Eco Friendly Composites Prepared from Lactic Acid Based Resin and Natural Fiber

Esmaeili, Nima, Javanshir, Shahrzad

January 2014

Lactic acid based thermoset were synthesised by reacting lactic acid with glycerol andfunctionalizing lactic acid branches by methacrylic anhydride. Resins with different chainlength were prepared and their thermo mechanical properties were examined through DMAanalysis and their molecular structures were analyzed by NMR method and their viscositywere investigated through rheometry analysis and three monomers were selected as the bestchain length. Degree of reaction in different reaction times was evaluated by a modifiedtitration method and bulk preparation of resin was performed by optimal process condition.DSC analysis was conducted in order to evaluate curing behaviour of resin with benzoylperoxide as cross-linking initiator. TGA analysis was performed to check thermo stability ofthe resin. Bio composites by viscose unidirectional and bidirectional knitted fabrics and alsonon woven viscose fiber with different fiber loads were prepared by ordinary hand layupimpregnation followed by compress moulding and their mechanical and thermo mechanicalproperties were characterized by tensile, flexural, charpy and DMA analysis and optimumfiber loads were identified for each fiber type. Ageing properties of prepared composites wereexamined by placing samples in climate chamber to simulate long time ageing and ageingexperiment was followed by tensile and flexural test to evaluate mechanical properties afterageing simulation. Composite`s swelling properties for water and some other solvents wereinvestigated and also their chemical resistance were evaluated by immersing them in 1M HCland KOH. The resin was also compared with a commercial oil based thermoset by preparingglass fiber reinforced composites and also effect of adding styrene to the resin were evaluated.Results of this work demonstrated that the novel synthesised have very high mechanical andthermo mechanical properties surpassing commercial oil based poly esters but ageingbehaviour is not very good however adding styrene can improve ageing properties. Also theresin is compatible with cellulosic natural fibers and forms strong composites. / Program: Masterutbildning i energi- och material

Biobased thermoset

thermoset poly lactic acid

biobased composite

natural fiber

viscose

Engineering and Technology

Teknik och teknologier

Transformation of lignin into biobased thermoset

Cederholm, Linnea

January 2018

Combined microwave assisted extraction/degradation of technical lignin in green solvents was successfully employed to generate polyphenolic oligomers with lower Mw than the starting material. For Lignoboost, the highest liquid yield (65 %) was obtained in 20 min at 160 °C using ethanol as solvent. This is an increase in ethanol soluble yield with 38 % compared to solvent extraction. The highest yield for Lignosulfonate was obtained with methanol as solvent, at 160 °C for 20 min. Obtained liquid fractions were analysed by SEC, FT-IR, DSC, TGA, 31P-NMR and 2D-HSQC NMR in order to explain the mechanism of the increased yield, and to study the structural changes after microwave extraction/degradation. 2D-NMR indicates cleavage of β-O-4 inter-unit linkages, but also that some modification around the bond could take place. Lignin based thermosets were synthesised employing the polyesterification between lignin, citric acid and poly(ethylene glycol) (PEG). It was concluded that introduction of PEG into the system was crucial for a homogenous thermoset synthesis with a high gel content. From TGA analysis it could be concluded that the thermoset based on original Lignoboost had a lower thermal stability than the counterparts prepared from lower molecular weight fractions. This implies that the esterification reaction between original Lignoboost and the other co-monomers is obstruct by sterically hindrance, which means that pre-conditioning is positive for the final material properties. / I denna studie utnyttjades en mikrovågsbaserad teknik, för att framgångsrikt extrahera och bryta ner lignin till polyfunktionella oligomerer med lägre molekylvikt än ursprungsmaterialet. Både lignin extraherat genom sulfat- och sulfitprocessen, d.v.s. kraft lignin (Lignoboost) och lignosulfonat, undersöktes. Det högsta lösliga utbytet för Lignoboost (67 %) kunde uppnås efter 20 min vid 160 °C genom att använda etanol som lösningsmedel, vilket är en ökning med 38 % jämfört med enbart extraktion i etanol. Under samma förhållanden uppnåddes även det högsta lösliga utbytet för Lignosulfonat, fast genom att använda metanol som lösningsmedel. De erhållna lösliga fraktionerna analyserades med hjälp av SEC, FT-IR, DSC, TGA, 31P-NMR samt 2D-HSQC NMR, med syftet att förklara ökning i lösligt utbyte samt studera eventuella strukturella förändringar efter bearbetning i mikrovågsugnen. Resultat från 2D-NMR indikerar på nedbrytning av β-O-4 bindningar, men även på att modifikationer kring bindningen kan ha uppkommit. Tvärbundna, ligninbaserade material syntetiserades genom att nyttja polykondensationsreaktionen mellan lignin, citronsyra och polyetylenglykol (PEG), vilket resulterade i esterbindningar. Det var möjligt att dra slutsatsen att introducering av PEG in i systemet var avgörande för att nå homogena material med hög andel tvärbindningar. Genom TGA analyser kunde det fastslås att tvärbundna material baserade obehandlad Lignoboost hade lägre termisk stabilitet än dess motsvarigheter baserade på fraktioner med lägre molekylvikt. Detta tyder på att esterreaktionen mellan obearbetad Lignoboost och de två andra monomererna försvåras genom steriskhindring, vilket innebär att bearbetning av ligninet medför positiva effekter på egenskaperna hos det slutgiltiga materialet.

lignin

microwave heating

solvolysis

biobased thermoset

lignin

mikrovågsbaserad teknik

solvolys

biobaserad härdplast

Polymer Chemistry

Polymerkemi

Synthesis and characterization of tall oil fatty acid based thermoset resin suitable for natural fiber reinforced composite

Chen, Rong

January 2012

Biobased thermoset resins were synthesized by functionalizing the tall oil fatty acid with hydrogen peroxide and then methacrylic anhydride. The obtained resins were characterized by FTIR to confirm the conversions. The cross-linking ability of the resins were checked by curing experiments and followed by DSC analysis regarding the extent of cross linking. TGA analysis was conducted to identify the thermal degradation patterns of cured resins. The obtained resins (blended with or without 33wt% styrene) were used as matrix and knitted viscose fibers were used as reinforcements to make bio-based composites. Ten layers of knitted viscose fibers were stacked crosswise (0/90⁰С) and hand lay-up impregnation was performed. The fiber ratio of all composites was around 63-66%. The composites were characterized by flexural testing, dynamic mechanical thermal analysis and charpy testing. This work demonstrates that manufacture of composites with both matrix and reinforcement fiber coming from renewable resources is feasible, and the resulted composites have satisfied mechanical performance. / Program: MSc in Resource Recovery - Sustainable Engineering

Tall oil fatty acid

modification

biobased thermoset resin

viscose fibre

biobased composite

compression moulding

Engineering and Technology

Teknik och teknologier

NanobiocompÃsitos superparamagnÃticos para aplicaÃÃo como antenas ressoadoras dielÃtricas / Superparamagnetic nanobiocomposites for application as dielectric resonator antennas

Andrà Leandro da Silva

14 August 2014

nÃo hà / à crescente o interesse mundial pelo desenvolvimento de tecnologias chamadas âverdesâ que possibilitem o uso de produtos com menor impacto ao meio ambiente, assim como tambÃm se fortalecem as polÃticas de incentivo ao aproveitamento mÃximo e sustentÃvel dos recursos naturais. O principal objetivo desse estudo foi desenvolver nanobiocompÃsitos superparamagnÃticos para aplicaÃÃo como antenas ressoadoras dielÃtricas. Para tal, um plÃstico termorrÃgido biobaseado foi preparado utilizando o cardanol em alternativa aos fenÃis petroquÃmicos. Esse plÃstico termorrÃgido foi utilizado como matriz para o preparo de biocompÃsitos, utilizando 15% em massa de fibra de bucha bruta e tambÃm modificada por tratamento quÃmico (NaOH 5, 10 e 15% e NaClO 1%) como fase dispersa. Para o preparo dos nanobiocompÃsitos, alÃm da fibra de bucha, nanopartÃculas de magnetita, sintetizadas pelo mÃtodo da coprecipitaÃÃo, foram impregnadas no plÃstico termorrÃgido em diferentes teores de 1, 5 e 10% em massa. TÃcnicas de Termogravimetria (TG), Calorimetria exploratÃria diferencial (DSC), AnÃlise dinÃmico-mecÃnica (DMA), Microscopia eletrÃnica de varredura (MEV), Microscopia Ãptica, Microscopia eletrÃnica de transmissÃo (MET), DifraÃÃo de raios X (DRX), Espectroscopia no infravermelho com transformada de Fourier (FTIR), Espectroscopia MÃssbauer, Ensaios de resistÃncia à traÃÃo, Medidas dielÃtricas, Magnetometria de amostra vibrante (VSM) e BiodegradaÃÃo em solo simulado foram utilizadas para caracterizaÃÃo. Os resultados mostraram que o tratamento alcalino melhorou a estabilidade tÃrmica e o Ãndice de cristalinidade da fibra de bucha. O agente reticulador utilizado (DETA) mostrou-se eficiente, possibilitando a cura completa dos materiais. Os biocompÃsitos com fibra tratada apresentaram maior estabilidade tÃrmica, resistÃncia à traÃÃo superior e melhor Ãndice de biodegradaÃÃo em relaÃÃo ao biocompÃsito com fibra natural. A magnetita sintetizada exibiu tamanho nanomÃtrico, alÃm de alta pureza, alta cristalinidade e carÃter superparamagnÃtico. Todos os nanobiocompÃsitos exibiram superparamagnetismo e mostraram excelente estabilidade tÃrmica, boas taxas de biodegradaÃÃo e melhor resistÃncia mecÃnica para o material com 10% de magnetita. Todas as antenas ressoadoras dielÃtricas preparadas apresentaram perda de retorno satisfatÃria e, portanto, adequaÃÃo para fins comerciais e tecnolÃgicos, com maior potencial para atuaÃÃo em banda larga. / There is a growing global interest for the development of green technologies that allow the use of products with less damage to environment, as well as for maximum and sustainable use of natural resources. The main aim of this study was to develop superparamagnetic nanobiocomposites for application as dielectric resonator antennas. For this purpose, a biobased thermoset plastic was prepared by using cardanol as an alternative to petrochemical phenol. This thermoset plastic was used as a polymer matrix and biocomposites were prepared by using 15 wt% of untreated and modified sponge gourd fibers by chemical treatment (NaOH 5, 10, and 15 wt% and NaClO 1 wt%) as dispersed phase. For the nanobiocomposites preparation, besides the sponge gourd fibers insertion, the thermoset plastic were also impregnated with magnetite nanoparticles in different contents (1, 5, and 10 wt%). Techniques of Thermogravimetry (TG), Differential Scanning Calorimetry (DSC), Dynamic Mechanical Analysis (DMA), Scanning Electron Microscopy (SEM), Optical Microscopy, Transmission Electron Microscopy (TEM), X-ray Diffraction (XRD), Fourier Transform Infrared Spectroscopy (FTIR), MÃssbauer Spectroscopy, Tensile testing, Dielectric measurements, Vibrating Sample Magnetometry (VSM) and Biodegradation in simulated soil were performed for characterization. The results showed that alkaline treatment improved the thermal stability and the crystallinity index of the sponge gourd fiber. The crosslinking agent used (Diethylenetriamine) was efficient and enabled complete cure for all materials. The biocomposites reinforced by treated fiber showed better thermal stability, superior performance in Tensile testing and greater biodegradation rates, when compared to the biocomposite reinforced by raw fiber. The magnetite particles exhibited nanometric size, high purity and crystallinity, and superparamagnetic character. All nanobiocomposites showed superparamagnetic behavior, excellent thermal stability, good biodegradation rates, and better mechanical strength for the material with magnetite 10 wt%. All dielectric resonators antennas exhibited satisfactory return loss and suitability for commercial and technological applications, especially for performance in broadband.

Cardanol

PlÃstico termorrÃgido biobaseado

Fibra de bucha vegetal

Magnetita

Ressoadores dielÃtricos

Cardanol

Biobased thermoset plastic

Sponge gourd fiber

Magnetite

Dielectric resonators

QUIMICA

Nanobiocompósitos superparamagnéticos para aplicação como antenas ressoadoras dielétricas / Superparamagnetic nanobiocomposites for application as dielectric resonator antennas

Silva, André Leandro da

January 2014

SILVA, André Leandro. Nanobiocompósitos superparamagnéticos para aplicação como antenas ressoadoras dielétricas. 2014. 126 f. : Dissertação (mestrado) - Universidade Federal do Ceará, Departamento de Quimica Orgânica e Inorgânica, Programa de Pós-Graduação e Biotecnologia, Renorbio - Rede Nordeste de Biotecnologia, Fortaleza-CE, 2014. / Submitted by demia Maia (demiamlm@gmail.com) on 2016-05-20T13:09:52Z No. of bitstreams: 1 2014_tese_alsilva.pdf: 6480806 bytes, checksum: 946e32810e24c5137dfbba52bfd30bb8 (MD5) / Approved for entry into archive by demia Maia (demiamlm@gmail.com) on 2016-05-20T13:10:43Z (GMT) No. of bitstreams: 1 2014_tese_alsilva.pdf: 6480806 bytes, checksum: 946e32810e24c5137dfbba52bfd30bb8 (MD5) / Made available in DSpace on 2016-05-20T13:10:43Z (GMT). No. of bitstreams: 1 2014_tese_alsilva.pdf: 6480806 bytes, checksum: 946e32810e24c5137dfbba52bfd30bb8 (MD5) Previous issue date: 2014 / There is a growing global interest for the development of green technologies that allow the use of products with less damage to environment, as well as for maximum and sustainable use of natural resources. The main aim of this study was to develop superparamagnetic nanobiocomposites for application as dielectric resonator antennas. For this purpose, a biobased thermoset plastic was prepared by using cardanol as an alternative to petrochemical phenol. This thermoset plastic was used as a polymer matrix and biocomposites were prepared by using 15 wt% of untreated and modified sponge gourd fibers by chemical treatment (NaOH 5, 10, and 15 wt% and NaClO 1 wt%) as dispersed phase. For the nanobiocomposites preparation, besides the sponge gourd fibers insertion, the thermoset plastic were also impregnated with magnetite nanoparticles in different contents (1, 5, and 10 wt%). Techniques of Thermogravimetry (TG), Differential Scanning Calorimetry (DSC), Dynamic Mechanical Analysis (DMA), Scanning Electron Microscopy (SEM), Optical Microscopy, Transmission Electron Microscopy (TEM), X-ray Diffraction (XRD), Fourier Transform Infrared Spectroscopy (FTIR), Mössbauer Spectroscopy, Tensile testing, Dielectric measurements, Vibrating Sample Magnetometry (VSM) and Biodegradation in simulated soil were performed for characterization. The results showed that alkaline treatment improved the thermal stability and the crystallinity index of the sponge gourd fiber. The crosslinking agent used (Diethylenetriamine) was efficient and enabled complete cure for all materials. The biocomposites reinforced by treated fiber showed better thermal stability, superior performance in Tensile testing and greater biodegradation rates, when compared to the biocomposite reinforced by raw fiber. The magnetite particles exhibited nanometric size, high purity and crystallinity, and superparamagnetic character. All nanobiocomposites showed superparamagnetic behavior, excellent thermal stability, good biodegradation rates, and better mechanical strength for the material with magnetite 10 wt%. All dielectric resonators antennas exhibited satisfactory return loss and suitability for commercial and technological applications, especially for performance in broadband. / É crescente o interesse mundial pelo desenvolvimento de tecnologias chamadas “verdes” que possibilitem o uso de produtos com menor impacto ao meio ambiente, assim como também se fortalecem as políticas de incentivo ao aproveitamento máximo e sustentável dos recursos naturais. O principal objetivo desse estudo foi desenvolver nanobiocompósitos superparamagnéticos para aplicação como antenas ressoadoras dielétricas. Para tal, um plástico termorrígido biobaseado foi preparado utilizando o cardanol em alternativa aos fenóis petroquímicos. Esse plástico termorrígido foi utilizado como matriz para o preparo de biocompósitos, utilizando 15% em massa de fibra de bucha bruta e também modificada por tratamento químico (NaOH 5, 10 e 15% e NaClO 1%) como fase dispersa. Para o preparo dos nanobiocompósitos, além da fibra de bucha, nanopartículas de magnetita, sintetizadas pelo método da coprecipitação, foram impregnadas no plástico termorrígido em diferentes teores de 1, 5 e 10% em massa. Técnicas de Termogravimetria (TG), Calorimetria exploratória diferencial (DSC), Análise dinâmico-mecânica (DMA), Microscopia eletrônica de varredura (MEV), Microscopia óptica, Microscopia eletrônica de transmissão (MET), Difração de raios X (DRX), Espectroscopia no infravermelho com transformada de Fourier (FTIR), Espectroscopia Mössbauer, Ensaios de resistência à tração, Medidas dielétricas, Magnetometria de amostra vibrante (VSM) e Biodegradação em solo simulado foram utilizadas para caracterização. Os resultados mostraram que o tratamento alcalino melhorou a estabilidade térmica e o índice de cristalinidade da fibra de bucha. O agente reticulador utilizado (DETA) mostrou-se eficiente, possibilitando a cura completa dos materiais. Os biocompósitos com fibra tratada apresentaram maior estabilidade térmica, resistência à tração superior e melhor índice de biodegradação em relação ao biocompósito com fibra natural. A magnetita sintetizada exibiu tamanho nanométrico, além de alta pureza, alta cristalinidade e caráter superparamagnético. Todos os nanobiocompósitos exibiram superparamagnetismo e mostraram excelente estabilidade térmica, boas taxas de biodegradação e melhor resistência mecânica para o material com 10% de magnetita. Todas as antenas ressoadoras dielétricas preparadas apresentaram perda de retorno satisfatória e, portanto, adequação para fins comerciais e tecnológicos, com maior potencial para atuação em banda larga.

Quimica

Cardanol

Plástico termorrígido biobaseado

Fibra de bucha vegetal

Magnetita

Ressoadores dielétricos

Cardanol

Biobased thermoset plastic

Sponge gourd fiber

Magnetite

Dielectric resonators

Engenharia de materiais

Nanocompósitos (materiais)

Nanobiotecnologia

Bionanotecnologia

Materiais dielétricos

Biobased Photocurable Resins for 3D-Printing of Self-Healable & Recyclable Thermosets / Biobaserade, UV-härdbara resin för 3D-utskrift av självläkande och återvinningsbara härdplaster

Gardell, Anna, Aspenberg, Maria, Aziz, Julia

January 2022

Överkonsumtionen av engångsartiklar i fossilbaserad plast är ett av dagens stora miljöproblem. Således finns en efterfrågan på strategier för framställning av biobaserade plaster i allmänhet och härdplaster i synnerhet. Tidigare forskning har visat att vanillin-baserade resin, genom UV-härdning och dynamisk iminkemi, kan användas i framställningen av härdplaster som är termiskt bearbetningsbara, kemiskt återvinningsbara och självläkande. Följaktligen är Digital Light Processing (DLP) 3D-utskrivning en möjlig och flexibel friformframställningsmetod med stor noggrannhet för sådana härdplaster.  Mot denna bakgrund framställdes, i detta projekt, tre olika UV-härdbara, biobaserade monomerer, i form av vitrimerresin, genom en tvåstegsreaktion: metakrylering av vanillin följt av iminbildning med tre olika aminer (etylendiamin, EDA; 2,2′-etylendioxi bisetylamin, EDEA och trimetylolpropan trispolypropylenglykol aminterminerad eter, T-403). De tre olika monomererna analyserades för att identifiera den mest lämpade för friformframställning av härdplast med DLP 3D-printning. Monomeren framställd med EDA kunde inte UV-härdas till en härdplast. De två andra monomererna, å andra sidan, härdades framgångsrikt till härdplaster med god termisk stabilitet (upp till ungefär 300 °C) samtidigt som de var termiskt bearbetningsbara. Vidare visade dessa härdplaster lovande resultat vad gäller självläkning och kemisk återvinningsbarhet. Härdningen av monomeren syntetiserad med EDEA krävde minst tidsåtgång. Utöver detta visade denna härdplast god stabilitet i ett flertal vanliga lösningsmedel samtidigt som den, till följd av dess dynamiska iminbindningar, kemiskt kunde återvinnas i hexylamin. Slutligen visades det hur detta resin framgångsrikt kunde användas i DLP 3D-utskrivning av härdplast. / One of the main causes of the petrochemical depletion is the overconsumption of single-use plastic products. New strategies based on the production of plastics (in particular thermosets) starting from bio-based resources are, therefore, demanded. Previous research has shown how vanillin-based vitrimer resins can be photocured into thermally reprocessable, chemically recyclable and self-healable imine thermosets; and the potential of the light-assisted 3D-printing techniques for the photocuring of resins with great accuracy and flexibility.  In this study, three different photocurable biobased vitrimer resins were synthesized through a two-step procedure involving the methacrylation of vanillin and the Schiff-base reaction with two different diamines (ethylenediamine, EDA; 2,2′-(Ethylenedioxy) bis(ethylamine), EDEA) and a triamine (trimethylolpropane tris[poly(propylene glycol), amine terminated] ether, T-403). The resins were analyzed in order to find the most suitable one for DLP 3D-printing. The resin with EDA, as diamine, could not be successfully UV-cured into a thermoset. The other two thermosets showed good thermal stability, up to about 300 °C, while still being thermally reprocessable. In addition, the thermosets were promising in terms of self-healability and chemical recyclability. The thermoset obtained from the Schiff-base resin synthesized with the diamine EDEA provided the shortest curing time. This resin also displayed good solvent resistance against common solvents and potential chemical recyclability in hexylamine through an imine exchange reaction. As a final step, the possibility to obtain tridimensional thermosets by curing this resin with a DLP 3D-printing was successfully demonstrated.

vanillin

vitrimer

imine

resin

dynamic covalent bonds

biobased thermoset

photocuring

chemical recyclability

self-healing

digital light processing (DLP)

3D-printing

vanillin

vitrimer

imin

resin

dynamiska kovalenta bindningar

biobaserad härdplast

fotohärdning

kemisk återvinningsbarhet

självläkning

digital light processing (DLP)

3D-utskrift

Polymer Chemistry

Polymerkemi