Damage mechanisms and tooth flank load capacity of oil‐lubricated peek gears

Illenberger, C. M.; Tobie, Thomas; Stahl, Karsten

doi:10.1002/app.52662

Cited by 10 publications

References 7 publications

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Applicability of classic analytical calculation approaches for the design of plastic gears

Rothemund,

Otto,

Stahl

2023

Forsch Ingenieurwes

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Plastic gears are produced cost-effectively in high volume but mainly for applications under low load. Current trends are leading to the design and application of plastic gears for more demanding operating conditions. This requires finding the optimum macrogeometry for the application, which is determined in practice using iterative design processes. Numerical and analytical approaches are available for the design of gears. Due to their speed, only the latter are suitable for an iterative design process. However, the approaches currently used in the calculation programs are designed with a focus on steel gears. Their applicability to gears made of plastics, which material properties differ drastically from those made of steel, is therefore only partially possible.The paper presents an investigation into the applicability of the classic analytical calculation approaches of Weber/Banaschek and Schmidt for contact analysis and the load-carrying capacity calculation of plastic gears. For this purpose, the results from analytical calculations are compared with those from numerical calculations. In addition, a comparison is made with typical standards (DIN3990, ISO6336) and guidelines (VDI2736).As a result, the paper provides an initial statement on the transferability of results from steel-focused analytical approaches to gears made of plastic. In addition, calculation results are identified in which particularly large differences occur between the various calculation approaches and which must be considered in the design phase.

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Applicability of classic analytical calculation approaches for the design of plastic gears

Rothemund,

Otto,

Stahl

2023

Forsch Ingenieurwes

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Novel heart valve leaflet designs with stiff polymeric materials and biomimetic kinematics

Smid,

Pappas,

Cesarovic

et al. 2024

Bio-des. Manuf.

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Despite continuous efforts to improve the robustness of cardiac valve implants, neither bioprosthetic nor mechanical valves fulfill both hemodynamic and durability requirements. This study discussed novel flexible leaflet designs, focusing on polymeric materials with proven hemocompatibility, such as polyether ether ketone, of much higher stiffness than native tissue, aiming at optimal valve implants. A biomimetic valve with a single-curvature belly-curve (B-C) was used as a reference for new design variants with a double-curvature B-C with varying radii. Soft (13.2 MPa) and stiff (2.4 GPa) leaflet materials and different thicknesses were studied using lean simulations and in vitro experiments under physiologic hemodynamic conditions. The performance was assessed using opening pressure (OP) and orifice area (OA). The latter was determined by a newly developed automatized image processing tool. Experimental trends are in agreement with simulations and demonstrated that a buckling-inspired double-curvature leaflet design significantly enhances the trileaflet valve opening behavior, which is particularly advantageous for stiffer leaflet materials. Compared to the reference, the best-performing variant showed an OP improvement of 47% and 44% based on simulations and experiments, respectively. In contrast, the achieved mean pressure differential was directly comparable to state-of-the-art bioprosthetic valves. The OA was slightly reduced for new variants but still in the satisfying range. Graphic abstract

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Experimental testing of polymer gears with consideration of their thermomechanical behavior

Černe

2025

Polymer Gears

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Damage mechanisms and tooth flank load capacity of oil‐lubricated peek gears

Cited by 10 publications

References 7 publications

Applicability of classic analytical calculation approaches for the design of plastic gears

Applicability of classic analytical calculation approaches for the design of plastic gears

Novel heart valve leaflet designs with stiff polymeric materials and biomimetic kinematics

Experimental testing of polymer gears with consideration of their thermomechanical behavior

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