Integrative Production Technology for High-Wage Countries

Cluster of Excellence - Integrative Production Technology for High-Wage Countries
Type public
Established October 2006
Provost Christian Brecher (speaker of the board)
Director Denis Özdemir (COO)
Location Aachen, NRW, Federal Republic of Germany
Website www.production-research.de

The Cluster of Excellence Integrative Production Technology for High-Wage Countries is an interdisciplinary research project of RWTH Aachen University combined in the “Aachen House of Integrative Production”. It pursues the long-term goal to increase the competitiveness of German manufacturing technology. The Cluster of Excellence was founded in October 2006 as part of the Excellence Initiative of the German Federal Ministry of Education and Research and the German Research Foundation. It was re-announced as a Cluster of Excellence on June 15, 2012.

Goals

It is the goal to ensure the production in high-wage countries during the changing conditions of the globalization. Based on the Cluster of Excellence, theories are developed that combine economical, ecological, and social aspects for the producing industry with the help of necessary methods and equipment. The aim of the academic researchers is to contribute seminal and sustainable production technologies to help enterprises with the problems of the location. The Cluster of Excellence “Integrative Production Technology for High-Wage Countries” is aiming to maintain the competitive ability of German Production Technology.

Research areas

Companies have to compete in an environment of increasing global competition. It has to be the concern of high-wage countries to evaluate and define the conditions under which domestic businesses can successfully develop and produce corresponding products. In order to meet the challenges, a fundamentally new understanding of product and production interrelations is required.
The Cluster of Excellence aims at developing a viable, production-scientific strategy and theory of production including necessary technology approaches. Various issues of individualisation, virtualisation and hybridisation of industrial production, self-optimisation are addressed, which are divided in four Integrative Cluster Domains (ICD).

ICD-A: Individualised Production

In contradiction to the incompatibility of economies of scale and economies of scope, manufacturing companies in high-wage countries are facing increasing challenges. This challenge corresponds to a resolution of the scale-scope-dichotomy. Product production systems have to be adjusted to one another regarding their specific degree of standardisation in order to resolve the dichotomy.
An integrated assessment model classifies product productions systems in four quantifiable fields of tension. Based on the model, the current operating point of a production system can be analysed. A configuration logic - derived trom the results of the analysis - provides the means to control a production system's configuration process.

ICD-B: Virtual Production Systems

The planning of production processes is characterised by unlinked simulations of specific aspects, which are based on standard assumption. The impact of ustream production processes cannot be taken into account. To increase simulation quality, individual simulations have to be linked and combined to a simulation chain.
The Virtual Production Systems researches a method to link simulation resources, data sets and access rights to the generated integrative simulation platform. The general concept also contains subsequent analysis of simulation results by methods of visualisation.

ICD-C: Hybrid Production Systems

An important part in securing the competitiveness of industrial production is advancing the manufacturing processes as it currently pushes existing boundaries of manufacturing technologies and taps new fields of applications.
The issue of Hybridisation of manufacturing technologies is the systematic development and early assessment of possible application. The integration of knowledge of different disciplines of production engineering is crucial to its success.

ICD-D: Self-optimising Production Systems

Cognitive technologies can enable production systems to adapt self-optimizingly to variable conditions. The primary objective is to ensure product quality by aligning the considered process chain to the fulfillment of the required product features by designing inter-process control loops. Therefor the production system can dynamically permit deviations of other goals during the production process or compensate deviations by specific reactions and increase it flexibility and competitiveness.

Research partner

More than 20 research institutes, 25 professors of engineering, materials, mathematics, economics, and psychology work with their research assistants in co-operation with the international industry.

Institutes

Institute Director
ACCESS e.V. Andreas Bührig-Polaczek
Research Institute for Operations Management Günther Schuh
Foundry Institute and Chair of Foundry Engineering (GI) Andreas Bührig-Polaczek
Institute and Chair of Surface Engineering Kirsten Bobzin
Institute and Chair of Metal Forming Gerhard Hirt
Institute of Plastics Processing, Chair of Plastics Processing Christian Hopmann
Institute and Chair of Ferrous Metallurgy Wolfgang Bleck
Chair and Institute of Industrial Engineering and Ergonomics Christopher Schlick
Welding and Joining Institute, Chair for Welding and Joining Technologies Uwe Reisgen
Institute for Textile Technology and Chair for Textile Machinery Thomas Gries
CATS Chair for Computational Analysis of Technical Systems Marek Behr
Department of Mechanism Theory and Dynamics of Machines (IGM) Burkhard Corves
Center for Learning and Knowledge Management, Department of Information Management in Mechanical Engineering (ZLW-IMA) Sabina Jeschke
SC Institut for Scientific Computing Christian Bischof
Laboratory for Machine Tools and Production Engineering Christian Brecher et al.
Fraunhofer Institute for Production Technology Fritz Klocke et al.
Fraunhofer Institute for Laser Technology Reinhart Poprawe
IfU Institut for Management Cybernetics e.V. Sabina Jeschke
Lectureship and Research Field Rubber Technology Edmund Haberstroh
Centre for Computing and Communication Christian Bischof
Institute of Automatic Control Dirk Abel
Chair of Business Administration and Sciences for Engineers and Natural Scientists Malte Brettel
Institute for Geometry and Practical Mathematics Wolfgang Dahmen
Technology and Innovation Management Group Frank Piller
Human Technology Centre Martina Ziefle

Industrial Partner

  • ALD
  • BMW
  • Carl Zeiss AG
  • CEROBEAR
  • Chiron-Werke GmbH
  • Daimler AG
  • Deutsche Edelstahlwerke
  • Dirostahl
  • Döllken Kunststoffverarbeitung GmbH
  • Dörries Scharmann Technologie GmbH
  • Dürr System GmbH Aircraft and Technology Systems
  • EADS
  • Eisenbau Krämer
  • Eppendorf Polymere GmbH
  • ESI
  • Europipe GmbH
  • Evonik Degussa
  • Festo AG & Co. KG
  • Ford Forschungszentrum Aachen GmbH
  • Freudenberg Simmerringe GmbH & Co. KG
  • Georgsmarienhütte
  • Hübner GmbH
  • Huf Tools GmbH Velbert
  • Johann Hay GmbH & Co. KG
  • Kugler
  • Kuka
  • LIBA Maschinenfabrik GmbH
  • MAGMA
  • OKE Group GmbH
  • Otto Junker Edelstahlgießerei GmbH
  • Phoenix Contact GmbH & Co. KG
  • Presswerk Krefeld GmbH & Co. KG
  • PSIPENTA Software Systems GmbH
  • Robert Bosch GmbH
  • SABIC Europe
  • Salzgitter Mannesmann Forschung GmbH
  • SIGMA Engineering GmbH
  • Smar Act GmbH
  • TGE Vorwerk Elektrowerke GmbH & Co. KG
  • ThyssenKrupp Steel AG
  • TRUMPF
  • Volkswagen Werkzeugbau Braunschweig

External links

Literature

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