attracted more attention in recent years. However, one big challenge that remains to solve in the traditional CapMix is to produce energy in a continuous way instead of an intermittent way. Here we achieve effective continuous energy production by using a two-cell flow electrode CapMix (F-CapMix) system. The performance of the F-CapMix is investigated under different experimental parameters that influence the power production of the system. Results show that the two-cell F-CapMix system is capable of continuously producing energy for long-term operation. Generally, the power density is dependent on the activated carbon loading, amounts of carbon black, feedwater flow rate, flow electrode flow rate, and the connected external resistance. Increasing the carbon loading and carbon black amounts is beneficial for improving power production. A slower flow rate of flow electrode and feedwater could improve the system’s performance. The external resistance should be matched to the internal resistance of the cell to achieve maximum power production. These results indicate the potential of F-CapMix and provide directions for its further optimizatio

Keywords
Salinity gradient energy; Capacitive energy extraction; flow electrode; CapMix; blue energy; F-CapMix
National Category
Chemical Engineering
Research subject
Chemical Engineering
Identifiers
urn:nbn:se:kth:diva-319600 (URN)
Note

QC 20221005

Available from: 2022-10-04 Created: 2022-10-04 Last updated: 2022-10-05Bibliographically approved
4. A single-cell system of Flow Electrode Capacitive Mixing (F-CapMix) with cross chamber for continuous energy production
Open this publication in new window or tab >>A single-cell system of Flow Electrode Capacitive Mixing (F-CapMix) with cross chamber for continuous energy production
(English)Manuscript (preprint) (Other academic)
Abstract [en]

The generation of the electricity from the salinity difference energy between the seawater and freshwater through Capacitive Mixing (CapMix) systems with solid electrodes was limited by the intermittent energy production. In this study, a single-cell CapMix system with flow-electrode (F-CapMix) was examined to produce electricity continuously from a simulated seawater and freshwater. The performance of the presented F-CapMix system is dependent on the activated carbon loading, amounts of carbon black, and the connected external resistance. Results suggest that performance can be enhanced by increasing the activated carbon loading and carbon black amounts because of the decrease on the system’s internal resistance. Furthermore, to achieve the maximum power density of the system, the external resistance should be matched to the internal resistance. The maximum power density of the presented   single-cell F-CapMix system was 74.3 mW/m2, which was comparable to the previous CapMix and F-CapMix systems. These results indicate the potential of F-CapMix and provide developing directions for its further optimization.

Keywords
Salinity gradient energy; Capacitive energy extraction; flow electrode; F-CapMix; Blue energy
National Category
Chemical Engineering
Identifiers
urn:nbn:se:kth:diva-319601 (URN)
Note

Manuscript, the paper 4 in my PhD thesis, QC 20221005

Available from: 2022-10-04 Created: 2022-10-04 Last updated: 2022-10-05Bibliographically approved

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