• Journal of the Korea Institute of Military Science and Technology
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• 제15권2호
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• pp.201-207
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• 2012

Pulsed lasers at the 613 nm and 1064 nm wavelengths on nanoseconds have been utilized to characterize the damage on Si photodiode exposed to intense illumination. Morphological damages and structural changes at sites on the photodiode irradiated during microseconds of laser pulses were analyzed by FE-SEM images and XRD patterns, respectively. The removal of oxide coating, ripple, melting marks, ridges, and crater on photodiodes were definitely observed in order of increasing the pulse intensities generated above the damage threshold. Then, the degradation in photosensitivity of the Si photodiode irradiated by high power density pulses was measured as a function of laser irradiation time at the various wavelengths. The free charge carrier and thermal diffusion mechanisms could have been invoked to characterize the damage. The relative photosensitivity data calculated using the thermal diffusion model proposed in this paper have been compared with the experimental data irradiated above the damage threshold.

• Analytical Science and Technology
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• 제7권4호
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• pp.527-540
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• 1994

The surface microstructure modification by $N^+ion$ implantation into 7050A1 alloy was investigated. Ion implantation method is to implant physically accelerated ions to the surface of a substrate. High doses of nitrogen($5{\times}10^{15}ions/cm^2$, $5{\times}10^{17}ions/cm^2$, $8{\times}10^{17}ions/cm^2$) were implanted into 7050A1 alloy using accelerating voltage of 100KeV and current density of $23.1{\mu}A/cm^2$. The implanted layers were characterized by EPMA, AES, XRD, and TEM. The experimental results were compared with computer simulation data. The results showed that AlN was formed from the surface to $4000{\AA}$ depth with Gaussian distribution and the damage region was also observed. This surface modification by $N^+ion$ implantation increased the microhardness of 7050A1 alloy surface.

• Journal of the Korean Institute of Gas
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• 제19권6호
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• pp.62-66
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• 2015

Considering for plants and structure under extreme conditions is required for the successful design, especially temperature and pressure. The ductile-brittle transition temperature (DBTT) for the materials under extreme condition needs to be considered. In this study, A-grade mild steel for the LNG carrier and offshore plant was examined by performing low-temperature Charpy V-notch (CVN) impact tests to investigate DBTT and the fracture toughness. The absorbed energy decreased gradually with the experimental temperature, which showed an upper-shelf energy region, lower shelf energy region, and transition temperature indicating DBTT. In addition, the fracture surface morphologies of the mild steels indicated ductile fractures at the upper-shelf energy level, with wide and large-sized dimples, whereas a brittle fracture surface, where was observed at the lower-shelf energy level, with both large and small cleavage facets. Based on the experimental results, ductile brittle transition temperature was estimated in about $-60^{\circ}C$.

• Journal of the Korean Wood Science and Technology
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• 제22권2호
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• pp.46-53
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• 1994

This study was conducted to investigate a feasibility of manufacturing wood fiber thermoplastic composites and to evaluate their mechanical properties. Wood fiber as a potential reinforcing filler was compounded with two thermoplastics (polypropylene and high density polyethylene) in high intensity thermokinetic plastic mixer aided with a wetting agent. It was found that wood fiber thermoplastic composites could be manufactured by injection molding process. The tensile and flexural strength of injection molded specimens were improved greatly with increasing wood fiber concentration. Tensile and flexural modulus increased proportionately with wood fiber concentration. Wood fiber provided reinforcement with thermoplastics in terms of strength and modulus. However, the percent elongation at break and energy to break were reduced with increasing wood fiber loadings. Impact strength also showed similar trend.

• Proceedings of the Korean Vacuum Society Conference
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• 한국진공학회 2009년도 제38회 동계학술대회 초록집
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• pp.105-105
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• 2010

자동차 차체부품에 적용되는 플라스틱 소재는 강도와 내마모성, 내충격성의 충분한 물성확보가 필요하며, 이에 플라스틱 소재의 기계적 특성 향상을 위해 유리 섬유가 다량 함유된 복합소재적용이 증가하고 있다. 반면 플라스틱이 고강도화함에 따라 제품 성형을 위한 사출 금형을 손상시키는 사례가 빈번하게 발생하고, 소재의 유동성 저하에 따른 사출 불량이 증가하고 있어 고강성 플라스틱 복합소재에 대응하는 고경도, 고내마모 특성이 부여된 사출 금형의 개발이 시급한 실정이다. 특히 사출 금형에 사용되는 소재는 기존 소재에 비해 우수한 내마모성과 함께 고광택을 유지하는 것이 더욱 중요해졌으며, 이에 따라 유럽, 일본과 국내 연구진에 의해 다양한 연구가 진행되고 있다. 그 중에서도 일본에서 개발되어 국내에도 소개된 래디칼 질화는 기존 질화법에 표면의 화합물 층만을 제어하는 것으로 다소의 표면 광택 효과는 있으나, 플라스틱 사출에 그대로 적용하기에는 무리가 따르므로 그 용도가 극히 제한적이다. 본 연구에서 적용한 나노 질화기술은 0.1torr 이하의 고진공에서 고밀도의 플라즈마 에너지를 발생시키는 방법으로 화합물층이 없는 나노 크기의 질화층을 소재 표면에 형성시키는 기술로서, 처리 후에도 표면의 색상 및 광택의 변화가 없는 것을 특징으로 한다. 또한 표면 경도 및 피로 특성을 향상시킴으로써 금형의 내구 수명을 향상시킬 것으로 기대된다. 본 연구에서는 KP4 금형 소재를 사용하여 플라즈마 이온 질화 시험 조건에 따른 소재의 경도 및 내마모 특성을 파악하고, 미세 조직 분석 및 XRD 분석 등을 통해 내마모 특성 향상에 대한 기본 특성을 평가하였다. 또한 인장시험을 통해 인장강도, 항복강도 및 연신율을 파악하고, 이를 토대로 고주기 피로시험을 실시함으로써 S-N curve를 얻고, 이를 통해 피로 강도 및 피로 수명에 미치는 나노 질화 처리의 영향을 파악하고자 하였다. 플라즈마 이온 질화 시험은 질소와 수소 비율($N_2:H_2$), 진공도, Screen bias voltage, Bias voltage를 변화시켰으며, 챔버 온도는 $400^{\circ}C$로 고정하였으며, 처리시간도 3시간으로 고정하였다. 질소와 수소의 비율은 3:1일 때 최고의 내마모 특성을 보였으며, 진공도는 내마모 특성에 큰 영향을 미치지 않는 것으로 관찰되었다. KP4의 초기 경도값은 약 302 Hv인 반면 최적의 나노 질화처리를 거친 시편에서는 800Hv 이상의 Vickers 경도값을 보였다. SEM 미세조직 분석과 EPMA를 통한 성분 분석을 시행한 결과 표층으로부터 약 $1.5{\mu}m$의 나노질화층을 확인할 수 있었다.

• Journal of Welding and Joining
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• 제7권3호
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• pp.19-27
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• 1989

Both the SS41 steel and the M.E.F(martensite encapsulated islands of frrite) dual phase steel made of SS41 steel by heat treatment were welded by friction welding, and then manufactured machinemade Vnotch standard Charpy impact specimens and precracked with a fatigue system at BM(base metal), HAZ(heat affected zone) and WZ(weld interface Zone). The impact test of them was performed with an instrumented impact test machine at a number of temperatures in constant loading velocity and the dynamic fracture characteristics were studied on bases of the absorbed energy, dynamic fracture toughness and fractography from the test. The results obtained are as follows; At the room temperature, the absorbed energy is HAZ.geq.WZ.geq.BM in case of the M.E.F. dual phase steel: BM.geq.HAZ.geq.WZ in case of the SS41 steel, HAZ.geq.BM.geq.WZ at the low temperature. The absorbed energy is decreased markedly with the temperature lowering; it is highly dependent on the temperature. The dynamic fracture toughness of the M.E.F. dual phase steel is HAZ.geq.WZ.geq.BM at the room temperature; BM.geq.WZ.geq.HAZ below-60.deg. C. Therefore the reliability of friction welding is uncertain at the low temperature(below-60.deg. C). The dynamic fracture toughness of the SS41 steel; HZA.geq.WZ.geq.BM at overall temperature region. The flaw formed by rotational upsetting pressure was shown y SEM; in this region. The absorbed energy per unit area and dynamic fracture toughness were low relative to other region.

• Transactions of the Korean Society of Mechanical Engineers A
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• 제35권9호
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• pp.991-997
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• 2011

This paper deals with the basic principles and procedures involved in the steam-chest molding process used for manufacturing expanded polypropylene (EPP) bead foam. Steam-chest molding is an integral process for EPP technology. However, little research has been carried out on the processing conditions for steam-chest molding this process. The characteristics of EPP foam are energy absorption, multiple-impact protection, low weight, structural strength, and durability. In this study, the steam pressure in steam-chest molding was varied to determine the optimum conditions for manufacturing EPP foam. Moreover, annealing was performed after EPP-foam molding to prevent the shrinkage of the steam-molded product. It was possible to verify the mechanism of foam shrinkage by observing the change in weight with time at different annealing temperatures. Moreover, a tensile test and scanning electron microscopy (SEM) analysis were performed to support these experimental results. The dimensional stability of each molded product was investigated at different steam pressures.

• Transactions of the Korean Society of Mechanical Engineers A
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• 제37권1호
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• pp.83-88
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• 2013

Progressive collapse is a chain reaction of failures propagating throughout a portion of a structure that is disproportionate to the original local failure. When column members are subjected to unexpected load (compression load), they will buckle if the applied load is greater than the critical load that induces buckling. The post-buckling strength of the columns will decrease rapidly, but if there is enough residual strength, the members will absorb the potential energy generated by the impact load to prevent progressive collapse. Thus, it is necessary to identify the relationship of the load-deformation of a column member in the progressive collapse of a structure up to final collapse. In this study, we carried out nonlinear FEM analysis and based on deflection theory, we investigated the load-deformation relationship of H-section steel columns when both ends were fixed.

• Journal of the Korea Academia-Industrial cooperation Society
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• 제15권5호
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• pp.2553-2558
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• 2014

Military rotorcraft should be designed taking into account the condition of the fuel cell bullet impact. The internal fluid pressure, stress of metal fitting and fuel cell, bullet kinetic energy can be included as the design factor for the fuel cell. The best way to obtain the important design data is to conduct the verification test with actual product. But, the verification test requires huge cost and long-term effort. Moreover, there is high risk to fail because of the sever test condition. Thus, the numerical simulation is required to reduce the risk of trial-and-error together with prediction of the design data. In the present study, the bullet impact simulation based on SPH(smoothed particle hydrodynamics) is conducted with the commercial package, LS-DYNA. As the result of the numerical simulation, the internal pressure of fuel cell is calculated as 350~360MPa and the equivalent stress caused by hydro-ram effect is predicted as 260~350MPa on metal fittings.

• Korean Journal of Metals and Materials
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• 제48권12호
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• pp.1047-1055
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• 2010

The objective of this study is to investigate the ballistic properties of Zr-based amorphous alloy surface composites fabricated by high-energy electron-beam irradiation. The mixture of Zr-based amorphous powders and $LiF+MgF_2$ flux powders was deposited on a pure Ti substrate, and then an electron beam irradiated this powder mixture to fabricate a one-layer surface composite. A four-layer surface composite, in which the composite layer thickness was larger than 3 mm, was also fabricated by irradiating the deposited powder mixture by an electron beam three times on the one-layer surface composite. The microstructural analysis results indicated that a small amount of fine crystalline particles were homogeneously distributed in the amorphous matrix of the surface composite layer. According to the ballistic impact test results, the surface composite layers effectively blocked a fast traveling projectile, while many cracks were formed at the composite layers, and thus the surface composite plates were not perforated. The surface composite layer containing ductile ${\beta}$ dendritic phases showed a better ballistic performance than the one without dendrites because dendritic phases hindered the propagation of shear bands or cracks.