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Chemical modification of lignin for the elaboration of novel biobased aromatic polymers and additives / Modification chimique de lignines pour l’élaboration de nouveaux polymères et additifs aromatiques biosourcésBuono, Pietro 25 September 2017 (has links)
Parmi les composants de la biomasse, la lignine est considérée comme l'un des plus prometteurs polymères naturels qui convient à la conversion de la biomasse en valable produits chimiques et matériaux. Malgré une grande quantité de lignine est générée dans l'industrie papetière, seule 2% est exploitée dans l'industrie chimique. La présence de soufre et la grande diversité moléculaire sont les principaux obstacles pour l'utilisation de la lignine. La modification chimique a été reconnue comme un outil pour contourner ces limites. Dans cette thèse, différentes stratégies de synthèse ont été appliquées pour introduire de nouveaux groupes chimiques sur une soude lignine que présents une haute fonctionnalisation de groups hydroxyles. Les dérivés correspondants de lignine ont été utilisés soit pour l’élaboration des matériaux par click polymérisations, soit pour augmenter l’hydrophobicité de la lignine à la fine de faciliter son traitement avec des matrices polymériques. / Among biomass components, lignin is considered one of the most promising natural polymers suitable for the conversion of biomass into renewable added-value chemicals and materials. However, large amount of lignin generated from wood pulping industry is burn as low cost energy source, and only 2% is exploited in the chemical industry. The presence of sulphur moieties and the large molecular diversity are the most reasons impeding the use of lignin as building blocks for the production of chemicals and materials. Chemical modifications have been acknowledged to be an important tool to circumvent these limitations. In the current work, taking advantage of the high hydroxyl groups content of a sulphur free soda lignin (SL), different synthetic strategies have been applied to introduce new chemical groups and used either to produce lignin derivatives suitable for “click” polymerization either to increase lignin hydrophobicity, facilitating its processing in polymeric matrices.
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Extraction of Material Parameters for Static and Dynamic Modeling of Carbon Black Filled Natural RubbersSandell, Viktor January 2017 (has links)
Volvo Car Corporation (Volvo Cars) develops powertrain mounting systems that uses components made up largely of filled rubber materials. The development of such components is today relying on external suppliers to design components based on requirements set by Volvo. To reduce costs and lead-time in the development process the possibility of in-house design of such components at Volvo Cars is being investigated. For this to be possible, knowledge must be built concerning modelling the mechanical properties of rubber materials. As part of this a parameter extraction method for modelling of filled rubber materials intended for finite element use has been developed in this project. Both a simple static model fitting procedure and a more complex dynamic model fitting procedure are detailed. Mechanical testing of four filled natural rubber materials with varying hardnesswas carried out at the facilities of Volvo Cars and recommendations have been made regarding the limits of the equipment and the specific test body geometry used. It was found that the lower limit for dynamic testing in regards to displacement amplitude is 0.02 mm. The highest frequency recommended is dependent on the material hardness but a higher limit of 200 Hz is recommended for the softest material investigated. The upper limit was found to be necessary due to inertia effects in the material. The models used to describe the static behaviour were hyperelastic phenomenological models independent on the second invariant such as the Yeoh and the linear neo-Hookean models. The dynamic model used the overlay method to capture therate and amplitude dependent properties of filled rubber. A generalized viscoelastic-elastoplastic rheological model using Maxwell and friction elements in parallel with alinear elastic element was presented and used. These were limited to having maximumfive of each element and no attempts at minimizing this number was made in this work.The dynamic model was fitted to experimental data using a minimization procedure focusing on dynamic modulus and damping at a range of frequencies and strain amplitudes.The proposed fitting procedure is a three segment loop in which FE simulationsof the experimental data is used as both a correction and a validation tool.Model validation showed good correlation of the fitted model to measured databefore correction was attempted. The correction step did not improve the model qualityand the reason for this was identified as poor post-processing. The proposed method together with lessons learned during the course of the project will be of importance for the future in-house development of rubber components at Volvo Cars.
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En modulär sko för en hållbar framtidPersson, Linn, Olsson, Johannes January 2020 (has links)
Vagabond Shoemakers is one of Europe’s leading design companies within the footwear industry. In the summer of 2019, the project group contacted the company to investigate the possibility to execute an innovation- and development project together. The project would turn into so much more, it would become the beginning of a sustainability work which would lead into a modular shoe for a sustainable future. The sustainability issues within the footwear industry are today bigger than the choice of sustainable materials. There is no good way of recycling or reusing shoes since there is no effective way of separating glue, textiles and rubber form each other. It was from this problem that the foundation of the project was created, is there a possibility to construct a modular shoe? A shoe from the constructions design to facilitate recycling and reuse, through the ability to efficiently separate the parts from each other. Together with Vagabond Shoemakers we would create the foundation of the future footwear industry. A product that would be called Klick-Skon based on the projects Klick-Concept. A product designed to meet the sustainability issues; the result came to be a modular shoe for a sustainable future.
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High Resolution 3D Printing with Cellulose AcetateHeyman, Nils January 2020 (has links)
In this project, an additive manufacturing technique called Direct Ink Writing has been used to 3D print structures from polymer solutions containing cellulose acetate. Cellulose acetate is a synthetic compound derived from plants. The intended application involves protein separation filters for medical purposes. The printing has been performed in a lab environment with focus on high resolution, with less than 10 micrometers in fibre size. Glass capillaries with an inner diameter of 3-10 micrometers were used as nozzles. Three-dimensional structures with a height of 100 micrometers and a fibre thickness of 2 micrometers were made. The results indicates that cellulose acetate is a promising polymer for Direct Ink Writing in high resolution. Improvements are needed in the ink design and/or the technical construction of the printer to avoid clogging of the nozzle.
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Non-woven textilier från träfibrer genom papperstillverkningsmetoder / Investigation of making nonwoven textiles with wood fibres and papermaking techniqueLindberg, Elin January 2015 (has links)
Idag är den största delen av textilierna antingen olje-(60 %) eller bomullsbaserade (30 %). Det är enbart en liten del som är baserade på träfibrer. Ett ökande behov av förnyelsebara textilier föreligger. Samtidigt är ett minskade pappersbehov en drivkraft till att använda de existerande pappersmaskinerna till att tillverka icke vävda textilliknande material. Till skillnad från vävda material kan materialet tillverkas direkt istället för att först tillverka trådar från fibrer. Möjligheter att ta fram textillika material av cellulosafibrer undersöktes. Dynamiska ark gjorda av en blandning av barrmassa och en blandning av barr- och lövmassa med 0, 55 och 70 vikt% polymjölksyra, PLA, tillverkades. Arken pressades ihop två och två med ett mellanlager av Expancel mikrosfärer och bindemedel. Mowilith DM 105 och Primal LT-2949 Emulsion användes som bindemedel. En jämförelse gjordes med ark med enbart bindemedel som mellanlager. En subjektiv utvärdering av vilket förhållande mellan Expancel mikrosfärer och bindemedel som var bäst lämpad gjordes. För utvärderingen ytbehandlades ett standard papper med 70 vikt% PLA. Den sats med högst koncentration av Expancel mikrosfärer som band bra till bindemedelet valdes. Draghållfastheten testades genom dragprovning enligt ISO 1924-2:1994 men med endast 5 prover istället för 10. Dragprovningen visade att tillsatsen av Expancel mikrosfärer ökade töjningen hos materialet. Materialen med högst koncentration av PLA gav den mjukaste känslan men också lägst styrka. / Today the main parts of textiles are either oil (60 %) or cotton based (30 %). It is only a small portion which is based on wood fibres. An increasing demand of renewable textiles is forthcoming. At the same time a decreasing demand of paper is one of the motivation of using the existing paper machines to produce nonwoven textile-like materials. Unlike woven fabrics the fabric can be manufactured directly rather than first producing yarn from fibres. Possibilities of developing a textile-like material of cellulose fibres were investigated. Dynamic lab sheets made of a mix of softwood pulp and a mix of softwood and birch pulp with 0, 55 and 70 weight % Poly(lactic acid), PLA, were manufactured. The sheets was pressed together two and two with a middle layer of Expancel microspheres and binder. Mowilith DM 105 and Primal LT-2949 emulsion were used as binders. A comparison was made between sheets with only binder as the middle layer. A subjective evaluation of which ratio between Expancel microspheres and binder material was best suited was made. For the evaluation a paper containing 70 weight% PLA was coated. The batch with highest concentration of Expancel microspheres, which bonded well to the binder, was chosen. The tensile strength was measured according to ISO 1924-2:1994 but with only 5 test samples instead of 10. The tensile tests showed that with Expancel microspheres resulted in increase of elongation of the material. The materials with the highest concentration of PLA had softest feeling but also lowest strength.
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Effect of strain rate on continuum and pre-cracked polymer failurePowar, Pratik Rajesh, Raeisi, Ashkan January 2021 (has links)
The main intention of this thesis work was to investigate the effect of strain rate on continuum and pre-cracked polymer failure. Low-Density Polyethylene (LDPE) was chosen to study experimentally and numerically. In order to cover wide range of strain rates, four specific strain rates were selected for the uniaxial tensile tests. To perform the tests, cyclic loading and unloading with relaxation was utilized in the room temperature for continuum specimen and for pre-cracked specimen monotonic tensile test till failure was utilized. Through Digital Image Correlation (DIC) the local strain distribution was assessed through the specimen and the deformation was compared with simulation results. Based on the extensive literature review of material models from PolyUMod library among Viscoplastic models, the Three Network Viscoplastic (TNV) model was selected to proceed with the calibration. The motivation behind choosing TNV model is it's capability of capturing load-unload curves, different strain rates as well as non-linear responses. Furthermore, it was seen that among Viscoplastic models, TNV has the lowest average errors which plays a vital role in this case as the accuracy of FE simulation directly depends on the calibration results. From the experimental results it was safe to say that with increasing strain rates LDPE films tend to get stiffer and stronger both in continuum and pre-cracked. Through the calibration it was seen that the predicted curves were in reasonable agreement with experimental ones. Hence,the calibrated model was exported as python script into Abaqus CAE to perform the simulations. The comparison was done and discussed in details between the simulation and experimental data in three orientations; MD (Machine Direction), CD (Cross Direction) and 45 direction.
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The Effect of Fatty Acid Unsaturation on Properties and Performance of Monomers and Latex Polymers from Plant OilsDemchuk, Zoriana January 2020 (has links)
The interest in renewable natural resources, including plant oils, has become increasingly appealing due to the oil abundance, availability, and wide range of applications for polymers and polymeric materials thereof.
In this dissertation, a library of plant oil-based acrylic monomers (POBMs) with a broad range of unsaturation was synthesized using a one-step transesterification. It is demonstrated that the unsaturation degree of plant oil remains preserved during the synthesis and determines the structure and properties of POBMs. The life cycle assessment (LCA) was conducted in this study to evaluate the environmental impact of soybean oil-based acrylic monomer (SBM) production. LCA was applied to provide guidance for SBM synthesis optimization, including the type of catalyst, the ratio between reactants, renewable sources (soybean oil/biodiesel), and solvent recycling. The performed LCA shows the positive effect of the inclusion of the solvent recycling step in the SBM synthesis.
This study shows that POBMs behave as conventional vinyl monomers in free radical polymerization and copolymerization. The monomer unsaturation impacts polymerization rate and molecular weight of resulted polymers decreasing as follows: poly(OVM) > poly(SFM) > poly(SBM) > poly(LSM), due allylic termination presented during polymerization.
A series of stable POBM-based latexes with high solid content (40-45 %) and monomer conversion (95-97 %) were synthesized using miniemulsion process. The incorporation of POBMs fragments provides the plasticizing effect on the resulting latex polymers, as seen by a noticeable decrease in their glass transition temperature (Tg). The crosslink density of POBM-based latex films follows the linear dependence vs. monomer feed unsaturation, providing a tool for controlling latex mechanical properties, including hardness, toughness, Young's modulus, etc. Besides, the presence of highly hydrophobic POBM fragments enhances water resistivity of latex coatings and films.
Following the "greener" vector of research, a variety of stable latexes from high oleic soybean oil-based monomer (HOSBM) and cardanol, eugenol, and guaiacol derivatives were synthesized in miniemulsion. Resulting polymeric materials advantageously combine flexibility provided by HOSBM fragments with strength facilitated by aromatic biobased units.
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Material Selection for Revolutionary new Electric Motor TypeBergman, Oskar, Stenerhag, Klara, Strömberg, Nicole, Gille, Katja January 2023 (has links)
No description available.
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Long-Term Performance of Polymeric Materials in Civil InfrastructureShaikh, Mohammad Shadab Sadique 14 July 2023 (has links)
Polymeric materials are popular in civil infrastructure due to their durability, strength, and resistance to corrosion and environmental degradation. However, the long-term performance of such materials in civil infrastructure is still being researched and investigated. This thesis will focus on the long-term performance of two civil infrastructure applications: 1) high-density polyethylene (HDPE) above-ground storage tanks (AST) and 2) silicone and self-healing polymeric concrete sealants.
HDPE is a strong and durable plastic material that is commonly used to store a wide range of liquids ASTs. Currently, there are no established protocols for carrying out non-destructive testing (NDT) and assessment of HDPE ASTs for regular inspections, so this study investigated the viability of using infrared thermography (IRT) and ultrasonic testing (UT) for routine inspection. The study discovered that environmental parameters, such as temperature, wind, and humidity, can affect IRT accuracy, and that a proper heating-cooling cycle can aid in defect detection. Concrete joints in pavement systems are often susceptible to deterioration. They are engineered cracks that enable concrete slabs to expand and contract in response to temperature. They serve the dual purpose of preventing water infiltration and improving ride quality, while extending the pavement's service life. Bridge joints, in particular, are susceptible to water and liquid penetration, which can result in extensive damage over time. By applying sealants to these connections, concrete structures can be protected from such damage, thereby extending their service life. Consequently, a better comprehension of sealant performance and additional research are required to develop effective solutions to address these issues and ensure the safety and longevity of concrete structures prone to cracking. In this study, samples of the two commercial silicone joint sealants were sandwiched between Portland cement mortar specimens and tested using a specially designed fixture to imitate the fatigue performance of the joint under simulated field conditions. The results of the study indicated that the fatigue life of the two silicone sealants were different, with Sealant 2 showed better performance than Sealant 1. Both sealants exhibited adhesive failure initiating debonding along the weak interface of cement mortar cube and joint sealant. The results of commercial sealants are then compared with self-healing polysulfide sealants. This indicates that the performance of sealants can vary, and additional research may be required to develop effective solutions to address these issues. / Master of Science / Polymeric materials are widely utilized in construction due to their durability, strength, and resistance to corrosion and environmental degradation. However, the long-term performance of these materials in civil infrastructure is still under investigation. This thesis specifically examines the long-term performance of two civil infrastructure applications: 1) high-density polyethylene (HDPE) above-ground storage tanks (ASTs) and 2) silicone and self-healing polymeric concrete sealants.
HDPE is a robust and durable plastic material commonly employed for storing various liquids in ASTs. Currently, there are no established protocols for conducting non-destructive testing (NDT) and assessment of HDPE ASTs during regular inspections. Therefore, this study investigates the viability of utilizing infrared thermography (IRT) and ultrasonic testing (UT) for routine inspections. The findings reveal that environmental factors such as temperature, wind, and humidity can impact the accuracy of IRT, and implementing a proper heating-cooling cycle can help in detecting such defects inside the tank structure.
Concrete joints in pavement systems are susceptible to deterioration. These engineered cracks allow concrete slabs to expand and contract in response to temperature changes, while preventing water infiltration and enhancing ride quality, thus prolonging the pavement's service life. Bridge joints, in particular, are prone to water and liquid penetration, leading to extensive damage over time. Applying sealants to these connections safeguards concrete structures, extending their service life. Consequently, understanding sealant performance and conducting further research are crucial for developing effective solutions to address these issues and ensure the safety and durability of concrete structures prone to cracking.
This study involves testing two commercially available silicone joint sealants by sandwiching them between Portland cement mortar specimens. A specially designed fixture is employed to simulate the fatigue performance of joints under field-like conditions. The performance of commercial sealants was also compared with self-healing polysulfide sealants. These findings highlight the variability in sealant performance, emphasizing the need for additional research to develop effective solutions.
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Size Effect in Polymeric Materials: the Origins and the Multi-physics Responses in Ultrasound FieldsPeng, Kaiyuan 06 January 2021 (has links)
The size effect in the thermo-mechanical behavior of polymeric materials is a critically important
phenomenon and has been the subject of many researches in past decades. For example,
polystyrene (PS), a widely used polymeric material, is brittle at the bulk state. When the
dimensions decreases to the nanoscale, such as PS in nanofibers, their ductility becomes
orders higher than their bulk state. In recent years a number of diverse applications, such
as scaffolds in tissue engineering, drug delivery devices, as well as soft robotics, are designed
by utilizing the unique properties of polymers at nanoscale. However, the inside mechanism
of the size dependency in polymeric materials are still not clear yet. In this dissertation, systematic
computational and experimental studies are made in order to understand the origins
of the size effect for one- and two-dimensional polymeric materials. This framework is also
expanded to investigate the size-dependent multi-physics response of functional polymeric
materials (shape memory polymers) which are actuated by high-intensity focused ultrasound
(HIFU). Our computational studies are based on molecular dynamic (MD) simulations at
the atomistic scale, and experimentally-validated finite element models at the bulk level.
From bottom-up direction, molecular dynamics can reveal the mechanisms of the size effect
in polymers at molecular level, and help predict properties of the bulk materials. In this
research, MD simulations are performed to track the origins of the size-effect in the mechanical
properties of PE and PS nanofibers. In addition, the size-dependent thermal response
of functional polymeric films is also studied at the atomistic scale by utilizing molecular dynamics simulations to predict the thermal properties and actuation mechanisms in these
materials when subjected to HIFU fields. From top-down direction, experiments and finite
element analysis, are also conducted in this research. An experimentally-validated finite
element framework is built to study the mechanical response of shape memory polymers
(SMPs) triggered by HIFU. As an external trail towards application fields, a SMP composite
with enhanced shape memory ability and also a two-way SMP are synthesized. A smart
gripper and also a self-rolling structure are designed by using these SMPs, which approves
that these SMPs are good components in designing soft robotics. Finally, The influence of
evaporation during fiber forming process is investigated by molecular dynamics simulation.
It is found that the formation of the microstructure of polymeric fibers at nanoscale depends
on the balance of stretching force and evaporation rate when the fiber is forming. / Doctor of Philosophy / Thermomechanical properties of a thin fiber, a thin film and a cube made of a polymer are
significantly different. Although, based on the extensive research that has been performed in
recent years our understanding of this size-dependency is advanced to a great degree in the
past decades, there are still many unanswered basic questions that can only be addressed
by performing computational and experimental investigation at different length scales, from
atomistic up to bulk level in polymers. In this research we target exploring some unknown aspects
of the size dependency in the thermomechanical properties of polymers by investigating
their deformation mechanisms at different length scales. As the first step, we will investigate
the mechanical properties of polymeric fibers. For these fibers, the mechanical properties
are strongly connected to the fiber's diameter. The prevailing hypothesis is that this size
dependency is closely related to the thickness of the surface layer of the nanofibers. Our
results show some unknown origins behind the size dependency of the mechanical properties
in polyethylene (PE) and polystyrene (PS) nanofibers, which originate from the deformation
mechanisms at the atomistic scale. In addition, not just the mechanical properties, the
thermal properties and response of functional polymers subjected to an external stimulation
are also related to their size. For example, the thermal conductivity of a fiber, a sheet and a
cube may be significantly different. Our study shows the thermal responses of different polymers
triggered by ultrasound are also different. The size and the type of the polymers will
both have influence on the final temperature in the polymeric materials, when the polymeric materials are heated by same ultrasound source. We also have applied our computational
and experimental frameworks to investigate this phenomenon. In addition, we also used a
new shape memory polymer composite and a two-way shape memory polymer on designing
soft robotics-like structures. Overall this research indicates that both mechanical response
and thermal responses of polymers are highly related to their dimension. Taking advantage
of these unique size effects, and by tailoring this property, diverse devices can be made for
being used in a broad range of applications.
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