Abstract
We present the modification of ethylene-propylene rubber (EPM) with vinyltetra-methydisiloxane (VTMDS) via reactive extrusion to create a new silicone-based material with the potential for high-performance applications in the automotive, industrial and biomedical sectors. The radical-initiated modification is achieved with a peroxide catalyst starting the grafting reaction. The preparation process of the VTMDS-grafted EPM was systematically investigated using process analytical technology (in-line Raman spectroscopy) and the statistical design of experiments (DoE). By applying an orthogonal factorial array based on a face-centered central composite experimental design, the identification, quantification and mathematical modeling of the effects of the process factors on the grafting result were undertaken. Based on response surface models, process windows were defined that yield high grafting degrees and good grafting efficiency in terms of grafting agent utilization. To control the grafting process in terms of grafting degree and grafting efficiency, the chemical changes taking place during the modification procedure in the extruder were observed in real-time using a spectroscopic in-line Raman probe which was directly inserted into the extruder. Successful grafting of the EPM was validated in the final product by 1H-NMR and FTIR spectroscopy.
Highlights
High-performance polymers receive considerable attention due to their special property profiles, enabling their usage in highly demanding application fields
We present the modification of ethylene-propylene rubber (EPM) with vinyltetramethydisiloxane (VTMDS) via reactive extrusion to create a new silicone-based material with the potential for high-performance applications in the automotive, industrial and biomedical sectors
Determination of grafting degree and grafting efficiency was performed in an analogous way as described in previous studies on grafting silane coupling agents onto ethylene propylene (EPM) and ethylene-octene copolymer (EOC) polyolefins [2,4]
Summary
High-performance polymers receive considerable attention due to their special property profiles, enabling their usage in highly demanding application fields. High-performance synthetic elastomers are obtained that can be used, for instance, as sealants in the automotive and construction industries due to their extraordinary chemical stability, mechanical performance and durability. These properties make them suitable as membrane materials for polymer electrolyte membrane (PEM) fuel cells [5,6,7,8,9,10]. A new addition-crosslinkable base-polymer with the potential for highperformance applications as synthetic rubber was produced and the possibility for in-line process control via in situ Raman spectroscopy was demonstrated. It is shown that both raw material consumption and formation of the grafted material can be monitored using in-line Raman spectroscopic probes directly in the process
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