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공력해석과 RCS해석 통합 500 lbs급 공대지 미사일 최적설계
배효길(Hyogil Bae),이광기(Kwangki Lee),정준오(Juno Jeong),상대규(Daekyu Sang),권장혁(Jang Hyuk Kwon) 한국항공우주학회 2012 韓國航空宇宙學會誌 Vol.40 No.2
최적설계 프레임워크를 구성하여 미사일 개념설계 단계에 필요한 공력해석(DATCOM)과 RCS 해석(POFACETS) 프로세스를 통합하였다. 미사일 형상정의는 제작과 설계의 동시성과 형상정보 산출 등을 목적으로 CAD(CATIA)를 기반으로 하였다. 정의된 형상정보가 자동적으로 해석 프로세스에 입력되도록 ModelCenter를 이용하여 프로세스들을 연결 하였다. 군요구도 정립부터 요구도 평가를 거쳐 미사일 설계 기준형상을 선정하였고, 양항비를 망대 구속조건으로 하여 RCS 최소화 최적설계를 실시하였다. 본 논문에서 구성한 최적설계 프레임워크를 이용하여 미사일 개념설계 단계에서 여러 미사일 형상들에 대한 효율적인 분석과 다양한 설계 전략을 구현할 수 있음을 확인하였다. Aerodynamic analysis(DATCOM) and radar cross section(RCS) analysis(POFACETS) were integrated for the air-to-surface missile concept design using a design framework. The missile geometry was defined based on the CAD(CATIA) for synchronizing the manufacturing with design processes. Aero/RCS analyses were linked with the CAD process under the ModelCenter framework in order to receive the geometry data automatically. The missile design baseline configuration was selected from ROC(requirement of capability). Then the RCS minimization was performed subject to thelargerthebetter constraint of the missile lift-to-drag ratio. This study demonstrated that various design strategies can be performed efficiently about many missile configurations using this design framework in the missile conceptual design phase.
배효길,정소라,Bae, Hyogil,Jeong, Sora 항공우주시스템공학회 2014 항공우주시스템공학회지 Vol.8 No.4
In preliminary design phase, the wing geometry of the civil aircraft was determined using the empirical equation and historical data. To make wing geometry more aerodynamically efficient, an aerodynamic shape optimization was conducted. For this purpose the parametric modeling, high fidelity CFD analysis and metamodel-based optimal design technique were adopted. The parametric modeling got the design process to achieve the improvement by generating the configuration outputs easily for the major design variables. The optimal design equations were formularized as the type of the multi-objective functions considering low/high speed and lift/drag coefficient. The optimal solution was explored with the help of the kriging metamodel and the desirability function, therefore the optimal wing planform was sought to be excellent at both low and high speed region. Additionally the optimal wing planform was validated that it was excellent not only at the specific AOA, but also all over the range of AOA.
이장호,강영신,배효길,이해창,Lee, Jangho,Kang, Youngsin,Bae, Hyogil,Lee, Hae-Chang 항공우주시스템공학회 2013 항공우주시스템공학회지 Vol.7 No.3
Tail wing is important to designing of civil aircrafts, because it is responsible for aircraft stability and control. Tail wing has a role in aircraft control and makes aircraft fly stably without any pilot control input. Also, designing of tail wing determine trim drag force in whole aircraft. Center of gravity(CG) of aircraft travels with various effects as placement of passenger's seats, location of cargo bay, etc. In designing horizontal tail volume, aircraft CG travel has to be considered to have margin so that it should be sized to provide adequate stability and control for the airplane's entire CG range throughout the flight envelope. Finally, it is essential to have sufficient elevator control to perform stall at forward CG for all flaps down configurations. Such stalls establish the FAR stall speed which airplane take-off and landing performance. This paper deals with the process for tail wing design regarding the aircraft CG travel and results for 95-seat type turboprop aircraft.