@inproceedings{28136, abstract = {{In order to achieve a sustainable competitive advantage, technology-oriented companies are more than ever asked to identify potentials of technologies for future business at an early stage and to convert them into innovations. Emergent technologies in particular have a high potential for radical innovations. However, the high innovation potential is offset by high market and technology uncertainties, which are caused by incomplete knowledge of the technology potential and development as well as of potential application contexts. In connection with emergent technologies, the finding of potential - i.e. the generation of knowledge regarding the potentials - is essential, as it lays the foundation for the search for potential application contexts. At the same time, this represents a challenge, since conventional market research approaches only have a limited effect here. The question that arises is how technology potentials can be derived in a discursive way. Furthermore, we hypothesize that the TRIZ approach has great potential for this: (1) In a reversal of the TRIZ logic, we see a way of accessing the TRIZ knowledge base via an analogy; (2) In this way, contradictions within the meaning of TRIZ can be determined, which can be addressed by the technology; (3) A continuous specification of the contradictions represents a possibility to infer technology potentials. The present article presents an approach developed at the Heinz Nixdorf Institute for a TRIZ-based potential finding within the framework of technology-induced innovation processes. The approach comprises the three phases of technology analysis, technology foresight and technology potential analysis. Based on the analysis of the current performance of the technology, the future performance is anticipated using the TRIZ development pattern. By reversing the TRIZ logic, technology potentials are finally determined. }}, author = {{Wall, Marina and Gausemeier, Jürgen and Peter, Stefan}}, editor = {{Gausemeier, Jürgen}}, pages = {{95--123}}, publisher = {{publishing series of the Heinz Nixdorf Institute, Paderborn}}, title = {{{TRIZ-based potential finding in technology-induced innovation processes}}}, year = {{2014}}, } @inproceedings{28186, abstract = {{Product innovations are of great strategic importance for securing the long-term competitiveness of companies. Often, however, companies are faced with two core problems when introducing product innovations to the market: There is a lack of a methodology for systematic customer integration in the product development process. In addition, due to their complexity and the novelty of the technologies used, the product concepts exceed the customers' imagination. This means that customers do not evaluate new product concepts objectively because they do not fully understand the product benefits. In this article, a software-supported procedure for early customer integration is presented. The core of the process is a multi-stage limit conjoint analysis with an integrated virtual reality application.}}, author = {{Backhaus, Klaus and Gausemeier, Jürgen and Stöcklein, Jörg and Jasper, Jonas and Westhoff, Katharina and Grafe, Michael}}, publisher = {{Fraunhofer IFF}}, title = {{{VR-based conjoint analysis for the early determination of customer benefits}}}, year = {{2014}}, } @inbook{28411, author = {{Gausemeier, Jürgen and Amshoff, Benjamin and Dülme, Christian and Kage, Martin}}, booktitle = {{Foresight and Technology Planning}}, editor = {{Gausemeier, Jürgen}}, pages = {{6--36}}, publisher = {{publishing series of the Heinz Nixdorf Institute, Paderborn}}, title = {{{Strategic planning of market services in the context of Industry 4.0}}}, volume = {{334}}, year = {{2014}}, } @inproceedings{28189, abstract = {{Innovative products are based on an interdisciplinary interaction between mechanics, electronics and information technology. The close interplay of the specialist disciplines makes special demands on the development process. For example, a uniform understanding of the specialists is particularly important for an efficient development of the product and the associated production system. Furthermore, the product concept often already determines the production system, even though new production technologies make innovative products possible in the first place. Therefore, the interactions between the product and the production system must be taken into account from the start during development. Currently, the development is mostly carried out separately in the specialist disciplines on the basis of existing methods and systematics, who often do not fully consider the existing interactions. Time-consuming and costly iteration loops are the result. This article therefore addresses the interactions and mutual dependencies between the product and the production system in the early phases of product development, such as an adaptation of the product design due to assembly requirements. The development process of a flashlight serves as an example. First, the interactions are described and analyzed. A methodology is then presented that takes these interactions into account in the context of the integrative development of product and production system in the early phases of product development. The methodology consists of a process model, a specification technique and a software tool. The process model serves as a guideline for the integrative development of product and production system, whereas the specification technology forms the core of the methodology and enables interdisciplinary collaboration of all people involved. For the product concept, the specification technology encompasses the aspects of the environment, application scenarios, requirements, functions, effective structure, behavior and design. The principle solution of the production system is represented by the aspects of production requirements, process sequence, resources and design. The software tool supports the developer in applying the methodology. The methodology presented is then demonstrated using the example product. whereas the specification technology forms the core of the methodology and enables interdisciplinary collaboration of all people involved. For the product concept, the specification technology encompasses the aspects of the environment, application scenarios, requirements, functions, effective structure, behavior and design. The principle solution of the production system is represented by the aspects of production requirements, process sequence, resources and design. The software tool supports the developer in applying the methodology. The methodology presented is then demonstrated using the example product. whereas the specification technology forms the core of the methodology and enables interdisciplinary collaboration of all people involved. For the product concept, the specification technology encompasses the aspects of the environment, application scenarios, requirements, functions, effective structure, behavior and design. The principle solution of the production system is represented by the aspects of production requirements, process sequence, resources and design. The software tool supports the developer in applying the methodology. The methodology presented is then demonstrated using the example product. Active structure, behavior and shape. The principle solution of the production system is represented by the aspects of production requirements, process sequence, resources and design. The software tool supports the developer in applying the methodology. The methodology presented is then demonstrated using the example product. Active structure, behavior and shape. The principle solution of the production system is represented by the aspects of production requirements, process sequence, resources and design. The software tool supports the developer in applying the methodology. The methodology presented is then demonstrated using the example product.}}, author = {{Petersen, Marcus and Bandak, Shatha and Gausemeier, Jürgen and Iwanek, Peter and Schneider, Marcel}}, editor = {{Schenk, Michael}}, issn = {{2196-7598}}, pages = {{13--21}}, publisher = {{Fraunhofer IFF}}, title = {{{Methodology for reporting Interactions between product and production system in the early phases of product development - a practical example}}}, year = {{2014}}, } @inproceedings{28293, abstract = {{Functional gradation means a tailored distribution of properties over the spatial dimensions of a component based on a complex manufacturing process chain. The synthetisation of these processes requires a framework that generates numerous information for the production system elaboration during the further design phases. Therefore a production system specification technique for functionally graded components is presented. The specification technique enables the visualisation of the resulting process chain with all information in a descriptive manner and offers an interface for Microsoft Visio.}}, author = {{Petersen, Marcus and Bauer, Frank and Hess, Stefan and Gausemeier, Jürgen and Gräßler, Iris}}, booktitle = {{Proceedings of the DESIGN 2014 - 13th International DESIGN Conference }}, issn = {{1847-9073}}, pages = {{1157--1166}}, publisher = {{Faculty of Mechanical Engineering and Naval Architecture, University of Zagreb / The Design Society, Glasgow}}, title = {{{Towards a Production System Specification Technique for Functionally Graded Components}}}, volume = {{2}}, year = {{2014}}, } @misc{28215, author = {{Gausemeier, Jürgen}}, isbn = {{978-3-942647-37-3}}, publisher = {{Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn}}, title = {{{Vorausschau und Technologieplanung. 9. Symposium für Vorausschau und Technologieplanung, Heinz Nixdorf Institut, 5. und 6. Dezember 2013}}}, volume = {{318}}, year = {{2013}}, } @inproceedings{27054, author = {{Gausemeier, Jürgen and Grafe, Michael and Meyer auf der Heide, Friedhelm}}, publisher = {{Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn, Band 311 }}, title = {{{11. Paderborner Workshop Augmented & Virtual Reality in der Produktentstehung}}}, volume = {{311}}, year = {{2013}}, } @proceedings{17443, editor = {{Gausemeier, Jürgen and Grafe, Michael and Meyer auf der Heide, Friedhelm}}, publisher = {{Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn}}, title = {{{11. Paderborner Workshop Augmented & Virtual Reality in der Produktentstehung}}}, volume = {{311}}, year = {{2013}}, } @inproceedings{23120, author = {{Kessler, Jan Henning and Gausemeier, Jürgen and Iwanek, Peter and Köchling, Daniel and Krüger, Martin and Trächtler, Ansgar}}, booktitle = {{Internationales Forum Mechatronik 2013}}, title = {{{Erstellung von Prozessmodellen für den Entwurf selbst-optimierender Regelungen}}}, year = {{2013}}, } @inproceedings{23130, author = {{Dziwok, Stefan and Just, Viktor and Schierbaum, Thomas and Schäfer, Wilhelm and Trächtler, Ansgar and Gausemeier, Jürgen and Pohlmann, Uwe and Schäfer, Wilhelm and Suck, Julian and Sudmann, Oliver and Tichy, Matthias}}, booktitle = {{9. Paderborner Workshop Entwurf mechatronischer Systeme}}, pages = {{375--394}}, publisher = {{Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn}}, title = {{{Integrierter Regelungs- und Softwareentwurf für komplexe mechatronische Systeme}}}, volume = {{310}}, year = {{2013}}, } @inproceedings{23136, author = {{Schmuedderich, Tanja and Trächtler, Ansgar and Brökelmann, Jan and Gausemeier, Jürgen}}, booktitle = {{Smart Product Engineering - Proceedings of the 23rd CIRP Design Conference (ISBN 978-3-642-30816, Springer-Verlag)}}, pages = {{23--32}}, title = {{{Procedural Model for the Virtual Commissioining on the Basis of Model-based Design}}}, year = {{2013}}, } @inproceedings{23137, author = {{Bauer, Frank and Gausemeier, Jürgen and Köchling, Daniel and Oestersötebier, Felix}}, booktitle = {{Smart Product Engineering - Proceedings of the 23rd CIRP Design Conference}}, publisher = {{Springer Berlin/Heidelberg}}, title = {{{Approach for an Early Validation of Mechatronic Systems using Idealized Simulation Models within the Conceptual Design}}}, year = {{2013}}, } @inproceedings{9801, author = {{Hunstig, Matthias and Al-Ashtari, Waleed and Hemsel, Tobias and Sextro, Walter}}, booktitle = {{9. Paderborner Workshop Entwurf mechatronischer Systeme}}, editor = {{Gausemeier, Jürgen and Dumitrescu, Roman and Rammig, Franz and Schäfer, Wilhelm and Trächtler, Ansgar}}, pages = {{359--372}}, publisher = {{Heinz Nixdorf Institut, Universität Paderborn}}, title = {{{Leistungs- und Bandbreitensteigerung von Energy-Harvesting-Generatoren für Energieautarke Systeme}}}, year = {{2013}}, } @inproceedings{9861, abstract = {{Selbstoptimierende mechatronische Systeme bieten die Möglichkeit, ihr Verhalten an geänderte Umgebungsbedingungen anzupassen. Dazu werden beispielsweise redundante Strukturen genutzt, Reglerparameter angepasst oder Regelstrategien umgeschaltet. Dies kann auch genutzt werden, um die Zuverlässigkeit des Systems zu steigern. Zugleich entstehen aber durch die gesteigerte Komplexität dieser Systeme zusätzliche Risiken. Um sicherzustellen, dass das System dennoch die gestellten Anforderungen bezüglich der Zuverlässigkeit erfüllt, ist eine Modellierung des Gesamtsystems und anschließende Zuverlässigkeitsbewertung notwendig. Dies ist aufgrund der situationsabhängigen Verhaltensanpassung und des nicht intuitiv vorhersehbaren Verhaltens jedoch nicht mit klassischen Verfahren möglich. Ein Modellierungsverfahren, das diese Eigenschaften abbilden kann, ist LARES (LAnguage for REconfigurable dependable Systems). Die Anwendung von LARES zur Bewertung der Zuverlässigkeit eines selbstoptimierenden Systems wird anhand des Feder-Neige-Moduls gezeigt. Es ist eine Baugruppe der Fahrzeuge eines innovativen Bahnsystems, der RailCabs. Das Feder-Neige-Modul dient dazu, unerwünschte Schwingungen des Fahrzeugaufbaus zu minimieren. Mit LARES können die Hardware-Komponenten des Systems, ihre in Abhängigkeit von der aktuellen Situation veränderten Belastungen sowie die nicht-deterministische Verhaltensadaption modelliert werden.}}, author = {{Meyer, Tobias and Sondermann-Wölke, Christoph and Sextro, Walter and Riedl, Martin and Gouberman, Alexander and Siegle, Markus}}, booktitle = {{9. Paderborner Workshop Entwurf mechatronischer Systeme}}, editor = {{Gausemeier, Jürgen and Dumitrescu, Roman and Rammig, Franz and Schäfer, Wilhelm and Trächtler, Ansgar}}, pages = {{161--174}}, publisher = {{Heinz Nixdorf Institut, Universität Paderborn}}, title = {{{Bewertung der Zuverlässigkeit selbstoptimierender Systeme mit dem LARES-Framework}}}, year = {{2013}}, } @inproceedings{29969, abstract = {{Die absehbare Entwicklung der Informations- und Kommunikationstechnik wird mechatronische Systeme mit inhärenter Teilintelligenz ermöglichen. Hierfür verwenden wir den Begriff Selbstoptimierung (S.O.). Selbstoptimierende (s.o.) Systeme reagieren autonom und flexibel auf sich ändernde Umfeldbedingungen [ADG+09]. Die Entwicklung derartiger Systeme erfordert eine enge Zusammenarbeit der Entwickler der beteiligten Domänen Mechanik, Elektrik/Elektronik, Regelungstechnik und Softwaretechnik. In diesem Beitrag wird erklärt, wie die Steigerung der Verlässlichkeit durch S.O. bei der Konzipierung eines s.o. Systems adäquat berücksichtigt wird. Die Konzipierung des hybriden Energiespeichersystems des innovativen Schienenfahrzeugs RailCab wird retrospektive durchgeführt. Dies erfolgt von der ersten Funktionsdefinition über die Lösungsauswahl und die dazugehörige Nutzwertanalyse bis hin zur Produktkonzeption des Energiespeichersystems. Es wird gezeigt, wie die Schwachstellen und Widersprüche eines technischen Systems identifiziert sowie mit Hilfe geeigneter Gegenmaßnahmen behoben werden können. Hierbei soll insbesondere die Integration der S.O. als Möglichkeit zur Behebung der Schwachstellen betrachtet werden. Somit wird gezeigt wann und wie die Entscheidung über die s.o. Auslegung des Systems getroffen und die Steigerung der Verlässlichkeit dabei ins Kalkül gezogen wird.}}, author = {{Gausemeier, Jürgen and Iwanek, Peter and Dorociak, Rafal and Stille, Karl Stephan Christian and Böcker, Joachim}}, booktitle = {{Wissenschaftsforum Intelligente Technische Systeme, 9. Paderborner Workshop Entwurf mechatronischer Systeme}}, keywords = {{Konzipierung, Selbstoptimierung, Verlässlichkeit, Mechatronik, Hybrider Energiespeicher, LEA-Publikation, Eigene}}, title = {{{Konzipierung eines selbstoptimierenden hybriden Energiespeichersystems unter besonderer Berücksichtigung der Verlässlichkeit}}}, year = {{2013}}, } @inbook{29970, author = {{Stille, Karl Stephan Christian and Böcker, Joachim}}, booktitle = {{Design Methodology for Intelligent Technical Systems}}, editor = {{Gausemeier, Jürgen and Josef Rammig, Franz and Schäfer, Wilhelm}}, keywords = {{Eigene}}, pages = {{46--49}}, publisher = {{Springer}}, title = {{{Crosslinked Test Benches}}}, year = {{2013}}, } @inbook{29971, author = {{Stille, Karl Stephan Christian and Romaus, Christoph and Böcker, Joachim}}, booktitle = {{Design Methodology for Intelligent Technical Systems}}, editor = {{Gausemeier, Jürgen and Josef Rammig, Franz and Schäfer, Wilhelm}}, pages = {{42--46}}, publisher = {{Springer}}, title = {{{Hybrid Energy Storage System (HES)}}}, year = {{2013}}, } @proceedings{25300, editor = {{Gausemeier, Jürgen and Dumitrescu, Roman and Rammig, Franz-Josef and Schäfer, Wilhelm and Trächtler, Ansgar}}, publisher = {{Heinz Nixdorf Institut, Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn}}, title = {{{9. Paderborner Workshop Entwurf mechatronischer Systeme}}}, volume = {{310}}, year = {{2013}}, } @article{28551, abstract = {{The technical article describes the simulative support of work planning and work control through a cloud application. On the basis of virtual machine tools, customers are supported in the automated setup of the machines and in efficient order scheduling. The approach presented is the core of the research project "Intelligent work preparation based on virtual machine tools" (InVorMa) within the framework of the top cluster "Intelligent Technical Systems OstWestfalenLippe" (it's OWL).}}, author = {{Bauer, Frank and Gausemeier, Jürgen and Rehage, Gerald}}, journal = {{wt workshop technology online}}, title = {{{Work preparation 4.0 - cloud-based use of virtual machine tools}}}, year = {{2013}}, } @inbook{28455, author = {{Gausemeier, Jürgen and Köster, Oliver and Rübbelke, René}}, booktitle = {{Foresight and Technology Planning}}, editor = {{Gausemeier, Jürgen}}, pages = {{7--36}}, publisher = {{publishing series of the Heinz Nixdorf Institute, Paderborn}}, title = {{{Systematics for the development of business in the product development}}}, year = {{2013}}, }