Biopolymer Structure Analysis and Saccharification of Glycerol Thermal Processed Biomass

Zhang, Wei

31 January 2015

Glycerol thermal processing (GTP) is studied as a novel biomass pretreatment method in this research with the purposes to facilitate biopolymer fractionation and biomass saccharification. This approach is performed by treating sweet gum particles on polymer processing equipment at high temperatures and short times in the presence of anhydrous glycerol. Nine severity conditions are studied to assess the impact of time and temperature during the processing on biopolymer structure and conversion. The GTP pretreatment results in the disruption of cell wall networks by increasing the removal of side-chain sugars and lignin-carbohydrate linkages based on severity conditions. After pretreatment, 41% of the lignin and 68% of the xylan is recovered in a dry powdered form by subsequent extractions without additional catalysts, leaving a relatively pure cellulose fraction, 84% glucan, as found in chemical pulps. Lignin structural analysis indicated GTP processing resulted in extensive degradation of B-aryl ether bonds through the C-y elimination, followed by abundant phenolic hydroxyl liberation. At the same time, condensation occurred in the GTP lignin, providing relatively high molecular weight, near to that of the enzymatic mild acidolysis lignin. Better thermal stability was observed for this GTP lignin. In addition to lignin, xylan was successfully isolated as another polymer stream after GTP pretreatment. The recovered water insoluble xylan (WIX) was predominant alkali soluble fraction with a maximum purity of 84% and comparable molecular weight to xylan isolated from non-pretreated fibers. Additionally, the narrow molecular weight distribution of recovered WIX, was arisen from the pre-extraction of low molecular weight water-soluble xylan. Additionally, a 20-fold increase of the ultimate enzymatic saccharification for GTP pretreated biomass was observed even with significant amounts of lignin and xylan remaining on the non-extracted fiber. The shear and heat processing caused a disintegrated cell wall structure with formation of biomass debris and release of cellulose fibrils, enhancing surface area and most likely porosity. These structural changes were responsible for the improved biomass digestibility. Additionally, no significant inhibitory compounds for saccharification are produced during GTP processing, even at high temperatures. While lignin extraction did not promote improvement in hydrolysis rates, further xylan extraction greatly increases the initial enzymatic hydrolysis rate and final level of saccharification. The serial of studies fully demonstrate glycerol thermal processing as a novel pretreatment method to enhance biomass saccharification for biofuel production, as well as facilitate biopolymer fractionation. Moreover, the study shows the impact of thermally introduced structural changes to wood biopolymers when heated in anhydrous environments in the presence of hydrogen bonding solvent. / Ph. D.

glycerol thermal processing

lignin

xylan

biomass saccharification

structural analysis

Evaluation of Alternative Electron Donors for Denitifying Moving Bed Biofilm Reactors (MBBRs)

Bill, Karen Alexandra

11 June 2009

Moving bed biofilm reactors (MBBRs) have been used effectively to reach low nutrient levels in northern Europe for nearly 20 years at cold temperatures. A relatively new technology to the US, the MBBR has most typically been used in a post-denitrification configuration with methanol for additional nitrate removal. Methanol has clearly been the most commonly used external carbon source for post-denitrification processes due to low cost and effectiveness. However, with the requirement for more US wastewater treatment plants to reach effluent total nitrogen levels approaching 3 mg/L, alternative electron donors could promote more rapid MBBR startup/acclimation times and increased cold weather denitrification rates. Bench-scale MBBRs evaluating four different electron donor sources, specifically methanol, ethanol, glycerol, and sulfide (added as Na2S), were operated continuously at 12 °C, and performance was monitored by weekly sampling and insitu batch substrate limiting profile testing. Ethanol and glycerol, though visually exhibited much higher biofilm carrier biomass content, performed better than methanol in terms of removal rate (0.9 and 1.0 versus 0.6 g N/m²/day.) Maximum denitrification rate measurements from profile testing suggested that ethanol and glycerol (2.2 and 1.9 g N/m²/day, respectively) exhibited rates that were four times that of methanol (0.49 g N/m²/day.) Sulfide also performed much better than any of the other three electron donors with maximum rates at 3.6 g N/m²/day and with yield (COD/NO₃-N) that was similar to or slightly less than that of methanol. Overall, the yield and carbon utilization rates were much lower than expected for all four electron donors and much lower than previously reported; indicating that there could be advantages for attached growth versus suspended growth processes in terms of carbon utilization rates. The batch limiting NO₃-N and COD profiles were also used to find effective K_s values. These kinetic parameters describe NO₃-N and COD limitations into the biofilm, which affect the overall denitrification rates. Compared to the other electron donors, the maximum rate for methanol was quite low, but the estimated K_s value was also low (0.4 mg/L N). This suggests high NO₃-N affinity and low mass transfer resistance. The other three electron donors estimated higher K_s values, indicating that these biofilms have high diffusion resistance. Biofilm process modeling is more complex than for mechanistic suspended growth, since mass transfer affects substrate to and into the biofilm. Simulating the bench-scale MBBR performance using BioWin 3.0, verified that μ_max and boundary layer thickness play key roles in determining rates of substrate utilization. Adjustments in these parameters made it possible to mimic the MBBRs, but it is difficult to determine whether the differences are due to the MBBR process or the model. / Master of Science

glycerol

external carbon

ethanol

denitrification

MBBR

methanol

sulfide

Síntese de nanopartículas de ouro com forma e tamanho controlados utilizando glicerol como um agente de redução e estabilização ecológico e de baixo custo / Synthesis of Shape and Size controlled gold nanoparticles using glycerol as a low-cost and environmental friendly reducing and stabilizing agent

Parveen, Rashida

26 June 2017

As nanopartículas de ouro (AuNPs), com formatos e distribuição de tamanhos definidos, têm atraído grande atenção devido às suas propriedades óticas e e catalíticas únicas, que dependem de da forma e tamanho de AuNPs e que são importantes para diversos aplicações. O desenvolvimento de métodos simples e ecológicamente seguros para a síntese de AuNPs de tamanho e forma controlados, empregando reagentes de baixo custo e de fácil manuseamento é, portanto, de grande importância. Considerando isto, realizou-se um estudo sistemático para preparar nanoparticlus de ouro (AuNPs) e prata (AgNPs) com um controle de forma e tamanho, empregando exclusivamente glicerol como um agente redutor flexivel, eco-friendly e de baixo custo. Em primeiro lugar, descrevemos um novo one-pot método para a preparação de nanorods ou nanobastões de ouro (AuNRs) monocristalinos com quase 100% de rendimento empragando o glicerol em meio alcalino como agente redutor e Brometo de hexadeciltrimetilamónio (CTAB) como agente controlador da forma de particulas. Podemos conseguir um controle da razões de aspecto (Aspect ratio do inglês, AR = 2 a 6), rendimento de AuNRs (27-99%) bem como da posicao de banda de absorção óticas de AuNRs (de 620 a 1200 nm) simplesmente variando as condições experimentais, principalmente o pH de meio reaccional (variou-se entre 12-13,5) e a concentração do AgNO3. Descobrimos que a formação de AuNRs é mais rápida a pH mais alto (> 11) e a maior temperatura (> 30 ° C), mas o rendimento de AuNRs é menor (< 70%). A análise de HRTEM mostrou que os AuNRs crescem na direcção [001] e têm uma estrutura do tipo fcc monocristalina, isenta de falhas estruturais ou deslocamentos. Em segundo lugar, realizamos com sucesso, pela primeira vez, a formação de nanoparticlulas esféricas de ouro (AuNPs), quase monodispersas de cerca de 8 nm, utilizando o glicerol bruto conhecido localmente como Glicerina Loíra (crude glycerol (CG) do inglê), tal como recebido, da planta de biodiesel pela. Não foi realizado nehum tratamento químico ou físico específico do CG, exceto filtração simples. Utilizaram-se duas amostras diferentes de CG com diferentes teores de glicerol (65% e 73%) e diferentes níveis de impurezas (baixo e alto) e tipos (orgânicos e inorgânicos) para preparar AuNPs, a fim de estudar o efeito de possíveis impurezas na formato e distribuição de tamanho de AuNPs. Para comparação, foram também preparadas AuNPs utilizando glicerol comercial puro (99,5%) em condições experimentais idênticas. Foram obtidos AuNPs com tamanho e formato semelhantes em ambos os casos (glicerol puro comercial e CG) indicando que o glicerol comercial pode ser substituído por CG na síntese de AuNPs e as impurezas orgânicas e inorgânicas não afectam significativamente a distribuição de tamanho de AuNPs preparadas . Este estudo abre novas possibilidades para um eco-friendly preparação de nanopartículas metálicas utilizando o CG com um agente redutor barato, não tóxico e biodegradável como. Em terceiro lugar, desenvolvemos um método de síntese de AuNPs do tipo Ligand-free (sem uso de agente establizante) empregando o glicerol tanto como agente redutor quanto com agente estabilizador. A ideia era evitar o uso de um agente estabilizante externo que muitas vezes diminui a actividade catalítica ou afeta adversamente a biocompatibilidade dos sistemas surfactante/AuNPs. Obtiveram-se AuNPs coloidais estáveis com uma distribuição de tamanho razoavelmente estreita (8 &plusmn; 3 nm) por este método e verificou-se que a estabilidade e distribuição de tamanho das partículas dependiam da razão água/glicerol, temperatura e pH dos meios reaccionais. Tais ligand-free AuNPs preparados utilizando glicerol podem ser utilizadas nas aplicações catáliticas e biomédicas. / Gold nanoparticles (AuNPs) especially with a control of size and shape have attracted great attention due to their shape-dependent optical properties that are important for many applications. The development of simpler and greener methods for the synthesis of size- and shape-controlled AuNPs employing low-cost and easily handled reagents is thus of great importance. Thus we have carried out a systematic study to prepare shape- and size-controlled AuNPs and AgNPs employing exclusively glycerol as an eco-friendly, low cost and pH-tunable reducing agent. Firstly, we report a new one-pot seedless method for the preparation of single-crystalline AuNRs in almost 100% yield based on the use of glycerol in alkaline medium as the reducing agent and hexadecyltrimethylammonium bromide (CTAB) as the shape-controlling agent. We could achieve a control of the aspect ratio (AR= 2 to 6), AuNRs yield (27-99%) as well the LSPR band of the AuNRs (620 to 1200 nm) by simply varying the experimental conditions, principally the pH of the reaction media (varied between 12-13.5 ) and the concentration of the AgNO3. We found that the formation of AuNRs is faster at higher pH (>11) and higher temperature (>30°C) but the AuNRs yield is smaller (< 70%). HRTEM analysis showed that the AuNRs grow in [001] direction and have a perfect single crystalline fcc structure, free from structural faults or dislocations. Secondly, we successfully carried out the formation of nearly monodisperse spherical AuNPs of around 8 nm using the as-received crude glycerol (CG) from the biodiesel plant for the first time. No special chemical or physical treatment of CG except simple filtration was carried out. Two different crude glycerol samples with different glycerol contents (65% and 73%) and different impurity levels (low and high) and types (organic and inorganic) were employed to prepare AuNPs so as to study the effect of possible impurities on the shape and size distribution of AuNPs. For comparison, AuNPs were also prepared using pure commercial (99.5 %) glycerol under identical experimental conditions. AuNPs with similar size and shape were obtained in both cases (commercial pure glycerol as well as CG) indicating that commercial glycerol can be replaced with CG in the AuNPs synthesis and the organic and inorganic impurities do not significantly affect the particle size distribution of prepared AuNPs. This study opens up new possibilities for the environment-friendly preparation of metallic nanoparticles using the low-cost, non-toxic and biodegradable CG as a reducing agent. Thirdly, we developed a ligand-free one-pot synthesis method of AuNPs employing the eco-friendly glycerol both as reducing agent and stabilizing agent. The idea was to avoid the use of an external stabilizing agent which often hinder the catalytic activity and adversely affect the biocompatibility of the surfactant/AuNP systems. Stable AuNPs with reasonably good size distribution (8 &plusmn; 3 nm) were obtained by this method and the stability and size distribution of the particles was found to be dependent on the water/glycerol ratio, temperature and pH of the reaction media. Such surfactant-free biocompatible AuNPs prepared using the eco-friendly glycerol may find useful applications in catalysis and biomedical applications.

Glicerol bruto

Glycerol

glycerol method

Gold nanoparticles

gold nanorods

Método Glicerol

Nanobastões de ouro

Nanopartículas de ouro

Nanopartículas de prata

silver nanoparticles

Síntese de nanopartículas de ouro com forma e tamanho controlados utilizando glicerol como um agente de redução e estabilização ecológico e de baixo custo / Synthesis of Shape and Size controlled gold nanoparticles using glycerol as a low-cost and environmental friendly reducing and stabilizing agent

Rashida Parveen

26 June 2017

As nanopartículas de ouro (AuNPs), com formatos e distribuição de tamanhos definidos, têm atraído grande atenção devido às suas propriedades óticas e e catalíticas únicas, que dependem de da forma e tamanho de AuNPs e que são importantes para diversos aplicações. O desenvolvimento de métodos simples e ecológicamente seguros para a síntese de AuNPs de tamanho e forma controlados, empregando reagentes de baixo custo e de fácil manuseamento é, portanto, de grande importância. Considerando isto, realizou-se um estudo sistemático para preparar nanoparticlus de ouro (AuNPs) e prata (AgNPs) com um controle de forma e tamanho, empregando exclusivamente glicerol como um agente redutor flexivel, eco-friendly e de baixo custo. Em primeiro lugar, descrevemos um novo one-pot método para a preparação de nanorods ou nanobastões de ouro (AuNRs) monocristalinos com quase 100% de rendimento empragando o glicerol em meio alcalino como agente redutor e Brometo de hexadeciltrimetilamónio (CTAB) como agente controlador da forma de particulas. Podemos conseguir um controle da razões de aspecto (Aspect ratio do inglês, AR = 2 a 6), rendimento de AuNRs (27-99%) bem como da posicao de banda de absorção óticas de AuNRs (de 620 a 1200 nm) simplesmente variando as condições experimentais, principalmente o pH de meio reaccional (variou-se entre 12-13,5) e a concentração do AgNO3. Descobrimos que a formação de AuNRs é mais rápida a pH mais alto (> 11) e a maior temperatura (> 30 ° C), mas o rendimento de AuNRs é menor (< 70%). A análise de HRTEM mostrou que os AuNRs crescem na direcção [001] e têm uma estrutura do tipo fcc monocristalina, isenta de falhas estruturais ou deslocamentos. Em segundo lugar, realizamos com sucesso, pela primeira vez, a formação de nanoparticlulas esféricas de ouro (AuNPs), quase monodispersas de cerca de 8 nm, utilizando o glicerol bruto conhecido localmente como Glicerina Loíra (crude glycerol (CG) do inglê), tal como recebido, da planta de biodiesel pela. Não foi realizado nehum tratamento químico ou físico específico do CG, exceto filtração simples. Utilizaram-se duas amostras diferentes de CG com diferentes teores de glicerol (65% e 73%) e diferentes níveis de impurezas (baixo e alto) e tipos (orgânicos e inorgânicos) para preparar AuNPs, a fim de estudar o efeito de possíveis impurezas na formato e distribuição de tamanho de AuNPs. Para comparação, foram também preparadas AuNPs utilizando glicerol comercial puro (99,5%) em condições experimentais idênticas. Foram obtidos AuNPs com tamanho e formato semelhantes em ambos os casos (glicerol puro comercial e CG) indicando que o glicerol comercial pode ser substituído por CG na síntese de AuNPs e as impurezas orgânicas e inorgânicas não afectam significativamente a distribuição de tamanho de AuNPs preparadas . Este estudo abre novas possibilidades para um eco-friendly preparação de nanopartículas metálicas utilizando o CG com um agente redutor barato, não tóxico e biodegradável como. Em terceiro lugar, desenvolvemos um método de síntese de AuNPs do tipo Ligand-free (sem uso de agente establizante) empregando o glicerol tanto como agente redutor quanto com agente estabilizador. A ideia era evitar o uso de um agente estabilizante externo que muitas vezes diminui a actividade catalítica ou afeta adversamente a biocompatibilidade dos sistemas surfactante/AuNPs. Obtiveram-se AuNPs coloidais estáveis com uma distribuição de tamanho razoavelmente estreita (8 &plusmn; 3 nm) por este método e verificou-se que a estabilidade e distribuição de tamanho das partículas dependiam da razão água/glicerol, temperatura e pH dos meios reaccionais. Tais ligand-free AuNPs preparados utilizando glicerol podem ser utilizadas nas aplicações catáliticas e biomédicas. / Gold nanoparticles (AuNPs) especially with a control of size and shape have attracted great attention due to their shape-dependent optical properties that are important for many applications. The development of simpler and greener methods for the synthesis of size- and shape-controlled AuNPs employing low-cost and easily handled reagents is thus of great importance. Thus we have carried out a systematic study to prepare shape- and size-controlled AuNPs and AgNPs employing exclusively glycerol as an eco-friendly, low cost and pH-tunable reducing agent. Firstly, we report a new one-pot seedless method for the preparation of single-crystalline AuNRs in almost 100% yield based on the use of glycerol in alkaline medium as the reducing agent and hexadecyltrimethylammonium bromide (CTAB) as the shape-controlling agent. We could achieve a control of the aspect ratio (AR= 2 to 6), AuNRs yield (27-99%) as well the LSPR band of the AuNRs (620 to 1200 nm) by simply varying the experimental conditions, principally the pH of the reaction media (varied between 12-13.5 ) and the concentration of the AgNO3. We found that the formation of AuNRs is faster at higher pH (>11) and higher temperature (>30°C) but the AuNRs yield is smaller (< 70%). HRTEM analysis showed that the AuNRs grow in [001] direction and have a perfect single crystalline fcc structure, free from structural faults or dislocations. Secondly, we successfully carried out the formation of nearly monodisperse spherical AuNPs of around 8 nm using the as-received crude glycerol (CG) from the biodiesel plant for the first time. No special chemical or physical treatment of CG except simple filtration was carried out. Two different crude glycerol samples with different glycerol contents (65% and 73%) and different impurity levels (low and high) and types (organic and inorganic) were employed to prepare AuNPs so as to study the effect of possible impurities on the shape and size distribution of AuNPs. For comparison, AuNPs were also prepared using pure commercial (99.5 %) glycerol under identical experimental conditions. AuNPs with similar size and shape were obtained in both cases (commercial pure glycerol as well as CG) indicating that commercial glycerol can be replaced with CG in the AuNPs synthesis and the organic and inorganic impurities do not significantly affect the particle size distribution of prepared AuNPs. This study opens up new possibilities for the environment-friendly preparation of metallic nanoparticles using the low-cost, non-toxic and biodegradable CG as a reducing agent. Thirdly, we developed a ligand-free one-pot synthesis method of AuNPs employing the eco-friendly glycerol both as reducing agent and stabilizing agent. The idea was to avoid the use of an external stabilizing agent which often hinder the catalytic activity and adversely affect the biocompatibility of the surfactant/AuNP systems. Stable AuNPs with reasonably good size distribution (8 &plusmn; 3 nm) were obtained by this method and the stability and size distribution of the particles was found to be dependent on the water/glycerol ratio, temperature and pH of the reaction media. Such surfactant-free biocompatible AuNPs prepared using the eco-friendly glycerol may find useful applications in catalysis and biomedical applications.

Glicerol bruto

Método Glicerol

Nanobastões de ouro

Nanopartículas de ouro

Nanopartículas de prata

Glycerol

glycerol method

Gold nanoparticles

gold nanorods

silver nanoparticles

Zum Einfluss textureller, struktureller und acider Eigenschaften phosphorsäuremodifizierter ZSM-5-Zeolithe auf die heterogen-katalysierte Umsetzung von Glycerol

Göhlich, Maik

04 April 2011

Die Nutzung von Kraftstoffen auf der Basis von Biodiesel erlaubt es, konventionelle, etablierte Antriebstechniken mit Nachhaltigkeit zu kombinieren. Daher kann in den nächsten Jahren mit einer weiteren weltweiten Steigerung der Biodieselproduktion gerechnet werden. Damit verbunden ist jedoch auch ein Anstieg der anfallenden Menge an Glycerol, das bei der Herstellung von Biodiesel als Koppelprodukt entsteht. Da traditionelle Märkte für Glycerol kaum mehr Wachstum zeigen, müssen neue Wege zur effizienten Verwertung von Glycerol gefunden werden. Die vorliegende Arbeit beschäftigt sich mit der heterogen-katalysierten Umsetzung von Glycerol zu Acrolein. Unter Verwendung von ZSM-5-Katalysatorproben mit unterschiedlichem Si/Al-Verhältnis und phosphorsäure-modifizierten Katalysatorproben konnte die Existenz von Synergieeffekten zwischen den texturellen, strukturellen und aciden Eigenschaften in der heterogen-katalysierten Glyceroldehydratisierung zu Gunsten der Acroleinselektivität eindeutig nachgewiesen werden. Eine selektive Umsetzung von Glycerol zu Acrolein wird daher an solchen Katalysatorproben ermöglicht, die ausgewogene texturelle, strukturelle und acide Eigenschaften aufweisen.

Glycerol

Glycerin

Phosphorsäure

ZSM-5

heterogene Katalyse

ZSM-5

glycerol

heterogeneous catalysis

phosphoric acid

ddc:547

rvk:VK 5587

Experimental and theoretical studies of water droplet surfaces in the presence of glycerol / Experimentella och teoretiska studier av vattendroppars ytor vid inverkan av glycerol

Anton, Nygren

January 2017

Water aerosols affect the climate because they have an impact on the radiation balance and cloud formation. Water is present in all forms in the atmosphere (water, ice and steam), for example as rain and hail. Water aerosols play an important role in many biological and chemical processes in the atmosphere. The most common form of water in the atmosphere is water droplets or vapor which often come from oceans and lakes and these aerosols often contain organic compounds. It is therefore interesting to study if organic compounds, in this case glycerol, will reside on the surface or inside the water droplets. The investigations were performed by using theoretical studies, molecular dynamic simulations in GROMACS, and experimental investigations; X-ray photoelectron spectroscopy with a liquid jet. The experiments were performed at BESSY II, Berlin. The concentrations of glycerol were varied from 75:1; 8:1 to 4:1 (water: glycerol molecules). The results were that the experiments and simulations indicated that when theconcentration of glycerol increased the glycerol concentration at the surface of the waterdroplet increases until a monolayer of glycerol molecules was formed at the surface. When the monolayer was formed (or close to) less and less glycerol molecules were placed at thewater surface and more and more glycerol molecules were placed in the bulk of the waterdroplet. / Vattenaerosoler påverkar klimatet eftersom de har en inverkan på strålningsbalansen och molnbildningen. Vatten finns i alla former i atmosfären (vatten, is och ånga) som bland annat regn och hagel. Vatten aerosolerna spelar en viktig roll i många kemiska och biologiska processer i atmosfären. Den vanligaste formen av vatten i atmosfären är små vattendroppar eller ånga som ofta kommer från hav och sjöar och som ofta innehar organiska föreningar. Då vattenaerosoler påverkar klimatet och organiska föreningar är vanligt förekommande i vattendroppar är det intressant att undersöka om organiska föreningar, i detta fall glycerol, hamnar på ytan eller inuti vattnet. Undersökningarna har gjorts genom att använda teoretiska perspektiv, molekylärdynamiska simuleringar i GROMACS, samt experimentella undersökningar i form av röntgen fotoelektronspektroskopi med en vätskejet. Dessa experiment utfördes i BESSY II, Berlin. Koncentrationerna av glycerol varierades från75:1; 8:1 till 4:1 (vatten: glycerolmolekyler). Resultaten från experimenten och simuleringarna indikerade att när koncentrationen av glycerol ökade så ökade glycerolkoncentrationen på ytan av vattendroppen tills det bildades ett monolager av glycerolmolekyler på vattenytan. När monolagret hade bildats så placerades mindre och mindre glycerolmolekyler på vattenytan och fler och fler glycerolmolekyler placerades inne i vattendroppen.

glycerol

water surface

BESSY II

MD

GROMACS

PES

XPS

glycerol

vattenytor

BESSY II

MD

GROMACS

PES

XPS

Physical Sciences

Fysik

Možnost zpracování glycerolové fáze z výroby bionafty / Possibilities of reprocessing of glycerol layer from the manufacture of bionaphta

Hýža, Bohumil

January 2014

The aim of this thesis was to introduce and apply the possibilities of using waste glycerol from biodiesel production and partly waste low-stiffen coolant from cars that could be applied in industry. At the beginning of the thesis is summarized biodiesel production and its world production. There is more developed biodiesel production in the Czech Republic and in the European Union and some European legal regulations and standards for biodiesel. Also described herein is a composition of biodiesel and the description of the technology of its production. In the theoretical section summarizes the physical and chemical properties of glycerol and there is also summarized the traditional use of glycerol as food, explosives, etc. There are also new procedures that were performed in the experimental part of the thesis. There are described the ion exchange mechanism, ion exchange resin properties and the properties of the acids and salts generated by neutralization with NaOH contained in the waste glycerol. Also is described herein the wood protection and properties of ethylene glycol coolants and properties of boroglycerol and boroglycol as protection for wood and mechanism of their preparation. Next is described the mechanism of dehydration of glycerol to acrolein and options which can perform the synthesis. In the experimental part, the pH of waste glycerol was measured, then was measured the exact amount of NaOH in the glycerol. There is also desribed cleaning of waste glycerol from NaOH using acidic cation exchange resins on columns, or by neutralization with oleic acid, lactic acid and CO2. Further syntheses were performed glycerol borate and ethylene glycol borate. Water amount in ethylene glycol and methanol with water amount in glycerol were found by distillation. Then were prepared boroglycol and boroglycerol. By the amount resulting from the amount of reaction water were observed reaction conditions H3BO3, Na2B4O7•10 H2O and glycerol. At the end was carried out experimental dilution resulting boroglycerol and boroglycol by ethanol, methanol, TMB. Finally, the diluted boroglycerol was deposited on wood. Dehydration of glycerol to acrolein under the catalytic action of KHSO4 was performed. The results are given all the results and discussed the possibility of using the knowledge gained in this work in the industry. In conclusion, there are listed the economic comparison using waste glycerol and crude oil as a raw material and also charts the development of oil prices in 40 years since 1970, and graph of the price of waste glycerol.

Možnosti zpracování odpadů glykolu a glycerolu na účelové látky / Possibilities of reprocessing of the glycol and glycerol waste into suitable materials

Hýža, Bohumil

January 2014

At the beginning of the thesis is summarized biodiesel production and its world production. There is more developed biodiesel production in the Czech Republic and in the European Union and some European legal regulations and standards for biodiesel. Also described herein is a composition of biodiesel and the description of the technology of its production. In the theoretical section summarizes the physical and chemical properties of glycerol and there is also summarized the traditional use of glycerol as food, explosives, etc. There are also new procedures that were performed in the experimental part of the thesis. Then, here are the proposed new procedures for processing waste glycerol and glycol, which were conducted in the experimental part of the thesis. There are described the ion exchange properties of the cation exchangers and also properties of salts generated by neutralization of NaOH in the waste glycerol with organic acids and CO2. There is also described wood protection, properties of ethylene glycol as coolant and properties of boroglycerols and boroglycols as protection for wood and mechanism of their preparation. Then there is described a mechanism of dehydration of glycerol to acrolein and options which can perform the synthesis. In the experimental part, the pH of waste glycerol was measured and then was measured the amount of NaOH in the waste glycerol. There is also desribed cleaning of waste glycerol from NaOH using acidic cation exchange resins on columns, or by neutralization with oleic acid, lactic acid and CO2. Further syntheses were performed glycerol borate and ethylene glycol borate. Water amount in ethylene glycol and methanol with water amount in glycerol were found by distillation. Then were prepared boroglycol and boroglycerol. By the amount resulting from the amount of reaction water were observed reaction conditions H3BO3, Na2B4O7•10 H2O and glycerol. At the end was carried out experimental dilution resulting boroglycerol and boroglycol by ethanol, methanol, TMB. Finally, the diluted boroglycerol was deposited on wood. Dehydration of glycerol to acrolein under the catalytic action of KHSO4 was performed. The results are given all the results and discussed the possibility of using the knowledge gained in this work in the industry. In conclusion, there are listed the economic comparison using waste glycerol and crude oil as a raw material and also charts the development of oil prices in 40 years since 1970, and graph of the price of waste glycerol. There is also discussed technological applicability of the methods used in practice.

Glycerolmetabolismus und Pathogenität von <i>Mycoplasma pneumoniae</i> / Glycerol metabolism and pathogenicity of <i>Mycoplasma pneumoniae</i>

Hames, Claudine

29 April 2008

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Glycerol

Virulenzfaktor

Phosphorylierung

Glycerol

virulence factor

phosphorylation

42.30 Mikrobiologie

WUK 000 Genetik der Mikroorganismen

Molekularbiologie der Mikrorganismen

Etude de procédés de conversion de biomasse en eau supercritique pour l'obtention d'hydrogène. : Application au glucose, glycérol et bio-glycérol / Study of biomass conversion in supercritical water processes to produce hydrogen. : Application to glucose, glycerol and bio-glycerol

Wu Yu, Qian Michelle

31 January 2012

Des nouveaux procédés éco-efficients basés sur une meilleure utilisation des ressources renouvelables sont nécessaires pour assurer la continuité du développement énergétique. La thèse étudie le procédé de gazéification en eau supercritique (T>374°C et P>22,1 MPa) de la biomasse très humide pour l’obtention de l’hydrogène, molécule ayant un potentiel énergétique très intéressant à valoriser avec un impact environnemental très favorable. L’étude porte sur l’application du procédé à la biomasse modèle (solutions de glucose, glycérol et leur mélange) ainsi qu’au bioglycérol, résidu de la fabrication du biodiesel. Les propriétés du solvant et les mécanismes prépondérants développés par l’eau en phase souset supercritique peuvent être contrôlés par les paramètres opératoires imposés au processus : température, pression, concentration en molécules organiques et catalyseur alcalin, temps de réaction... Les études paramétriques des systèmes réactionnels ont été menées dans des réacteurs batch à deux échelles différentes, les phases résultantes étant caractérisées par des protocoles analytiques élaborés et validés dans le cadre de l’étude. Le suivi du milieu réactionnel en batch lors de son déplacement vers l’état supercritique a mis en évidence une conversion avancée des molécules organiques et une identification de certains intermédiaires générés. Parmi les paramètres étudiés, la température et le temps de réaction influent le plus le rendement à l’obtention d’hydrogène en présence de catalyseur (K2CO3) dans les réacteurs batch, rendements de 1,5 et 2 mol d’H2 respectivement par mol de glycérol et de glucose introduites. Les gaz obtenus contiennent des proportions variables d’hydrocarbures légers et du CO2. Environ 75% du carbone est converti en phase gaz et liquide (sous forme de carbone organique et inorganique), le restant étant déposé sous forme solide ou huileuse. L’analyse du solide généré (plus de 90% de C) laisse apparaître différentes phases, y compris la formation de nanoparticules sphériques. Enfin, la gazéification en réacteur continu du glycérol préchauffé a montré de meilleurs rendements en hydrogène que le procédé batch, pendant que celle du bioglycérol demande une évolution du procédé à cause de la précipitation en phase supercritique des sels contenus dans le réactant. En conclusion, la gazéification en eau supercritique de la biomasse peut être considérée comme une alternative intéressante à d’autres procédés physico-chimiques de production de l’hydrogène. L’amélioration du procédé sera possible par son intensification menée en parallèle avec l’utilisation de matériaux plus performants et le contrôle de la salinité de la phase réactante. / Supercritical water (T > 374 ° C and P > 22.1 MPa) gasification of wet biomass for hydrogen production is investigated. This process converts a renewable resource into a gas, which is mainly composed of hydrogen and hydrocarbons with interesting energy potential, and which can be separated at high pressure. In addition, the greenhouse gas effect of the process is zero or negative. Model biomasses (glucose, glycerol and their mixture) and bio-glycerol, residue from bio-diesel production, have been gasified by different processes: two-scale batch reactors (5 mL and 500 mL) and a continuous gasification system. Supercritical water acts as a reactive solvent, its properties can be adjusted by the choice of the experimental (P, T) couple. The operating parameters, e.g. temperature, pressure, concentration of biomass and alkaline catalysts, reaction time… allow favoring certain reaction mechanisms. In order to characterize the processes, specific analytical protocols have been developed and validated. The intermediates, formed during the heating time in the batch reactors, have been identified. Among the investigated operating parameters, temperature and reaction time have the greatest influence on the hydrogen production in batch reactors. In the presence of catalyst (K2CO3), H2 yields of 1.5 mol/mol glucose and 2 mol/mol glycerol have been respectively observed. The obtained gas contains different proportions of light hydrocarbons and CO2. About 75% of the carbon is converted into gas and liquid (in form of organic and inorganic carbon). The conversion leads also to a solid or oily residue. In the generated solid phase (composed over 90% of C), spherical nanoparticles are observed via electronic microscopy. The hydrogen production from glycerol is improved in the continuous process compared to batch reactors, however, bio-glycerol supercritical water gasification requests process improvement due to the precipitation of the salt contained in the reactant. In conclusion, supercritical water gasification of biomass can be considered as an promising alternative process for hydrogen production. The process should be improved by more performing equipments and by the control of the salinity content of the crude biomass.

Hydrogène

Catalyseur alcalin

Glucose

Glycérol

Glycérol brut

Supercritical water gasification (SCWG)

Hydrogen

Alkali catalyst

Glucose

Glycerol

Crude glycerol