The computing environment has changed rapidly to enable large-scale finite element models to be analyzed at the PC or workstation level, such as multi-core CPU, optimal math kernel library implementing BLAS and LAPACK, and popularization of direct sparse solvers. In this paper, the design considerations on a parallel finite element code for shared memory based multi-core CPU system are proposed; (1) the use of optimized numerical libraries, (2) the use of latest direct sparse solvers, (3) parallelism using OpenMP for computing element stiffness matrices, and (4) assembly techniques using triplets, which is a type of sparse matrix storage. In addition, the parallelization effect is examined on the time-consuming works through a large scale finite element model.

As demands for freeform structure were gradually increased, researches about various shapes of claddings have been conducted. Particularly, claddings made from concrete easily made complex shapes. Because of this advantage, many researches about manufacturing methods and light weight of concrete mainly have been conducted. For example ALC (Autoclaved Lightweight Concrete) was the most popular claddings that had a great strength without aggregate and were cured at high temperature and pressure conditions. This paper showed multi-layer reinforcement system, exactly 5 layers polymer reinforcement method, that consisted of 3D printing material with low weight and high performance mechanical properties. Finite element analysis were performed to predict the maximum deformations loaded by wind and self-weight. Joints of analysis model were simplified as the pin joint. The variable of this analysis was the material arrangement of 3 layers located at center among exterior layer. Finally, the maximum deformations of analysis results were compared with the limitations of claddings.

Climate change resulted in the growing occurrence frequency of typhoons, and the damage it caused was also increasing. In this study, the soundproofing and windproof walls installed on the domestic road were modeled by using ABAQUS, a commercial finite element analysis program. Correspondingly, steel column, aluminum frame and transparent acrylic plate were modeled. Based on the result from individual part of soundproof wall model, the number of soundproof wall parts for optimal design was determined to be five parts. The design standard of road construction barrier was applied to this optimum model to perform the safety evaluation for strong wind disaster. In the future, it will be possible to improve the guidelines for design of soundproofing walls in Korea by carrying out further experiment to increase the reliability of safety evaluation of soundproofing walls.

At modern mechanical and automotive industry, the material with light weight proceeds in order to thr environmental issue and high performance. Machine part is fastened with numbers of bolts and nuts. Generally, the metal part at mechanical structure is fastened with bolt and nut through puncturing. But it is difficult to puncture at CFRP with the property of fiber structure like the general metal. In this study, the fracture behavior is investigated by the hole and crack at the plate of the unidirectional CFRP due to ply angle. The thickness of plate is 2 mm. Two laminates with the varied ply angles are layered and eight plies are made. The hole is placed at the center of plate and the cracks with the length of 2 mm are generated on both left and right sides from the hole. The finite element program of ANSYS is carried out in order to analyze the CFRP with fiber layer. As analysis, the maximum reaction force and equivalent stress are investigated due the angle of ply. The reaction force in case of the stacking angle of 90° is shown to be greatest among all specimens.

V-Coupling is commonly used as a mechanical fastener to connect the turbine housing and the bearing housing in a turbocharger assembly. The back plate between the turbine housing and bearing housing would be compressed by tightening torque of the coupling bolt in order to protect the gas leakage at a turbocharger’s operation. This paper presents the numerical and experimental method for the prediction of the mechanical behavior and sealing performance of the coupling system. The test was conducted to verify the finite element model by measuring the circumferential and axial direction strains of V-coupling under turbocharger’s assembly load. Finite element analysis was carried out to obtain the mechanical strains and contact pressures of the coupling. It can be seen that the analysis results are in good agreement with the measured strains from the coupling’s assembly load. And, the pressure distribution of the back plate also presented to identify the sealing performance of the turbocharger’s coupling system.

In this study, nonlinear finite element analysis based on the Modified Compression Field Theory has been conducted to evaluate shear strength of RC walls with opening. On the analysis, reinforcement ratio within development length of rebars nearby the opening was reduced in the model in order to investigate the effect of opening on shear strength of RC shear walls. The nonlinear finite element analysis has been verified through comparison with the test result in literature. Through the verification, it was investigated that the analysis considering the development length of rebars well reflected the effect of an opening on shear strength of RC shear walls while current design provisions did not reasonably consider one.

The boundary reaction method(BRM) is a substructure time domain method, it removes global iterations between frequency and time domain analyses commonly required in the hybrid approaches, so that it operates as a two-step uncoupled method. The BRM offers a two-step method as follows: (1) the calculation of boundary reaction forces in the frequency domain on an interface of linear and nonlinear regions, (2) solving the wave radiation problem subjected to the boundary reaction forces in the time domain. In the time domain analysis, the near-field soil is modeled to simulate the wave radiation problem. This paper evaluates the performance of the BRM according to modeling extent of near-field soil for the nonlinear SSI analysis of base-isolated NPP structure. For this purpose, parametric studies are performed using equivalent linear SSI problems. The accuracy of the BRM solution is evaluated by comparing the BRM solution with that of conventional SSI seismic technique. The numerical results show that the soil condition affects the modeling range of near-field soil for the BRM analysis as well as the size of the basemat. Finally, the BRM is applied for the nonlinear SSI analysis of a base-isolated NPP structure to demonstrate the accuracy and effectiveness of the method.

OBJECTIVES : The objective of this research is to determine the integrity of pavement structures for areas where voids exist. Furthermore, we conducted the study of voided-area analysis and remaining life prediction for pavement structures using finite element method. METHODS : To determine the remaining life of the existing voided areas under asphalt concrete pavements, field and falling weight deflectometer (FWD) tests were conducted. Comparison methods were used to have better accuracy in the finite element method (FEM) analysis compared to the measured surface displacements due to the loaded trucks. In addition, the modeled FEM used in this study was compared with well-known software programs. RESULTS : The results show that a good agreement on the analyzed and measured displacements can be obtained through comparisons of the surface displacement due to loaded trucks. Furthermore, the modeled FEM program was compared with the available pavement-structure software programs, resulting in the same values of tensile strains in terms of the thickness of asphalt concrete layers. CONCLUSIONS: The study, which is related to voided-area analysis and remaining life prediction using FEM for pavement structures, was successfully conducted based on the comparison between our methods and the sinkhole grade used in Japan.

In this study, refined finite element (FE) analyses intended to evaluate the capacity of the existing water purification plant structures against seismic force are conducted with an aim to predict possibility generating tension crack and compression crushing. The FE models for three types of main plant structures were constructed to take ground condition, boundary condition, and water interaction into consideration for advanced simulation. The nonlinear dynamic analyses were performed by using ground motion data which have been used for seismic design. Both compression crushing and tention crack, which are distributed over concrete plant structures during peak ground acceleration (PGA), are investigated by analyzing failure possibility controlled with the strain limits. After observing FE analysis results, it is possible to predict tenstion cracking which can be found at some parts of the main structure.

This study mainly evaluate the aseismic performance of the existing intake tower structure, which is one of the national important infra structures, on the basis of the refined finite element (FE) analysis results. The realistic evaluation for structural damage was conducted by using the nonlinear material model that takes tension and compression strength of deteriorate concrete into consideration during FE modeling. In addition, not only tension crack but also compression crushing was analyzed by utilizing field contour functions provided in the program during nonlinear dynamic analyses when peak ground acceleration (PGA) occurred. After observing FE analysis results, it can be shown that the damage of the intake tower is the most likely to occur at the water level and the base support.

Formulation of the finite element method(FEM) for dynamic interaction between a pantograph and contact wire, including non-linear formulation associated with contact wire stagger in the railway overhead contact line is presented. Penalty method is chosen for modelling contact between a pantograph and contact wire. The formulation is validated by comparing the simulated contact forces with measurements taken from 300 km/h KTX operation.

In military, empty cartridge recovery case of personal small arms is a device used to collect the empty cartridge after consumption of bullets. It has different shapes depending on the shape of small arms. However, It should be designed in a shape that wraps around the outlet for empty cartridge and it should be no restrictions to the movement of small arms. It has been used to spread military. but military is demanding design improvement due to frequent damage of empty cartridge recovery case. In this report, We improved the shape of the product in order to prevent damage to the product and verified through the FEM analysis and prototype test. According to the result of simulation, best modified modelling of this study has been reduced about 19% of the stress compared to initial modelling. In addition, modified products were confirmed durability, wearability and fixability through fire test.

The axial thrust acting on the turbocharger rotor is basically generated by the unbalance between turbine wheel gas forces and compressor wheel air forces. It has a significant influence on the friction losses, which reduces the overall efficiency and performance of high-speed turbocharger. Therefore, it’s important to calculate the thrust forces under operating conditions (surge, choke and etc.) in a turbocharger. The purpose of this paper is the development of numerical simulation methods which were verified by experimental results of axial thrust and thermally induced constraint tests of the turbocharger. The first FE model showed the relationship between thrust forces and strains by calculating the strains on specially designed thrust bearing and were compared with test results. And the second one is to identify the thermally induced strains in order to remove the thermal effects from measured strains. With these models, it’s possible to inversely predict the magnitudes of the axial thrust by directly measured strains and temperatures under operating turbocharger.

In this study, TbDyFe thin films with the thickness of 1000 Å are fabricated by DC magnetron sputtering. TbDyFe thin films are prepared by DC magnetron sputtering method. The pressure of Ar gas below 1.33 kPa and DC input power of 200 W are used for the sputtering conditions. During sputtering process the substrate holder is heated up to 150 ℃. The thin films are deposited to a thickness of 1000 Å on polyimide substrate with a thickness of 2 μm. The fabricated microstructures are observed by X-ray diffraction (XRD) and the film thickness is measured. Magnetostrictions are determined from the curvature of the thin films which are measured by the optical cantilever method. The experimental results are discussed with numerical data.

최근 서울 도심 지역에 위치한 주요 포장도로에서의 동공발생 문제가 다양한 원인으로 인하여 이전 보다 더 빈번하게 나타나는 것으로 대두되고 있는 실정이다. 이 문제는 포트홀과 싱크홀 수 증가와 포장 도로에서의 다른 문제들을 야기 시킨다. 사실, 포장도로에서의 동공발생을 일으키는 주체적인 원인은 강 우, 강설과 같은 기후 변화와 밀접한 관련이 있다. 이 연구에서는, 한국형도로포장설계법에 기반하여 개 발된 KPRP(Korea Pavement Research Program : 한국형 포장설계프로그램)를 이용하여 동상방지층 의 구조적 성능을 모니터링 하고, 유한요소해석 프로그램 중 하나인 KICTPAVE 프로그램을 이용하여 KPRP프로그램의 신뢰도를 확인하고자 한다. KPRP 프로그램은 한국형 도로포장설계법에 기반을 두고 개발 된 프로그램 이다. 사실. 이전에 사용되어지던 설계 법은 AASHTO Interim Guide Method(1972) 로, 한국형포장설계프로그램의 개발 전 국내에서 가장 보편적으로 사용된 설계법이다. 이 설계법은 주어 진 조건 하에서만 포장 단면을 설계하는 법을 도출해내기 때문에 다양한 조건에서의 설계와 구조적인 개 량이 어렵다는 지적이 나오게 되었다. 이를 보완하기 위하여 국내에서의 주어진 조건에 적합하게 도로 포장의 횡단을 설계하기 위해 개발된 한국형포장설계프로그램이 나오게 되었다. 본 연구에서는, KPRP 와 KICTPAVE를 이용하여 동상방지층의 구조적 성능을 더욱 정밀하게 연구하게 된다. 한국형포장설계프로그램은 설계조건을 반영한 후, 횡단면 조건 설정, 기상조건 반영, 교통량 반영, 포장 재료 물성치 반영 및 동상방지층 설치 여부 판단과정을 거쳐 공용성을 예측하게 된다. 설계조건 반영은 한 국형포장설계프로그램에서 제공하는 기본 DB를 활용하여 횡단 설계를 하였다. 본 연구는 효과적인 공용성 분석을 위하여 세 가지 경우로 나누어서 해석을 실시하였는데, 그 조건들은 아래 표 1에 나온 것과 같다. 표 1은 동상방지층의 구조적 성능을 한국형포장설계프로그램을 이용하여 분석해낸 결과 이다. 표 1을 보면 두께와 상관없이 모든 구조적 성능이 일치하게 되는 결과를 가져와서 KICTPAVE 프로그램을 이용하여 조 건을 5가지로 나누어 유한요소해석을 실시하였다. 각 층(동상방지층-노상토, 보조기층-동상방지층, 기층 -보조기층, 표층-기층, 표층 사이의 노드와 요소)은 5cm간격으로 0cm에서 20cm 까지 다섯 가지 경우의 조건으로 나누어서 해석을 하였다. 그 결과 보조기층과 동상방지층 사이의 변형률은 동상방지층의 두께가 두꺼워질수록 증가되는 현상을 보였다. 하지만, 이와는 반대로 노상토와 동상방지층 사이에서 발 생하는 변형률은 동상방지층의 두께가 두꺼워 질 수록 감소되는 현상을 보였다.

지난해 2월말 경 용산역 근처 공사현장 인근 인도에서 도로함몰이 발생하여 보행자가 추락하여 부상을 입는 사고가 발생했다. 이를 계기로 서울시는 도로함몰의 조기예방을 위해 세계 최고수준의 기술을 보유 한 일본 업체와 협력하여 차량형 GPR(Ground Penetrating Rader : 전자파를 지표에 투과하여 지하의 빈 공간 형상 데이터를 수집하는 레이더 장치)을 이용한 도로하부 동공탐사 용역을 실시하였다. 서울시 동공탐사용역을 계기로 현장적응 시운전과 기술진의 분석훈련을 거쳐 실질적 탐사는 지난해 12 월부터 시작되었으며 약 4개월 동안 도로함몰 개연성이 높은 주요 간선도로 48km구간에서 105개의 공동 을 발견하였으며 금년 말까지는 약 200여개를 포함해 총 300여개의 공동이 발견될 것으로 예상했다. 이번 조사로 발견된 공동 중 위험도가 가장 높은 A급 공동이 약 60%로 61개가 발견되었고 그보다 낮은 등급의 B급 공동이 35개가 발견되어 5월 말까지 복구할 예정이며 도로함몰 가능성이 그나마 낮은 C급 공동 8개는 연구를 위해 일정 기간 관찰 후 복구할 예정이라고 밝혔다. 서울시 자치구별 공동 발견 현황을 살펴보면 송파구가 약 30%인 32개로 가장 많은 공동이 발견되었고 뒤이어 용산구 21개, 종로구 19개 순으로 나타났 다. 본 연구는 상용 유한요소해석 프로그램인 ABAQUS를 이용하여 공동 규모에 따른 아스팔트 포장도로 의 거동에 대한 분석을 실시하였다. 이를 위해 공동의 규모는 공동 위험도 평가 등급에 따른 A, B ,C 등급 으로 분류하였으며 공동의 발생 범위는 1.5m 이내로 설정하였다. 해석을 위한 단면 구성은 아스팔트 콘크 리트 층, 보조기층, 노상의 구조로 이루어져 있으며 접합상태를 의미하는 tie contact를 선택하고 각 층의 재료에 대한 입력물성은 일반적으로 아스팔트 콘크리트 포장구조체에 사용되는 범위를 적용하였다. 해석 모델은 연직하중만이 작용하는 Axisymmetric으로 구성하였으며 해석에 사용된 하중은 포장도로 설계시 사용되는 원형 등분포하중으로 설정하였다. 해석은 각 층의 단면, 재료물성과 하중 그리고 공동의 규모를 변화시키며 실시하였고 아스팔트 포장체의 표면 처짐, 변형률 등을 분석하였다.

최근에 요소망의 재구성이 불필요하고 균열의 가시화에 강점을 가지는 확장유한요소법(XFEM)을 이용한 균열 해석이 많이 연구되고 있지만 주로 단일재료로 이루어진 부재의 해석에 집중되어 있다. 본 논문에서는 복합재료 부재인 철근콘크리트보의 다중균열 해석에 확장유한요소법을 적용하며 그 적용성과 타당성을 살펴보았다. 확장유한요소해석 기능이 탑재된 상용해석프로그램인 ABAQUS를 사용하여 균열해석을 수행하였으며 그 결과를 실험결과와 비교하였다. 확장유한요소법에서 인접요소에 동시에 균열이 발생할 경우 균열의 불연속성이 나타나지 않은 부가자유도 잠김 현상을 발견하였고 이에 대한 원인과 그 해결방안을 제시하였다. 또한 실험결과와 유사한 다중균열 발생을 위한 모델링 기법도 제시하였다. 확장유한요소법을 이용한 해석결과는 실험결과와 유사한 균열 양상 및 균열 간격을 보여 주었으며 하중-변위 관계에 있어서도 실험에 근접한 결과를 보여 주었다.