Obiettivo A new tool material for cold forging applications was developed using numerical simulation techniques (FEM) for the design and a powder metallurgical route (HIP) for the production. The basic idea was to find an optimised microstructure of the two phase material by simulating different distribution sof hard particles within the metal matrix. On the micro-scale, loading was applied by a field of deformations which was obtained by a macroscopical simulation of a particular cold forming process in bolt making. A new double dispersion microstructure was found to show the best resistance against crack propagation. Specimens were produced by hot isostatic pressing. Afterwards the new material was tested in the laboratory. Wear resistance and bending strength of the double dispersive material are comparable to a standard dispersion material with the same volume fraction of particles, but fracture toughness is increased by about 30%. Testing the new material in bolt making showed that the life time of the tool is increased by a factor of 8.The cold forging of metals calls for advanced tooling materials with improved fracture strength and toughness. These mechanical properties depend on the size, shape, orientation, amount and distribution of wear resistant hard phases, which are embedded in a hardened steel matrix.Starting from a macroscopical finite element analysis of stresses and strains in a tool, the regions of highest loading are modeled by fine-scale FEM. This enables a simulation of various microscopical situations as far as the hard phases and the size of the plastic zone in the matrix are concerned. These parameter studies and the experimental parameter verifications are used to elaborate failure criteria an to design the microstructure of advanced tooling materials with optimal properties.Compared to conventional manufacturing via ingot and hot working, the powder metallurgy and spray deposition offer more possibilities to realize a designed microstructure. These methods are used to produce and test advanced tooling materials on a laboratory scale. Campo scientifico engineering and technologymaterials engineeringmetallurgy Programma(i) FP3-BRITE/EURAM 2 - Specific programme (EEC) of research and technological development in the field of industrial and materials technologies, 1990-1994 Argomento(i) 1.3.1 - Metals and metal matrix composites Invito a presentare proposte Data not available Meccanismo di finanziamento CSC - Cost-sharing contracts Coordinatore Centre National de la Recherche Scientifique (CNRS) Contributo UE Nessun dato Indirizzo EVOIL-USTL 59655 Villeneuve d'Ascq Francia Mostra sulla mappa Costo totale Nessun dato Partecipanti (2) Classifica in ordine alfabetico Classifica per Contributo UE Espandi tutto Riduci tutto RUHR-UNIVERSITÄT BOCHUM Germania Contributo UE Nessun dato Indirizzo UNIVERSITATSSTRAßE 150 4630 BOCHUM Mostra sulla mappa Costo totale Nessun dato SWEDISH INST FOR METALS RESEARCH Svezia Contributo UE Nessun dato Indirizzo DROTTNING KRISTINAS VAG 48 114 28 STOCKHOLM Mostra sulla mappa Costo totale Nessun dato