|
| |
|
|
Utilization of biomass for the energy purposes
Romanová, Kristýna ; Ing.Ondřej Kosík, Ph.D. (referee) ; Flodrová, Dana (advisor)
The theoretical part of work focuses on the issue of biomass used for energy purposes, in particular agricultural waste, which can be used as a substrate for biogas station. Furthermore, examines the composition of polymer substrates, which affects most biogas process. The aim of this work was to measure each sample of enzyme activity of biomass, which is used as a raw material for biogas plants.
|
|
|
Preparation of Microbial Metabolites from Waste Materials
Zichová, Miroslava ; Márová, Ivana (referee) ; Stloukal, Radek (referee) ; Rosenberg, Michal (advisor)
In this thesis the use of waste materials for the microbial production of important metabolites is reported. The first part is focused on the use of waste paper (a lignocellulosic material) as a non-traditional source for the production of bioethanol. The second part is focused on the immobilization of cellulolytic enzymes, which are used for the hydrolysis of lignocellulosic materials. First, the waste paper (cardboard) was pre-treated using a blender and a vibratory mill. The pre-treated cardboard was used for the production of ethanol by the method of simultaneous saccharification and fermentation. This method was optimized with free cells of Saccharomyces cerevisiae. Then strains suitable for the immobilization were selected. Strains of S. cerevisiae and Pichia kudriavzevii were immobilized by encapsulation into the polyvinyl alcohol carrier and tested again for the ethanol production by simultaneous saccharification and fermentation. In the second part of the work a carrier from waste polyethylene terephthalate bottles was prepared and used for the immobilization of the cellulolytic complex. The basic characteristics were determined, such as optimal pH and optimal temperature, storage, operational and thermal stability, enzyme kinetics and the mode of action of the enzyme. Compared to two other commercial carriers this carrier showed to be suitable for the immobilization of the cellulolytic complex.
|
|
|
Immobilization of selected glycanohydrolases
Reichstädter, Marek ; Trachtová, Štěpánka (referee) ; Omelková, Jiřina (advisor)
The theoretical part of this thesis deals with cellulolytic enzymes, their microbial producers, the possibilities of using such enzymes in the industry and how can be enzymes - not only cellulolytic - immobilized. Experimental part examines the preparations created by immobilizing various amounts of the commercially used cellulolytic complex Cellulast 1.5L onto various synthetic carriers made of polyethylene terephthalate - commercially used Sorsilen, PET carrier and glutaraldehyde-treated PET carrier. Enzyme activity of these preparations was determined by Somogyi - Nelson method by spectrophotometry. For the highest activity immobilized preparation was determined the temperature- and the pH-optimum. The difference in effects change between the free and immobilized enzyme by measuring viscosity decrease of the substrate depending on the degradation of glycosidic bonds was also studied.
|
|
|
Enzymatic hydrolysis of waste cardboard using the SSF method - a source of raw materials for the production of liquid biofuels.
Hlaváček, Viliam ; Stloukal, Radek (referee) ; Gabriel, Petr (advisor)
This master’s thesis discusses the useof enzymatic hydrolysis process of waste cardboard using simultaneous saccharification and fermentation (SSF) as a source of raw materials for production of liquid biofuels. This thesis is based on theses written by Ing. Brummer and Ing.Lepař.Thus, results gained in these works have been used and also further developed. The theoretical part summarizes the reasons for further development of SSF method and discusses, as well, the achievements reached in the processing of lignocellulosic waste materials by the SSF method so far.This section also discusses the general characteristics of lignocellulosic materials and also of the cellulolytic enzymes. It focusses also on individual pretreatment methods of lignocellulosic material and options of increasing the yield of the whole process. The experimental part verifies the particular results reached in previous theses and at the same time a further optimization of the method has been carried out because of the transfer of the whole process into a fermenter. Cardboard was set as the substrate for the experiments as it was evaluated by Ing. Brummer as the best one for enzymatic hydrolysis which was carried out by enzymes from Novozymes®. Parameters such as temperature, pH and kind of used buffer, the loading concentration of substrate and enzymes, were set according to the thesis of Ing. Lepař, which was aimed to their optimization. The SSF process done in fermenter of 2.0 l volume confirmed the previous results and furthermore it has been more effective through optimization of the added inoculum volume. It has been confirmed that the best substrate is cardboard finely grinded by vibrating mill. Also experiments with added nutrients had been done as an effort to increase the ethanol concentration, but these haven’t resulted insatisfying results. The maximal concentration of ethanol was 23,49 g/l, which was achieved after further optimization of various conditions. This result equals to experimental yield of 84,79 %.
|
|
|
Preparation of Microbial Metabolites from Waste Materials
Zichová, Miroslava ; Márová, Ivana (referee) ; Stloukal, Radek (referee) ; Rosenberg, Michal (advisor)
In this thesis the use of waste materials for the microbial production of important metabolites is reported. The first part is focused on the use of waste paper (a lignocellulosic material) as a non-traditional source for the production of bioethanol. The second part is focused on the immobilization of cellulolytic enzymes, which are used for the hydrolysis of lignocellulosic materials. First, the waste paper (cardboard) was pre-treated using a blender and a vibratory mill. The pre-treated cardboard was used for the production of ethanol by the method of simultaneous saccharification and fermentation. This method was optimized with free cells of Saccharomyces cerevisiae. Then strains suitable for the immobilization were selected. Strains of S. cerevisiae and Pichia kudriavzevii were immobilized by encapsulation into the polyvinyl alcohol carrier and tested again for the ethanol production by simultaneous saccharification and fermentation. In the second part of the work a carrier from waste polyethylene terephthalate bottles was prepared and used for the immobilization of the cellulolytic complex. The basic characteristics were determined, such as optimal pH and optimal temperature, storage, operational and thermal stability, enzyme kinetics and the mode of action of the enzyme. Compared to two other commercial carriers this carrier showed to be suitable for the immobilization of the cellulolytic complex.
|
|
|
Immobilization of selected glycanohydrolases
Reichstädter, Marek ; Trachtová, Štěpánka (referee) ; Omelková, Jiřina (advisor)
The theoretical part of this thesis deals with cellulolytic enzymes, their microbial producers, the possibilities of using such enzymes in the industry and how can be enzymes - not only cellulolytic - immobilized. Experimental part examines the preparations created by immobilizing various amounts of the commercially used cellulolytic complex Cellulast 1.5L onto various synthetic carriers made of polyethylene terephthalate - commercially used Sorsilen, PET carrier and glutaraldehyde-treated PET carrier. Enzyme activity of these preparations was determined by Somogyi - Nelson method by spectrophotometry. For the highest activity immobilized preparation was determined the temperature- and the pH-optimum. The difference in effects change between the free and immobilized enzyme by measuring viscosity decrease of the substrate depending on the degradation of glycosidic bonds was also studied.
|
|
|
Enzymatic hydrolysis of waste cardboard using the SSF method - a source of raw materials for the production of liquid biofuels.
Hlaváček, Viliam ; Stloukal, Radek (referee) ; Gabriel, Petr (advisor)
This master’s thesis discusses the useof enzymatic hydrolysis process of waste cardboard using simultaneous saccharification and fermentation (SSF) as a source of raw materials for production of liquid biofuels. This thesis is based on theses written by Ing. Brummer and Ing.Lepař.Thus, results gained in these works have been used and also further developed. The theoretical part summarizes the reasons for further development of SSF method and discusses, as well, the achievements reached in the processing of lignocellulosic waste materials by the SSF method so far.This section also discusses the general characteristics of lignocellulosic materials and also of the cellulolytic enzymes. It focusses also on individual pretreatment methods of lignocellulosic material and options of increasing the yield of the whole process. The experimental part verifies the particular results reached in previous theses and at the same time a further optimization of the method has been carried out because of the transfer of the whole process into a fermenter. Cardboard was set as the substrate for the experiments as it was evaluated by Ing. Brummer as the best one for enzymatic hydrolysis which was carried out by enzymes from Novozymes®. Parameters such as temperature, pH and kind of used buffer, the loading concentration of substrate and enzymes, were set according to the thesis of Ing. Lepař, which was aimed to their optimization. The SSF process done in fermenter of 2.0 l volume confirmed the previous results and furthermore it has been more effective through optimization of the added inoculum volume. It has been confirmed that the best substrate is cardboard finely grinded by vibrating mill. Also experiments with added nutrients had been done as an effort to increase the ethanol concentration, but these haven’t resulted insatisfying results. The maximal concentration of ethanol was 23,49 g/l, which was achieved after further optimization of various conditions. This result equals to experimental yield of 84,79 %.
|
|
| |
|
|
Utilization of biomass for the energy purposes
Romanová, Kristýna ; Ing.Ondřej Kosík, Ph.D. (referee) ; Flodrová, Dana (advisor)
The theoretical part of work focuses on the issue of biomass used for energy purposes, in particular agricultural waste, which can be used as a substrate for biogas station. Furthermore, examines the composition of polymer substrates, which affects most biogas process. The aim of this work was to measure each sample of enzyme activity of biomass, which is used as a raw material for biogas plants.
|
guest ::
