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The focus of this thesis was to investigate how PCL and PLGA react to the heat exposure that comes with the MEW process over a defined timespan.
To assess the thermal stability of PCL during MEW over 25 d, an automated collection of fibers has been used to determine the CTS on each day of heating for three different temperatures. PCL is exceptionally stable over 25 d at 75 °C, whereas for 85 °C and 95 °C a slight upward trend during the last 10 d could be observed, which is an indication for thermal degradation. Same trend could be observed for diameter of fibers produced at a fixed collector speed. For all temperatures, CTS during the first 5 d decreased due to inhomogeneities of the melt. Physical analysis of the fibers by XRD and mechanical testing showed no significant changes.
To investigate the chemical details of the thermal durability, PCL was artificially aged over 25 d at 75 °C, 85 °C and 95 °C. Data from GPC analysis and rheology revealed that PCL is degrading steadily at all three temperatures. Combined with GC-MS analysis, two different mechanisms for degradation could be observed: random chain scission and unzipping. Additional GPC experiment using a mixture of PCL and a fluorescence labelled PCL showed that PCL was undergoing ester interchange reactions, which could explain its thermal stability.
PLGA was established successfully as material for MEW. GPC results revealed that PLGA degraded heavily in the one-hour preheating period. To reduce the processing temperature, ATEC was blended with PLGA in three mixtures. This slowed down degradation and a processing window of 6 h could be established. Mechanical testing with fibers produced with PLGA and all three blends was performed. PLGA was very brittle, whereas the blends showed an elastic behavior. This could be explained by ester interchange reactions that formed a loosely crosslinked network with ATEC.
Influence of Carbon Additives on the Electrochemical Performance of Modern Lead-Acid Batteries
(2023)
In the first part of this thesis, a validation of both short-term and long-term DCA tests on 2 V laboratory cells is focussed. The aim is to improve the laboratory cell level measurement technology for dynamic charge acceptance regarding the investigation of carbon additives. To address this issue, it is crucial to apply carbon additives generating a remarkable difference in charge acceptance. For this purpose, five different carbon additives providing a variation in the specific external surface were included as additives in the negative plates of 2 V lead-acid cells. Both short-term (charge acceptance test 2 from SBA and DCA from EN) and long-term (Run-in DCA from Ford) DCA tests were executed on the lead-acid cells. Further understanding of the mechanism was studied by applying electrochemical methods like cyclic voltammetry and electrochemical impedance spectroscopy.
The second part of this thesis aims to understand the impact of carbon surface functional groups on the electrochemical activity of the negative electrodes as well as the DCA of 2 V lead-acid cells. In order to address this topic, commercially available activated carbon was modified by different chemical treatments to incorporate specific surface functional groups in the carbon structure. A series of activated carbons having a broad range of pH was prepared, which were used as additives in the negative electrodes. The corresponding lead-acid cells were subjected to cyclic voltammetry and DCA test according to EN. Further, the physical and chemical properties of the functionalized carbon additives were intensively analyzed to establish a structure-property relationship with a focus on DCA.