Optimal Selection of Active Jet Parameters for a Ducted Tail Wing Aimed at Improving Aerodynamic Performance
Abstract
:1. Introduction
- (1)
- By studying the effects of parameters such as momentum coefficient, jet hole position, jet hole height, and jet angle on improving the aerodynamic performance of the ducted tail wing, we found that compared with jet hole height and jet angle, momentum coefficient and jet hole position are more effective on improving the aerodynamic performance of the ducted tail wing.
- (2)
- Under a trailing edge jet, the relatively good jet condition occurs when the jet hole height is equal to 0.25% of the aerodynamic chord length, and the jet angle is equal to 0°. At this time, with the increase of the jet momentum coefficient, the effect of increasing lift of the ducted tail wing is the best.
- (3)
- Finally, a comparative analysis is conducted on the lift and drag characteristics between the ducted tail wing and traditional tail wing, and it is found that the ducted tail wing can generate lift at 0° attack angle and will not stall in the high attack angle range of 12°~22°.
2. Research Object
3. Jet Parameters and Numerical Simulation Methods
3.1. Selection of Active Jet Parameters
3.2. Simulation Method and Computational Grid Independence
3.2.1. Simulation Method
3.2.2. Grid Independence Verification
4. Result Analysis
4.1. The Improvement Effect of Momentum Coefficient on Aerodynamic Performance
4.2. The Improvement Effect of Jet Hole Height on Aerodynamic Performance
4.3. The Improvement Effect of Jet Hole Position on Aerodynamic Performance
4.4. The Improvement Effect of Jet Angle on Aerodynamic Performance
4.5. Advantages and Principle Analysis of the Ducted Tail Wing
5. Conclusions
- (1)
- The improvement effect of jet hole height and jet angle on the aerodynamic performance of ducted tail wing is relatively small. Through comparative analysis, it is found that under the conditions of jet hole height H2 = 0.25%c and jet angle = 0°, it is more conducive to improving the aerodynamic performance of the ducted tail wing.
- (2)
- The momentum coefficient and jet hole position are the main factors affecting the aerodynamic performance of the ducted tail wing. Under the conditions of H2 = 0.25%c, jet angle = 0°, and L1 = 100%c (jet hole located at the trailing edge of the tail wing), the improvement effect of the aerodynamic performance of the tail wing is relatively good as the momentum coefficient increases. At = 0.04, the average of is 0.403; When = 0.03, the average of is 0.329; When = 0.02, the average of is 0.262; When = 0.01, the average of is 0.191. When increases from 0.01 to 0.04, the average growth of can reach 110%.
- (3)
- A comparative analysis is conducted on the aerodynamic performance of ducted tail wings and NACA0012 airfoils. It is found that the ducted tail can generate lift at a 0° angle of attack. In this way, under low angle of attack conditions, the ducted tail can generate control force without jet flow, which can save control energy. Compared with the NACA0012 airfoil, the ducted tail does not stall at angles of attack ≥12° and can provide stable control momentum for the aircraft at high attack angles.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
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Serial Number | Parameter | Values |
---|---|---|
1 | 0.00/0.01/0.02/0.03/0.04 | |
2 | H1 | 0.25%c |
3 | H2 | 0.25%c/0.35%c/0.45%c |
4 | L1 | 20%c/40%c/60%c/80%c/100%c |
5 | 0°/10°/20°/30° | |
6 | 0° |
Model | The Number of Sparse Grids | The Number of Medium Grids | The Number of Fine Grids |
---|---|---|---|
NACA0012 tail wing | 1.40 × 105/2.10 × 105 | 3.50 × 105/4.70 × 105 | 6.80 × 105 |
Jet ducted tail wing | 3.56 × 106 | 7.06 × 106 | 1.50 × 107 |
Aerodynamic Parameters | The Number of Sparse Grids | The Number of Medium Grids | The Number of Fine Grids |
---|---|---|---|
Lift coefficient | 0.8791 | 0.8945 | 0.8963 |
Drag coefficient | 0.1548 | 0.1887 | 0.1924 |
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Jia, H.; Zheng, H.; Zhou, H.; Huo, S. Optimal Selection of Active Jet Parameters for a Ducted Tail Wing Aimed at Improving Aerodynamic Performance. Aerospace 2024, 11, 851. https://doi.org/10.3390/aerospace11100851
Jia H, Zheng H, Zhou H, Huo S. Optimal Selection of Active Jet Parameters for a Ducted Tail Wing Aimed at Improving Aerodynamic Performance. Aerospace. 2024; 11(10):851. https://doi.org/10.3390/aerospace11100851
Chicago/Turabian StyleJia, Huayu, Huilong Zheng, Hong Zhou, and Shunbo Huo. 2024. "Optimal Selection of Active Jet Parameters for a Ducted Tail Wing Aimed at Improving Aerodynamic Performance" Aerospace 11, no. 10: 851. https://doi.org/10.3390/aerospace11100851
APA StyleJia, H., Zheng, H., Zhou, H., & Huo, S. (2024). Optimal Selection of Active Jet Parameters for a Ducted Tail Wing Aimed at Improving Aerodynamic Performance. Aerospace, 11(10), 851. https://doi.org/10.3390/aerospace11100851