Your search keyword '"Seynstahl, Armin"' showing total 18 results

1. Structural reorientation and compaction of porous MoS2 coatings during wear testing

Author

Krauß, Sebastian, Seynstahl, Armin, Tremmel, Stephan, Meyer, Bernd, Bitzek, Erik, Göken, Mathias, Yokosawa, Tadahiro, Zubiri, Benjamin Apeleo, Spiecker, Erdmann, and Merle, Benoit

Subjects

Condensed Matter - Materials Science

Abstract

Industrial upscaling frequently results in a different coating microstructure than the laboratory prototypes presented in the literature. Here, we investigate the wear behavior of physical vapor deposited (PVD) MoS2 coatings: A dense, nanocrystalline MoS2 coating, and a porous, prismatic-textured MoS2 coating. Transmission electron microscopy (TEM) investigations before and after wear testing evidence a crystallographic reorientation towards a basal texture in both samples. A basal texture is usually desirable due to its low-friction properties. This favorable reorientation is associated to a tribological compaction of the porous specimens. Following running-in, sliding under high contact pressure ultimately leads to a wear rate as small as for an ideal grown bulk MoS2 single crystal grown by chemical vapor deposition (CVD). This suggests that the imperfections of industrial grade MoS2 coatings can be remediated by a suitable pretreatment.

Published

2022

2. Enhancing the lifetime and vacuum tribological performance of PVD-MoS2 coatings by nitrogen modification

Author

Seynstahl, Armin, Köbrich, Manuel, Rosnitschek, Tobias, Göken, Mathias, and Tremmel, Stephan

Published

2024

3. Evaluation of DLC, MoS2, and Ti3C2Tx thin films for triboelectric nanogenerators

Author

Tremmel, Stephan, Luo, Xiongxin, Rothammer, Benedict, Seynstahl, Armin, Wang, Bo, Rosenkranz, Andreas, Marian, Max, and Zhu, Laipan

Published

2022

4. Ti3C2Tx solid lubricant coatings in rolling bearings with remarkable performance beyond state-of-the-art materials

Author

Marian, Max, Feile, Klara, Rothammer, Benedict, Bartz, Marcel, Wartzack, Sandro, Seynstahl, Armin, Tremmel, Stephan, Krauß, Sebastian, Merle, Benoit, Böhm, Thomas, Wang, Bo, Wyatt, Brian C., Anasori, Babak, and Rosenkranz, Andreas

Published

2021

5. Dimensional Accuracy and Mechanical Characterization of Inconel 625 Components in Atomic Diffusion Additive Manufacturing

Author

Rosnitschek, Tobias, primary, Stierle, Catharina, additional, Orgeldinger, Christian, additional, Seynstahl, Armin, additional, Alber-Laukant, Bettina, additional, and Tremmel, Stephan, additional

Published

2024

6. Process-Integrated Component Microtexturing for Tribologically Optimized Contacts Using the Example of the Cam Tappet—Numerical Design, Manufacturing, DLC-Coating and Experimental Analysis.

Author

Orgeldinger, Christian, Reck, Manuel, Seynstahl, Armin, Rosnitschek, Tobias, Merklein, Marion, and Tremmel, Stephan

Subjects

LUBRICATED friction, SHEET metal, MANUFACTURING processes, SURFACE coatings, FRICTION, DIAMOND-like carbon, ELASTOHYDRODYNAMIC lubrication

Abstract

To meet the demand for energy-efficient and, at the same time, durable, functional components, the improvement of tribological behavior is playing an increasingly important role. One approach to reducing friction in lubricated tribological systems is the microtexturing of the surfaces tailored to the application, but in most cases, this leads to increased manufacturing costs and thus often makes their use in industry more difficult. In this work, we, therefore, present an approach for an efficient design and fully integrated production process using a cam tappet as an example. For the used cam tappet contact, we first determined the optimal texture geometries using two differently complex EHL (elastohydrodynamic lubrication) simulation models. Based on these, textured tappets were manufactured in a combined manner using sheet-bulk metal-forming and deposition with a diamond-like-carbon (DLC) coating for additional wear protection without further post-processing of the coating. We show that the simulation approach used has a rather subordinate influence on the optimization result. The combined forming of components with textured surfaces is limited by the local material flow, the resulting texture distortion, and tool wear. However, a targeted process design can help to exploit the potential of single-stage forming. The applied DLC coating has good adhesion and can completely prevent wear in subsequent reciprocal pin-on-disc tests, while the friction in the run-in behavior is initially higher due to the soothing effects of the coating. The experiments also show a tendency for shallow textures to exhibit lower friction compared to deeper ones, which corresponds to the expectations from the simulation. [ABSTRACT FROM AUTHOR]

Published

2024

7. Enhancing the lifetime and vacuum tribological performance of PVD-MoS2 coatings by nitrogen modification

Author

Seynstahl, Armin, primary, Köbrich, Manuel, additional, Rosnitschek, Tobias, additional, Göken, Mathias, additional, and Tremmel, Stephan, additional

Published

2023

8. Effects of Nitrogen Modification of Porous PVD–MoS2 Coatings on the Tribological Behavior under Rolling–Sliding Conditions in Vacuum

Author

Seynstahl, Armin, primary, Polzer, Markus, additional, Bartz, Marcel, additional, Wartzack, Sandro, additional, and Tremmel, Stephan, additional

Published

2023

9. Surface Properties and Tribological Behavior of Additively Manufactured Components: A Systematic Review

Author

Orgeldinger, Christian, primary, Seynstahl, Armin, additional, Rosnitschek, Tobias, additional, and Tremmel, Stephan, additional

Published

2023

10. Einfluss fertigungsbedingter Effekte auf das tribologische Verhalten im ADAM-Verfahren gedruckter Bauteile

Author

Orgeldinger, Christian, primary, Seynstahl, Armin, additional, Rosnitschek, Tobias, additional, and Tremmel, Stephan, additional

Published

2023

11. Effects of Nitrogen Modification of Porous PVD–MoS 2 Coatings on the Tribological Behavior under Rolling–Sliding Conditions in Vacuum.

Author

Seynstahl, Armin, Polzer, Markus, Bartz, Marcel, Wartzack, Sandro, and Tremmel, Stephan

Subjects

TRIBOLOGY, SURFACE coatings, ROLLING contact, SOLID lubricants, NITROGEN, COMPACTING

Abstract

In order to improve the tribological performance of PVD–MoS2 coatings, which are frequently used as a solid lubricant for operating in challenging environments, e.g., in a vacuum, they can be modified with nitrogen. This work evaluates the tribological behavior and a possible compaction occurring during the initial tribological load in the rolling contact for pure and nitrogen-modified PVD–MoS2 coatings in a vacuum. Short-running tests (1000 cycles) of coated steel discs paired with uncoated steel discs made from 100Cr6 (1.3505, AISI 52100) were conducted on a two-disc tribometer. The slide-to-roll ratio of 10.5% was kept constant, while the load was varied in two steps from 1.1 GPa to 1.6 GPa. Subsequently, a comparison was made between the worn and the pristine coatings by means of nanoindentation and an optical analysis of the wear track. The formation of a load-bearing solid lubrication was achieved for both MoS2-variants. The main differences affected the material transfer and wear mechanisms. The worn coatings reached a similar wear coefficient of 4 × 10−6 mm3N−1m−1 and a possible compaction of the coatings was found, indicated through an increased indentation hardness (for MoS2 1158% and MoS2:N 96% at a 1.1 GPa load). The assumed tribological mechanism changed with nitrogen modification, but scales with increasing load. The nitrogen-modified MoS2 coating showed less compaction than pure MoS2, while the frictional behavior was improved by a 17% reduction of the coefficient of friction. [ABSTRACT FROM AUTHOR]

Published

2023

12. Structural reorientation and compaction of porous MoS2 coatings during wear testing

Author

Krauß, Sebastian, primary, Seynstahl, Armin, additional, Tremmel, Stephan, additional, Meyer, Bernd, additional, Bitzek, Erik, additional, Göken, Mathias, additional, Yokosawa, Tadahiro, additional, Zubiri, Benjamin Apeleo, additional, Spiecker, Erdmann, additional, and Merle, Benoit, additional

Published

2022

13. Einfluss fertigungsbedingter Effekte auf das tribologische Verhalten im ADAM-Verfahren gedruckter Bauteile.

Author

Orgeldinger, Christian, Seynstahl, Armin, Rosnitschek, Tobias, Zimmermann, Anna, and Tremmel, Stephan

Subjects

MANUFACTURING processes, SURFACE preparation, PETROLEUM

Abstract

Copyright of Tribologie und Schmierungstechnik is the property of Narr Francke Attempto Verlag GmbH & Co.KG and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

14. Microstructure, Mechanical Properties and Tribological Behavior of Magnetron-Sputtered MoS₂ Solid Lubricant Coatings Deposited under Industrial Conditions

Author

Seynstahl, Armin, Krauß, Sebastian, Bitzek, Erik, Meyer, Bernd, Merle, Benoit, and Tremmel, Stephan

Subjects

PVD, nanoindentation, friction, microstruct, MoS2, wear mechanisms

Abstract

Depositing MoS2 coatings for industrial applications involves rotating the samples during the PVD magnetron sputtering process. Here, we show that a 3-fold substrate rotation, along a large target–substrate distance given by the deposition unit, introduces porosity inside the coatings. The mechanical properties and wear behavior strongly correlate with the degree of porosity, which, in turn, depends on the temperature and the rotational speed of the substrate. Ball-on-disk tests and nanoindentation wear experiments show a consistent change in tribological behavior; first, a compaction of the porous structure dominates, followed by wear of the compacted material. Compaction was the main contributor to the volume loss during the running-in process. Compared to a dense coating produced without substrate rotation, the initially porous coatings showed lower hardness and a distinct running-in behavior. Tribological lifetime experiments showed good lubrication performance after compaction

Published

2021

15. Microstructure, Mechanical Properties and Tribological Behavior of Magnetron-Sputtered MoS2 Solid Lubricant Coatings Deposited under Industrial Conditions

Author

Seynstahl, Armin, primary, Krauß, Sebastian, additional, Bitzek, Erik, additional, Meyer, Bernd, additional, Merle, Benoit, additional, and Tremmel, Stephan, additional

Published

2021

16. Evaluation of DLC, MoS2, and Ti3C2Txthin films for triboelectric nanogenerators

Author

Tremmel, Stephan, Luo, Xiongxin, Rothammer, Benedict, Seynstahl, Armin, Wang, Bo, Rosenkranz, Andreas, Marian, Max, and Zhu, Laipan

Abstract

Due to their cost-effective fabrication, easy integration, and low frequency working range, triboelectric nanogenerators (TENGs) demonstrate tremendous potential in green energy harvesting to power smart devices and the internet of things (IoT). However, there is an urgent need to synergistically maximize their output and improve their durability to ensure a long-lasting high performance. This study aims at elucidating the performance of protective thin films deposited on the wear-prone PTFE surface of TENGs including doped and undoped, single- and multi-layer hydrogenated DLC films, MoS2coatings fabricated by physical vapor deposition and multi-layer Ti3C2Tx(MXene) films. The deposited coatings are characterized by electron microscopy, and Raman spectroscopy. Their triboelectric performance is analyzed for TENGs operating in contact separation and freestanding sliding modes. We verified that MXenes outperformed the other films in contact separation mode due to the good electron gain ability of functional oxygen and fluorine groups. In sliding mode, the undoped a-C:H coating performed on a comparable level to the uncoated reference and superior to the tungsten-doped DLC and MoS2films. The film withstood long-term tests without notable signs of wear; merely the output slowly decreased with time due to graphitization and thus potential material transfer to the mating body.

Published

2022

17. Microstructure, Mechanical Properties and Tribological Behavior of Magnetron-Sputtered MoS 2 Solid Lubricant Coatings Deposited under Industrial Conditions.

Author

Seynstahl, Armin, Krauß, Sebastian, Bitzek, Erik, Meyer, Bernd, Merle, Benoit, and Tremmel, Stephan

Subjects

SOLID lubricants, LUBRICATION & lubricants, NANOINDENTATION tests, MECHANICAL wear, SURFACE coatings, MICROSTRUCTURE

Abstract

Depositing MoS2 coatings for industrial applications involves rotating the samples during the PVD magnetron sputtering process. Here, we show that a 3-fold substrate rotation, along a large target–substrate distance given by the deposition unit, introduces porosity inside the coatings. The mechanical properties and wear behavior strongly correlate with the degree of porosity, which, in turn, depends on the temperature and the rotational speed of the substrate. Ball-on-disk tests and nanoindentation wear experiments show a consistent change in tribological behavior; first, a compaction of the porous structure dominates, followed by wear of the compacted material. Compaction was the main contributor to the volume loss during the running-in process. Compared to a dense coating produced without substrate rotation, the initially porous coatings showed lower hardness and a distinct running-in behavior. Tribological lifetime experiments showed good lubrication performance after compaction. [ABSTRACT FROM AUTHOR]

Published

2021

18. Microstructure, Mechanical Properties and Tribological Behavior of Magnetron-Sputtered MoS2 Solid Lubricant Coatings Deposited under Industrial Conditions

Author

Seynstahl, Armin, Krauß, Sebastian, Bitzek, Erik, Meyer, Bernd, Merle, Benoit, and Tremmel, Stephan

Subjects

PVD, nanoindentation, lcsh:TA1-2040, friction, microstructure, MoS2, lcsh:Engineering (General). Civil engineering (General), ddc:600, wear mechanisms

Abstract

Depositing MoS2 coatings for industrial applications involves rotating the samples during the PVD magnetron sputtering process. Here, we show that a 3-fold substrate rotation, along a large target–substrate distance given by the deposition unit, introduces porosity inside the coatings. The mechanical properties and wear behavior strongly correlate with the degree of porosity, which, in turn, depends on the temperature and the rotational speed of the substrate. Ball-on-disk tests and nanoindentation wear experiments show a consistent change in tribological behavior, first, a compaction of the porous structure dominates, followed by wear of the compacted material. Compaction was the main contributor to the volume loss during the running-in process. Compared to a dense coating produced without substrate rotation, the initially porous coatings showed lower hardness and a distinct running-in behavior. Tribological lifetime experiments showed good lubrication performance after compaction.