| People | Locations | Statistics |
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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Zenkert, Dan
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (38/38 displayed)
- 2024Fatigue performance and damage characterisation of ultra-thin tow-based discontinuous tape compositescitations
- 2024Strength analysis and failure prediction of thin tow-based discontinuous compositescitations
- 2022Multifunctional Carbon Fiber Composites: A Structural, Energy Harvesting, Strain-Sensing Material
- 2020Carbon Fiber Based Positive Electrodes in Laminated Structural Li-Ion Batteriescitations
- 2019Carbon Fibre Composite Structural Batteries: A Reviewcitations
- 2018Lithium iron phosphate coated carbon fiber electrodes for structural lithium ion batteriescitations
- 2018Graphitic microstructure and performance of carbon fibre Li-ion structural battery electrodescitations
- 2017Structural lithium ion battery electrolytes via reaction induced phase-separationcitations
- 2016Impact response of ductile self-reinforced composite corrugated sandwich beamscitations
- 2015Integral versus differential design for high-volume manufacturing of composite structurescitations
- 2015Piezo-Electrochemical Energy Harvesting with Lithium-Intercalating Carbon Fiberscitations
- 2015Analysis of Carbon Fiber Composite Electrode
- 2015Dynamic compression response of self-reinforced poly(ethylene terephthalate) composites and corrugated sandwich corescitations
- 2015Cost and weight efficient partitioning of composite automotive structurescitations
- 2013Compression and tensile properties of self-reinforced poly(ethylene terephthalate)-compositescitations
- 2013Expansion of carbon fibres induced by lithium intercalation for structural electrode applicationscitations
- 2012Impact of electrochemical cycling on the tensile properties of carbon fibres for structural lithium-ion composite batteriescitations
- 2011Impact of mechanical loading on the electrochemical behaviour of carbon fibers for use in energy storage composite materials
- 2011Failure mode shifts during constant amplitude fatigue loading of GFRP/foam core sandwich beamscitations
- 2011Strength of multi-axial laminates with multiple randomly distributed holes
- 2011Impact of the mechanical loading on the electrochemical capacity of carbon fibres for use in energy storage composite materials
- 2011Failure Mechanisms in Composite Panels Subjected to Underwater Impulsive Loadscitations
- 2011Optimisation of Composite Stuctures : Design for Cost
- 2010Testing and analysis of ultra thick compositescitations
- 2010Cost/weight optimization of composite prepreg structures for best draping strategycitations
- 2010Spectrum Slam Fatigue Loading of Sandwich Materials for Marine Structures
- 2010Buckling of laser-welded sandwich panels : ultimate strength and experimentscitations
- 2009Strength of GRP-Laminates with Multiple Fragment Damages
- 2009Damage Tolerance of Naval Sandwich Panelscitations
- 2009Notch and Strain Rate Sensitivity of Non-Crimp Fabric Compositescitations
- 2009Tension, compression and shear fatigue of a closed cell polymer foamcitations
- 2008Cost optimization of composite aircraft structures including variable laminate qualitiescitations
- 2008The Compressive and Shear Responde of Corrugated Hierarchical and Foam Filled Sandwich Structures
- 2007NOTCH AND STRAIN RATE SENSITIVITY OF NON CRIMP FABRIC COMPOSITES
- 2006Fatigue of closed cell foamscitations
- 2005Damage tolerance assessment of composite sandwich panels with localised damagecitations
- 2005Compression-after-impact strength of sandwich panels with core crushing damagecitations
- 2005Fatigue of closed cell foamscitations
Places of action
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article
Carbon Fiber Based Positive Electrodes in Laminated Structural Li-Ion Batteries
Abstract
<jats:p>The structural battery concept was first introduced in 2004 by Wetzel et.al [1]. In general, approximately 60% of a total cell is the active material and the rest is dead mass such as casing, current collectors, additives, etc. The desire to develop safe, environmentally friendly, and more competitive electric vehicles give rise to a new type of multi-functional lightweight composite materials, also termed as structural battery composites. A structural battery is a multifunctional battery that can carry the load while storing the energy and therefore reduce the overall weight of a mobile electric device. The major component of a multifunctional battery is the carbon fibers as they are lightweight materials, have good electrical, electrochemical, and mechanical properties. Carbon fibers were shown that they can reversibly intake lithium ions with a capacity of up to 350 mAh g<jats:sup>-1 </jats:sup>that is similar to graphite (372 mAh g<jats:sup>-1</jats:sup>) [2]. Having around 1000 S cm<jats:sup>-1 </jats:sup>electrical conductivity, carbon fibers can be used without additional current collectors. Removing current collectors and additives from the total structure and introducing carbon fibers into Lithium-ion batteries decreases the non-active mass as well as providing mechanical stability to the system. Structural batteries also called laminated composite batteries consist of a negative and positive electrode where structural battery electrolyte (SBE) sits in between the laminas. In a composite material, a bulk phase (polymer/matrix) encases the reinforcing phase which is carbon fiber in the structural battery. Polymer matrix holds the carbon fibers together and transfers the loads to fibers, while carbon fibers carry the load. A structural battery electrolyte (SBE) was developed at KTH as a load-carrying polymer matrix that simultaneously conducts ions [3]. A schematic illustration of the laminated structural battery is shown in Figure 1a. The upper lamina corresponds to the negative electrode where the SBE is reinforced with carbon fibers. In the lower lamina, SBE is reinforced with carbon fibers that are coated with a positive electrode material (e.g. LiFePO<jats:sub>4</jats:sub>). The positive electrode is a challenge, as carbon fibers need a coating with an active material that adheres well to the carbon fibers. Obtaining an evenly distributed coating of positive electrode particles affects the mechanical performance of the structural battery [2].</jats:p><jats:p>In this work, we present different coating techniques to make a structural positive electrode in a laminated structural battery. Accordingly, electrophoretic deposition (EPD) and spray coating methods are investigated individually. As it is important to have evenly coated single fibers within a tow, uniform current distribution within the EPD cell is of high importance. A specific EPD cell is designed for this aim and it is used to coat carbon fibers electrochemically and uniformly. This new cell design gives the flexibility to obtain the electrochemical parameters (distance, coating thickness, current distribution, etc.) to encase the fibers in a tow homogeneously and hence, several micrometers of coating thickness can be obtained. Spray coating is a versatile technique that is also applicable to the carbon fibers. Within this technique, an electrode slurry ink is prepared for the spray gun, and fibers are coated layer by layer to have as homogenous coating as possible. The coated carbon fibers are tested electrochemically and mechanically to investigate their performance in a battery cell (Figure 1.b.).Morphological analyses were also conducted using scanning electron microscopy (SEM) as illustrated in Figure 1c.</jats:p><jats:p>References</jats:p><jats:p>[1] E. Wetzel. Multifunctional Composites for Future Energy Storage in Aerospace Structures. Communications, and Structure. AMPITAC Q. 8 (2004), 91-95.</jats:p><jats:p>[2] J. Hagberg. Carbon Fibres for Multifunctional Lithium-Ion Batteries, Doctoral Thesis. KTH Royal Institute of Technology, Stockholm, Sweden, 2018.</jats:p><jats:p>[3] N. Ihrner, W. Johannisson, F. Sieland, D. Zenkert,M. Johansson. Structural lithium-ion battery electrolytes: Via reaction induced phase-separation. Journal of Material Chemistry A 5.48 (2017), 25652-25659.</jats:p><jats:p><jats:inline-formula><jats:inline-graphic xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="983fig1.jpg" xlink:type="simple" /></jats:inline-formula></jats:p><jats:p>Figure 1</jats:p><jats:p />