Publication detail
Performance and stability comparison of hydrostatic bearing pad geometry optimization approaches
MICHALEC, M. FOLTÝN, J. SVOBODA, P. KŘUPKA, I. HARTL, M.
English title
Performance and stability comparison of hydrostatic bearing pad geometry optimization approaches
Type
journal article in Web of Science
Language
en
Original abstract
Hydrostatic bearings are commonly used across a range of applications, yet their reliance on externally pressurized lubricants presents significant energy consumption challenges. This research aims to experimentally assess various approaches for optimizing the geometry of hydrostatic bearing pads. Utilizing a two-pad hydrostatic tester equipped with online diagnostics, we analyzed optimized multi-recess pads developed through both analytical methods and computational fluid dynamics (CFD). Our results demonstrate that the CFD method achieves a substantially greater film thickness recess pressure compared to the analytical method under similar experimental conditions. Additionally, the CFD approach reduces pumping power losses by 14%. However, this improvement in performance is accompanied by a reduction in film stiffness and an increased sensitivity to eccentric overload or misalignment, as highlighted in our findings. While the adoption of CFD-optimized geometries offers significant potential for lowering energy consumption, maintaining precise alignment especially in large-scale applications remains essential. In summary, our study suggests that employing CFD optimization can effectively reduce the service costs associated with hydrostatic bearings, but optimal outcomes necessitate careful alignment considerations.
English abstract
Hydrostatic bearings are commonly used across a range of applications, yet their reliance on externally pressurized lubricants presents significant energy consumption challenges. This research aims to experimentally assess various approaches for optimizing the geometry of hydrostatic bearing pads. Utilizing a two-pad hydrostatic tester equipped with online diagnostics, we analyzed optimized multi-recess pads developed through both analytical methods and computational fluid dynamics (CFD). Our results demonstrate that the CFD method achieves a substantially greater film thickness recess pressure compared to the analytical method under similar experimental conditions. Additionally, the CFD approach reduces pumping power losses by 14%. However, this improvement in performance is accompanied by a reduction in film stiffness and an increased sensitivity to eccentric overload or misalignment, as highlighted in our findings. While the adoption of CFD-optimized geometries offers significant potential for lowering energy consumption, maintaining precise alignment especially in large-scale applications remains essential. In summary, our study suggests that employing CFD optimization can effectively reduce the service costs associated with hydrostatic bearings, but optimal outcomes necessitate careful alignment considerations.
Keywords in English
Hydrostatic lubrication, Bearing geometry, Experimental testing
Released
30.04.2025
Publisher
Springer Nature
Location
HEIDELBERG, GERMANY
ISSN
1434-0860
Volume
89
Number
4
Pages from–to
1–10
Pages count
10
BIBTEX
@article{BUT197844,
author="Michal {Michalec} and Jan {Foltýn} and Petr {Svoboda} and Ivan {Křupka} and Martin {Hartl},
title="Performance and stability comparison of hydrostatic bearing pad geometry optimization approaches",
year="2025",
volume="89",
number="4",
month="April",
pages="1--10",
publisher="Springer Nature",
address="HEIDELBERG, GERMANY",
issn="1434-0860"
}