670 Industrielle und handwerkliche Fertigung
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Die Automobilindustrie sieht sich seit Jahren rasant verändernden Markt-, Umwelt- und Wettbewerbsbedingungen ausgesetzt. Der Entwicklungsprozess in der Automobilindustrie wird dadurch zunehmend komplexer. Die Einbeziehung neuer Partner aus anderen Industriebereichen und der Wissenschaft stellt hierbei ein großes Innovationspotential dar, insbesondere Systeminnovationen können hierdurch gefördert werden. Die Herausforderungen solch interdisziplinärer, interorganisationaler Entwicklungsprojekte können nur im geeigneten Umfeld gemeistert werden. In der Literatur als auch in der Industrie lassen sich zahlreiche Kooperationsmodelle identifizieren. Die Eignung dieser Modelle für die interdisziplinäre, interorganisationale Entwicklung in der Automobilindustrie wird anhand geeigneter Kriterien bewertet. Abschließend werden die Ergebnisse der Analyse empirisch überprüft und für den praktischen Fall der ARENA2036 angewendet.
Mastering of complex systems and interfaces, idea and innovation management as well as virtually integrated product and process planning are essential competences to be developed and fostered to cope with the changing role of the workforce in a future industry 4.0 work system. Learning factories, like the Logistics Learning Factory at Reutlingen University, which are equipped with state-of-the-art infrastructure, offer a high potential to decidedly address these competences.
In academia and industry learning factories are established as close-to-reality learning environments for education and training in the manufacturing domain. Although the approach and concept of existing learning factories is often similar, orientation and design of individual facilities are diverse. So far, there is no structured framework to describe learning factory approaches. In the paper a multidimensional description model is presented in form of a morphology which can be used as a starting point for the structuring and classification of existing learning factory application scenarios as well as a support for the development and improvement of learning factory approaches.
Shorter product life cycles and emerging technologies in the field of industrial equipment are changing the prerequisites and circumstances under which the design of assembly and logistics systems take place. Planners have to adapt the production in accordance with the underlying product at a higher pace, oversee a more complex system and - most importantly - find the ideal solution for functional as well as social interaction between humans and machines in a cyber-physical system. Such collaborative work systems consider the individual capabilities and potentials of humans and machines to combine them in a manner that assists the operator during his daily work routine towards more productive, less burdening work. To be able to design work systems which act on that maxim, specific competences such as the ability of integrated process and product planning as well as systems and interface competence are required. The ESB Logistics Learning Factory trains students as well as professionals to gain such qualification by providing a close-to-reality learning environment based on a didactical concept which covers all relevant methods for ergonomic work system design and a state-of-the-art infrastructure composed of a manual assembly system, service robots, visual assistance systems, sensor-based work load monitoring and logistical resources. Group-based, activity oriented scenarios enable the participants to put the learnings into practice within their professional environments. By this, learning factories have an indirect impact on the transfer of proven best practices to the industry and thereby on the diffusion of the idea of human-centric working environment.
In the last decade, numerous learning factories for education, training, and research have been built up in industry and academia. In recent years learning factory initiatives were elevated from a local to a European and then to a worldwide level. In 2014 the CIRP Collaborative Working Group (CWG) on Learning Factories enables a lively exchange on the topic "Learning Factories for future oriented research and education in manufacturing". In this paper results of discussions inside the CWG are presented. First, what is meant by the term Learning Factory is outlined. Second, based on the definition a description model (morphology) for learning factories is presented. The morphology covers the most relevant characteristics and features of learning factories in seven dimensions. Third, following the morphology the actual variance of learning factory manifestations is shown in six learning factory application scenarios from industrial training over education to research. Finally, future prospects of the learning factory concept are presented.
Das dynamische Verhalten von Werkzeugmaschinen ist für die Stabilität während der Bearbeitung sowie die Qualität der erzeugten Werkstücke von besonderer Bedeutung. Ein Einflussfaktor darauf ist die Dämpfung. Im Bereich der Maschinengestelle kommen seit langer Zeit unterschiedliche Materialien zum Einsatz. In diesem Fachbeitrag werden die Dämpfungskennwerte unterschiedlicher Gestellwerkstoffe an geometrisch gleichen Proben vergleichend gegenübergestellt. Als weitere Kenngröße wurde die Lage der (1. Biege-) Eigenfrequenz als Maß für die massebezogene dynamische Steifigkeit verwendet. Die Effekte beim Übergang von einfachen Bauteilen zu komplexen Strukturen runden den Fachartikel ab.
Few unfocused factories outperform competitors, but Focus is elusive because the environment is constantly evolving and this requires changes to a factory’s key tasks. So how can focus be achieved and sustained? We present insights derived from an historical analysis of the German Hewlett-Packard server plant which went through a series of Focus changes over the years. Using this example, we provide clues for the right timing of Focus changes and discuss critical structural and infrastructural changes required during the Focus transitions, as well as cross-functional coordination and leadership challenges. Our assertion is that production operations constitute a system that can adapt to disruptive Change by using the levers of manufacturing policies to stay focused on a limited but absolutely essential task which creates a strategic advantage.
In the powder coating of veneered particle boards the highly reactive hybrid epoxy/polyester powder transparent Drylac 530 Series from TIGER Coatings GmbH & Co. KG, Wels, Austria was used. Curing is accelerated by a mixture of catalysts reaching curing times of 3 min at 150 °C or 5 min at 135 °C which allows for energy and time savings making Drylac Series 530 powder suitable for the coating of temperaturesensitive substrates such as MDF and wood.
Industry 4.0 predicts that industrial processes, technological infrastructure and all corresponding Business processes, with the help of information and communication technology (ICT), will advance to integrated, ad-hoc interconnected and decentralized Cyber-Physical Production Systems (CPPS) with real-time capabilities of selfoptimization and adaptability. Considering this change, the human being will remain in a dominant role, because it is not expected that the human factor with its characteristics and capabilities will be substituted entirely by autonomously acting technology in the foreseeable future. The mechanical intelligence, for instance, is limited to the selection of predefined options, while human creativity, flexibility, the ability to learn and to improve are required to design and configure systems, processes and products. Humans have the expertise and experience to analyze, assess and solve - even in exceptional situations. However, the amount of purely manual tasks for shop floor workers will decrease. Their role will change from a manually executing to a proactive preconceiving worker with increased responsibility. Due to the growing degree of digitalization and interconnectedness, also the tasks and responsibilities for planning and design personnel will continuously expand and become more complex. The work in versatile ad-hoc networks with advanced ICT-Tools and assistance systems will lead to increased requirements regarding the knowledge, capability and capacity of the respective employees. The on-going pervasion of IT and emergence of systems with unprecedented complexity specifically require significantly improved capabilities in analysis, abstraction, problem solving and decision making from future labour. Accordingly, the industry is asking for graduates that are educated interdisciplinary and practice-oriented. Some universities already meet these expectations, using learning factories for realistic, action-oriented classes and trainings. Lecturers are confronted with the challenge to identify future job profiles and correlated qualification requirements, especially regarding the conceptualization and implementation of CPPS, and to adapt and enhance their education concepts and methods adequately and consequently. For the new, virtual world of manufacturing a proper understanding of engineering as well as Computer sciences is essential. Industry 4.0 implies this interdisciplinary split. Integrated competencies for product and process planning and design, methodological competencies for systematical idea and innovation management as well as a holistic system and Interface competence will be crucial to achieve interconnection of physical and digital processes and machines. The Vienna University of Technology and the ESB Reutlingen committed to integrate key aspects of Industry 4.0 into their respective learning factories successively. Thus, the students will act as the coordinators of the CPPS and thereby remain in the center of all learning and implementation activities.
Fundamentale Veränderungen der heutigen Arbeitswelt stellen Menschen, Systeme, Prozesse und ganze Organisationen vor erhebliche Herausforderungen. Der Faktor Mensch leistet in allen Bereichen dieses Wirkgefüges einen essentiellen Beitrag zum Wettbewerbsvorteil vieler produzierender Unternehmen am Standort Deutschland. Der Wandel von Automatisierung zu selbststeuernden Unternehmen geht dabei nicht spurlos an dem wandlungsfähigsten Glied dieses Gefüges, dem Menschen, vorüber. Belastungsarten verändern sich, singuläre Bewältigungsstrategien genügen nicht mehr, um einen optimalen Beanspruchungszustand jedes einzelnen Individuums zu erreichen und gleichzeitig das höchstmögliche Potenzial zu schöpfen. Das Belastungs- und Beanspruchungscockpit bildet einen Lösungsansatz zur systematischen und durchgängigen Bewertung von Belastungszuständen und der individuellen Beanspruchung von Beschäftigten an Montagearbeitsplätzen. Es liefert in Echtzeit Informationen zum Belastungs- und Beanspruchungszustand des Mitarbeiters und kann mit Ergonomiebewertungsverfahren verknüpft werden. Der Aspekt der Multidimensionalität umfasst die Bewertung verschiedener Indikatoren unter Betrachtung ihrer Wirkzusammenhänge.