TY - JOUR AU - Schöppner, Volker AU - Dörner, M. AU - Marschik, C. AU - Steinbichler, G. ID - 24231 JF - Polymers TI - Development of an Analytical Model to Describe the Disperse Melting in Wave-Dispersion Screws ER - TY - JOUR AU - Moritzer, Elmar AU - Jilg, J. AU - Schilp, C. AU - Krempl, N. AU - Friesenbichler, W. ID - 24232 JF - Kunststoffe TI - Die Kunst der Entformung ER - TY - JOUR AU - Moritzer, Elmar AU - Hopp, Matthias AU - Wittke, Marius ID - 24233 JF - WAK Jahreszeitschrift TI - EINSATZ VON MASCHINELLEM LERNEN FÜR DIE REZYKLAT-VERARBEITUNG ER - TY - JOUR AU - Moritzer, Elmar AU - Krassmann, Dimitri ID - 24234 JF - Joining Plastics TI - Entwicklung einer neuartigen Fügetechnik für Organoblech-Hybridverbindungen ER - TY - CONF AU - Moritzer, Elmar AU - Krassmann, Dimitri AU - Brikmann, Johannes ID - 24235 T2 - 10. Fügetechnisches Gemeinschaftskolloquium TI - Entwicklung eines Spritzgießsonderverfahrens zur Herstellung von Hybridbauteilen aus faserverstärkten Thermoplasten und Metallblechen ER - TY - CONF AU - Moritzer, Elmar AU - Kartelmeyer, S. AU - Hüttemann, M. AU - Jaroschek, C. ID - 24237 T2 - 78th Annual Technical Conference for Plastics Professionals (ANTEC) TI - INJECTION MOLD COOLED WITH ADDITIVE MANUFACTURED HEAT PIPE CORE-ELEMENT ER - TY - CONF AU - Moritzer, Elmar AU - Mühlhoff, Frederik Marvin ID - 24238 T2 - Annual Technical Conference of the Society of Plastics Engineers (ANTEC) 2020 TI - Inline Surface Activation in the multi Injection Molding Process ER - TY - JOUR AU - Moritzer, Elmar AU - Mühlhoff, Frederik Marvin AU - Lochbaum, Ella AU - Krampe, Erhard ID - 24239 JF - KGK - Rubberpoint TI - InMould-Plasma Technologie - Dauerhaft beständige 2K-Verbunde aus originär inkompatiblen Kunststoffen ER - TY - JOUR AU - Rasche, David B. AU - Tigges, Lena AU - Schmid, Hans-Joachim ID - 24240 JF - Review of Scientific Instruments SN - 0034-6748 TI - An apparatus to synthesize ceramic nanoparticles with a precisely adjusted temperature history and a significant mass output ER - TY - JOUR AB - For gas phase nanoparticle production, hot wall reactors are widely used. In this article, we will describe the fundamental design considerations for a hot wall reactor system able to produce oxide nanoparticles. The system is outstanding in its ability to produce mostly spherical nanoparticles at particle sizes of up to 100 nm and even larger at mass outputs in the order of grams per hour by being able to rapidly quench the aerosol. While high production rates or larger particle sizes are already easily obtained with hot wall reactors, it is very challenging to produce these spherical particles at high mass rates. We will show in this research that the temperature and the particle number concentration are the major aspects influencing the particle morphology at the end of the process. Investigation on the performance of the setup shows good control over the temperature and the particle production stability. A representative particle characterization using SEM and scanning mobility particle sizer showed that particles are mostly spherical, while the particle size distribution had a geometric standard deviation close to 1.5. In addition to the aspects mentioned above, a possibility to manipulate the aggregation downstream of the reactor is to be presented as well. We found that applying electrical charges to the aerosol particles (in opposite polarity) can significantly foster aggregation. AU - Rasche, David B. AU - Tigges, Lena AU - Schmid, Hans-Joachim ID - 24241 JF - Review of Scientific Instruments TI - An Apparatus to Synthesize Ceramic Nanoparticles with a Precisely Adjusted Temperature History and a Significant Mass Output VL - 91 ER -