Obrazovanje hloridnih i bromidnih kompleksa kobalta(II) u električki nesimetričnim vodenim rastopima soli / Cobalt(II) chloride and bromide complex formation in electrical unsymmetric aqueous molten salts

Vraneš Milan

23 February 2009

<p>U ovoj doktorskoj disertaciji proučavano je građenje kompleksa&nbsp;kobalta(II) sa hloridnim i &nbsp;bromidnim jonima u vodenim&nbsp;rastopima tipa&nbsp;xCa(NO3)2&middot;zH₂O&nbsp;&ndash; (1-x)NH₄NO_3&nbsp;pri različitom sastavu soli (x= 0,3 &ndash; 0,9), različitom sadržaju vode (z= 2,67 &ndash; 6,67) i na različitim temperaturama (45, 55 i 65^oC).</p><p>Istraživanja su imala za cilj proučavanje reakcije građenja&nbsp;kompleksa kobalta(II) sa hloridnim i bromidnim jonima u&nbsp;vodenim rastopima xCa(NO₃)₂&middot;zH₂O &ndash; (1&ndash;x)NH₄NO₃, &nbsp;uticaja&nbsp;temperature, sastava elektrolita i sadržaja vode na proces&nbsp;kompleksiranja, kao i određivanje termodinamičkih parametara&nbsp;koji karakteri&scaron;u reakcije asocijacije u ovim sistemima. Ovakvi&nbsp;rastopi soli su posebno interesantni zbog svoje niske tačke&nbsp;topljenja i visoke latentne toplote topljenja pa se mogu koristiti&nbsp;kao fazno-promenljivi materijali za skladi&scaron;tenje toplotne&nbsp;energije.</p> / <p>In this thesis absorption spectra of cobalt(II) chloride and&nbsp;bromide in calcium nitrate &ndash; ammonium nitrate &ndash; water&nbsp;system of the composition&nbsp; xCa(NO₃)₂&middot;zH₂O &ndash; (1&ndash;x)NH₄NO_3&nbsp;(x= 0.30 - 0.90 and z= 2.67 &ndash; 6.67) have been&nbsp;investigated in the wavelength range 400-800 nm at three&nbsp;different temperatures: 45, 55 and 65^oC.</p><p>Temparature, composition of the melt and water&nbsp;content influence on complex formation reactions between&nbsp;cobalt(II) and halide ions in aqueous xCa(NO₃)₂&middot;zH₂O &ndash;<br />(1&ndash;x)NH₄NO₃ melts have been studied. Thermodynamic&nbsp;parameters for cobalt(II) &ndash; halide association process in&nbsp;different solvents also were determined.</p><p>Investigated systems are interesting because of&nbsp;their high values of latent heat of fusion and low melting&nbsp;points. Due to these reasons, some melts are proposed for&nbsp;<br />heat energy storage materials, usually known as phase&nbsp;change materials (PCM).</p>

Investigation of Charge Transfer Kinetics in Non–Aqueous Electrolytes Using Voltammetric Techniques and Mathematical Modeling

Shen, Dai

28 January 2020

No description available.

Chemical Engineering

deep eutectic solvents

high temperature molten salts

ethaline

electrochemical kinetics

electrochemical engineering

electrochemical redox reactions

complexation

diffusion-reaction modeling

molten salt electrolysis

neodymium

Novel Approach to Design, Optimization, and Application of Thermal Batteries and Beyond

Yazdani, Aliakbar

03 June 2021

No description available.

Chemical Engineering

Engineering

Energy

Battery

Thermal Molten Salt Battery

Electrolyte

Cathode

Electrode

Energy Storage

Energy Density

Chemical Engineering

Ceramic Separator

Ionic Conductivity

溶融塩電気化学プロセスによる緻密質炭素膜の形成 / ヨウユウエン デンキ カガク プロセス ニヨル チミツシツ タンソマク ノ ケイセイ

湯川 晃宏, Akihiro Yukawa

22 March 2014

本研究では比較的安価な設備を用い、低温で量産性のある炭素膜を得ることが出来る溶融塩電気化学プロセスに着目し、電解条件が炭素膜に及ぼす影響、浴温が炭素膜に及ぼす影響、基材前処理における酸活性が炭素膜と基材の密着性に及ぼす影響等を明らかにしたものである。 / 博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University

金属溶融塩

炭素膜

PR電解

陰極還元

metal molten salt

carbon film

PR electrolysis

cathodic reduction

Development of an integrated tool to design, estimate cost and calculate annual performances of a solar power tower / Utveckling av ett verktyg som kan utforma, beräkna kostnaden och beräckna årliga avkastningar på ett smält salt soltorn

Blampain, Emil

January 2018

This Master Thesis consisted in realizing a tool able to design, estimate the cost and calculate annual yields of a molten salt solar power tower. Such tool was made for a company providing CSP equipment and plant solutions for engineering, engineering and procurement or also EPC of a solar power tower. The Company wishes to propose competitive plant configurations presenting a good trade-off between cost and revenues. The Company can oversee the EPC of a whole power plant or/and supply some components of the molten salt cycle and of the water/steam cycle. The tool models a large scale solar power tower with a thermal energy storage system on EBSILON®Professional 12.04, a thermodynamic software.   When launching a simulation, the tool sizes the components of the molten salt cycle (design phase) according to user’s inputs, the other components have their characteristics based on a reference project. Depending on the size of the components, the total cost is determined and the revenues over a year of operation are calculated (annual performance). When performing several simulations with different configurations, the Company can judge about the economic viability of plant configurations by comparing their LCOEs and NPVs.   The present document describes the result of the Master Thesis, that is to say the tool itself, what it contains and how it works. The methodology adopted to design the components is presented in depth, the way costs were calculated is exposed. The document explains the annual performance calculations and the simple operation strategy implemented. Finally, a technical and cost validation was carried out but it would require some further work to be complete. The design and cost calculations are performed in few seconds, the annual calculations take around 2-3h.   One main contribution of the Master Thesis is to show that designing, estimating costs and calculating annual performances is feasible in a single tool operating at a high level of detail. Using the tool during a solar power tower project could considerably facilitate the current process in place at the Company. It can also allow to compare an important number of configurations to determine a good techno-economic solution. / Denna uppsats bestod i att genomföra ett verktyg som kan utforma, beräkna kostnaden och beräkna årliga avkastningar på ett smält salt soltorn. Ett sådant verktyg gjordes för ett företag inom soltornsteknik, upphandling och konstruktion (SUK) som vill föreslå konkurrenskraftiga anläggningskonfigurationer som presenterar en bra avvägning mellan kostnad och intäkter. Företaget, samtidigt som det övervakar SUK för en hel kraftverk, levererar det också vissa komponenter i den smälta saltcykeln. Verktyget modellerar ett storskaligt soltorn med ett värmeenergilagringssystem på EBSILON®Professional 12.04, en termodynamisk programvara.   När en simulering startas, ritar verktyget komponenterna i den smälta saltcykeln (designfas) enligt användarens inmatningar, de andra komponenterna är baserade på ett referensprojekt. Beroende på komponenternas storlek bestäms den totala kostnaden och intäkterna över ett verksamhetsår beräknas (årlig prestation). När flera simuleringar görs med olika konfigurationer kan företaget bedöma sin ekonomiska lönsamhet genom att jämföra sina LCOE och NPV.   Det här dokumentet beskriver resultatet av masterprojektet, det vill säga själva verktyget, vad det innehåller och hur det fungerar. Den metod som antagits för att designa komponenterna presenteras grundligt samt hur kostnaderna beräknades. Dokumentet förklarar de årliga prestationsberäkningarna och den enkla operationsstrategin som implementerats. Slutligen genomfördes en teknisk och kostnadsvalidering, men det skulle kräva ytterligare insats för att göra arbetet fullständigt. Konstruktionen och kostnadsberäkningarna utförs på få sekunder, de årliga beräkningarna tar cirka 2-3 timmar.   Ett huvudbidrag av examensarbetet är att visa att utformning, uppskattning av kostnader och beräkning av årliga prestanda är möjlig i ett enda verktyg som arbetar på en detaljrik nivå. Att använda verktyget under ett soltornsprojekt kan betydligt underlätta den nuvarande processen på plats hos företaget. Det kan också göra det möjligt att jämföra ett viktigt antal konfigurationer för att bestämma en bra tekno-ekonomisk lösning.

Solar power tower

EBSILON®Professional

Modelling

Molten salt

Design methodology

Cost estimation

Annual performance

Soltorn

EBSILON®Professional

Modellering

Smält salt

Designmetodik

Kostnadsberäkning

Årlig prestanda.

Energy Engineering

Energiteknik

End-of-life wind blade recycling through thermal process

Benz, Kerstin

January 2023

Renewable energy production with wind turbines has been rising in the last 30 years and it is a crucial technology, which is necessary for the energy transition. As sustainable as the energy production of wind turbines is, the waste management of the blade material is not. Most of the blades end up on a landfill or get incinerated. There are different types of recycling methods, but the most commonly used is to shred the fibers into little pieces and reusing them for filler material in the concrete industry. This approach does not actually split up the blade material into its components but it is more of a downcycling. In this thesis, a new type of pyrolysis will be looked into, which splits up the blade material into its components namely glass fibers and plastic using molten salt. This process would make the glass fiber industry more sustainable by introducing a recycled glass fiber with minimal loss in quality. In a first step, the blade material will be examined more closely with a thermogravimetric analysis to find out what kind of plastic it is and what temperature would be necessary to pyrolyze it. This information will be used to conduct an experiment in a molten salt solution and determine the necessary reaction time and temperature. This data will be used to compare the costs of this method with shredding the material and the conventional pyrolysis. From the thermogravimetric analysis, it was possible to determine that the type of plastic used in this turbine was made out of epoxy. The maximum degredation of this material occurred at 380 ◦C. Not many experiments could be conducted in order to find the optimal conditions for the pyrolysis process due to difficulties with the furnace. Nevertheless, one sample was successfully pyrolyzed at a temperature of 400 ◦C with a residence time of 15 minutes. With the current market conditions in the recycled glass fibers industry, this product would be too expensive and the demand would be too little. However, the market is expected to grow in the next couple years due to rising interests in circular economy and governments introducing regulations. Nevertheless, it is necessary to increase the efficiency of the molten salt pyrolysis in order to be applicable to a bigger scale. More experiments should be conducted with cheaper molten salt in order to sink the costs of the process.

Wind Turbine Blades

Recycling

Glass Fiber Reinforced Plastic

Molten Salt Pyrolysis

Övrig annan teknik

Composite Science and Engineering

Kompositmaterial och -teknik

In-Situ Chlorine Gas Generation for Chlorination and Purification of Rare Earth and Actinide Metals

Schvaneveldt, Mark H

01 August 2022

Rare earth and actinide metals, critical to security, medicine, and the economy, have been processed through methods such as solvent extraction and electrorefining. To minimize radiological waste and improve yield, a 'chloride volatility' process--also known as the chlorination and volatilization process (CVP)--has been proposed and demonstrated for processing rare earths. The process takes advantage of the low vapor pressure of rare earth chlorides (<700 >°C), CaCl2 was added to LaCl3 to lower the melting temperature. LaCl3 electrochemical behavior has not previously been studied in CaCl2. Cyclic voltammetry (CV) and square wave voltammetry (SWV) were applied to LaCl3 salts in CaCl2-LiCl and CaCl2 to study the metal ion behavior. Various electrode materials were compared at low CV scan rates (s-1) to determine compatibility with chlorine gas evolution. Experiments of eutectic LaCl3-CaCl2 were performed and analyzed to determine the efficacy of chlorine gas generation via electrolysis for the CVP. Through galvanostatic electrolysis, oxidation of chloride ions and subsequent chlorination of rare earth was demonstrated, with cerium chosen as the representative rare earth metal. Through a quadrupole mass spectrometer plumbed in line with the electrolytic cell, the quality of the generated gas was analyzed.

rare earth

actinide

chlorine

molten salt

volatility

cyclic voltammetry

square wave voltammetry

diffusion coefficient

exchange current density

electron transfer coefficient

Engineering

Integrated Study of Rare Earth Drawdown by Electrolysis for Molten Salt Recycle

Wu, Evan

January 2017

No description available.

Nuclear Engineering

Chemistry

Pyroprocessing

Rare Earth Drawdown

Lanthanum

Gadolinium

Neodymium

Exchange current density

Apparent potential

Diffusion Coefficient

Electrolysis

Electrode kinetic model

BET model

High concentration

Molten salt recycle

Feasibility Study on Conducting a Subcritical Molten Salt Reactor Experiment Using a DD Neutron Source / Evaluation of Different Reactivity Measurement Methods

Mahdi, Mohammed

January 2020

Over the last two decades, there has been widespread international interest in the development of the molten salt reactor concept due to its passive safety, high coolant boiling temperature, low operational pressure, high thermal efficiency, and ease of breeding. Terrestrial Energy Incorporated (TEI) is developing a thermal-spectrum converter type molten salt reactor, called the Integral Molten Salt Reactor (IMSR-400) to be built by 2030. A physics experiment is needed in order to validate the theoretical predictions of the temperature reactivity coefficients of the IMSR-400. This thesis will determine the feasibility of conducting a subcritical experiment, utilizing a Deuterium-Deuterium Fusion Neutron Source (DD). / Thesis / Master of Science (MSc)

Nuclear Energy

Molten Salt Reactor

Experiment

Subcritical Pile

Reactivity Measurement

Engineering Design Process

Feasibility

Neutronic Analysis

Serpent Monte-Carlo Reactor Physic Code

Conceptual design of a breed & burn molten salt reactor

Kasam, Alisha

January 2019

A breed-and-burn molten salt reactor (BBMSR) concept is proposed to address the Generation IV fuel cycle sustainability objective in a once-through cycle with low enrichment and no reprocessing. The BBMSR uses separate fuel and coolant molten salts, with the fuel contained in assemblies of individual tubes that can be shuffled and reclad periodically to enable high burnup. In this dual-salt configuration, the BBMSR may overcome several limitations of previous breed-and-burn (B$\&$B) designs to achieve high uranium utilisation with a simple, passively safe design. A central challenge in design of the BBMSR fuel is balancing the neutronic requirement of large fuel volume fraction for B$\&$B mode with the thermal-hydraulic requirements for safe and economically competitive reactor operation. Natural convection of liquid fuel within the tubes aids heat transfer to the coolant, and a systematic approach is developed to efficiently model this complex effect. Computational fluid dynamics modelling is performed to characterise the unique physics of the system and produce a new heat transfer correlation, which is used alongside established correlations in a numerical model. A design framework is built around this numerical model to iteratively search for the limiting power density of a given fuel and channel geometry, applying several defined temperature and operational constraints. It is found that the trade-offs between power density, core pressure drop, and pumping power are lessened by directing the flow of coolant downwards through the channel. Fuel configurations that satisfy both neutronic and thermal-hydraulic objectives are identified for natural, 5$\%$ enriched, and 20$\%$ enriched uranium feed fuel. B$\&$B operation is achievable in the natural and 5$\%$ enriched versions, with power densities of 73 W/cm$^3$ and 86 W/cm$^3$, and theoretical uranium utilisations of 300 $\mathrm{MWd/kgU_{NAT}}$ and 25.5 $\mathrm{MWd/kgU_{NAT}}$, respectively. Using 20$\%$ enriched feed fuel relaxes neutronic constraints so a wider range of fuel configurations can be considered, but there is a strong inverse correlation between power density and uranium utilisation. The fuel design study demonstrates the flexibility of the BBMSR concept to operate along a spectrum of modes ranging from high fuel utilisation at moderate power density using natural uranium feed fuel, to high power density and moderate utilisation using 20$\%$ uranium enrichment.