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백승길,박중용,Paek, Seung-Kil,Park, Joongyong 항공우주시스템공학회 2015 항공우주시스템공학회지 Vol.9 No.4
The purpose of this research is to develop co-simulation methodology of codes developed in different modeling and simulation environment. We develop aerodynamic FMU(Functional Mock-up Unit) meeting FMI(Functional Mock-up Interface) specification version2 utilizing Legacy FORTRAN aerodynamic code based on unsteady vortex lattice method. It is concluded that making FMU is possible utilizing Legacy code made in any language which can be compiled and linked with object in FMI API coded in C language. This paper explains QTronic's method of using FMU SDK(Software Development Kit) and suggestion for using FORTRAN properly. Finally, we make articulated rotor/aerodynamics co-simulation by integrating aerodynamics FMU and rotor FMU developed by Modelica.
Redmine과 Git을 활용한 헬리콥터 능동진동제어시스템 소프트웨어 형상관리
백승길,박중용,Paek, Seung-Kil,Park, Joongyong 한국시스템엔지니어링학회 2017 시스템엔지니어링학술지 Vol.13 No.1
Korea Aerospace Research Institute takes part in the vibration control software development for an Active Vibration Control System (hereafter, AVCS) for helicopters with Korea Aerospace Industries Ltd. in the Light Civil Helicopter (LCH) Project. The vibration control software is being developed per RTCA/DO-178C certification regulation and use of configuration management tools for software outputs is required. Redmine, an open source software is for issue or bug tracking and management software. Git, another open source software is a distributed version control software and is developed for Linux OS development. This paper introduces the functionalities of Redmine and Git, the reason why they are selected for the configuration management tool for the software outputs, and how they are being used for AVCS software development.
Lift-Tilt 개념의 eVTOL 항공기 임무 분석 도구 개발
백승길(Seung-Kil Paek),채상현(Sanghyun Chae),강희정(Hee Jung Kang) 한국항공우주학회 2021 韓國航空宇宙學會誌 Vol.49 No.10
항우연은 eVTOL 항공기의 개념설계 및 기본설계를 위한 설계프레임워크를 개발하고 있다. 오픈소스 SUAVE 패키지를 활용하여 틸트 프롭 및 리프트 프롭을 갖는 Lift-Tilt 개념의 전기수직이착륙기에 대한 저충실도 임무분석도구를 개발하였다. 그 개발을 위하여 SUAVE의 프롭성능해석 기능을 검토하였다. 매 임무 세그먼트에서 트림해를 자동적으로 찾기 위해 병렬처리 및 실험계획법을 통한 전역최적화 기법을 적용한 알고리듬을 구현하였다. 동 도구를 사용하여 1인승급 전기추진 수직이착륙 유무인 겸용 개인항공기(OPPAV)의 임무분석을 수행하고 동 항공기의 기본설계데이터와 비교하였다. KARI (Korea Aerospace Research Institute) is developing a design framework for the concept and preliminary design of eVTOL aircrafts. A low fidelity mission analysis tool was developed for the eVTOL aircrafts of Lift-Tilt Concept, which have tilt propellers and lift propellers, using open source SUAVE package. For its development, a review for the propeller performance analysis functionality was made. To find the trim solution at each mission segment automatically, an algorithm is implemented, using a global optimization technique through parallel processings and DOE(design of experiment). Using the tool, the one seated eVTOL OPPAV(optionally piloted personal air vehicle) was modeled and evaluated, which results were compared with the preliminary design data.
백승길(Seung-Kil Paek),이상욱(Sang-Wook Lee) 한국항공우주연구원 2007 항공우주기술 Vol.6 No.1
본 연구에서는 선미익을 채용한 경항공기인 반디호의 수출형 시제기에 대한 플러터 해석을 수행하였다. 내부 하중 생성용 유한요소모델을 기초로 강성 모델을 작성하였고, 중량통제를 위한 중량 DB에 근거하여 중량 모델을 작성하였다. 공력모델은 DLM을 이용하였다. 작성된 모델을 이용하여 1차 플러터 해석을 수행하였다. 이를 토대로 주요 진동 모드를 구분해 내고, 지상진동시험을 수행하여 진동 특성을 획득하였다. 획득된 고유진동수를 근거로 유한요소모델의 수정이 이루어졌고 2차 해석이 수행되었다. 해석 결과 주요 플러터 근의 특성을 정리하였다. 가장 중요한 플러터 근은 롤 운동을 갖는 강체 모드와 반대칭주익 피칭 모드의 연계 모드로 판명되었다. In this study was made the flutter analysis for the export model of Firefly(Bandi-ho), the small canard aircraft. Stiffness model based on internal load generation finite element model was generated. Mass model based on the weight DB for weight control was generated. Aerodynamic model based on Doublet Lattice Method was generated. Preliminary flutter analysis was made. Based on it, major vibration modes are identified and experimentally obtained via the ground vibration test. The obtained normal mode frequencies were used to correlate the finite element model. Flutter analysis was made again and major flutter mechanisms were summarized. The most important flutter root was identified as a coupled root between rigid body roll mode and anti-symmetric wing pitching mode.