Dr.-Ing. Janett Schmelzer
Dr.-Ing.
Werkstofftechnik
Completed projects
Determining the comminution behavior of plastic particles in milling processes
Duration: 01.09.2022 bis 30.06.2024
The recycling of plastics is an important issue in terms of environmental sustainability, recyclability and of waste management. The development of proper technologies for plastic recycling is generally recognized as a priority. To achieve this aim, the technologies that have been developed and applied in mineral processing can be adapted to recycling systems. In particular, the improvement of comminution technologies is one of the main actions to improve the quality of recycled plastics. The aim of this work is to study the comminution processes in milling for different types of plastic materials.
Innovative production of novel multi-component bio-materials
Duration: 08.03.2022 bis 07.08.2022
Artificial prostheses can be successfully implanted in the human body for many years and improve the mobility, vitality and quality of life of patients. A variety of different ceramic and metallic implant materials, such as alumina-hardened zirconia and the alloys Ti-Al-V and Co-Cr-Mo, are already in clinical use. However, there is a constant need and scientific interest in improving the properties and longevity of implants in terms of wear resistance, corrosion and, in particular, biocompatibility and tissue compatibility, e.g. to prevent inflammatory reactions. The innovative material class of bio-refractory metal materials(bio-MEAs) and bio-high entropy alloys (bio-HEAs) represent a unique design approach for the development of new biomedical materials. In addition to attractive mechanical properties and excellent wear and corrosion resistance, this class of materials offers potential for improved biocompatibility compared to previously used materials.
In addition to the development of new alloy concepts, the focus is also on the production of biocompatible materials. In recent years, demand for additive manufacturing - known as 3D printing - has risen sharply in the industrial sector, but especially in the field of medical implants. Due to the layered structure, highly complex geometries in anatomical shapes and delicate lightweight structures can be realized, which can hardly be produced using conventional methods. Another advantage of additive manufacturing is that the required patient-specific implants can be made available in a very short time. This results in very specific advantages for the additive manufacturing of implants that bring both economic and patient welfare benefits, as waiting times and therefore inpatient stays and the resulting complications can be massively reduced. The project, which is funded by the Innovation Fund of Otto von Guericke University (OVGU) Magdeburg, aims to intensify the interdisciplinary collaboration between the Chair of High Temperature Materials at the OVGU's Faculty of Mechanical Engineering and the Experimental Orthopaedics research department at the Orthopaedic University Hospital Magdeburg. New findings on the development of biocompatible HEAs/MEAs, innovative manufacturing strategies and important mechanical properties of the new materials are to be investigated.
This text was translated with DeepL
Active oxidation protection coatings for Mo-Si-B high-temperature materials
Duration: 01.07.2016 bis 30.04.2022
High-temperature resistant Mo-Si-B materials are being intensively investigated as suitable substitutes for nickel-based materials. One problem with these materials that has not yet been solved is their oxidation behavior. The Mo solid solution phase in particular oxidizes catastrophically depending on the temperature, forming a volatile Mo oxide. Previously known protective coating systems have not been able to solve this problem satisfactorily. The aim of the project is therefore to develop a novel, active protective system based on preceramic polymers containing fillers with a high oxygen absorption capacity in combination with the inhibition of oxygen diffusion in cooperation with Prof. M. Scheffler (Chair of Non-Metallic Materials).
Prof. Krüger's department is producing suitable active filler particles for this purpose, which are then applied to the substrate materials via a slurry using a dip coating process. Oxidation tests at different temperatures with subsequent analysis of the coating and the coating-substrate interface are intended to show the extent to which the oxidation behavior of the substrate is influenced by the new coating systems.
Innovative biocompatible alloys
Duration: 01.05.2021 bis 30.04.2022
The requirements placed on medical devices and medical technology components are heavily dependent on their use. For a long time, biocompatible materials were regarded as chemically and biologically inert within the human body, but this has since been revised, as there is always a response from the body.
Nanostructured biomaterials, including those based on refractory metals, may be of great interest for the future of the biomedical industry and are therefore increasingly the focus of current research. Their fundamentally good compatibility in the human body together with excellent mechanical properties are decisive factors here. The use of titanium and titanium alloys in surgery has steadily increased due to their good combination of properties compared to other metallic implant materials such as stainless steel and cobalt-chromium alloys. Biocompatible titanium and titanium-based alloys are characterized by good fatigue strength, corrosion resistance and low density, resulting in a high specific strength-to-weight ratio that allows for lighter and stronger structures. One of the most popular titanium alloys used in medicine today is Ti-6Al-4V. However, even approved medical materials can still be optimized for acceptance in the human body.
In this project, the first cell population experiments are being carried out on new, innovative materials with mesenchymal stem cells and osteoblasts. They are a perfect indicator of biocompatibility and cell ingrowth behavior for potential implant materials or other medical materials.
This text was translated with DeepL
Additive manufactured particle-reinforced vanadium alloys
Duration: 01.07.2020 bis 30.06.2021
Multiphase vanadium alloys are the focus of current research into new high-temperature materials due to their outstanding mechanical properties. By combining the ductile vanadium solid solution phase with high-strength intermetallic or intermediate phases, a material with optimized properties is being developed.
In the LextrA (https://forschung-sachsen-anhalt.de/project/lextra-laserbasierte-additive-fertigung-20506) project, various vanadium materials were processed into compact test specimens for the first time using the additive manufacturing process DED (Direct Energy Deposition).
Using DED, oxide particles were introduced into multiphase vanadium materials at the ILT Aachen in order to optimize the mechanical properties. The research task at OVGU is to investigate the new materials with regard to the homogeneous distribution of the particles in the microstructure and to describe their mode of action. The strength-enhancing effect of the introduced particles will be quantitatively evaluated in comparison to a particle-free reference material.
This text was translated with DeepL
LextrA: Laser-based additive manufacturing of innovative intermetallic materials
Duration: 01.02.2017 bis 30.06.2020
The use of innovative materials contributes to the energy and resource efficiency of technical processes. Ultra-high temperature materials based on intermetallic phases and refractory metals have the potential to substantially increase the efficiency of gas turbines. This requires fundamental scientific research on microstructure-properties relationships of potential multi-phase alloys.
For the project LextrA we selected different intermetallic materials based on iron aluminides, vanadium silicides and molybdenum silicides. Conventional ingot metallurgical processes are limited in their applicability due to the high melting point of the intermetallic and refractory materials. Additive manufacturing techniques provide new options to allow the integration of complex cooling structures in turbine blades and are resource efficient alternatives of conventional processes. This combination of optimized material and improved cooling system will result in a significant increase in the operation temperature of modern gas turbines, which leads to higher process efficiency. The project consortium evaluates the applicability of two additive manufacturing processes, namely directed energy deposition (DED) and laser powder bed fusion (LPBF).
Vanadium-based high-temperature materials
Duration: 01.10.2014 bis 31.03.2017
The requirement profile for high-temperature materials for complex technical applications consists of good mechanical properties across the entire application range and sufficient oxidation resistance. In the case of dynamically moving components, density is also an important criterion for material selection. High-melting-point materials based on vanadium (Ts = 1910°C) have the advantage that the density can be reduced by around 30% compared to reference materials such as nickel alloys and by around 20% compared to steels. This project aims to lay the foundation for the development of high-strength vanadium materials. In the first approach, vanadium-silicon solid solution materials are produced via the process of mechanical alloying and their properties are determined. The application of kinetic models, taking into account the real process variables, serves to understand and optimize the process of mechanical alloying for this material system. In the next step, silicide phases (e.g. V3Si and V5SiB2) are integrated into the solid solution materials in order to optimize the high-temperature strength.
This text was translated with DeepL
2025
Peer-reviewed journal article
A novel approach to produce metal–metal composites by leveraging immiscibility - laser powder bed fusion of nanosilver-dispersed titanium
Shokri, Hamed; Rittinghaus, Silja-Katharina; Schmelzer, Janett; Bertrand, Jessica; Gökce, Bilal
In: Advanced engineering materials - Weinheim : Wiley-VCH Verl., Bd. 27 (2025), Artikel 2401512, insges. 8 S. [Online version of record before inclusion in an issue]
A comparative analysis of in vivo-generated and artificial CoCrMo wear particles created by high-energy ball milling and the Buchhorn method
Buchholz, Adrian; Höpfer, Rebecca; Becker, Julia; Voropai, Vadym; Schmelzer, Janett; Krüger, Manja; Bertrand, Jessica
In: Materials - Basel : MDPI, Bd. 18 (2025), Heft 3, Artikel 643, insges. 14 S.
2023
Peer-reviewed journal article
Efficient sintering of Mo matrix composites - a study of temperature dependences and the use of the sinter additive Ni
Solodkyi, Ievgen; Petrusha, Vadym; Grigoroscuta, Mihai Alexandru; Schmelzer, Janett; Hasemann, Georg; Betke, Ulf; Badica, Petre; Krüger, Manja
In: Metals - Basel : MDPI, Bd. 13 (2023), Heft 10, Artikel 1715, insges. 15 S.
2022
Peer-reviewed journal article
High temperature oxidation performance of an additively manufactured Mo9Si8B alloy
Becker, Julia; Schmigalla, Sven; Schultze, Sabine; Rittinghaus, Silja-Katharina; Weisheit, Andreas; Schmelzer, Janett; Krüger, Manja
In: Oxidation of metals - Dordrecht [u.a.] : Springer Science + Business Media B.V, Bd. 97 (2022), S. 167-181
Dissertation
Microstructure and properties of powder metallurgical manufactured V-rich V-Si-B alloys for high-temperature application
Schmelzer, Janett; Krüger, Manja
In: Magdeburg: Universitätsbibliothek, Dissertation Otto-von-Guericke-Universität Magdeburg, Fakultät für Maschinenbau 2022, 1 Online-Ressource (XVII, 124 Blätter, 8,23 MB) [Literaturverzeichnis: Blatt 112-124][Literaturverzeichnis: Blatt 112-124]
2021
Abstract
A novel alloy development approach - biomedical high-entropy alloys
Regenberg, Maximilian; Schmelzer, Janett; Hasemann, Georg; Krüger, Manja
In: Intermetallics 2021 - International Conference, 04-08 October 2021 : Educational Center Kloster Banz, Germany : programme and abstracts , 2021 - Jena, Germany : Conventus Congressmanagement & Marketing GmbH ; Krüger, Manja, S. 109-110, Artikel O-HEA-04 [Intermetallics 2021, International Conference, 4th till 8th October 2021 : Educational Center Kloster Banz, Germany]
Biocompatibility of pure refractory metals and their combination as high entropy alloys
Schmelzer, Janett; Hasemann, Georg; Regenberg, Maximilian; Betke, Ulf; Krüger, Manja; Walles, Heike; Scheffler, Michael
In: Intermetallics 2021 - International Conference, 04-08 October 2021 : Educational Center Kloster Banz, Germany : programme and abstracts , 2021 - Jena, Germany : Conventus Congressmanagement & Marketing GmbH ; Krüger, Manja, S. 172-173, Artikel P-13 [Intermetallics 2021, International Conference, 4th till 8th October 2021 : Educational Center Kloster Banz, Germany]
Particle strengthening of additively manufactured Me-SiB (Me = Mo, V) alloys
Schmelzer, Janett; Rittinghaus, Silja-Katharina; Wilms, Markus B.; Michael, Oliver; Krüger, Manja
In: Intermetallics 2021 - International Conference, 04-08 October 2021 : Educational Center Kloster Banz, Germany : programme and abstracts , 2021 - Jena, Germany : Conventus Congressmanagement & Marketing GmbH ; Krüger, Manja, S. 59-60, Artikel O-SI-04 [Intermetallics 2021, International Conference, 4th till 8th October 2021 : Educational Center Kloster Banz, Germany]
Peer-reviewed journal article
Strengthening of additively manufactured Me-Si-B (Me = Mo, V) by Y2O3 particles
Schmelzer, Janett; Rittinghaus, Silja-Katharina; Wilms, Markus B.; Michael, Oliver; Krüger, Manja
In: International journal of refractory metals & hard materials - Amsterdam [u.a.] : Elsevier Science, Bd. 101 (2021), Artikel 105623
Additive manufacturing of a near-eutectic MoSiB alloy - processing and resulting properties
Fichtner, D.; Schmelzer, Janett; Yang, W.; Heinze, C.; Krüger, Manja
In: Intermetallics - Amsterdam [u.a.] : Elsevier Science - 128 (2021), Artikel 107025
A novel alloy development approach - biomedical equiatomic Ta-Nb-Ti alloy
Regenberg, Maximilian; Schmelzer, Janett; Hasemann, Georg; Bertrand, Jessica; Krüger, Manja
In: Metals - Basel : MDPI, Bd. 11 (2021), Heft 11, Artikel 1778, insges. 12 S.
2020
Peer-reviewed journal article
Recent advances in additive manufacturing of Mo-Si-B alloys - a status report onthe cooperative project LextrA
Krüger, Manja; Schmelzer, Janett; Fichtner, D.; Heinze, C.; Küsters, Y.; Rittinghaus, S. K.; Weisheit, A.; Heinz, R.; Gerking, L.; Gruber, K; Schmigalla, S.; Schulze, S.
In: IOP conference series / Institute of Physics - London [u.a.] : Institute of Physics - Vol. 882 (2020), Paper 012011, insgesamt 9 Seiten [ Symposium: Symposium on Materials and Joining Technology, Magdeburg, Germany, 7-8 September 2020]
Oxidation response of additively manufactured eutectic Mo-Si-B alloys
Becker, Julia; Fichtner, D.; Schmigalla, S.; Schultze, S.; Heinze, C.; Küsters, Y.; Hasemann, Georg; Schmelzer, Janett; Krüger, Manja
In: IOP conference series / Institute of Physics - London [u.a.] : Institute of Physics - Vol. 882 (2020), Paper 012002, insgesamt 9 Seiten [Symposium: Symposium on Materials and Joining Technology, Magdeburg, Germany, 7-8 September 2020]
Direct energy deposition of TiAl for hybrid manufacturing and repair of turbine blades
Rittinghaus, Silja-Katharina; Schmelzer, Janett; Rackel, Marcus Willi; Hemes, Susanne; Vogelpoth, Andreas; Hecht, Ulrike; Weisheit, Andreas
In: Materials - Basel : MDPI - Vol. 13 (2020), 19, Article 4392, insgesamt 14 Seiten
Printability and microstructural evolution of a near-eutectic three-phase V-based alloy
Schmelzer, Janett; Rittinghaus, Silja-Katharina; Gruber, Karl; Veit, Peter; Weisheit, Andreas; Krüger, Manja
In: Additive manufacturing - Amsterdam [u.a.] : Elsevier - Vol. 34 (2020), Artikelnummer 101208
2019
Peer-reviewed journal article
The potential of mechanical alloying to improve the strength and ductility of Mo-9Si-8B-1Zr alloys - experiments and simulation
Krüger, Manja; Kauss, Olha; Naumenko, Konstantin; Burmeister, C.; Wessel, E.; Schmelzer, Janett
In: Intermetallics - Amsterdam [u.a.] : Elsevier Science - Vol. 113 (2019), Artikel 106558
Processing of Mo silicide powders as filler particles in polymer-derived ceramic coatings for Mo-Si-B substrates
Krüger, Manja; Schmelzer, Janett; Smokovych, Irina; Lopez Barillao, Jennifer; Hasemann, Georg
In: Powder technology - Amsterdam [u.a.] : Elsevier Science, Bd. 352 (2019), S. 381-385
Article in conference proceedings
Laser additive manufacturing of intermetallic alloys for high-temperature applications
Rittinghaus, Silja-Katharina; Schmelzer, Janett; Wilms, Markus B.; Krüger, Manja
In: Industrial perspectives in additive technologies - Örebro, Sweden ; The Austrian Society for Metallurgy and Materials . - 2019, S. 110-117
2018
Peer-reviewed journal article
Printability of gas atomized Mo-Si-B powders by laser metal deposition
Schmelzer, Janett; Rittinghaus, S.-K.; Weisheit, A.; Stobik, M.; Paulus, J.; Gruber, K.; Wessel, E.; Heinze, C.; Krüger, Manja
In: International journal of refractory metals & hard materials - Amsterdam [u.a.] : Elsevier Science, Bd. 78 (2019), S. 123-126 [Online first]
Article in conference proceedings
Additive Fertigung gasverdüster Mo-Si-B Pulver durch Laserauftragsschweißen
Schmelzer, Janett; Rittinghaus, S.-K.; Weisheit, A.; Stobik, M.; Paulus, J.; Gruber, K.; Wessel, E.; Krüger, Manja; Heinze, C.
In: Fachtagung Werkstoffe und Additive Fertigung - Sankt Augustin : Deutsche Gesellschaft für Materialkunde e. V. . - 2018, S. 244-249 [Konferenz: DGM-Tagung, 25.-26. April 2018, Potsdam]
2017
Abstract
Formation of silicides in mechanically alloyed V-Si solid solution powders
Schmelzer, Janett; Günther, Christoph Daniel; Krüger, Manja
In: Intermetallics 2017 - Bad Staffelstein : Educational Center Kloster Banz, S. 117-118 [Konferenz: Intermetallics 2017]
Book chapter
Bildung von Siliziden in mechanisch legierten V-Si Mischkristallpulvern
Schmelzer, Janett; Baumann, Torben; Dieck, Sebastian; Krüger, Manja
In: 16. Sommerkurs Werkstoffe und Fügen - Magdeburg, 08. und 09. September 2017 , korrigierte Auflage - Magdeburg : Universitätsbibliothek, S. 161-168
2016
Peer-reviewed journal article
Hardening of VSi alloys during high energy ball milling
Schmelzer, Janett; Baumann, Torben; Dieck, Sebastian; Krüger, Manja
In: Powder technology - Amsterdam [u.a.] : Elsevier Science, Bd. 294 (2016), S. 493-497
Similarities and differences in mechanical alloying processes of V-Si-B and Mo-Si-B powders
Krüger, Manja; Schmelzer, Janett; Helmecke, Maria
In: Metals - Basel : MDPI - Vol. 6.2016, 10, Art. 241, insgesamt 16 S.
2015
Peer-reviewed journal article
Mechanical properties and failure probability of compact agglomerates
Russell, Alexander; Schmelzer, Janett; Müller, Peter; Krüger, Manja; Tomas, Jürgen
In: Powder technology - Amsterdam [u.a.] : Elsevier Science, Bd. 286 (2015), S. 546-556