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Carreno-Morelli Efrain

Professeur-e HES Ordinaire, Responsable du groupe de recherche Technologies des poudres et matériaux avancés

Hauptkompetenzen

Materials Science and Engineering

Ceramics & Metal-Ceramic Composites

SLM & Binder Jetting 3D-Printing

Hauptvertrag

Professeur-e HES Ordinaire, Responsable du groupe de recherche Technologies des poudres et matériaux avancés

Telefon-Nummer: +41 58 606 88 37

Büro: ENP.23.N115

HES-SO Valais-Wallis - Haute Ecole d'Ingénierie
Rue de l'Industrie 23, 1950 Sion, CH

Bereich
Technique et IT

Hauptstudiengang
Systèmes industriels

Efraín Carreño-Morelli, Professor of Materials Technology, was born in 1966 in Córdoba (Argentina) and has the swiss, argentinian and italian citizenships. At the age of 15 he entered National University of Córdoba, from which he graduated in 1989 with a MSc in Physics. Then, he moved to the Atomic Centre of Bariloche to pursue a PhD Thesis on the subject "Metallurgical properties of Al-Mg-Si alloys subjected to neutron irradiation and thermomechanical treatments", which he submitted in 1994. In parallel with his studies of physics and materials science, he also followed courses of astronomy, medicine and philosophy. Working with the oil industry in Patagonia, he developed in 1994 a monitoring system to evaluate the operation condition of sucker rod pumps (pumpjacks) in oil wells, which was successfully tested and commercialized. Arriving at the Swiss Federal Institute of Technology Lausanne EPFL in 1995, he was a research assistant in the Physics Department, where he performed investigations on the processing and damping behaviour of metal matrix composites, dislocation dynamics in ordered intermetallic compounds, and anelastic properties of aluminium alloys. In 2000 he joined the Swiss Federal Institute of Materials Testing and Research EMPA in Thun, where he was a project manager in the development of metal matrix composites, with a special interest in the development of porous ceramic preforms by 3D-Printing.

Dr. Carreño-Morelli assumed in 2001 his present position with the University of Applied Sciences and Arts Western Switzerland in Sion. He currently teaches in several courses of materials science and engineering, including powder metallurgy, composites and ceramic materials. He has coached over 60 bachelor and master thesis. His research interests are in the fields of powder metallurgy, additive manufacturing, and processing of metal-ceramic composites. At the Institute of Systems Engineering, he has been responsible for setting-up the technologies of powder injection moulding for metals and ceramics, press and sintering, selective laser melting and binder jetting three dimensional printing. He leads the Powder Technology and Advanced Materials Research Group since 2011. He is the author of numerous refereed publications in international journals and conferences and has filled 5 patent applications. He also serves as an external reviewer for several scientific journals. He is on the editorial board of the journals Papers in Physics and Powder Metallurgy Progress. He is a member of the European Powder Metallurgy Association (EPMA), the Professional Society for Powder Metallurgy (APMI International), the Swiss Innovation Booster Additive Manufacturing (IBAM), the SVMT Expert Group Powder Technology and the Argentinian Physics Association. Since 2010 he serves as a member of the Technical Program Committee (TPC) of the International Powder Metallurgy Congress EuroPM, as well as in the TPCs of the Powder Metallurgy World Congress WorldPM2016 and WorldPM2022. Since 2021 he is also in the TPC of the North American Powder Metallurgy and Additive Manufacturing conferences Powdermet-AMPM from the Metal Powder Industry Federation. In 2023 he has joined the organizing committee of the International Conference. on Advanced Manufaturing ASTM-ICAM.

He has made pioneering contributions in the processing of carbon nanotube - metal matrix composites, the injection moulding of titanium-niobium alloys and the 3D printing of nickel-free stainless steels. Among his major achievements are the powder injection moulding of titanium from titanium hydride, the net-shape processing of shape memory alloys, the additive manufacturing of fully dense hard metals and the invention of a novel variant of the three-dimensional printing technique: Solvent on Granules 3D Printing (SG-3DP).

BSc HES-SO en Systèmes industriels - HES-SO Valais-Wallis - Haute Ecole d'Ingénierie

Technologie des matériaux
Technologie des poudres
Matériaux Céramiques
Matériaux composites
Fabrication additive - Techniques d'impression 3D

MSc HES-SO en Engineering - HES-SO Master

Technologie des matériaux
Technologie des poudres
Metal and Ceramic Injection Moulding (MIM & CIM)
Ceramics and Metal-Ceramic Composites
Fabrication additive - Techniques d'impression 3D

Laufend

Outils de coupe performants en cermets structurés par laser à impulsions ultra-courtes.

Rolle: Mitgesuchsteller/in

Description du projet :

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain , Wälder Georg , Constantin Raymond

Durée du projet: 15.02.2021

Statut: Laufend

Additive manufacturing of novel aluminum alloys - Innosuisse No 35906.1 IP-ENG

Rolle: Hauptgesuchsteller/in

Description du projet :

The goal of this project is to develop a low cost novel aluminum alloy for additive manufacturing with good processability and enhanced mechanical properties.

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain

Partenaires professionnels: Novelis Switzerland SA

Durée du projet: 01.12.2019

Statut: Laufend

Additive Manufacturing of Cemented Carbide Parts - Innosuisse No 28800.1 IP-ENG

Rolle: Hauptgesuchsteller/in

Financement: Innosuisse

Description du projet :

An inkjet printing technique will be developed for producing cemented carbide inserts for the construction industry. The goal of printing green parts, followed by debinding and sintering, is to enhance production flexibility and reduce lead times of innovative products, tailored to customer needs.

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain

Partenaires professionnels: Hilti Corporation

Durée du projet: 27.10.2018

Statut: Laufend

Abgeschlossen

Electro Sinter Forging of Permanent Magnets

Rolle: Hauptgesuchsteller/in

Financement: Innosuisse

Description du projet :

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain , Rodriguez Arbaizar Mikel

Partenaires professionnels: Zeller Andreas, EPoS Technologies SA

Durée du projet: 14.04.2023 - 14.10.2023

Montant global du projet: 15'000 CHF

Url des Projektstandortes: https://www.aramis.admin.ch/Grunddaten/?ProjectID=53203

Statut: Abgeschlossen

Additive manufacturing of low thermal expansion silicon carbide parts

Rolle: Hauptgesuchsteller/in

Financement: Swiss Space Center

Description du projet :

The goal of this project is to assess the feasibility of producing Silicon carbide, low thermal expansion parts by the 'Solvent on Granule Three Dimensional Printing Technique', which is an original development of HES-SO Valais already tested in a range of materials.
The field of application is the manufacturing of light weight, thermally stable and radiation resistant elements for high precision mechanisms and scientific instruments, in particular optics instruments subjected to severe environment conditions in Space, notably under harsh temperature.

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain

Durée du projet: 04.06.2019 - 31.01.2020

Statut: Abgeschlossen

Novel titanium alloys for cost-effective production of parts by powder metallurgy

AGP

Rolle: Hauptgesuchsteller/in

Financement: Höganäs AB

Description du projet : The development work concerns production and investigations of different Ti-based alloying systems, in order to find a Ti-alloy suitable for compaction and sintering, and for MIM. The work will start with a comprehensive literature study to establish the state of art, and to find suitable alloying elements that might improve the possibility to use the alloy in PM applications. Alloys of interest will be produced by Höganäs AB, the Helmholtz-Zentrum Geesthacht (HZG) or be purchased. Processing of parts and evaluation of the alloys in different applications will be performed at the HZG, the HES-SO Valais-Wallis, and at Höganäs.

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain , Rodriguez Arbaizar Mikel

Partenaires académiques: VS - Institut Systèmes industriels; Carreno-Morelli Efrain, VS - Institut Systèmes industriels

Durée du projet: 01.09.2015 - 31.12.2018

Montant global du projet: 26'850 CHF

Statut: Abgeschlossen

Processing of low thermal expansion alloy parts by a novel three dimensional printing technique (3DP-lnvar)

AGP

Rolle: Hauptgesuchsteller/in

Financement: Swiss Space Center EPFL

Description du projet : The goal of this project is to assess the feasibility of producing Invar (Fe-36Ni), low thermal expansion parts by the novel 'Solvent on Granule Three Dimensional Printing Technique', which has been recently developed at HES-SO Valais. The field of application is the manufacturing of light weight and thermallly stable structural elements for high precision mechanisms and scientific instruments to be flown in space, in particular optics instruments. Low coefficient of thermal expansion below 1 ppm/°C, reduced porosity and high sintered density, reduced contamination, good shape preservation and dimensional stability are among the target properties.

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain , Rodriguez Arbaizar Mikel

Partenaires académiques: VS - Institut Systèmes industriels; Carreno-Morelli Efrain, VS - Institut Systèmes industriels

Durée du projet: 01.06.2017 - 30.11.2017

Montant global du projet: 14'700 CHF

Statut: Abgeschlossen

Moulage par injection de poudres métalliques à l'aide de liants biosourcés

AGP

Rolle: Hauptgesuchsteller/in

Financement: HES-SO Rectorat

Description du projet : Le but de ce projet est de développer un nouveau procédé pour produire des pièces par moulage par injection de poudres métalliques, à l'aide de liants polymères biosourcés. Les domaines d'application sont l'horlogerie et l'industrie biomédicale. L'originalité du projet réside dans l'utilisation de liants écologiques pour le transport des poudres lors du moulage et pour conférer de la résistance aux corps verts. Ces liants sont retirés par la suite et ne sont donc pas présents dans les pièces frittées, qui sont faites de matériaux conventionnels. Donc, le projet ne concerne pas le développement de nouveaux matériaux mais un nouveau procédé de fabrication. Un avantage du moulage et du micromoulage des pièces net-shape est la quantité réduite de matière qui est nécessaire. Le caractère biodégradable des polymères naturels permet en plus de réduire l'impact sur l'environnement. Haute résistance à la corrosion et absence de ferromagnétisme sont d'une importance majeure dans les domaines d'application visés, Des poudres d'alliages de titane et d'acier inoxydable sans nickel seront utilisées. Les liants seront sélectionnés parmi des polymères générés par fermentation bactérienne, des gélatines d'origine végétale ou animale, de la cellulose, de l'amidon et d'autres polymères naturels. Leur capacité à conférer de la résistance aux corps verts et remplacer des liants conventionnels dérivés du pétrole sera établie. Des pièces de test seront produites et caractérisées. Des procédés récemment développés à la HES-SO Valais seront notamment utilisés: d'une part le moulage par injection d'alliages de titane à partir d'hydrures métalliques, d'autre part la biosynthèse de polyhydroxyalcanoates (PHAs) par fermentation bactérienne. La HEIA-FR contribuera dans la caractérisation, la sélection et la réutilisation des liants, plastifiants, surfactants et solvants. Le contrôle dimensionnel des pièces, l'analyse des défauts par tomographie, le bilan énergétique et l'évaluation des impacts environnementaux du procédé seront réalisés à l'HEPIA. En collaboration avec la Société Soprod SA, on produira pièce complexe des dimensions réduites pour mouvement de montre en quartz, qui permettra d'évaluer le potentiel et les limites des nouveaux feedstocks.

Forschungsteam innerhalb von HES-SO: Girard Hervé , Dabros Michal , Micaux Fabrice , Zinn Manfred , Carreno-Morelli Efrain , Grand Pascal , Sthioul Hervé , Richard Jacques , Chappuis Thierry , Hanik Nils , Rodriguez Arbaizar Mikel

Partenaires académiques: VS - Institut Systèmes industriels; VS - Institut Technologies du vivant; hepia inSTI; FR - EIA - Institut ChemTech; Carreno-Morelli Efrain, VS - Institut Systèmes industriels

Durée du projet: 01.10.2015 - 30.11.2017

Montant global du projet: 237'500 CHF

Statut: Abgeschlossen

Diamond-based cutting tools with incorporated dry lubricant - Innosuisse 14701.1;7 PFIW-IW

Rolle: Hauptgesuchsteller/in

Description du projet :

Diamond cutting discs for construction materials with incorporated dry lubricant will be developed. The lubricant is expected to reduce friction and consequently improve the cutting performance and decrease the power consumption. The segments will be produced by uniaxial compaction of metal powder, diamond, and lubricant mixtures, followed by high temperature sintering. Dry lubricants with different composition, morphology, size, and volume fraction will be employed. The performance of the discs made with the segments will be assessed by cutting tests.

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain

Durée du projet: 01.01.2013 - 26.05.2015

Statut: Abgeschlossen

Casting simulation for next generation nozzle guide vane production - Innosuisse 10674.1;8 PFIW-IW

Rolle: Hauptgesuchsteller/in

Description du projet :

The main objective is the creation of advanced modeling capabilities for the production of next generation nozzle guide vanes (NGV). The project is an essential part of the proposed ERANET MATERA+ VANCAST project (part of the European FP7 program). In this project the modeling of mold filling, solidification, residual stress, microstructure and defect evolution during equiaxed casting processes will be further developed and improved, based upon experiments.

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain

Durée du projet: 11.11.2010 - 23.12.2014

Statut: Abgeschlossen

Composants ferromagnétiques fabriqués par pressage uniaxial de poudres SMC (soft magnetic composites)

AGP

Rolle: Hauptgesuchsteller/in

Financement: HES-SO Rectorat

Description du projet : Le but de ce projet est la fabrication des composants ferromagnétiques doux à partir des poudres métalliques enrobées d'une couche isolante. La mise en forme se fait par pressage uniaxial suivi d'un traitement thermique à basse température (sans frittage). Le noyau conducteur des grains reste isolé et la résistivité électrique augmente, ce qui permet de réduire les pertes par courants de Foucault. Le procédé est de grand intérêt du point de vue énergétique, car le rendement peut être augmenté dans un grand nombre d'applications, en particulier dans les moteurs électriques.

Forschungsteam innerhalb von HES-SO: Ottonin Cyril , Carreno-Morelli Efrain , Germanier Alain , Rodriguez Arbaizar Mikel , Herzog Raoul , Mabillard Eric

Partenaires académiques: IAI; VS - Institut Systèmes industriels; Carreno-Morelli Efrain, VS - Institut Systèmes industriels

Durée du projet: 01.04.2013 - 15.09.2014

Montant global du projet: 60'000 CHF

Statut: Abgeschlossen

Moulage par injection de pièces poreuses à partir de feedstocks contenant des additifs formateurs de pores

AGP

Rolle: Hauptgesuchsteller/in

Financement: HES-SO Rectorat

Description du projet : Le but de ce projet est le développement des matériaux poreux pour implants par moulage par injection des poudres (PIM). Biocompatibilité, bon accrochage et module d'élasticité comparable à l'os sont requis pour les implants permanents, pour des raisons de fonctionnalité et sécurité, ainsi que pour limiter les opérations de remplacement. Des implants en titane ou zircone poreux produits par technologie PIM peuvent satisfaire ces exigences, pourvu que le taux de porosité et la taille des pores soient appropriés pour une croissance rapide des tissus dans l'implant. À cet effet, des nouveaux feedstocks contenant des additifs formateurs de pores seront développés, pour une porosité ouverte entre 30% et 60% avec des pores de taille comprise entre 50um et 500um.

Forschungsteam innerhalb von HES-SO: Girard Hervé , Carreno-Morelli Efrain , Rodriguez Arbaizar Mikel

Partenaires académiques: VS - Institut Systèmes industriels; Carreno-Morelli Efrain, VS - Institut Systèmes industriels

Durée du projet: 01.03.2012 - 28.02.2013

Montant global du projet: 30'000 CHF

Statut: Abgeschlossen

Novel feedstock for metal injection molding

AGP

Rolle: Hauptgesuchsteller/in

Financement: GKN Sinter Metals

Description du projet : Agar-based feedstock for MIM of big parts

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain , Rodriguez Arbaizar Mikel , Mabillard Eric

Partenaires académiques: HES-SO Valais-Wallis

Durée du projet: 01.08.2006 - 05.03.2009

Montant global du projet: 155'000 CHF

Statut: Abgeschlossen

CTI 5990.3 Carbon Nanotube Composites

AGP

Rolle: Hauptgesuchsteller/in

Financement: EPFL

Description du projet : The present project aims at developing composite materials, in which the reinforcements are carbon nanotubes (CNTs) and the matrices aluminum or magnesium alloys. Because of the very high Young modulus (~ 1000 GPa) of the CNTs associated with their high flexibility, the nano-structured composites could exhibit excellent elastic and anelastic properties. Applications of such materials may be found in microtechnics and space industry, where components of high rigidity associated with a high internal damping are needed. Moreover, because of their good hydrogen adsorption ability, CNTs associated with magnesium can be interesting materials for hydrogen storage.

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain

Partenaires académiques: HES-SO Valais-Wallis; Carreño-Morelli Efrain, HES-SO Valais-Wallis

Durée du projet: 01.11.2002 - 31.12.2008

Montant global du projet: 45'260 CHF

Statut: Abgeschlossen

Capteurs de pression produits par déposition des couches épaisses sur substrat métallique

AGP

Rolle: Hauptgesuchsteller/in

Financement: CTI; Huba Control AG

Description du projet : Les capteurs de force et de pression basés sur la technologie des couches épaisses déposées sur céramique occupent une part de marché importante en raison de leur bas coût de production (industries automobile, frigorifique et chimique). Cependant, leurs applications restent limitées en raison du joint polymère nécessaire à l'étanchéité. Ce projet vise à développer des corps de capteur en acier et la technologie des couches épaisses appropriée pour la fabrication des capteurs de haute fiabilité pouvant être assemblés par soudage.

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain , Knupfer Pierre-André , Mabillard Eric

Partenaires académiques: Partenaire indéfini; HES-SO Valais-Wallis; EPFL; Berner Fachhochschule; Carreño-Morelli Efrain, HES-SO Valais-Wallis

Durée du projet: 01.10.2004 - 31.05.2006

Montant global du projet: 563'894 CHF

Statut: Abgeschlossen

DSLP - Déposition sélective de liant sur des poudres

AGP

Rolle: Hauptgesuchsteller/in

Financement: HES-SO Valais-Wallis; HES-SO Rectorat

Description du projet : Etude de faisabilité d'un procédé génératif qui consiste à déposer un liant sélectivement pour joindre des particules de poudre et construire un objet couche par couche. Le corps vert ainsi obtenu est soumis à un déliantage suivi d'un frittage. Les matériaux de base comprennent des liants polymères, des poudres métalliques élémentaires ou pré-alliées base Fe, Cu, Al, et des poudres céramiques à base de zircone ou d'alumine. La maîtrise de ce nouveau procédé de mise en forme sans moule offre un potentiel important pour la construction des pièces de géométrie complexe qui ne sont pas réalisables par les méthodes conventionnelles. Etapes du projet : - mise au point d'une buse pour la déposition du liant - mise en route d'un système expérimental de déposition de liant sur des poudres - développement des systèmes poudre-liant pour la réalisation des corps verts - établissement des étapes de déliantage et frittage nécessaires pour la consolidation des pièces métalliques et céramiques

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain , Knupfer Pierre-André , Mabillard Eric

Partenaires académiques: VS - Institut Systèmes industriels; Carreño-Morelli Efrain, VS - Institut Systèmes industriels

Durée du projet: 01.10.2003 - 30.08.2005

Montant global du projet: 127'607 CHF

Statut: Abgeschlossen

Injection de poudres métalliques et céramiques

AGP

Rolle: Mitarbeiter

Financement: HES-SO Valais-Wallis; FR - Ecole d'ingénieurs de Fribourg

Description du projet : Injection de poudres métalliques et céramiques (méthode PIM)

Forschungsteam innerhalb von HES-SO: Carreno-Morelli Efrain , Costa Christian , Grand Pascal

Durée du projet: 01.08.1999 - 31.01.2001

Montant global du projet: 192'600 CHF

Statut: Abgeschlossen

2024

over 100 peer-reviewed papers in international journals and conference proceedings

Wissenschaftlicher Artikel

Carreno-Morelli Efrain

please refer to ResearchGate and ORCID links in the top of the page, 2024

2023

High-oxygen MIM Ti-6Al-7Nb :

Wissenschaftlicher Artikel ArODES

microstructure, tensile and fatigue properties

Alexandra Amherd Hidalgo, Thomas Ebel, Robert Frykholm, Efrain Carreno-Morelli, Florian Pyczak

Materials Today Communications, 34, 104982

Link zur Publikation

Zusammenfassung:

The intention to make cost-effective titanium parts by powder metallurgy (PM) is a challenge. The oxygen content in PM titanium alloys depends on the powder production method used and increases during handling and sintering of powders. This paper contributes to understand the influence of oxygen on tensile and high cycle fatigue (HCF) properties of Ti‐6Al‐7Nb processed by MIM. It was confirmed that oxygen could purposely be used as a potent strengthener. However, special attention has to be paid if using an excessive amount of oxygen that might cause a dramatic drop of ductility due to deformation mode changes and evolution of non-equilibrium microstructures. It has been determined that such a non-equilibrium microstructure contributes to strengthening and loss of ductility and it can be controlled using an optimised cooling rate during the sintering cycle. Moreover, it was found that oxygen produces a progressive reduction of HCF properties. In summary, this study validates the tolerance of MIM α + β titanium alloys to certain amounts of oxygen content in relation to the mechanical properties.

2022

Fused filament fabrication of stainless steel structures - from binder development to sintered properties

Wissenschaftlicher Artikel ArODES

Marius A. Wagner, Amir Hadian, Tutu Sebastien, Frank Clemens, Thomas Schweizer, Mikel Rodriguez Arbaizar, Efrain Carreno-Morelli, Ralph Spolenak

Additive Manufacturing, 2022, vol. 49, article no. 102472

Link zur Publikation

Zusammenfassung:

Additive manufacturing of metals by 3D printing of polymeric filaments containing high loading of metal powder, subsequent debinding, and sintering offers a potent alternative to the widespread beam-based processes. The polymeric binder is the decisive component for a successful fabrication process. This study presents the development of a multi-component binder system for filament-based 3D printing of 316 L stainless steel in various optimization steps. The binder contains a polyethylene (PE) backbone, which ensures the structural integrity during solvent debinding. A soluble binder component consisting of a thermoplastic elastomer (TPE) and a second PE is used, to reduce the polymer content via solvent extraction prior to thermal debinding. The TPE grants flexibility to the filaments, while the PE allows reduction of the viscosity and increase in stiffness and strength. This enables precise tuning of the rheological and mechanical properties of the filaments. The capabilities of the binder system developed, are demonstrated by the fabrication of 3D plate-lattices. The structures are printed, subjected to a two-step solvent – thermal debinding procedure, and finally sintered. In the compression tests the structures are able to undergo large plastic deformations without fracture, highlighting their potential for energy absorption applications. The main contribution of this work is the development and disclosure of a binder system with two types of soluble polymers. This allows the precise control of the mechanical and rheological properties, as well as the backbone fraction of the binder. Based on the characterization performed, the binder system can be easily modified to adapt for other solid loading materials and fractions, as parameters like stiffness, viscosity, or backbone content can be adjusted precisely.

2021

A comparative study of cemented carbide parts produced by solvent on granules 3D-printing (SG-3DP) versus press and sinter

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, P. Alveen, S. Moseley, Mikel Rodriguez-Arbaizar, Kevin Cardoso

International Journal of Refractory Metals and Hard Materials, 2021, vol. 97, article no. 105515

Link zur Publikation

Zusammenfassung:

Cemented carbide parts have been manufactured from WC-12Co granules by “Solvent on Granules 3D-Printing” and compared with reference parts produced by conventional press and sintering. SG-3DP consists in growing a green part layer-by-layer by selective solvent jetting on powder-polymer granule beds. Both 3D printed green parts and uniaxially pressed compacts have been consolidated by thermal debinding and liquid phase sintering. Further densification has been achieved by hot isostatic pressing. 3D-printed parts subjected to hot isostatic pressing exhibit 99.9% of theoretical density, 1308 ± 10 HV30 hardness and 12.1 ± 0.3 MPa∙m½ indentation toughness, which are comparable to properties of a commercial fine grained WC-12Co. Percussion drilling tests with fully dense SG-3DP drill plates have also been carried out successfully on concrete.

2020

Three-dimensional printing of hard materials

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Patricia Alveen, Steven Moseley, Mikel Rodriguez Arbaizar, Kevin Cardoso

International Journal of Refractory Metals and Hard Materials, 2020, vol. 87, article no. 105110

Link zur Publikation

Zusammenfassung:

Tungsten cemented carbide parts have been produced by the “Solvent on Granule” 3D-Printing technique. It consists in growing layer-by-layer a green part by spreading a powder-polymer granule bed, followed by selective solvent jetting, and layer consolidation after solvent evaporation. The granules are prepared by wet blending, drying, milling and sieving to appropriate size range. The printed green parts are consolidated by thermal debinding and liquid phase sintering. Fully dense WC-Co test parts and a drill bit have been produced from presintered powder and elementary Co powder. The microstructures are equivalent to those of press and sintered parts. Good shape retention and tolerances are achieved.

2017

MIM of nickel-free nitrogen strengthened austenitic stainless steel from bipolymer based feedstock

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Manfred Zinn, Mikel Rodriguez Arbaizar, Hervé Girard, Monica Bassas-Galia, Thierry Chappuis, Jacques Richard

Powder Injection Moulding International, 2017, vol. 11, no. 4

Link zur Publikation

Zusammenfassung:

Nickel-free stainless steels are of high interest for medical and dental applications, as well as consumer goods where contact with the skin is a consideration. In this paper Prof Efraín Carreño-Morelli and colleagues from the University of Applied Sciences and Arts Western Switzerland evaluate the MIM processing of the high-nitrogen content austenitic stainless steel P558. This is processed using a novel environmentally friendly binder that incorporates a polymer produced by bacterial fermentation.

Sintering optimisation of Fe–Si soft magnetic materials processed by metal injection moulding

Wissenschaftlicher Artikel ArODES

A. Páez-Pavòn, A. Jiménez-Morales, Mikel Rodriguez Arbaizar, Efrain Carreno-Morelli, J. M. Torralba

Powder Metallurgy, 2017, vol. 60, no. 2, pp. 112-119

Link zur Publikation

Zusammenfassung:

Soft magnetic materials are used in a wide variety of electromagnetic devices such as motors, relays and sensors. Over the years, the devices are becoming smaller. Therefore, it is essential to produce small parts without compromising the final properties. Metal injection moulding (MIM) is a cost-effective technique to produce small and complex soft magnetic parts with optimal mechanical and magnetic performance. These properties can be improved by maximising the sintered density and by the reduction of impurities content. These factors are strongly related to the sintering parameters. The goal of this study is to determine the influence of the sintering parameters on the final properties of iron–silicon soft magnetic alloys processed by metal injection moulding. In this work, two alloys were sintered under different conditions. The effect of the sintering conditions on both mechanical and magnetic properties was evaluated.

2016

Metal injection moulding of superelastic TiNi parts

Wissenschaftlicher Artikel ArODES

Jacques-Eric Bidaux, Alexandra Amherd Hidalgo, Hervé Girard, Mikel Rodriguez Arbaizar, Lionel Reynard, Jacques Chevallier, François Aeby, Jean Charles Giachetto, Efrain Carreno-Morelli

Key Engineering Materials, 2016, vol. 704, pp. 173-182

Link zur Publikation

Zusammenfassung:

TiNi shape-memory properties are successfully used today for the fabrication of various technical devices. The limited machinability and high cost of TiNi encourage the use of near-net shape production techniques such as metal injection moulding. In this work TiNi alloys tensile test specimens are produced by metal injection moulding from pre-alloyed powders. A binder based on a mixture of polyethylene, paraffin wax and stearic acid is used. Parts with a density of about 96.6% of theoretical density are obtained. Scanning electron microscopy coupled with EDX measurements reveals a microstructure consisting of a TiNi matrix with small Ti4Ni2Ox and TiC inclusions. DSC and X-ray diffraction observations indicate the presence of additional Ni4Ti3 precipitates. The parts exhibit full superelasticity at room temperature even for strains of up to 4%, without the need for additional thermal post-treatments. Ultimate tensile strengths up to 980 MPa are obtained.

Nickel-free P558 stainless steel processed from metal powder – PHA biopolymer feedstocks

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Manfred Zinn, Mikel Rodriguez-Abraizar, Monica Bassas

European Cells and Materials, 2016, vol. 32, suppl. 2, p. 32

Link zur Publikation

2014

Low elastic modulus Ti–17Nb processed by powder injection moulding and post-sintering heat treatments

Wissenschaftlicher Artikel ArODES

Jacques E. Bidaux, Richard Pasquier, Mikel Rodriguez Arbaizar, Hervé Girard, Efrain Carreno-Morelli

Powder Metallurgy, 2014, vol. 57, no. 5, pp. 320-323

Link zur Publikation

Zusammenfassung:

Ti–Nb alloys are attractive as biomaterials because of their excellent combination of low elastic modulus, high strength, corrosion resistance and enhanced biocompatibility. The effect of a post-sintering quenching treatment on the microstructure and mechanical properties of powder injection moulded Ti–17Nb has been investigated. Tensile test specimens were produced using a feedstock based on blended elemental powders, some of which were solution-treated in the β phase field and water quenched. Both as-sintered and quenched alloys had densities 95·5% of theoretical. The as-sintered material showed an α−β structure, whereas after quenching a fully martensitic α″ structure was obtained. The modulus of elasticity of the water-quenched alloy (∼45 GPa) was about 40% lower than that of the as-sintered alloy (∼76 GPa).

Investment casting of nozzle guide vanes from nickel-based superalloys :

Wissenschaftlicher Artikel ArODES

part II – grain structure prediction

Agustin Jose Torroba, Ole Koeser, Loic Calba, Laura Maestro, Efrain Carreno-Morelli, Mehdi Rahimian, Srdjan Milenkovic, Ilchat Sabirov, javier Llorca

Integrating Materials and Manufacturing Innovation, 2014, vol. 3, pp. 369-384

Link zur Publikation

Zusammenfassung:

The control of grain structure, which develops during solidification processes in investment casting of nozzle guide vanes (NGVs), is a key issue for optimization of their mechanical properties. The main objective of this part of the work was to develop a simulation tool for predicting grain structure in the new generation NGVs made from MAR-M247 Ni-based superalloy. A cellular automata - finite element (CAFE) module is employed to predict the three-dimensional (3D) grain structure in the as-cast NGV. The grain structure in the critical sections of the experimentally cast NGV is carefully analyzed, the experimental results are compared with the modeling outcomes, and the model is calibrated via tuning parameters which govern grain nucleation and growth. The grain structures predicted by the calibrated model show a very good accordance with the real ones observed in the critical sections of the as-cast NGV. It is demonstrated that the calibrated CAFE model is a reliable tool for the foundry industry to predict grain structure of the as-cast NGVs with very high accuracy.

Investment casting of nozzle guide vanes from nickel-based superalloys :

Wissenschaftlicher Artikel ArODES

part I – thermal calibration and porosity prediction

Agustin Jose Torroba, Ole Koeser, Loic Calba, Laura Maestro, Efrain Carreno-Morelli, Mehdi Rahimian, Srdjan Milenkovic, Ilchat Sabirov

Integrating Materials and Manufacturing Innovation, 2014, vol. 3, pp. 344-368

Link zur Publikation

Zusammenfassung:

Investment casting is the only commercially used technique for fabrication of nozzle guide vanes (NGVs), which are one of the most important structural parts of gas turbines. Manufacturing of NGVs has always been a challenging task due to their complex shape. This work focuses on development of a simulation tool for investment casting of a new generation NGV from MAR-M247 Ni-based superalloy. A thermal model is developed to predict thermal history during investment casting. Experimental casting trials of the NGV are carried out and the thermal history of metal, mold, and insulation wrap is recorded. Inverse modeling of the casting trials is used to define accurately some thermophysical parameters and boundary conditions of the thermal model. Based on the validated thermal model, another model is developed to predict porosity in the as-cast NGVs. The porosity predictions are in good agreement with the experimental results in the as-cast NGVs. The advantages and shortcomings of the developed modeling tool are discussed.

Production of titanium grade 4 components by powder injection moulding of titanium hydride

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Jacques-Eric Bidaux, Mikel Rodriguez Arbaizar, Hervé Girard

Powder Metallurgy, 2014, vol. 57, no. 2, pp. 89-92

Link zur Publikation

Zusammenfassung:

Recent developments are presented on powder injection moulding of titanium from metal hydride powders and binders composed of polyethylene, paraffin wax and stearic acid. The feasibility of using this route to process fit for purpose, complex parts is assessed. Titanium hydride offers a low cost solution compared with pure titanium powders. Feedstocks for powder injection moulding were prepared in a sigma mixer. Tensile test specimens and demonstration parts were injection moulded. Solvent debinding in heptane was followed by thermal debinding and dehydrogenation under argon. Titanium parts were sintered at 1200°C under argon. Sintered parts exhibit a linear shrinkage of about 20%, good shape preservation and reproducibility. The yield strength (519 MPa), ultimate tensile strength (666 MPa), elongation to fracture (15%) and interstitial content measured by quantitative analysis meet the requirements for titanium grade 4.

Porous titanium processed by powder injection moulding of titanium hydride and space holders

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Mikel Rodriguez Arbaizar, Jacques-Eric Bidaux

Powder Metallurgy, 2014, vol. 57, no. 2, pp. 93-96

Link zur Publikation

Zusammenfassung:

Biocompatibility, bone-like mechanical properties, and good bone-to-implant anchorage are current requirements for permanent implants. Porous titanium can satisfy these requirements provided that sufficient porosity, large enough pores and interconnections allowing bone ingrowth can reliably be obtained with controlled processes. In the present work, porous parts are processed from titanium hydride based feedstocks containing space holders. Two formulations have been developed: a feedstock with a polyethyleneglycol based binder and NaCl space holders, and a feedstock with a paraffin based binder and PMMA space holders. Depending on the sintering conditions, porosity levels between 30 and 60% and open porosity between 10 and 40% are obtained, with pore sizes in the range 50–500 μm. The microstructure, porosity and mechanical properties of porous titanium sintered at various temperatures have been characterised by scanning electron microscopy and compression tests.

2013

Metal injection moulding of low modulus Ti–Nb alloys for biomedical applications

Wissenschaftlicher Artikel ArODES

Jacques-Eric Bidaux, C. Closuit, Mikel Rodriguez Arbaizar, Daniel Zufferey, Efrain Carreno-Morelli

Powder Metallurgy, 2013, vol. 56, no. 4, pp. 263-266

Link zur Publikation

Zusammenfassung:

Titanium alloys containing β stabilising elements such as Nb, Zr and Ta are particularly promising as implant materials because of their excellent combination of low modulus, high strength, corrosion resistance and biocompatibility. A low elastic modulus is important for implants to avoid stress shielding and associated bone resorption. The difficulty of producing complex shapes of these alloys by conventional methods makes metal injection moulding (MIM) attractive. Ti–17Nb alloy parts with densities 94% of theoretical have been produced by MIM of a feedstock based on blended elemental powders. Scanning electron microscopy reveals a typical α−β Widmanstätten microstructure with a precipitated α phase layer along the grain boundaries. The parts exhibit an ultimate tensile strength of 768 MPa and a plastic elongation of over 5%. The modulus of elasticity, about 84 GPa, is more than 20% lower than that of cp Ti and Ti–6Al–4V.

Opportunities and limits of in vitro cytotoxicity test methods exemplified by powder metallurgy titanium alloys

Wissenschaftlicher Artikel ArODES

M. Pusnik, A. Bruinink, Mikel Rodriguez Abraizar, Efrain Carreno-Morelli, Manfred Zinn

Europen Cells and Materials, 2013, vol. 26, supp. 4, p. 44

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Opportunities and limits of in vitro cytotoxicity test methods exemplified by powder metallurgy titanium alloys

Wissenschaftlicher Artikel ArODES

Mascha Pusnik, Arie Bruinink, Mikel Rodriguez Arbaizar, Efrain Carreno-Morelli, Manfred Zinn

European cells and materials, 2013, vol. 26, suppl. no. 4, p. 44

Link zur Publikation

Zusammenfassung:

Testing for in vitro cytotoxicity aims at obtaining data for a test material from simplified in vitro systems that can be used to make a prognosis for a key step within the processes occurring after implantation in the human body. Depending on the application of the test specimens, one can choose from a number of different assays to assess its bioacceptance in terms of absence of cytotoxicity. While guidelines (e.g. ISO, ASTM) describe a number of mandatory test procedures for official approval, additional tests have to be performed to properly evaluate the in vitro effects of test specimen on cells. In this work we evaluate for the bioacceptance of different Ti alloys by two different assays; the agar overlay test and the extraction test, both described by the ISO 10993-5 guidelines. Opportunities and limits of cytotoxicity testing based on these and other methods are discussed.

Porous titanium by powder injection moulding of titanium hydride and PMMA space holders

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Alexandra Amherd Hidalgo, Mikel Rodriguez Arbaizar, Daniel Zufferey, Alejandro Várez, Jacques-Eric Bidaux

European cells and materials, 2013, vol. 26, suppl. no. 4, p. 16

Link zur Publikation

Zusammenfassung:

Porous titanium is used as implant material because of its high specific strength, bone-like stiffness, biocompatibility and good bone cell ingrowth provided that the open pores have sizes between 100 μm and 500μm. Powder metallurgy has been successfully used to produce titanium foams by using the space holder method. Recently, Ti grade 4 has been obtained by powder injection moulding (PIM) of titanium hydride, which is cheaper and less reactive than pure titanium. The feasibility of a novel route combining TiH2 and space holders to produce porous titanium is explored in this work.

2012

Processing of a low modulus Ti-Nb biomaterial by metal injection moulding (MIM)

Professioneller Artikel ArODES

Jacques-Eric Bidaux, C. Closuit, Mikel Rodriguez Arbaizar, D. Zufferey, Efrain Carreno-Morelli

Powder Injection Moulding International, 2012, vol. 6, no. 4, pp. 70-73

Link zur Publikation

Zusammenfassung:

Ti alloys containing β stabilising elements such as Nb, Zr and Ta are particularly promising as implant materials because of their excellent combination of low modulus, high strength, corrosion resistance and biocompatibility. A low elastic modulus is important for implants to avoid stress shielding and associated bone resorption. The difficulty of producing complex shapes of these alloys by conventional methods makes Metal Injection Moulding attractive. In this work, Ti-17Nb alloy parts with densities of 94% of theoretical density have been produced by metal injection moulding of a feedstock based on blended elemental powders. Scanning electron microscopy reveals a typical α-β Widmanstätten microstructure with a precipitated α phase layer along the grain boundaries. The parts exhibit an ultimate tensile strength of 768 MPa and a plastic elongation of over 5%. The modulus of elasticity, about 84 GPa, is more than 20% lower than that of CP Ti and Ti-6Al-4V.

2011

Net-shape titanium grade 4 parts processed from titanium hydride powders

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Mikel Rodriguez Arbaizar, Hervé Girard, H. Hamdan, Jacques-Eric Bidaux

European cells and materials, 2011, vol. 22, suppl. 4, p. 33

Link zur Publikation

Metal injection moulding of Ti-Nb alloys for implant application

Wissenschaftlicher Artikel ArODES

Jacques-Eric Bidaux, C. Closuit, Mikel Rodriguez Arbaizar, Efrain Carreno-Morelli

European cells and materials, 2011, vol. 22, suppl. 4, p. 32

Link zur Publikation

Nano-silicon carbide reinforced aluminium produced by high-energy milling and hot consolidation

Wissenschaftlicher Artikel ArODES

L. Kollo, C. R. Bradbury, R. Veinthal, C. Jäggi, Efrain Carreno-Morelli, M. Leparoux

Materials Science and Engineering:, 2011, vol. 528, no. 21, pp. 6606-6615

Link zur Publikation

Zusammenfassung:

High-energy milling was studied for the ex situ strengthening of aluminium with silicon carbide (SiC) nanopowders. Heptane was used as a milling agent for both planetary- and attritor ball milling. Considering the different milling techniques and the differences in the resulting powders, effective dispersion of the nano SiC was achieved. Composite samples compacted by hot pressing showed an increase in hardness (HV20 = 220) and a decrease in Al crystallite size from 220 to 55 nm with the nano-SiC content increasing from 1 up to 20 vol.%. The ultimate tensile strength was measured for extruded samples which resulted in 205 MPa (17% elongation) for 1 vol.% of nano-SiC and a strength of 420 MPa (4% elongation) for 10 vol.% of nano-SiC reinforcement. The mechanical properties were compared with what was predicted by the Hall–Petch relationship.

2010

Titanium parts by powder injection moulding of TiH2-based feedstocks

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, William Krstev, B. Romeira, Mikel Rodriguez Arbaizar, Hervé Girard, Jacques-Eric Bidaux, S. Zachmann

Powder injection moulding international, 2010, vol. 4, no. 3, pp. 60-63

Link zur Publikation

Zusammenfassung:

Titanium parts have been processed from feedstocks composed of titanium hydride powders, low density polyethylene, paraffin wax and stearic acid. A two-step debinding process has been used, which consists of solvent debinding in heptane at 50°C followed by thermal debinding at 500°C. Sintering was performed at 1200°C. Both thermal debinding and sintering were performed under a protective atmosphere in a MIM furnace equipped with molybdenum heating elements and a debinding retort. Special care in powder handling, feedstock preparation, debinding and sintering atmospheres, allowed to limit the residual oxygen, nitrogen and carbon contents, which were determined by quantitative analysis. The mechanical properties of net‑shape sintered parts were measured by tensile tests. A tensile strength of 580 MPa and an elongation of 1.8% were obtained. Experimental watch bracelet segments were injection moulded, showing good shape preservation and reproducibility.

Hydrogen storage properties of as-synthesized and severely deformed magnesium – multiwall carbon nanotubes composite

Wissenschaftlicher Artikel ArODES

Vladimir M. Skripnyuk, Eugen Rabkin, Leonid A. Bendersky, Arnaud Magrez, Efrain Carreno-Morelli, Yuri Estrin

International Journal of Hydrogen Energy, 2010, vol. 35, no. 11, pp. 5471-5478

Link zur Publikation

Zusammenfassung:

We prepared a Mg-2 mass % multiwall carbon nanotubes composite employing a powder metallurgy technique. The kinetics of hydrogen absorption/desorption of the as-synthesized composite was much faster than that of reference samples of pure Mg. The pressure-composition isotherm (measured at 300 °C) of the as-synthesized composite exhibited no measurable pressure hysteresis, with the equilibrium hydrogen pressures in the plateau region being higher than those of pure Mg by a factor of up to 1.8. Equal channel angular pressing of the as-synthesized composite led to a slow down of the absorption/desorption processes at the initial stages of the processes, and to their acceleration at the later stages. We suggested that the mechanism responsible for the good kinetic performance of the as-synthesized composite was fast diffusion of hydrogen through the cores of carbon nanotubes. We put forward a hypothesis relating the increase in equilibrium hydrogen pressure in the as-synthesized composite to the elastic constraints imposed by carbon nanotubes on the Mg matrix.

Investigation of planetary milling for nano-silicon carbide reinforced aluminium metal matrix composites

Wissenschaftlicher Artikel ArODES

Lauri Kollo, Marc Leparoux, Christopher R. Bradbury, Christian Jäggi, Efrain Carreno-Morelli, Mikel Rodriguez Arbaizar

Journal of Alloys and Compounds, 2010, vol. 489, no. 2, pp. 394-400

Link zur Publikation

Zusammenfassung:

High-energy planetary milling was used for mixing aluminium powders with 1 vol.% of silicon carbide (SiC) nanoparticles. A number of milling parameters were modified for constituting the relationship between the energy input from the balls and the hardness of the bulk nanocomposite materials. It was shown that mixing characteristics and reaction kinetics with stearic acid as process control agent can be estimated by normalised input energy from the milling bodies. For this, the additional parameter characterising the vial filling was determined experimentally. Depending on the ball size, a local minimum in filling parameter was found, laying at 25 or 42% filling of the vial volume for the balls with diameter of 10 and 20 mm, respectively. These regions should be avoided to achieve the highest milling efficiency.After a hot compaction, fourfold difference of hardness for different milling conditions was detected. Therewith the hardness of the Al–1 vol.% nanoSiC composite could be increased from 47 HV0.5 of pure aluminium to 163 HV0.5 when milling at the highest input energy levels.

2009

Break the mould

Professioneller Artikel ArODES

Efrain Carreno-Morelli

Medical device developments, 2009, vol. 2, pp. 57-59

Link zur Publikation

Zusammenfassung:

Powder injection moulding combines flexible design with the strength of metals. Safety is key in medical devices, so corrosion-resistant and biocompatible materials such as titanium are ideal. Metal and ceramic injection moulding techniques are expected to see growth over the next few years.

2008

Three-dimensional printing of stainless steel parts

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Sebastien Martinerie, Lisa Mucks, B. Cardis

Materials Science Forum, 2008, vol. 591-593, pp. 374-379

Link zur Publikation

Zusammenfassung:

Stainless steel parts have been manufactured by two different layer by layer additive processes. The first one is a standard three dimensional process, in which metal powders are bound by selective deposition of binder with a printer head. The second one is a novel process, which is based on the selective deposition of a solvent on metal-polymer granule beds. The microstructures of green and sintered parts are characterized by optical and scanning electron microscopy, and the mechanical properties evaluated by hardness and tensile tests. Solvent on granule printing allows to reach mechanical properties similar to those of metal injection moulding parts.

Powder injection moulding of NiTi shape memory materials

Wissenschaftlicher Artikel ArODES

Jacques-Eric Bidaux, A. Jochem, Efrain Carreno-Morelli

Powder injection moulding international, 2008, vol. 2, no. 1, pp. 59-62

Link zur Publikation

Zusammenfassung:

NiTi parts have been produced by a new powder injection moulding route using a feedstock consisting of elemental TiH2 and Ni powder blended with an organic binder. The microstructure has been characterised by scanning electron microscopy coupled with energy-dispersive X-ray analysis. The sintered parts are porous except a dense surface layer. The bulk is NiTi with some Ti-rich domains. The surface layer is mostly NiTi with a dispersion of Ni-rich phases and some oxides and carbides. The presence of a martensitic transformation in the temperature range above room temperature has been shown by differential scanning calorimetry. Shape memory effects of more than 4% have been achieved.

2007

Three-dimensional printing of shape memory alloys

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Sebastien Martinerie, Jacques-Eric Bidaux

Materials Science Forum, 2007, vol. 534-536, pp. 477-480

Link zur Publikation

Zusammenfassung:

A novel variant of the three-dimensional printing technique has been developed and used to manufacture NiTi parts. Instead of metal powder the process uses granules, which consist of a mixture of metal powder and organic binder. These granules are spread on a working table. Then a solvent is dispensed with a printer head to consolidate a selected area of the granule bed and the table is moved down. The "solvent on granule" printing process is repeated until a threedimensional green body is obtained. The green part is finally debinded and sintered to obtain a dense and fully metallic part. NiTi parts have been successfully produced by this technique with densities of about 95% of the theoretical density. Detailed information on the microstructure has been obtained by X ray diffraction. Sintered parts exhibit shape memory effect, which has been measured during thermal cycling under tensile stress.

2006

Carbon nanotubes :

Buchkapitel ArODES

metal matrix composites

Efrain Carreno-Morelli

Dans Contescu, Cristian I., Lyshevski, Sergey Edward, Schwarz, James A., Dekker Encyclopedia of Nanoscience and Nanotechnology (9 p.). 2006, Boca Raton, FL, USA : CRC Press

Link zur Publikation

Zusammenfassung:

High elastic modulus and very low density make carbon nanotubes excellent candidates for use as reinforcements in composite materials. Lightweight, high strength and stiffness, enhanced hardness and enhanced electrical properties are among the drivers for the development of metal-nanotube composites. Unlike nanotube reinforced polymer- and ceramic-matrix composites, the manufacturing of bulk metal-matrix composites has been the subject of a reduced number of studies, and remains a great challenge involving the expertise of materials scientists. Until now, most of the classical processing techniques have failed in obtaining acceptable results, an exception being the powder metallurgy route. Uniform dispersion of nanotubes in the metal matrix and high nanotube-metal interfacial strength are among the main issues to be solved. This chapter outlines the recent advances in the field.

2005

Carbon nanotube / light-metal composites

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, N. Schmidt, Robert Schaller, Laszlo Forro

TMS letters, 2005, vol. 2, no. 4, pp. 119-120

Link zur Publikation

Zusammenfassung:

Novel light metal matrix composites have been processed by powder metallurgy. The feasibility of manufacturing magnesium- and aluminum-based composites reinforced with carbon nanotubes has been assessed. Blends of metal powders and CVD processed multi-wall carbon nanotubes were compacted by hot pressing followed by hot isostatic pressing. Sintering conditions were found, which allowed to obtain bulk specimens with sound mechanical properties.

2004

Carbon nanotube/magnesium composites

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Jian Yang, E. Couteau, K. Hernadi, J. W. Seo, C. Bonjour, L. Forró, Robert Schaller

physica status solidi (a), 2004, vol. 201, no. 8, pp. R53-R55

Link zur Publikation

Zusammenfassung:

Novel magnesium matrix composites reinforced with carbon nanotubes have been processed by powder metallurgy. Blends of metal powders and multi-wall carbon nanotubes were compacted by uniaxial hot pressing followed by hot isostatic pressing. A uniform dispersion of nanotubes in the metal matrix was obtained. A coating method of nanotubes is described, which is promising to improve the matrix-reinforcement bonding strength.

High performance very low frequency forced pendulum

Wissenschaftlicher Artikel ArODES

I. Gutiérrez-Urrutia, M. L. Nó, Efrain Carreno-Morelli, B. Guisolan, R. Schaller, J. San Juan

Materials Science and Engineering: A, 2004, vol. 370, no. 1-2, pp. 435-439

Link zur Publikation

Zusammenfassung:

A forced torsion pendulum has been constructed for the measurement of mechanical loss angle (tan δ) and elastic shear modulus in three different modes: (a) as a function of temperature (80–1250 K), at imposed frequency, during heating or cooling at imposed heating or cooling rate (0.1–5 K/min); (b) as a function of frequency (10–10−4 Hz) in isothermal conditions, and (c) as a function of amplitude (5×10−6 to 5×10−5) at imposed frequency and under isothermal conditions. The mechanical part of the pendulum has been designed in such a way that torsional plastic deformation of the specimen can be performed in situ, i.e., at low temperatures to generate fresh dislocations in metals, and at high temperatures to enhance grain boundary sliding, for instance. The whole installation is computer controlled and exhibits not only outstanding performances but also a very high capability of working in different conditions, being a useful tool for studying a large variety of mechanisms in different materials.

Quantifying thermomechanical fatigue of light-metal-matrix composites by mechanical spectroscopy

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli

Metallurgical and Materials Transactions, 2004, vol. 35

Link zur Publikation

Zusammenfassung:

This article reviews recent progress in understanding the stress-relaxation mechanisms in metal-matrix composites (MMCs) subjected to thermomechanical fatigue. Mechanical loss, dynamic shear modulus, and permanent torsional-strain measurements have been performed with forced oscillations during thermal cycling. A transient mechanical-loss maximum, which is absent in the monolithic material, appears during cooling. It has been attributed to the development of plastic zones around the reinforcements by dislocation generation and motion, which result from the differential thermal contraction of the matrix and reinforcement. This damping maximum is strongly dependent on both measurement and material parameters. The reversible shear-modulus evolution during thermal cycling suggests that no interfacial debonding occurs. In unalloyed matrices, extended thermal-stress-induced pleasicity occurs, leading to a plateau in the shear modulus, which is recovered at low temperatures by plastic-zone overlapping and matrix strain hardening. Simultaneously measured strain-temperature loops exhibit both reversible and permanent plasticity during thermal cycling (strain ratcheting).

2003

Selective laser sintering of aluminium- and titanium-based composites: processing and characterisation

Wissenschaftlicher Artikel ArODES

Sebastien Vaucher, Efrain Carreno-Morelli, C. André, Olivier Beffort

physica status solidi (a), 2003, vol. 199, no. 3, pp. R11-R13

Link zur Publikation

Zusammenfassung:

Metal matrix composites have been processed by selective laser sintering of metal-ceramic powder blends. The feasibility of manufacturing Al- and Ti-based composites reinforced with various ceramic particles has been assessed. The resulting microstructures are strongly dependent on the laser power and metal-ceramic reactivity. High laser power results in improved density. In-situ grown carbides develop during sintering in AlMg12–SiC and Ti-graphite systems. On the contrary, no discernible reaction has been observed in AlSi20–SiC and Ti-diamond systems.

2002

Mechanical loss and dimensional stability during thermal cycling of SiC particle reinforced aluminium alloys

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, Robert Schaller

physica status solidi (a), 2002, vol. 194, no. 1, pp. R1-R3

Link zur Publikation

1998

Processing and characterization of aluminium-based MMCs produced by gas pressure infiltration

Wissenschaftlicher Artikel ArODES

Efrain Carreno-Morelli, T. Cutard, A. Schaller, C. Bonjour

Materials Science and Engineering: A, 1998, vol A251, pp. 48-57

Link zur Publikation

Zusammenfassung:

A device has been designed and built for unidirectional infiltration of ceramic preforms with a molten metal. It allows production of Al or Mg alloys reinforced with short or continuous ceramic fibres. The apparatus has been tested for different alloys and preforms by varying the process parameters (infiltration pressure, fibre content, melt superheat, preform preheat and solidification speed). As an example, full infiltration of Al2O3–SAFFIL chopped preforms with an Al–4wt.%Cu–1wt.%Mg–0.5wt.%Ag alloy has been achieved under controlled conditions by using a gas pressure between 1 and 3 MPa. The resulting metal matrix composite has been characterised by microscopical observations and mechanical tests. Measurements of Young’s modulus, density, microhardness and mechanical loss show that the optimal process conditions for Al–4wt.%Cu–1wt.%Mg–0.5wt.%Ag–SAFFIL composites are a temperature of 750°C for both preform and melt and the maximum infiltration pressure of 3 MPa. Preliminary tests have shown that the gas pressure infiltration apparatus is also suitable to produce continuous fibre reinforced and hybrid metal matrix composites.

2024

over 80 presentations at international conferences

Konferenz

Carreno-Morelli Efrain

., 24.08.2024, .

2023

Solvent-on-granules 3D-printing and material extrusion of soft magnetic Fe-6.5Si alloy

Konferenz ArODES

Efrain Carreno-Morelli, Ludovic Meylan, Mikel Rodriguez Arbaizar, Xavier Carthoblaz-Délèze, Benoît Sahli, Rajasundar Chandran, Gioele Balestra

Proceedings of European Powder Metallurgy Congress, EuroPM2023, 1-4 October 2023 , Lisbon, Portugal

PEOPLE@HES-SO Verzeichnis der Mitarbeitenden und Kompetenzen

Carreno-Morelli Efrain

Professeur-e HES Ordinaire, Responsable du groupe de recherche Technologies des poudres et matériaux avancés

Hauptkompetenzen

Materials Science and Engineering

Powder Metallurgy

Powder Injection Moulding

MIM & CIM

Ceramics & Metal-Ceramic Composites

Additive manufacturing

SLM & Binder Jetting 3D-Printing

Professeur-e HES Ordinaire, Responsable du groupe de recherche Technologies des poudres et matériaux avancés

PEOPLE@HES-SO
Verzeichnis der Mitarbeitenden und Kompetenzen