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위상 최적 설계를 통한 복합소재 대차프레임용 제동장치 브래킷의 경량화 연구
이우근(Woo Geun Lee),김정석(Jung Seok Kim) 대한기계학회 2015 大韓機械學會論文集A Vol.39 No.3
본 연구에서는 위상 최적 설계 기법을 활용하여 복합소재 대차프레임의 제동장치 브래킷 경량 설계를 수행하였다. 제동장치 브래킷은 12t 와 9t 로 각각 두 가지 모델을 대상으로 하였다. 위상최적화시설계영역은 단면적이 가장 넓은 수직면과 수평면으로 설정하였다. 제한조건은 제동장치 브래킷의 Z 축의 변위 값을 초기 변위 값보다 2.5% 증가이고, 목적함수는 제동장치 브래킷의 질량 최소화로 하였다. 또한 최적화 계산 시간을 줄이기 위해 대차프레임을 생략하고 대차프레임 대신 1D beam 요소를 적용하여 Z 축 변위를 기준으로 전체모델과 동일하게 등가시켜 두 모델간의 상관성을 확보 하였다. 그 결과 12t 모델은 60kg, 9t 모델은 31kg 감소하였고, 최적화 모델의 유한요소해석을 통하여 안전성을 검증하였다. In this study, the lightweight design of a brake bracket for a composite bogie was studied by considering two brake bracket models with thicknesses of 12t and 9t, respectively. For achieving this goal, finite element analysis and topology optimization were conducted. Firstly, the largest cross-sectional areas of the vertical and horizontal plates of the brake bracket were selected as the design variables. As the constraint, the Z-axis displacement of the brake bracket was increased by 2.5 units from the initial displacement value. The minimum volume fraction of the design regions was chosen as the objective function. The full model comprised a composite bogie frame and brackets attached together. However, to reduce the analysis time, 1D beam elements were used instead of the composite bogie frame by ensuring its equivalence with the full model. The result revealed that the weights of the 12t and 9t models of the brake bracket were reduced to 60 kg and 31 kg, respectively.
Mg Alloy(AZ61) 마찰교반용접 조건에 따른 용접부의 온도와 기계적 특성변화
이우근(Woo Geun Lee),김정석(Jung Seok Kim),선승주(Seung-Ju Sun) 한국생산제조학회 2017 한국생산제조학회지 Vol.26 No.4
Friction stir welding was performed using six welding conditions to evaluate the mechanical properties and microstructure of the welded zone based on its temperature change in the extruded plate of magnesium alloy AZ61. The welded zone temperature was measured using a thermocouple, and the maximum temperature ranges for the advancing and retreating sides were approximately 210-315°C and 254-339°C, respectively. Depending on the welding conditions, a temperature difference of more than 100°C was observed. In addition, the maximum yield strength and maximum tensile strength of the welded component was 84.4% and 96.9%, respectively, of those of the base material. For the temperatures exceeding 300°C, oxidation defects occurred in the weld zone, which decreased the mechanical strength of the weld zone. The microstructure and texture confirmed that fracture occurred because of the grain size deviation of the welding tool and the severe anisotropy of the texture of the welded joints.