@article{15942, author = {{Reuter, Corin and Tröster, Thomas}}, issn = {{0263-8231}}, journal = {{Thin-Walled Structures}}, pages = {{1--9}}, title = {{{Crashworthiness and numerical simulation of hybrid aluminium-CFRP tubes under axial impact}}}, doi = {{10.1016/j.tws.2017.03.034}}, volume = {{117}}, year = {{2017}}, } @phdthesis{16070, author = {{Weiß Borkowski, Nathalie }}, isbn = {{978-3-8440-5013-4}}, publisher = {{Shaker Verlag Band 2017/22}}, title = {{{Analyse des Verformungsverhaltens von Übergangszonen partiell pressgehärteter Strukturen}}}, year = {{2017}}, } @inproceedings{16075, author = {{Ahlers, Dominik and Tröster, Thomas}}, location = {{Nördlingen}}, title = {{{Aspekte der Produktentwicklung in der additiven Fertigung}}}, year = {{2017}}, } @inproceedings{16338, abstract = {{To detect errors or find potential for improvement during the CAD-supported development of a complex technical system like modern industrial machines, the system’s virtual prototype can be examined in virtual reality (VR) in the context of virtual design reviews. Besides exploring the static shape of the examined system, observing the machines’ mechanics (e.g., motor-driven mechanisms) and transport routes for the material transport (e.g., via conveyor belts or chains, or rail-based transport systems) can play an equally important role in such a review. In practice it is often the case, that the relevant information about transport routes, or kinematic properties is either not consequently modeled in the CAD data or is lost during conversion processes. To significantly reduce the manual effort and costs for creating animations of the machines complex behavior with such limited input data for a design review, we present a set of algorithms to automatically determine geometrical properties of machine parts based only on their triangulated surfaces. The algorithms allow to detect the course of transport systems, the orientation of objects in 3d space, rotation axes of cylindrical objects and holes, the number of tooth of gears, as well as the tooth spacing of toothed racks. We implemented the algorithms in the VR system PADrend and applied them to animate virtual prototypes of real machines.}}, author = {{Brandt, Sascha and Fischer, Matthias and Gerges, Maria and Jähn, Claudius and Berssenbrügge, Jan}}, booktitle = {{Volume 1: 37th Computers and Information in Engineering Conference}}, isbn = {{9780791858110}}, location = {{Cleveland, USA}}, pages = {{91:1--91:10}}, title = {{{Automatic Derivation of Geometric Properties of Components From 3D Polygon Models}}}, doi = {{10.1115/detc2017-67528}}, volume = {{1}}, year = {{2017}}, } @inproceedings{16339, abstract = {{In der CAD-unterstützten Entwicklung von technischen Systemen (Maschinen, Anlagen etc.) werden virtuelle Prototypen im Rahmen eines virtuellen Design-Reviews mit Hilfe eines VR-Systems gesamtheitlich betrachtet, um frühzeitig Fehler und Verbesserungsbedarf zu erkennen. Ein wichtiger Untersuchungsgegenstand ist dabei die Analyse von Transportwegen für den Materialtransport mittels Fließbändern, Förderketten oder schienenbasierten Transportsystemen. Diese Transportwege werden im VR-System animiert. Problematisch dabei ist, dass derartige Transportsysteme im zugrundeliegenden CAD-Modell in der Praxis oft nicht modelliert und nur exemplarisch angedeutet werden, da diese für die Konstruktion nicht relevant sind (z.B. der Fördergurt eines Förderbandes, oder die Kette einer Förderkette), oder die Informationen über den Verlauf bei der Konvertierung der Daten in das VR-System verloren gehen. Bei der Animation dieser Transportsysteme in einem VR-System muss der Transportweg also aufwändig, manuell nachgearbeitet werden. Das Ziel dieser Arbeit ist die Reduzierung des notwendigen manuellen Nachbearbeitungsaufwandes für das Design-Review durch eine automatische Berechnung der Animationspfade entlang eines Transportsystems. Es wird ein Algorithmus vorgestellt, der es ermöglicht mit nur geringem zeitlichem Benutzeraufwand den Animationspfad aus den reinen polygonalen dreidimensionalen Daten eines Transportsystems automatisch zu rekonstruieren.}}, author = {{Brandt, Sascha and Fischer, Matthias}}, booktitle = {{Wissenschaftsforum Intelligente Technische Systeme (WInTeSys) 2017}}, location = {{Paderborn}}, pages = {{415--427}}, publisher = {{Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn}}, title = {{{Automatische Ableitung der Transportwege von Transportsystemen aus dem 3D-Polygonmodell}}}, volume = {{369}}, year = {{2017}}, } @inproceedings{16382, author = {{Klingler, Florian and Pannu, Gurjashan Singh and Sommer, Christoph and Dressler, Falko}}, booktitle = {{Proceedings of the 23rd Annual International Conference on Mobile Computing and Networking - MobiCom '17}}, isbn = {{9781450349161}}, title = {{{Connecting Simulation and Real World: IEEE 802.11p in the Loop}}}, doi = {{10.1145/3117811.3131265}}, year = {{2017}}, } @article{13276, author = {{Rutkai, Gábor and Köster, Andreas and Guevara-Carrion, Gabriela and Janzen, Tatjana and Schappals, Michael and Glass, Colin W. and Bernreuther, Martin and Wafai, Amer and Stephan, Simon and Kohns, Maximilian and Reiser, Steffen and Deublein, Stephan and Horsch, Martin and Hasse, Hans and Vrabec, Jadran}}, issn = {{0010-4655}}, journal = {{Computer Physics Communications}}, pages = {{343--351}}, title = {{{ms2: A Molecular Simulation Tool for Thermodynamic Properties, Release 3.0}}}, doi = {{10.1016/j.cpc.2017.07.025}}, volume = {{221}}, year = {{2017}}, } @article{13279, author = {{Schappals, Michael and Mecklenfeld, Andreas and Kröger, Leif and Botan, Vitalie and Köster, Andreas and Stephan, Simon and García, Edder J. and Rutkai, Gabor and Raabe, Gabriele and Klein, Peter and Leonhard, Kai and Glass, Colin W. and Lenhard, Johannes and Vrabec, Jadran and Hasse, Hans}}, journal = {{Journal of Chemical Theory and Computation}}, number = {{9}}, pages = {{4270--4280}}, title = {{{Round Robin Study: Molecular Simulation of Thermodynamic Properties from Models with Internal Degrees of Freedom}}}, doi = {{10.1021/acs.jctc.7b00489}}, volume = {{13}}, year = {{2017}}, } @phdthesis{102, author = {{Becker, Matthias}}, publisher = {{Universität Paderborn}}, title = {{{Engineering Self-Adaptive Systems with Simulation-Based Performence Prediction}}}, doi = {{10.17619/UNIPB/1-133}}, year = {{2017}}, } @article{22038, abstract = {{Micro Physiological Systems (MPS), also known as Multi-Organ-Chip, Organ-on-a-Chip, or Body-on-a-Chip, are advanced microfluidic systems that allow the cultivation of different types of cells and tissue in just one common circuit. Furthermore, they thus can also adjust the interaction of these different tissues. Perspectival MPS will replace animal testing. For fast and flexible manufacturing and marking of MPS, a concept for a universal micromachining platform has been developed which provides the following latest key technologies: laser micro cutting of polymer foils, laser micro- and sub-micro-structuring of polymer foils, 3D printing of polymer components as well as optical inspection and online process control. The combination of different laser sources, processing optics, inspection systems, and print heads on multiple axes allows the change and exactly positioning to the workpiece during the process. Therewith, the realization of MPS including 3D printed components as well as direct laser interference patterned surfaces for well-defined cell adhesion and product protection is possible. Additional basic technologies for the generation of periodical line-like structures at polycarbonate foils using special Direct Laser Interference Patterning (DLIP) optics as well as for the 3D printing of fluid-tight cell culture reservoirs made of Acrylonitrile Butadiene Styrene directly onto polycarbonate microfluidics were established. A first prototype of the universal micromachining platform combining different lasers with Direct Laser Writing and DLIP is shown. With this laser micro cutting as well as laser micro-structuring of polycarbonate (PC) foils and therewith functionalization for MPS application could be successfully demonstrated.}}, author = {{Moritzer, Elmar and Hirsch, André and Günther, K. and Sonntag, F. and Klotzbach, U. and Lasagni, A.F.}}, journal = {{Micromachines}}, number = {{246}}, publisher = {{MDPI}}, title = {{{Universal Micromachining Platform and Basic Technologies for the Manufacture and Marking of Microphysiological Systems}}}, doi = {{10.3390/mi8080246}}, volume = {{8}}, year = {{2017}}, } @book{31856, editor = {{Häsel-Weide, Uta and Nührenbörger, M.}}, isbn = {{978-3-941649-22-4}}, pages = {{297}}, publisher = {{Grundschulverband e. V.}}, title = {{{Gemeinsam Mathematik lernen. Mit allen Kindern rechnen.}}}, year = {{2017}}, } @article{34440, abstract = {{In this paper, the influence of surface roughness on the local tribological load with a dry sliding contact is studied. First, three artificial rough surfaces with similar structure but different asperity heights are generated and projected on a smooth ball. After that, a contact pattern is determined between a rough ball and a smooth surface taking into account the elastic only as well as the linear elastic-perfectly plastic material description. On the basis of the calculated contact pressure distribution, the subsurface stresses and a three-dimensional temperature distribution in the sliding contact are calculated. The solutions show that a low surface roughness not necessarily results in low local tribological load of the surface. }}, author = {{Magyar, Balázs and Sauer, Bernd}}, journal = {{Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology}}, number = {{4}}, pages = {{489--502}}, title = {{{Methods for the simulation of the pressure, stress, and temperature distribution in the contact of fractal generated rough surfaces}}}, doi = {{10.1177/1350650115593962}}, volume = {{231}}, year = {{2017}}, } @inproceedings{25077, author = {{Akin, Akbulut and Stephan , Abke and Christoph, Laroque}}, booktitle = {{Proceedings of the 2017 Winter Simulation Conference (accepted)}}, editor = {{ W. K. V, Chan and D’Ambrogio, A and Zacharewicz, G and Mustafee, N and Wainer, G and Page, E}}, publisher = {{Institute of Electrical and Electronics Engineers, Inc.}}, title = {{{Automated Model Verification using an Equivalence Test on a Reference Model}}}, year = {{2017}}, } @inbook{33615, author = {{Rezat, Sara and Lehnen, Katrin}}, booktitle = {{Ästhetische Erfahrungen – Theoretische Konzepte und empirische Befunde zur kulturellen Bildung. (Studien zur Germanistik und Anglistik, 22)}}, editor = {{Grosser, Sabine and Köller, Katharina and Vorst, Claudia}}, pages = {{31--57}}, publisher = {{Peter Lang Verlag}}, title = {{{Ästhetisch-kulturelle Erfahrungsräume materialgestützten Schreibens}}}, year = {{2017}}, } @inproceedings{35227, author = {{Kiekbusch, T and Magyar, Balázs and Sauer, B}}, booktitle = {{VDI Berichte 2308}}, isbn = {{978-3-18-092308-6}}, pages = {{103--112}}, publisher = {{VDI Verlag GmbH}}, title = {{{Multi-Ebenen-Simulation zur Berechnung der lokalen Lebensdauer in hochbelasteten Wälzkontakten}}}, year = {{2017}}, } @inproceedings{35225, author = {{Magyar, Balázs and Thielen, S and Löwenstein, M and Becker, A and Sauer, B}}, location = {{Beijing}}, title = {{{EHL Simulation of the Timing Chain Drive}}}, volume = {{ID 494908}}, year = {{2017}}, } @inproceedings{35226, author = {{Thielen, S and Magyar, Balázs and Foko Foko, F and Sauer, B}}, location = {{Beijing}}, title = {{{EHL Simulation of the Radial Shaft Sealing System}}}, volume = {{ID 494903}}, year = {{2017}}, } @misc{22531, abstract = {{Die Erfindung betrifft eine Bremseinrichtung (12) für eine im unbetätigten Zustand eingefallene Bremse (10), wobei die Bremseinrichtung (12) eine Druckplatte (18), eine Gegenplatte (20), eine zum Verpressen einer Bremsscheibe (16) zwischen der Druckplatte (18) und der Gegenplatte (20) auf die Druckplatte (18) wirkende Energiespeichereinrichtung (22) sowie eine Lüftvorrichtung (26) zum Lüften der Bremse (10) aufweist, wobei diese Lüftvorrichtung (26) zum Lüften der Bremse (10) eine der Energiespeichereinrichtung (22) entgegenwirkende Aktoreinrichtung (28) aufweist. Es ist vorgesehen, dass die Lüftvorrichtung (26) weiterhin ein Getriebe (30) zur abschaltbaren Kraftübertragung der Kraft der Aktoreinrichtung (28) auf die Druckplatte (18) aufweist, wobei das Abschalten der Kraftübertragung über eine Schalteinrichtung (32) der Lüftvorrichtung (26) steuerbar ist. Die Erfindung betrifft weiterhin eine entsprechende im unbetätigten Zustand eingefallene Bremse (10).}}, author = {{Zimmer, Detmar and Schadomsky, Magnus Hubert and Kriegel, Nils-Peter and Küter, Winfried and Neumann, Christopher}}, title = {{{Bremseinrichtung für eine im unbetätigten Zustand eingefallene Bremse und entsprechende Aktoreinrichtung zum Lüften der Bremse}}}, year = {{2017}}, } @inproceedings{35223, author = {{Heimes, J and Bactavatchalou , R and Bock, E and Frölich, D and Kaiser, F and Langner, T and Morgenstern, S and Magyar, B and Sauer, B}}, isbn = {{978-3-9817451-2-2}}, pages = {{67/1--67/10}}, publisher = {{GfT}}, title = {{{Parametrisches thermisches Netzwerk zur Simulation der Temperaturverteilung eines RWDR-Prüfstandes}}}, year = {{2017}}, } @inproceedings{35224, author = {{Thielen, S and Magyar, Balázs and Foko Foko, F and Sauer, B}}, isbn = {{978-3-9817451-2-2}}, pages = {{22/1--22/8}}, publisher = {{GfT}}, title = {{{EHL simulation of radial shaft seals}}}, year = {{2017}}, }