The objective of the Collaborative Research Centre 1368 (CRC) is to develop a basic understanding of the processes and mechanisms involved in manufacturing, assembly and handling technology in oxygen-free environments. This will open up the completely new field of "oxygen-free production", which will add new possibilities to established processes, significantly increase the performance of the products manufactured and enable entirely new processes. Production processes in the metalworking industry are still carried out in the presence of oxygen. This leads to the surface contamination of the metals with oxygen. The resulting oxide layer mainly acts as a detrimental factor in production and limits the possibilities for metal processing. Due to the presence of oxygen, there is an unexploited potential of technical possibilities in almost all production processes. In fact, production in an oxygen-free atmosphere offers considerable technical, economic and resource-relevant advantages and renders completely new processes possible. Within the Collaborative Research Centre an oxygen-free atmosphere is generated by the use of silane (SiH4) doped inert gas. By the reaction of the silane with the residual oxygen contained in the inert gas, oxygen partial pressures of less than 10–23 bar, and thus a practically oxygen-free atmosphere can be achieved at ambient pressure. In terms of oxygen partial pressure these conditions are those of an extremely high vacuum (XHV-adequate). Because of the strongly reducing effect of silane, such atmospheres offer various possibilities for removing oxide layers from semi-finished products and suppress (re-)oxidation of the materials. In the first funding period, the scientific subprojects investigated the effects of the complete absence of oxygen on the mechanisms in the process zone for the production groups of casting, forming, coating, joining and cutting as well as methods for the active deoxidation of surfaces and powders. Research aspects were the mechanisms at the active sites of the respective processes and the modelling of processes at surfaces and interfaces. The large positive effects observed in the majority of the processes under consideration demonstrate that the hoped-for technological leaps can be expected to become a reality. In the second funding period, the basic understanding gained and knowledge about specific process interactions will be further deepened. For this purpose, the processes will be tailored to the new environmental conditions. Adapting the process conditions and parameters enables the potential to be further exploited by combining various of the large effects observed.

DFG Programme Collaborative Research Centres

• A01 - Properties and local microstructures of oxide-free compound castings (Project Heads Klose, Christian ;  Maier, Hans Jürgen )
• A02 - Investigation of the processability of metal powders by selective laser beam melting in an XHV-adequate atmosphere (Project Heads Kaierle, Stefan ;  Overmeyer, Ludger )
• A03 - Novel process combination for the production of components based on titanium aluminide in an oxygen-free atmosphere (Project Head Behrens, Bernd-Arno )
• A04 - Process-integrated metallic sintered coatings for hot stamping with resistance heating (Project Heads Holländer, Ulrich ;  Hübner, Sven )
• A05 - Investigation of cold pressure welding under XHV-adequate atmosphere in the roll bonding process (Project Head Nürnberger, Florian )
• A06 - Flux-free laser beam brazing by local deoxidation (Project Heads Kaierle, Stefan ;  Overmeyer, Ludger ;  Seffer, Sarah )
• B02 - Firmly bonded interface transitions by thermal coating with arc and plasma spraying processes (Project Head Möhwald, Kai )
• B03 - Chemical mechanisms in titanium cutting (Project Heads Bergmann, Benjamin ;  Dittrich, Marc-André ;  Prasanthan, Vannila )
• B04 - Adhesive-based assembly processes in an XHV-adequate atmosphere on deoxidized and oxidized surfaces (Project Heads Maus-Friedrichs, Wolfgang ;  Raatz, Annika )
• B06 - Reduction of metallurgically induced pore formation during arc welding of pure copper by XHV-adequate conditions in the arc welding process (Project Head Hassel, Thomas )
• C01 - Determination of mechanisms and processes for the deoxidation of material surfaces and implementation thereof in both, laboratory and pilot plant scale (Project Heads Maus-Friedrichs, Wolfgang ;  Wegewitz, Lienhard )
• C02 - Deoxidation of gasborne powders (Project Head Weber, Alfred )
• C03 - Investigation of tribological systems for tool wear protection in XHV-adequate atmosphere (Project Head Wurz, Marc Christopher )
• C04 - Machining concepts for grinding in oxygen-free atmosphere (Project Heads Denkena, Berend ;  Prasanthan, Vannila )
• C05 - Molecular dynamics simulations of interfacial phenomena during joining with deoxidized and oxidized composite partners (Project Head Merkert, Nina )
• INF - Research Data Management for oxygen-free production (Project Heads Auer, Sören ;  Mozgova, Iryna )
• S01 - Central Analytics (Project Heads Gustus, Ph.D., René ;  Maus-Friedrichs, Wolfgang )
• S02 - Development of a Modelling Approach for the Economic Evaluation of Process and Process Chain Innovations in Early Innovation Phases (Project Heads Kuprat, Vivian ;  Nyhuis, Peter )
• T01 - Usage of Dielectric Barrier Discharge (DBD) plasmas in longitudinal high-frequency welding to realize oxygen-free manufacturing conditions (Project Heads Maus-Friedrichs, Wolfgang ;  Wiche, Henning )
• Z - Central Task (Project Head Maier, Hans Jürgen )

• B05 - Control of the oxygen content in the thermal arc and the effect on the material transition for the production of oxygen-free joints (Project Head Hassel, Thomas )

Applicant Institution Gottfried Wilhelm Leibniz Universität Hannover

Participating University Technische Universität Clausthal; Universität Paderborn

Participating Institution Laser Zentrum Hannover e.V. (LZH)

Spokesperson Professor Dr.-Ing. Hans Jürgen Maier