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Low-energy recycling of poly(ethylen terephthalate) waste
Slabá, Jitka ; Beneš, Hynek (advisor) ; Cajthaml, Tomáš (referee)
This thesis deals with a new low-energy method of chemical recycling of poly(ethylene terephthalate) (PET) using natural oils as reagents and microwave irradiation to accelerate depolymerization. The results of experiments with PET waste and castor oil, when the reaction mixture was heated in microwave reactor, showed that a complete depolymerization of PET chain has occured. Optimal conditions for the depolymerization PET were established: wt. ratio of PET / castor oil = 1 / 9.7, when the molar ratio of ester bonds of PET / hydroxyl groups of castor oil = 1 / 2.7, catalyst : zinc acetate at wt 1% from the PET mass, reaction temperature ranging from 235 to 245řC and the reaction time 60 min. Decomposition experiments also showed, that microwave irradiation accelerated decomposition of PET. Depolymerization reactionin MW reactor was complete at 6x shorter reaction time than the decomposition in the classically heated reactor. The results of analysis showed that the resulting product,the recyclate, was composed of unreacted castor oil and polyol products, that contained partially or fully esterified structural unit of PET, which were ended by ester-linked units of castor oil.
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Hybrid materials with improved thermomechanical properties
Perchacz, Magdalena ; Beneš, Hynek (advisor) ; Vlček, Tomáš (referee) ; Brožek, Jiří (referee)
Epoxy resins have been broadly used in the industry for adhesives, laminates, coatings, composites, encapsulation of electronic devices, printed circuit boards, etc. Despite their excellent adhesion to different materials, heat and chemical resistance and good mechanical properties, they also exhibit few drawbacks like brittleness, high thermal expansion coefficient (CTE), poor resistance to crack initiation and growth. Therefore, the thesis is focused on the preparation of epoxy-silica hybrid materials exhibiting improved thermomechanical properties compared to the neat epoxides, without impairing their beneficial features. The main synthetic route of epoxy-silica hybrids' preparation has been the sol-gel process of alkoxysilanes, allowing either in-situ formation of high purity and homogeneity silica particles or creation of various siloxane structures in a form of liquid (sol) silica-based precursors. The sol-gel method, on one hand, helps to omit too high viscosity of nanofiller suspension and energy-intensive nanofiller dispergation problems, but on the other hand, is often associated with necessity to use solvents and to remove formed volatiles. Therefore, in the first part of the thesis, a simple solvent-free sol-gel procedure, enabling to minimize the side-effect of solvent evaporation and...
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Biodegradability assessment of new types of lightweight polyurethanes
Tošovská, Kateřina ; Innemanová, Petra (advisor) ; Beneš, Hynek (referee)
The subject of the bachelor thesis is biological degradation (biodegradation) of new types of lightweight polyurethanes which were synthesized for an agriculture application. The theoretical part summarises the utilization and biodegradation principles of polyurethanes and it outlines standardised methods for quantification of biodegradability potential. The biodegradability potential of the new materials was tested respirometrically according to the standard D 5988 under laboratory conditions for 150 days. Cellulose (the positive control) was mineralised of 30,25±2,28 %. The best biodegradable material (PUR-B) was mineralised of 9,73±1,95 %. According to the procedure described in the standard D 5988 our results were undervalued. Consequently absorbed CO2 released from biodegradeble materials was stabilised by reaction with BaCl2. The reaciton is needed to interpret the results correctly. A screening method for a quick test of biodegradability was designed. It included biodegradation by bacterial inoculum in mineral medium. The availability of materials for microbial degradation was meassured as a time-dependent function of optical density. The non-biodegradable residual particles of plastics represent a potential risk for the environment. The issue of microplastics and their quantification was...
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Application of renewable and recyclable raw materials for preparation of new polymers
Horák, Pavel ; Beneš, Hynek (advisor) ; Cajthaml, Tomáš (referee)
This thesis deals with optimalization of flexible polyurethane foam recycling with using of natural polyols based on rape seed oil and fish oil and it explores applications of depolymerized polyol product by formulations of new polyurethane materials. The experiments of depolymerisation showed that both tested natural oil (rape seed oil and fish oil) can be used as effective reagents for polyurethane recycling. Reaction conditions of depolymerisation were optimised with model flexible polyurethane foam and applied on waste foam from real conditions. Gain of depolymerisation is one-faze low viscosity (to 1500 mPa.s) liquid polyol products with content of hydroxyl groups ca 3 mmol/g. These polyols can be used for polymerisation of new materials. First application of recycled polyols was formulation of polyurethane foam systems. Through optimising of formula was prepared low-density semirigid foam containing 100 percentage of recycled polyol. Properties of these foams correspond to commercial foams. To prepare of homogenous cast polyurethane system based on recycled polyols it was necessary to add proper solvent, therefor extent of application has been lowered. On that account the systems were tested for study of polyaddition reaction and for following properties of the material. In these tests, the reactivity...
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Microwave-assisted preparation of polymer materials
Bujok, Sonia ; Beneš, Hynek (advisor) ; Brožek, Jiří (referee) ; Duchet-Rumeau, Jannick (referee)
Bearing in mind environmental concerns and global trends in ecology, biodegradable polyesters have gained enormous attention as alternative to non-biodegradable, commercial polymers used mainly in packaging industry contributing to the worldwide environment pollution. However, substitution of conventional polymers with biodegradable polyesters is limited due to their inferior mechanical and barrier properties, which can be improved by the introduction of relatively small content of non-toxic nanofillers. Nevertheless, environmental pollution is not only affected by material itself, but also manufacturing and processing sector in terms of energy sustainability. In case of the latter, low energetic processes are nowadays preferential. Thus, using microwave irradiation as the more efficient energy source, which can lead to shortening of process time, has become currently investigated subject. In this thesis, microwave-assisted in-situ synthesis of biodegradable nanocomposites based on polycaprolactone and non-toxic clay nanoparticles (layered double hydroxides) was studied and described in detail in four subsections (4.1-4.4). The first subsection (4.1) describes one-pot synthesis of Mg2+ /Al3+ layered double hydroxides functionalized with highly microwave-absorbing ionic liquids. In order to improve...
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Book of Abstracts and Programme
Beneš, Hynek
The book of abstracts and program of the 8th Workshop on Green Chemistry and Nanotechnologies in Polymer Chemistry contain contributions in thematically focused scientific sessions covering all frontiers topics in (i) Green Polymer Chemistry: green materials composed of renewable resources, biodegradable materials, low environmental impact routes such as microwave assisted polymerizations, green solvents comprising ionic liquids, polymer waste valorization, etc., and in (ii) Polymer Nanotechnologies: nanomaterials with bio-based and functional nanofillers, nanostructured networks, polymer nanoparticles for sustainable technologies, etc.
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Hybrid materials with improved thermomechanical properties
Perchacz, Magdalena ; Beneš, Hynek (advisor) ; Vlček, Tomáš (referee) ; Brožek, Jiří (referee)
Epoxy resins have been broadly used in the industry for adhesives, laminates, coatings, composites, encapsulation of electronic devices, printed circuit boards, etc. Despite their excellent adhesion to different materials, heat and chemical resistance and good mechanical properties, they also exhibit few drawbacks like brittleness, high thermal expansion coefficient (CTE), poor resistance to crack initiation and growth. Therefore, the thesis is focused on the preparation of epoxy-silica hybrid materials exhibiting improved thermomechanical properties compared to the neat epoxides, without impairing their beneficial features. The main synthetic route of epoxy-silica hybrids' preparation has been the sol-gel process of alkoxysilanes, allowing either in-situ formation of high purity and homogeneity silica particles or creation of various siloxane structures in a form of liquid (sol) silica-based precursors. The sol-gel method, on one hand, helps to omit too high viscosity of nanofiller suspension and energy-intensive nanofiller dispergation problems, but on the other hand, is often associated with necessity to use solvents and to remove formed volatiles. Therefore, in the first part of the thesis, a simple solvent-free sol-gel procedure, enabling to minimize the side-effect of solvent evaporation and...
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Biodegradability assessment of new types of lightweight polyurethanes
Tošovská, Kateřina ; Innemanová, Petra (advisor) ; Beneš, Hynek (referee)
The subject of the bachelor thesis is biological degradation (biodegradation) of new types of lightweight polyurethanes which were synthesized for an agriculture application. The theoretical part summarises the utilization and biodegradation principles of polyurethanes and it outlines standardised methods for quantification of biodegradability potential. The biodegradability potential of the new materials was tested respirometrically according to the standard D 5988 under laboratory conditions for 150 days. Cellulose (the positive control) was mineralised of 30,25±2,28 %. The best biodegradable material (PUR-B) was mineralised of 9,73±1,95 %. According to the procedure described in the standard D 5988 our results were undervalued. Consequently absorbed CO2 released from biodegradeble materials was stabilised by reaction with BaCl2. The reaciton is needed to interpret the results correctly. A screening method for a quick test of biodegradability was designed. It included biodegradation by bacterial inoculum in mineral medium. The availability of materials for microbial degradation was meassured as a time-dependent function of optical density. The non-biodegradable residual particles of plastics represent a potential risk for the environment. The issue of microplastics and their quantification was...
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Low-energy recycling of poly(ethylen terephthalate) waste
Slabá, Jitka ; Beneš, Hynek (advisor) ; Cajthaml, Tomáš (referee)
This thesis deals with a new low-energy method of chemical recycling of poly(ethylene terephthalate) (PET) using natural oils as reagents and microwave irradiation to accelerate depolymerization. The results of experiments with PET waste and castor oil, when the reaction mixture was heated in microwave reactor, showed that a complete depolymerization of PET chain has occured. Optimal conditions for the depolymerization PET were established: wt. ratio of PET / castor oil = 1 / 9.7, when the molar ratio of ester bonds of PET / hydroxyl groups of castor oil = 1 / 2.7, catalyst : zinc acetate at wt 1% from the PET mass, reaction temperature ranging from 235 to 245řC and the reaction time 60 min. Decomposition experiments also showed, that microwave irradiation accelerated decomposition of PET. Depolymerization reactionin MW reactor was complete at 6x shorter reaction time than the decomposition in the classically heated reactor. The results of analysis showed that the resulting product,the recyclate, was composed of unreacted castor oil and polyol products, that contained partially or fully esterified structural unit of PET, which were ended by ester-linked units of castor oil.
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