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Synthetic jet을 이용한 스마트 무인기 익형 주위의 유동 제어
김민희(Min hee Kim),김상훈(Sang Hoon Kim),김우례(Woore Kim),김종암(Chongam Kim),김유신(Yushin Kim) 한국전산유체공학회 2009 한국전산유체공학회 학술대회논문집 Vol.2009 No.4
In order to reduce the download around Smart UAV(SUAV) at hovering and transition mode, flow control using synthetic jet has been performed. Many of the complex tift rotor flow features are captured including wing leading and trailing edge separation, and the large region of separated flow beneath the wing. First, in order to control the trailing edge separation, synthetic jet is located at 30, 95% of flap chord length. The flow control using synthetic jet on flap shows that staff characteristics depending on several mode can be improved through separation vortices resizing. Also, a flap jet and a 0.01c jet which control the separation efficiently are applied at the same time at each test case because controlling the leading edge separation is essential for download reduction. As a result, time averaged download is reduced about 18% comparing with no control case at hovering mode and 48% at transition mode. These research results show that if flow control using leading edge jet and trailing edge jet is used effectively to the SUAV in overall flight mode, flight performance and stability can be improved.
Synthetic jet을 이용한 스마트 무인기(SUAV) 유동제어 Part 2 : 천이 비행 모드에서 synthetic jet을 이용한 유동제어
김민희(Min Hee Kim),김상훈(Sang Hoon Kim),김우례(Woore Kim),김종암(Chongam Kim),김유신(Yushin Kim) 한국항공우주학회 2009 韓國航空宇宙學會誌 Vol.37 No.12
스마트 무인기 익형 주위의 유동 구조를 파악하고 이를 바탕으로 synthetic jet을 이용하여 천이 비행 모드에서의 수익하중 감소 여부를 파악하였다. 스마트 무인기의 실제 비행 모드에서의 유동 구조를 분석하여 앞전 및 뒷전에서 발생하는 와류에 의해서 수익하중이 크게 증가함을 밝혔다. 이에 앞전과 뒷전에서 발생하는 유동의 박리를 효과적으로 제어하기 위하여 Part 1의 결과를 바탕으로 0.01c, 0.95c<SUB>flap</SUB> 지점에 jet을 위치시키고 각각 무차원 주파수(F+)를 0.5, 5로 작동시켜 그에 따른 유동구조 변화와 항력 감소율을 알아보았다. 그 결과 천이 비행 모드에서의 유동 제어를 위해서는 앞전에 위치한 jet만을 작동시킬 경우 가장 효과적으로 수익하중을 감소시킬 수 있음을 밝혔다. 이에 정지 비행 모드에서 뿐만 아니라 천이 비행 모드에서 synthetic jet을 이용하여 유동을 제어한다면 스마트전 비행 모드에서의 비행성능과 안정성을 동시에 향상시킬 수 있을 것이다. In order to reduce the download around the Smart UAV(SUAV) at Transition mode, flow control using synthetic jet has been performed. Many of the complex tilt rotor flow features are captured including the leading and trailing edge separation, and the large region of separated flow beneath the wing. Based on the results of part 1 of the present work, synthetic jet is located at 0.01c, 0.95c<SUB>flap</SUB> and it is operated with the non-dimensional frequency of 0.5, 5 to control the leading edge and trailing edge separation. Consequently, download is substantially reduced compared to with no control case at transition mode using leading edge jet only. The present results show that the overall flight performance and stability of the SUAV can be remarkably improved by applying the active flow control strategy based on synthetic jet.
Synthetic jet을 이용한 스마트 무인기(SUAV) 유동제어 Part 1 : 정지 비행 모드에서 synthetic jet을 이용한 유동제어
김민희(Min Hee Kim),김상훈(Sang Hoon Kim),김우례(Woore Kim),김종암(Chongam Kim),김유신(Yushin Kim) 한국항공우주학회 2009 韓國航空宇宙學會誌 Vol.37 No.12
스마트 무인기 익형 주위의 유동 구조를 파악하고 이를 바탕으로 synthetic jet을 이용하여 정지 비행 모드에서의 수익하중 감소 여부를 파악하였다. 스마트 무인기의 실제 비행 모드에 대하여 유동 구조를 분석하여 앞전 및 뒷전에서 발생하는 와류에 의해서 수익하중이 크게 증가함을 밝혔다. 이에 앞전과 뒷전에서 발생하는 유동의 박리를 제어하기 위하여 0.01c, 0.3c<SUB>flap</SUB>, 0.95c<SUB>flap</SUB> 위치에 jet을 위치시켰다. 또한 무차원 주파수(F+)의 변화에 따른 유동 구조 변화와 항력 감소율을 알아보았다. 그 결과, 와류의 유동 구조를 변화시켜 앞전과 뒷전에서 발생하는 거대한 와류의 박리 주기를 짧게 하고 와류의 크기를 감소시켜 정지 비행 모드에서 수익 하중을 효과적으로 감소시킬 수 있었다. In order to reduce the download around the Smart UAV(SUAV) at hovering, flow control using synthetic jet has been performed. Many of the complex tilt rotor flow features are captured including the leading and trailing edge separation, and the large region of separated flow beneath the wing. In order to control the leading edge andtrailing edge separation, synthetic jet is located at 0.01c, 0.3c<SUB>flap</SUB>, 0.95c<SUB>flap</SUB>. As non-dimensional frequency, the flow pattern is altered and the rate of drag reduction is changed. The results show that synthetic jets shorten the vortex period and decrease the vortex size by changing local flow structure. By using leading edge jet and trailing edge jet, download is efficiently reduced compared to no control case at hovering mode.
Single and High-Lift Airfoil Design Optimization Using Aerodynamic Sensitivity Analysis
Kim, Chang Sung,Lee, Byoungjoon,Kim, Chongam,Rho, Oh-Hyun The Korean Society for Aeronautical and Space Scie 2001 International Journal of Aeronautical and Space Sc Vol. No.
Aerodynamic sensitivity analysis is performed for the Navier-Stokes equations coupled with two-equation turbulence models using a discrete adjoint method and a direct differentiation method respectively. Like the mean flow equations, the turbulence model equations are also hand-differentiated to accurately calculate the sensitivity derivatives of flow quantities with respect to design variables in turbulent viscous flows. The sensitivity codes are then compared with the flow solver in terms of solution accuracy, computing time and computer memory requirements. The sensitivity derivatives obtained from the sensitivity codes with different turbulence models are compared with each other. The capability of the present sensitivity codes to treat complex geometry is successfully demonstrated by analyzing the flows over multi-element airfoils on Chimera overlaid grid systems.
Kim, Minhee,Lee, Byunghyun,Lee, Junhee,Kim, Chongam The Korean Society for Aeronautical and Space Scie 2016 International Journal of Aeronautical and Space Sc Vol.17 No.3
This paper presents experimental and computational investigations of synthetic jets with a circular exit for improving flow control performance. First, the flow feature and vortex structure of a multiple serial circular exit were numerically analyzed from the view point of flow control effect under a cross flow condition. In order to improve separation control performance, experimental and numerical studies were conducted according to several key parameters, such as hole diameter, hole gap, the number of hole, jet array, and phase difference. Experiments were carried out in a quiescent condition and a forced separated flow condition using piezoelectrically driven synthetic jets. Jet characteristics were compared by measuring velocity profiles and pressure distributions. The interaction of synthetic jets with a freestream was examined by analyzing vortical structure characteristics. For separation control performance, separated flow over an airfoil at high angles of attack was employed and the flow control performance of the proposed synthetic jet was verified by measuring aerodynamic coefficient. The circular exit with a suitable hole parameter provides stable and persistent jet vortices that do beneficially affect separation control. This demonstrates the flow control performance of circular exit array could be remarkably improved by applying a set of suitable hole parameters.
AERODYNAMIC SENSITIVITY ANALYSIS FOR NAVIER-STOKES EQUATIONS
Kim, Hyoung-Jin,Kim, Chongam,Rho, Oh-Hyun,Lee, Ki Dong 한국산업정보응용수학회 1999 한국산업정보응용수학회 Vol.3 No.2
Aerodynamic sensitivity analysis codes are developed via the hand-differentiation using a direct differentiation method and an adjoint method respectively from discrete two-dimensional compressible Navier-Stokes equations. Unlike previous other researches, Baldwin-Lomax algebraic turbulence model is also differentiated by hand to obtain design sensitivities with respect to design variables of interest in turbulent flows. Discrete direct sensitivity equations and adjoint equations are efficiently solved by the same time integration scheme adopted in the flow solver routine. The required memory for the adjoint sensitivity code is greatly reduced at the cost of the computational time by allowing the large banded flux jacobian matrix unassembled. Direct sensitivity code results are found to be exactly coincident with sensitivity derivatives obtained by the finite difference. Adjoint code results of a turbulent flow case show slight deviations from the exact results due to the limitation of the algebraic turbulence model in implementing the adjoint formulation. However, current adjoint sensitivity code yields much more accurate sensitivity derivatives than the adjoint code with the turbulence eddy viscosity being kept constant, which is a usual assumption for the prior researches.