Building a Practical Natural Laminar Flow Design Capability

Campbell, Richard L.; Lynde, Michelle N.

doi:10.2514/6.2017-3059

Cited by 16 publications

(4 citation statements)

References 18 publications

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“…In this study, the CFD method was used to realize high-fidelity calculations of the airfoil and propeller [25]. Reynolds-averaged Navier Stokes (RANS) equations were the governing equations, and finite volume method and second-order upwind scheme were used.…”

Section: Numerical Methods and Validationmentioning

confidence: 99%

Aerodynamic Optimization and Analysis of Low Reynolds Number Propeller with Gurney Flap for Ultra-High-Altitude Unmanned Aerial Vehicle

Yao

Zhang

et al. 2022

Applied Sciences

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Ultra-high-altitude unmanned aerial vehicles have created a high demand for the performance of propellers under low Reynolds numbers, while the efficiency of such propellers by the existing design framework has reached a bottleneck. This paper explores the possibility of extending the Gurney flap on low Reynolds number propellers to achieve efficiency breakthrough. An iterative optimization strategy for propellers with Gurney flaps is established, in which cross-sectional airfoils can be continuously optimized under updated Reynolds numbers and lift coefficients. A computational fluid dynamics (CFD) simulation based on the γ-Reθ model was used as an aerodynamic analysis method. Propellers with and without Gurney flaps were optimized successively. Optimal results were analyzed using the CFD method. Results showed that an optimal propeller with a Gurney flap can achieve an efficiency of 82.0% in cruising conditions, which is 1.8% higher than an optimal propeller without a Gurney flap. Compared with the latter, the consumed power of the optimal propeller with a Gurney flap can be reduced by 2.2% with the same advance speed. Furthermore, the variation of the improvement by the Gurney flap propeller, along with its Reynolds number, was studied. A wind tunnel test indicates that the performance of the propellers obtained by the CFD method are in good agreement with the test results.

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Section: Numerical Methods and Validationmentioning

confidence: 99%

Aerodynamic Optimization and Analysis of Low Reynolds Number Propeller with Gurney Flap for Ultra-High-Altitude Unmanned Aerial Vehicle

Yao

Zhang

et al. 2022

Applied Sciences

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“…Lately, a new discussion on the value for the transition -factor to be used with compressible stability theory has arisen in the context of the NASA NLF common research model and the Crossflow-Attenuated NLF design [17][18][19][20]. The question is whether = 10 is adequate when using compressible stability theory.…”

Section: Incompressible Versus Compressible Stability Theorymentioning

confidence: 99%

Simplified Hybrid Laminar Flow Control for the A320 Fin. Part 2: Evaluation with the e^N-method

Schrauf

Geyr

2021

AIAA Scitech 2021 Forum

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“…attachment line transition, TS instabilities, CF instabilities, and bypassinduced transition. In the laminar flow wing design, the attachment line transition can be diverted with the help of a "Gaster bump" [17]. CF instability is the second phenomenon that induces transition.…”

Section: Introductionmentioning

confidence: 99%

Hybrid Laminar Flow Control Optimizations for Infinite Swept Wings

Shi

Lan

Yang

2023

International Journal of Aerospace Engineering

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Maintaining the laminar flow on surfaces through active control is a significantly promising technique for reducing fuel burn and alleviating environmental concerns in commercial aviation. However, there is a lack of systematic parameter studies for the hybrid laminar flow control (HLFC) together with natural laminar flow (NLF). To address this need, we optimize the infinite swept wings with different sweep angles and at various conditions, including different Mach numbers, Reynolds numbers, and lift coefficients. The Reynolds-averaged Navier-Stokes (RANS) solver coupled with the linear stability theory is applied for the laminar-turbulent transition prediction, and the traditional optimization method based on evolutionary algorithms is applied for laminar flow wing optimization. The optimization results found that HLFC is required when the NLF fails at a larger sweep angle (35°) and Reynolds number ( 20 × 10 6 ). The lower pressure peak with boundary-layer suction is found to delay the transition of the regional aviation condition. Besides, the pressure distribution of HLFC is similar to NLF results at the lower Reynolds number ( 10 × 10 6 ) or sweep angle (25°), i.e., a gentle negative pressure gradient near the leading edge and a small favorable pressure gradient behind it. Clarifying the characteristics of laminar flow wings will advance the application of the laminar flow technique within its field.

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Building a Practical Natural Laminar Flow Design Capability

Cited by 16 publications

References 18 publications

Aerodynamic Optimization and Analysis of Low Reynolds Number Propeller with Gurney Flap for Ultra-High-Altitude Unmanned Aerial Vehicle

Aerodynamic Optimization and Analysis of Low Reynolds Number Propeller with Gurney Flap for Ultra-High-Altitude Unmanned Aerial Vehicle

Simplified Hybrid Laminar Flow Control for the A320 Fin. Part 2: Evaluation with the e^N-method

Hybrid Laminar Flow Control Optimizations for Infinite Swept Wings

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Building a Practical Natural Laminar Flow Design Capability

Cited by 16 publications

References 18 publications

Aerodynamic Optimization and Analysis of Low Reynolds Number Propeller with Gurney Flap for Ultra-High-Altitude Unmanned Aerial Vehicle

Aerodynamic Optimization and Analysis of Low Reynolds Number Propeller with Gurney Flap for Ultra-High-Altitude Unmanned Aerial Vehicle

Simplified Hybrid Laminar Flow Control for the A320 Fin. Part 2: Evaluation with the eN-method

Hybrid Laminar Flow Control Optimizations for Infinite Swept Wings

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Product

Resources

About

Simplified Hybrid Laminar Flow Control for the A320 Fin. Part 2: Evaluation with the e^N-method