EXPERIMENTAL ANALYSIS OF ELECTRIC DOUBLE LAYER AND LITHIUM-ION CAPACITORS FOR ENERGY STORAGE SYSTEMS AND THEIR APPLICATION IN A SIMULATED DC METRO RAILWAY SYSTEM

Wootton, Mackenzie

January 2018

This works begins by providing motivation for additional research and political interest in the use of passenger railway systems as a method of ‘green’ transportation. Additional motivation for the adoption of energy saving methods within new and existing railway systems is also provided. This motivation stems from the relatively small carbon dioxide emissions per passenger kilometer and large quantity of electrical energy used in association with passenger railway systems. In specific cases, both theoretical analyses and experimental implementations of energy storage in railway systems have shown a reduction in electrical energy use and/or vehicle performance gains. Current railway energy storage systems (ESS) commonly make use of battery or electric double layer capacitor (EDLC) cells. A review of select energy storage technologies and their application in railway systems is provided. For example, the developing Qatar Education City People Mover system makes use of energy dense batteries and power dense EDLCs to provide the range and power needed to operate without a conventional railway power source between stations, formally called catenary free operation. As an alternative to combining two distinct energy storage technologies, this work looks at experimentally characterizing the performance of commercially available lithium ion capacitors (LiCs); a relatively new energy storage cell that combines characteristics of batteries and EDLCs into one cell. The custom cell testing apparatus and lab safety systems used by this work, and others, is discussed. A series of five tests were performed on two EDLC cells and five LiC cells to evaluate their characteristics under various electrical load conditions at multiple temperatures. The general conclusion is that, in comparison to the EDLC cells tested, the LiC cells tested offer a superior energy density however, their power capabilities are relatively limited, especially in cold environments, due to larger equivalent series resistance values. The second topic explored in this work is the development of a MATLAB based DC powered passenger vehicle railway simulation tool. The simulation tool is connected to the experimental analysis of EDLC and LiC cells by comparing the volume and mass of an energy storage system needed for catenary free (no conventional DC power supply) operation between train stations using either energy storage technology. A backward facing modelling approach is used to quantify the drive cycle electrical power demands as a function of multiple vehicle parameters and driving parameters (eg. acceleration rate, travel distance and time). Additional modelling methods are provided as a resource to further develop the simulation tool to include multiple vehicles and their interactions with the DC power supply. Completion of the multi-vehicle simulation tool with energy storage systems remains a task for future work. / Thesis / Master of Applied Science (MASc)

Electric double layer capacitor

Lithium-ion capacitor

Energy storage system

Étude et modélisation du fonctionnement et du vieillissement des « Lithium-Ion Capacitors » (LiC) / Study and modeling of the functioning and aging of Lithium-ion Capacitors (LiC)

El Ghossein, Nagham

06 December 2018

Le « Lithium-Ion Capacitor » (LiC) est un supercondensateur hybride dont les caractéristiques peuvent être placées entre un condensateur à double couche électrique (supercondensateur) et une batterie lithium-ion. Il possède des densités d’énergie et de puissance intermédiaires grâce à sa composition hybride à base d'une électrode positive en charbon actif identique à celle d’un supercondensateur et d'une électrode négative en carbone pré-lithié identique à celle d’une batterie lithium-ion. L'objectif de cette thèse est d'étudier le vieillissement des LiC industrialisés aussi bien dans le cadre d’un vieillissement en stockage (calendaire) qu’en utilisation (cyclage). Un de leur spécificité principale concerne l’évolution particulière de leur capacité en fonction de la tension à leurs bornes (C(V)). Le premier type de vieillissement qu’est le vieillissement calendaire permet de représenter le comportement des LiC lorsqu’ils sont stocker avant utilisation ou lorsqu’ils sont en veille. La dégradation de leurs paramètres liée au vieillissement, est alors essentiellement influencée par leur tension et la température. Des essais de vieillissement à trois tensions caractéristiques et deux températures différentes sont étudiés. L’évolution des impédances des cellules a été suivie tout au long du vieillissement afin d’identifier un modèle électrique de suivi du vieillissement dont les paramètres sont liés aux phénomènes électrochimiques. Par ces essais, la meilleure tension de stockage des LiC, permettant la prolongation de leur durée de vie a été mise en évidence. Par ailleurs, des mécanismes de vieillissement différents d’une tension caractéristique à l’autre sont révélés et soulignent la spécificité de fonctionnement des LiC. Ces résultats ont été confirmés par des analyses post-mortem. Le second type de vieillissement étudié est le vieillissement par cyclage qui prend en compte l'impact du courant sur la durée de vie des LiC. Le choix des profils de courant de cyclage a été effectué en considérant le principe de fonctionnement électrochimique des LiC. Les évolutions des impédances et des courbes C(V) des cellules sont comparées et interprétées. Les mécanismes de vieillissement prenant naissance lors du cyclage continu sont abordés. Ils dépendent de la fenêtre de potentiel sur laquelle les LiC fonctionnent pendant leur utilisation. La fenêtre de tension optimale qui assure une longue durée de vie des LiC est aussi mise en évidence / Lithium-Ion Capacitors (LiCs) are the new emerging technology of hybrid supercapacitors that combines the advantages of conventional supercapacitors and lithium-ion batteries. They provide intermediate energy and power densities due to their hybrid composition based on a positive electrode made of activated carbon similar to that of supercapacitors and a negative electrode made of pre-lithiated carbon similar to that of lithium-ion batteries. The aim of this thesis is to study the aging of commercial LiCs using two accelerated aging procedures: calendar aging and cycle aging. One of their main particularities concerns the nonlinear capacitance evolution with respect to their voltage (C(V) curve). The first accelerated aging test is related to the calendar life of LiCs that represents their behavior independently of their usage. The degradation of their parameters due to aging is mainly affected by the voltage and the temperature only. These tests were applied to several cells at three different voltage values and two temperatures. The evolution of their impedances were followed during the whole aging period in order to identify an electrical model that can accurately describe the progress of aging and that possesses electrochemically meaningful parameters. The best voltage value that ensures the extension of the lifetime of LiCs was identified using the results of these tests. In addition, aging mechanisms that extremely depend on the applied voltage value were identified. They highlight the particularity of the functioning of LiCs. These results were confirmed using post-mortem analyses. The second accelerated aging test is the cycle aging that assesses the impact of the current on the life cycle of LiCs. The choice of current profiles was based on the electrochemical operating principle of LiCs. The evolution of the impedances and the C(V) curves of LiCs were compared and analyzed. Aging mechanisms produced during cycle aging were also evaluated. They depend on the voltage range in which the LiC operates. The optimal voltage window that guarantees a long lifetime of LiCs was highlighted

Supercondensateur hybride

Supercondensateur lithium-ion

Durée de vie

Vieillissement

Mécanismes de vieillissement

Energy storage system

Hybrid supercapacitor

Lithium-ion capacitor

Lifetime prediction

Aging

Aging mechanisms

620

Etude d'électrolytes organiques pour la réalisation de supercondensateurs lithium-ion / Study of electrolytes for lithium-ion capacitors

Dahbi, Mouad

25 January 2013

Le travail réalisé dans cette thèse concerne l'optimisation d’électrolytes organiques pour supercondensateur lithium-ion. Plusieurs solvants ont été sélectionnés pour la formulation de mélanges binaires ou ternaires additionnés de sel de lithium. Les propriétés physicochimiques et électrochimiques de ces électrolytes contenant LiTFSI ou LiPF6 (EC/DMC ; dinitrile/DMC ; EC/Ester/3DMC, EC/MiPC/3DMC) ont été caractérisées en vue de leur utilisation dans des dispositifs hybrides, l’objectif étant de satisfaire à la fois aux exigences des matériaux graphite et carbone activé. Les interactions solvant-solvant et solvant-sel des électrolytes ont été étudiées à partir des théories de Jones-Dole, Stocks-Einstein et Bjerrum appliquées aux mesures de viscosités et conductivités. Cela a permis de développer des modèles prédictifs de la conductivité dans des cas de solvants purs ou de mélanges simples. La deuxième partie de cette thèse a été dédiée à la réalisation de demi-cellules avec différentes formulations d'électrolytes à la fois sur carbone activé et sur graphite. Les interfaces électrodes/électrolytes et séparateurs/électrolytes ont été étudiées. La corrosion des collecteurs en Al en présence de LiTFSI a fait l'objet d'une étude qui a permis de dégager une solution consistant en la formulation d'un électrolyte additionné de 1% d'additifs source de fluorure tel que LiPF6. Enfin, des dispositifs complets graphite/carbone activé ont été réalisés en utilisant les différents électrolytes optimisés ce qui a permis de mettre en évidence le gain en énergie (x5) pour un tel système par rapport aux supercondensateurs symétriques classiques. / The objective of this thesis is to broaden the knowledge of electrochemical, thermo physical and thermodynamic properties of different efficient and safe organic electrolytes for Lithium-ion Capacitors (LICs). Several solvent structures have been first selected to design new electrolytes based on binary or ternary solvent mixtures. These solvents were then characterized through conductivity, viscosity and electrochemical studies, in order to assess their structure and properties relationships. Based on this investigation, best compromise between mobility and ionic concentration has been evaluated to formulate the best electrolytes. Generally, it was proved that the addition of solvents with very low viscosity provides efficient electrolytes. Based on conductivity and viscosity measurements, a theoretical study on solvent-solvent and solvent-salt interactions has been then performed using different well-known equations based on Stock-Einstein, Jones-Dole and Bjerrum theories to understand, rationalize, correlate and then predict their transport properties. The second part of the study concentrated on the characterization of selected electrolytes in an asymmetric LIC prior to developing such electrolytes in any high performance asymmetric capacitor devices. In other words, the main objective of this part is to verify the compatibility of designed electrolytes with each element, e.g. electrodes (graphite, activated carbon) and current collectors (aluminum), of a LIC device. To drive such analysis, different experimental investigations between electrodes/electrolytes and between collectors/electolytes were in fact investigated. Using this strategy, asymmetric systems LICs containing a formulated organic electrolyte were fully characterized to deter mine the electrochemical performances of the designed solution in LIC conditions and then compared with those observed using classical electrolyte currently used.

Supercondensateur lithium-ion

Électrolyte

Conductivité

Viscosité

Interaction

Angles de contact

Propriétés interfaciales

Cyclage

Stabilité électrochimique

Lithium-ion capacitor

Electrolyte

Conductivity

Viscosity

Interaction

Contact angles

Interfacial properties

Cycling ability

Electrochemical stability