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성능향상 패키지 적용 효과 분석 - Airbus 350 기종을 중심으로 -
장성우,조율현,유재림,유광의,Jang, Sungwoo,Cho, Yul Hyun,Yoo, Jae Leame,Yoo, Kwang Eui 한국항공운항학회 2021 한국항공운항학회지 Vol.29 No.3
PIP is an abbreviation of 'Performance Improvement Package', which is a package that can improve performance by applying some design changes to existing aircraft. Boeing provides PIP applicable to B777-200, and Airbus provides PIP applicable to A350-900 as standard. PIP provided by Boeing and Airbus is a separate task, but it is expected to reduce fuel consumption by reducing drag through aerodynamic improvements. The PIP applied to the A350-900 includes work such as increasing Winglet Height and re-twisting Outboard Wing. This study is to verify the effect of PIP application of the A350-900 aircraft and use it as basic data for economic analysis. The aerodynamic improvement studies and expected effects of the PIP application were examined, and the actual flight data of the PIP-applied and the non-applied aircraft were compared to confirm the PIP application effect. This paper provides empirical results for the aviation industry on the PIP application efficiency as a method of improving fuel efficiency and reducing carbon emission.
불확실성을 고려한 발포 알루미늄 샌드위치 패널의 귀납적 설계 전개법
장성우(Sungwoo Jang),최해진(Hae-Jin Choi) 대한기계학회 2013 대한기계학회 춘추학술대회 Vol.2013 No.12
Aluminum foams are useful material for absorbing impact energy due to its high specific strength and high energy absorbing capacity with light weight. In this study, we design a sandwich panel with aluminum foam core by controlling processing parameters of foam core and panel geometry under manufacturing uncertainty. In order to support this robust design of sandwich panels, a new design approach, inductive design exploration method (IDEM), is used in this paper. In IDEM, feasible ranged sets of design specifications are explored in the design hierarchy from the top to bottom level (inductive design). With given design requirements at the top level, a designer identifies feasible ranges at the lower level variable space and this process is continued until the lowest level design space. Applying this method for the integrated design of sandwich panel and its core material, the feasible ranges of core thickness and processing parameters are achieved step by step to satisfy the required performance. Finally, a designer is able to select the best design among the feasible ranges of design variables.
A321 Sharklet 모델의 운항실적을 이용한 윙렛 장착 효과 검증 및 경제성 분석
장성우(Sungwoo Jang),이영재(Youngjae Lee),김강욱(Kangwook Kim),유재림(Jae Leame Yoo),유광의(Kwang Eui Yoo) 한국항공우주학회 2021 韓國航空宇宙學會誌 Vol.49 No.4
윙렛은 유도항력을 줄이기 위한 장비로, 1980년대부터 보잉사에서 제작한 항공기에 장착되기 시작했고, 에어버스에서는 2009년부터 ‘Sharklet’이라는 이름의 윙렛을 개발하여 A320 Family에 장착 옵션으로 제공하기 시작했다. 윙렛은 날개 끝단에서 발생하는 유도항력을 감소시켜 이륙성능 향상, 연료소모량 감소, 유상탑재량 증대 및 운항거리 증가의 효과를 내고 있다. 본 연구는 Sharklet이 장착된 A321 항공기와 미장착된 A321 항공기의 실제 운항 데이터를 분석하여 윙렛 장착에 따른 연료 효율성 향상을 검증하고 이에 따른 경제성 분석을 목적으로 한다. 이를 통해 항공기 도입 시 윙렛 장착 사양 결정 혹은 기존 항공기의 업그레이드를 위한 의사 결정에 활용할 수 있다. 이를 위해 윙렛 장착에 따른 공력 특성 연구 사례조사와 효과 확인 연구를 수행하고 경제성을 검증하였다. Winglets are specialized wingtip devices to reduce induced drag, and they have been installed on Boeing-made aircraft since the 1980s, Airbus has also developed a winglet named ‘Sharklet’ since 2009 and has started providing them as an option to the A320 Family. The winglet has the effect of improving take-off performance, reducing fuel consumption, increasing payload, and increasing flight distance by reducing the induced drag generated at the tip of the wing. The purpose of this study is to analyze the actual flight data of the sharklet-installed and non-sharklet-installed models of the A321 aircraft to verify the fuel efficiency improvement due to the winglet installation, and to analyze the economic analysis accordingly. Through this, it can be used to determine the winglet installation when introducing an aircraft or to make a decision for upgrading the existing aircraft. To this end, a case study on the aerodynamic characteristics and effects of the winglet installation was conducted, and the economic analysis was verified.
장성우(Sungwoo Jang),유재림(Jae Leame Yoo),유광의(Kwang Eui Yoo) 한국항공우주학회 2022 韓國航空宇宙學會誌 Vol.50 No.1
항공기 중량은 성능 및 연료효율성에 영향을 미치는 중요한 요소이다. 항공기의 개념 설계 단계에서는 요소 중량을 추정함에 중량 당 연료소모 비용과 같은 경험식을 이용하여 비용과 중량 간의 균형을 맞추는 과정을 수행한다. 또한, 항공사에서 항공기를 운용할 때 중량관리 활동을 통해 연료효율성 향상 및 연료절감과 탄소저감을 추진한다. 항공기 중량 변화와 연료 소모 변화 사이의 연관성을 중량비용(Cost of Weight)이라고 하며, 중량비용은 항공기에 중량 추가 혹은 감소가 연료소모에 미치는 영향을 평가함에 사용하고 있다. 본 연구에서는 기존 중량비용 산정 방법의 문제점을 확인하고, 이를 해결하기 위한 새로운 방법의 중량비용 산정 방법을 소개한다. Breguet의 Range Formula와 A350-900 항공기의 실제 비행 데이터를 이용하여 이륙중량과 착륙중량 기반의 두 가지 중량비용을 산정한다. 결론에서는 이륙중량과 착륙중량 기반의 중량비용을 다른 용도로 사용함이 합리적임을 제시하였다. 특히, 착륙중량 기반의 중량비용은 유사 항공기 개념설계 단계에서 요소중량 추정 및 비용과 중량 최적화에 하나의 경험식으로 활용할 수 있다. Aircraft weight is an important factor affecting performance and fuel efficiency. In the conceptual design stage of the aircraft, the process of balancing cost and weight is performed using empirical formulas such as fuel consumption cost per weight in estimating element weight. In addition, when an airline operates an aircraft, it promotes fuel efficiency improvement, fuel saving and carbon reduction through weight management activities. The relationship between changes in aircraft weight and changes in fuel consumption is called the cost of weight, and the cost of weight is used to evaluate the effect of adding or reducing weight to an aircraft on fuel consumption. In this study, the problems of the existing cost of weight calculation method are identified, and a new cost of weight calculation method is introduced to solve the problem. Using Breguets Range Formula and actual flight data of the A350-900 aircraft, two weight costs are calculated based on take-off weight and landing weight. In conclusion, it was suggested that it is reasonable to use the cost of weight based on the take-off weight and the landing weight for other purposes. In particular, the cost of weight based on the landing weight can be used as an empirical formula for estimating element weight and optimizing cost and weight in the conceptual design stage of similar aircraft.
크리깅 근사모델기반 복합충격 저항 샌드위치 패널 최적설계
장성우(Sungwoo Jang),백운경(Woon-Kyoung Baik),최해진(Hae-Jin Choi),박순석(Soon Suk Park) (사)한국CDE학회 2015 한국CDE학회 논문집 Vol.21 No.2
Sandwich panels consisting of various materials have widely been applied for mitigating dynamic impacts such as ballistic and blast impacts. Especially, the selection of materials for different core set-ups can directly influence its performance. In this study, we design the sandwich panels for alleviating ballistic and blast impacts by controlling the stacking sequence of core materials and their thicknesses. FEM studies are performed to simulate the dynamic behavior of sandwich panels subjected to ballistic and blast impacts. Delamination between the core layers is also considered in the FEM studies for feasible design. Based on the FEM data, kriging models are generated for approximating design space and quickly predicting the FEM outputs. Finally, design optimizations are implemented to find the optimum stacking sequence of core materials and thicknesses with given impact situations.