Your search keyword '"Rothammer, Benedict"' showing total 7 results

1. Experimental investigation of tool-sided surface modifications for dry deep drawing processes at the tool radii area

Author

Krachenfels, Kim, Rothammer, Benedict, Tremmel, Stephan, and Merklein, Marion

Published

2019

2. Wear Mechanism of Superhard Tetrahedral Amorphous Carbon (ta‐C) Coatings for Biomedical Applications

Author

Rothammer, Benedict, primary, Schwendner, Michael, additional, Bartz, Marcel, additional, Wartzack, Sandro, additional, Böhm, Thomas, additional, Krauß, Sebastian, additional, Merle, Benoit, additional, Schroeder, Stefan, additional, Uhler, Maximilian, additional, Kretzer, Jan Philippe, additional, Weihnacht, Volker, additional, and Marian, Max, additional

Published

2023

3. Design of Amorphous Carbon Coatings Using Gaussian Processes and Advanced Data Visualization

Author

Sauer, Christopher, primary, Rothammer, Benedict, additional, Pottin, Nicolai, additional, Bartz, Marcel, additional, Schleich, Benjamin, additional, and Wartzack, Sandro, additional

Published

2022

4. Adaption of tribological behavior of a-C:H coatings for application in dry deep drawing

Author

Häfner Tom, Rothammer Benedict, Tenner Jennifer, Krachenfels Kim, Merklein Marion, Tremmel Stephan, and Schmidt Michael

Subjects

Tribology, Surface Modification, Dry Deep Drawing, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Nowadays the sheet metal forming industry faces challenges regarding efficient usage of resources and sustainability. One strategy to increase the environmental friendliness is to abandon the application of lubricants. The direct contact between tool and workpiece leads to an intensive interaction which increases friction. Especially for deep drawing processes with long sliding distances, this causes distinctive wear. The tool sided application of carbon based coatings is a well-known approach to reduce friction and wear. Former studies have shown a beneficial behavior of hydrogenated amorphous carbon based coatings (a-C:H) to improve the tribological conditions in contact with steel sheets and aluminium alloys under dry conditions. Within this study the coating process and the resulting coating properties will be analyzed. Afterwards mechanical and laser based surface treatment processes prior and after the deposition process will be investigated to reduce the coating roughness. Different roughness values were achieved by varying the surface treatment processes. The laser based finishing enables a reduction of the Spk values by removing single roughness asperities. In order to identify the necessary process parameters for the laser treatment, an analytical model of the material removal was applied. The laser surface treatment achieved similar roughness characteristics compared to mechanical treatment. In this study the tribological behavior of a-C:H coated tools was analyzed under dry conditions within strip drawing tests. The tribological investigations revealed that for dry deep drawing of zinc coated DC04 a broader range of Spk values leads to acceptable tribological conditions whereas for AA5182 a smoother tool surface has to be ensured to prevent adhesion and utilize the full potential of a-C:H coatings.

Published

2018

5. Amorphous Carbon Coatings for Total Knee Replacements—Part II: Tribological Behavior

Author

Rothammer, Benedict, Marian, Max, Neusser, Kevin, Bartz, Marcel, Böhm, Thomas, Krauß, Sebastian, Schroeder, Stefan, Uhler, Maximilian, Thiele, Simon, Merle, Benoit, Kretzer, Jan Philippe, and Wartzack, Sandro

Subjects

biomedical applications, total knee arthroplasty, wear, UHMWPE, Ti64, friction, DLC coating, Organic chemistry, Article, QD241-441, ddc:540, CoCr, biotribology, pin-on-disk, ddc:620

Abstract

Diamond-like carbon coatings may decrease implant wear, therefore, they are helping to reduce aseptic loosening and increase service life of total knee arthroplasties (TKAs). This two-part study addresses the development of such coatings for ultrahigh molecular weight polyethylene (UHMWPE) tibial inlays as well as cobalt-chromium-molybdenum (CoCr) and titanium (Ti64) alloy femoral components. While the deposition of a pure (a-C:H) and tungsten-doped hydrogen-containing amorphous carbon coating (a-C:H:W) as well as the detailed characterization of mechanical and adhesion properties were the subject of Part I, the tribological behavior is studied in Part II. Pin-on-disk tests are performed under artificial synovial fluid lubrication. Numerical elastohydrodynamic lubrication modeling is used to show the representability of contact conditions for TKAs and to assess the influence of coatings on lubrication conditions. The wear behavior is characterized by means of light and laser scanning microscopy, Raman spectroscopy, scanning electron microscopy and particle analyses. Although the coating leads to an increase in friction due to the considerably higher roughness, especially the UHMWPE wear is significantly reduced up to a factor of 49% (CoCr) and 77% (Ti64). Thereby, the coating shows continuous wear and no sudden failure or spallation of larger wear particles. This demonstrated the great potential of amorphous carbon coatings for knee replacements.

Published

2021

6. Amorphous Carbon Coatings for Total Knee Replacements-Part I: Deposition, Cytocompatibility, Chemical and Mechanical Properties

Author

Rothammer, Benedict, Neusser, Kevin, Marian, Max, Bartz, Marcel, Krauß, Sebastian, Böhm, Thomas, Thiele, Simon, Merle, Benoit, Detsch, Rainer, and Wartzack, Sandro

Subjects

biomedical applications, cytocompatibility, total knee arthroplasty, UHMWPE, Ti64, technology, industry, and agriculture, DLC coating, Organic chemistry, Article, hardness, adhesion, QD241-441, ddc:540, CoCr, biotribology, ddc:600

Abstract

Diamond-like carbon (DLC) coatings have the potential to reduce implant wear and thus to contribute to avoiding premature failure and increase service life of total knee replacements (TKAs). This two-part study addresses the development of such coatings for ultrahigh molecular weight polyethylene (UHMWPE) tibial inlays as well as cobalt–chromium–molybdenum (CoCr) and titanium (Ti64) alloy femoral components. While a detailed characterization of the tribological behavior is the subject of part II, part I focusses on the deposition of pure (a-C:H) and tungsten-doped hydrogen-containing amorphous carbon coatings (a-C:H:W) and the detailed characterization of their chemical, cytological, mechanical and adhesion behavior. The coatings are fabricated by physical vapor deposition (PVD) and display typical DLC morphology and composition, as verified by focused ion beam scanning electron microscopy and Raman spectroscopy. Their roughness is higher than that of the plain substrates. Initial screening with contact angle and surface tension as well as in vitro testing by indirect and direct application indicate favorable cytocompatibility. The DLC coatings feature excellent mechanical properties with a substantial enhancement of indentation hardness and elastic modulus ratios. The adhesion of the coatings as determined in modified scratch tests can be considered as sufficient for the use in TKAs.

Published

2021

7. Towards the Understanding of Lubrication Mechanisms in Total Knee Replacements – Part I: Experimental Investigations

Author

Nečas, David, Vrbka, Martin, Marian, Max, Rothammer, Benedict, Tremmel, Stephan, Wartzack, Sandro, Galandáková, Adéla, Gallo, Jiří, Wimmer, Markus A., Křupka, Ivan, Hartl, Martin, Nečas, David, Vrbka, Martin, Marian, Max, Rothammer, Benedict, Tremmel, Stephan, Wartzack, Sandro, Galandáková, Adéla, Gallo, Jiří, Wimmer, Markus A., Křupka, Ivan, and Hartl, Martin

Abstract

This contribution is aimed at the detailed understanding of lubrication mechanisms within total knee replacement. While Part I is focused on the experimental investigation, Part II deals with the development of a predictive numerical model. Here, a knee simulator was used for direct optical observation of the contacts between a metal femoral and a transparent polymer components. Transient dynamic conditions were applied. Mimicked synovial fluids with fluorescently labelled constituents were used as the test lubricants. The results showed that -globulin forms thin boundary lubricating film, being reinforced by the interaction of phospholipids and hyaluronic acid. Further development of lubricating film is attributed to albumin layering. Based on the results, a novel lubrication model of the knee implant is proposed., Tato studie je zaměřena na detailní porozumění mechanismů mazání v náhradě kolenního kloubu. Zatímco část I představuje experimentální pozorování, část II se zabývá vývojem prediktivního numerického modelu. V této části studie byl využit kolenní simulátor pro přímé optické pozorování kontaktu kovové femorální komponenty a vložky zhotovené z průhledného polymeru. Byly aplikovány proměnné dynamické podmínky. Jako mazivo byly využity modelové synoviální kapaliny s fluorescenčně označenými složkami. Výsledky ukázaly, že -globulin má tendenci formovat tenkou meznou vrstvu, která je vyztužená fosfolipidy v interakci s kyselinou hyaluronovou. Další nárůst mazacího filmu je připisován vrstvení albuminu. Na základě výsledků je představen nový teoretický model mazací vrstvy v kolenní náhradě.

Published

2021