The Enhancement of Oil Delivery and Bearing Performance via a Guiding-Structured Nozzle under Oil–Air Lubrication
Abstract
:1. Introduction
2. Test Device and Nozzle Structure
3. Results and Discussion
3.1. Nozzle Type and Lubricant Type on the Torque and Temperature Rise
3.2. Oil–Air Injection Pattern and Oil Droplet Distributions
4. Conclusions
- (1)
- With an increase in the oil supply amount, both torque and temperature initially decrease and then increase, resulting in an optimal oil supply amount at the turning point. All the results indicate that the guiding-structured nozzle exhibits smaller values for the optimal oil supply amount compared to those of the conventional nozzle, highlighting its superior oil delivery capability.
- (2)
- The synthetic oils exhibit a reduction in the optimal oil supply amount, torque, and temperature rise within the mixed lubrication regime primarily due to their propensity for forming an anti-friction absorption layer on surfaces. Beyond the optimum value, churning loss is predominantly influenced by the properties of bulk oils. Via comprehensive comparisons, it can be concluded that PAG oil demonstrates superior performance.
- (3)
- The jet flow patterns of the guiding-structured nozzle exhibit a higher degree of concentration compared to the conventional nozzle, thereby enhancing the penetration capability of the jet flow through the air curtain. Moreover, oil droplets emitted from the guiding-structured nozzle demonstrate uniform distribution with a narrow diameter range. The oil supply stability and the droplet diameter are determined by both the type of nozzle and surface adsorption properties of oils, which subsequently affect oil aggregation at the outlet of the nozzle.
- (4)
- The results suggest that the regulation of oil delivery and bearing performance can be achieved via nozzle structure design. Further research will be conducted to investigate the influence of parameters such as fiber diameter, fiber number, and fiber material (considering surface wettability) on jet flow patterns and oil droplet size.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Lubricants | Density (kg/m3 at 22 °C) | Dynamic Viscosity (Pa·s at 22 °C) | Kinematic Viscosity (mm2·s at 40 °C) | Viscosity Index | |
---|---|---|---|---|---|
Mineral | Paraffin | 863 | 0.079 | 46 | 103 |
Naphthenic | 949 | 0.134 | 46 | 50 | |
Synthetic | PAG | 1089 | 0.116 | 46 | 210 |
Ester | 970 | 0.108 | 46 | 120 |
Lubricants | Conventional Nozzle (μm) | Guiding-Structured Nozzle (μm) | |
---|---|---|---|
Mineral | Paraffin | 100~600 | 40~100 |
Naphthenic | 100~400 | 20~90 | |
Synthetic | PAG | 30~240 | 10~100 |
Ester | 10~120 | 10~50 |
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Zi, X.; Chen, K.; Bai, Q.; Li, X.; Jin, X.; Wang, X.; Guo, F. The Enhancement of Oil Delivery and Bearing Performance via a Guiding-Structured Nozzle under Oil–Air Lubrication. Lubricants 2024, 12, 60. https://doi.org/10.3390/lubricants12020060
Zi X, Chen K, Bai Q, Li X, Jin X, Wang X, Guo F. The Enhancement of Oil Delivery and Bearing Performance via a Guiding-Structured Nozzle under Oil–Air Lubrication. Lubricants. 2024; 12(2):60. https://doi.org/10.3390/lubricants12020060
Chicago/Turabian StyleZi, Xintian, Kai Chen, Qinghua Bai, Xinming Li, Xuyang Jin, Xu Wang, and Feng Guo. 2024. "The Enhancement of Oil Delivery and Bearing Performance via a Guiding-Structured Nozzle under Oil–Air Lubrication" Lubricants 12, no. 2: 60. https://doi.org/10.3390/lubricants12020060
APA StyleZi, X., Chen, K., Bai, Q., Li, X., Jin, X., Wang, X., & Guo, F. (2024). The Enhancement of Oil Delivery and Bearing Performance via a Guiding-Structured Nozzle under Oil–Air Lubrication. Lubricants, 12(2), 60. https://doi.org/10.3390/lubricants12020060