• 한국산학기술학회논문지
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• 제19권7호
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• pp.72-80
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• 2018

과학 및 공학 분야 등에서 유한체적법등과 같은 전산해석방법은 비약적으로 발전하여 주로 대학 연구실 및 기업 등에서 활용하고 있었으나 최근에는 대학의 교육과정에서도 전산해석방법이 도입되고 있다. 이것을 계기로 공학대학의 기계공학과등에서 전산유체동역학이 학부 3학년 또는 4학년에 개설되고 있다. 일반적으로 전산유체동역학에서 다루는 수치해석 예제는 상용 전산유체동역학 소프트웨어 회사에서 개발한 예제이다. 따라서 학부 학생들은 저학년에서 학습한 유체역학의 이론적 해와 전산유체동역학 강의에서 학습하는 수치해석 해를 서로 비교할 수 없는 상황이 되고 있다. 따라서 본 연구에서는 유체동역학의 고전적인 해석 대상인인 정상 상태의 수평 원관 층류 유동의 이론적 배경을 설명한 뒤 ANSYS FLUENT를 이용하여 정상 상태의 수평 원관 층류 유동에 대한 수치해석 해를 구하여 이론적 해와 수치해석 해를 서로 비교하여 학생들의 전산유체동역학에 대한 개념을 확실히 다짐으로서 학생들의 현장적응능력을 높였으며 해당 강좌에 대한 강의 평가 결과 학생들이 전산유체동역학에 대한 이해력과 tutorial에 대한 만족도가 매우 높았다.

• 대한기계학회:학술대회논문집
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• 대한기계학회 2000년도 춘계학술대회논문집A
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• pp.661-665
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• 2000

A method of considering the fluid induced external force in structural dynamic analysis is presented in this study. The fluid induced pressure distribution around a structure in discrete number of orientation. and velocity is calculated by using a CFD code and tabulated as resultant forces and moments in a database. These forces and moments are interpolated and employed as external forces during the dynamic analysis of structure. The reliability and usefulness of the present method is validated by using a simple discrete system example through transient analysis. The flutter speed is obtained and compared to the analytical solution. Comparing to the method in which structural dynamic and fluid flow analyses are performed simultaneously, the present method is very efficient to save computational effort.

• 대한기계학회:학술대회논문집
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• 대한기계학회 2008년도 추계학술대회B
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• pp.2589-2593
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• 2008

In a fuel cell vehicle using polymer electrolyte membrane fuel cell(PEMFC), hydrogen is over-supplied to gain higher stack efficiency. So it is needed considering fuel efficiency to re-circulate hydrogen which is not reacted in stack. And to re-circulate hydrogen, a blower or an ejector is used. Ejector re-circulation system has several merits compared with blower system, for example no parasite energy, simple structure and no lubrication system. But the secondary flow of an ejector in fuel cell vehicle, has high humidity because of crossover problem in stack. Therefore in this paper, ejector is designed by 1-D modeling and CFD with the primary and secondary flow of hydrogen. And the ejector which has the primary and secondary flow of air, is designed to have the same Reynolds number and Mach number at the nozzle exit as the hydrogen ejector's. And this air ejector is tested while the humidity of the secondary flow is varied.

• 한국전산유체공학회:학술대회논문집
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• 한국전산유체공학회 2009년 추계학술대회논문집
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• pp.151-158
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• 2009

To implement the insects' flapping flight for developing flapping MAVs(micro air vehicles), the unsteady flow characteristics of the insects' forward flight is investigated. In this paper, two-dimensional FSI(Fluid-Structure Interaction) simulations are conducted to examine realistic flow features of insects' flapping flight and to examine the flexibility effects of the insect's wing. The unsteady incompressible Navier-Stokes equations with an artificial compressibility method are implemented as the fluid module while the dynamic finite element equations using a direct integration method are employed as the solid module. In order to exchange physical information to each module, the common refinement method is employed as the data transfer method. Also, a simple and efficient dynamic grid deformation technique based on Delaunay graph mapping is used to deform computational grids. Compared to the earlier researches of two-dimensional rigid wing simulations, key physical phenomena and flow patterns such as vortex pairing and vortex staying can still be observed. For example, lift is mainly generated during downstroke motion by high effective angle of attack caused by translation and lagging motion. A large amount of thrust is generated abruptly at the end of upstroke motion. However, the quantitative aspect of flow field is somewhat different. A flexible wing generates more thrust but less lift than a rigid wing. This is because the net force acting on wing surface is split into two directions due to structural flexibility. As a consequence, thrust and propulsive efficiency was enhanced considerably compared to a rigid wing. From these numerical simulations, it is seen that the wing flexibility yields a significant impact on aerodynamic characteristics.