• Design & Manufacturing
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• 제16권4호
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• pp.34-39
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• 2022

Sustained economic development around the world is accelerating resource depletion. Research and development of secondary batteries that can replace them is also being actively conducted. Secondary batteries are emerging as a key technology for carbon neutrality. The core of an electric vehicle is the battery (secondary battery). Therefore, in this study, the temperature change by the heat source of the hammer and the rotational speed (rpm) of the abrasive disc of the Classifier Separator Mill (CSM) was repeatedly calculated and analyzed using the heat flow simulation STAR-CCM+. As the rotational speed (rpm) of the abrasive disk increases, the convergence condition of the iteration increases. Under the condition that the inlet speed of the Classifier Separator Mill (CSM) and the heat source value of the disc hammer are the same, the disc rotation speed (rpm) and the hammer temperature are inversely proportional. As the rotational speed (rpm) of the disc increases, the hammer temperature decreases. However, since the wear rate of the secondary battery material increases due to the strong impact of the crushing rotational force, it is determined that an appropriate rpm setting is necessary. In CSM (Classifier Separator Mill), it is judged that the flow rate difference is not significantly different in the direction of the pressure outlet (Outlet 1) right above the classifier wheel with the fastest flow rate. Because the disc and hammer attachment technology is adhesive, the attachment point may deform when the temperature of the hammer rises. Therefore, it is considered necessary to develop high-performance adhesives and other adhesive technologies.

• 대한치과보철학회지
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• 제49권2호
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• pp.114-119
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• 2011

연구 목적: 미세 인장결합강도 측정을 위한 시편 제작 시 발생하는 스트레스가 결합강도에 어떠한 영향을 미치는 지를 알아보고자 하였다. 연구 재료 및 방법: 원통 모양의 지르코니아 블럭을 다이아몬드 디스크를 이용해 디스크 형태로 자른 후 소결하였다. 소결된 지르코니아 디스크에 소성시 수축을 고려한 적당한 크기의 틀을 제작하여 LAVA ceram (3M ESPE, Seefeld, Germany) 도재를 축성한 후 소성하였다. 먼저 그룹 1은 디스크 모양의 시편을 충분히 물을 뿌려가며 다이아몬드 디스크를 이용하여 $1{\times}1{\times}7\;mm^3$의 막대기 모양으로 저속에서 절단하였다 (n = 15). 그룹 2는 같은 방법으로 $1.2{\times}1.2{\times}7\;mm^3$로 자른 후 두꺼운 다이아몬드 디스크를 이용해 $1{\times}1{\times}7\;mm^3$로 트리밍하였다 (n = 15). 그 후 특별히 제작된 지그에 각각의 시편을 core-veneer의 접착면이 오염되지 않도록 조심히 접착한 후 미세 인장결합강도 측정기 (Instron 8848, $Instron^{(R)}$ Co., Norwood, USA)를 이용하여 미세 인장결합강도를 측정하였다. 측정이 끝난 시편은 파절면을 stereomicroscope (MZ6, Leica Microsystems GmbH, Wetzlar, Germany) 로 30배 확대 관찰하여 파절의 종류를 구분하였다. 결과: 지르코니아 코어와 비니어링 세라믹 간의 평균 미세 인장결합강도는 절단만 시행한 그룹은 $28.8{\pm}7.0\;MPa$, 절단 후 트리밍을 한 그룹은 $11.0{\pm}33\;MPa$로 절단후 트리밍을 한 시편이 유의성 있게 결합강도가 낮아진 것으로 나타났다 (P=.00). 결론: 미세 인장결합강도 측정을 위한 시편 제작 시 가능한 한 스트레스를 가하지 않고 미세 시편을 제작하는 것이 중요하다고 사료된다.

• 구강회복응용과학지
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• 제22권2호
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• pp.149-159
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• 2006

Statement of problem. Porcelain repair mainly involves replacement with composite resin, but the bond strength between composite resin and all-ceramic coping materials has not been studies extensively. Purpose. The objective of this study was to investigate the influence of composite resin and ceramic etching pattern on shear bond strength of Empress2 ceramic and observe the change of microstructure of ceramic according to etching methods. Material and methods. Eighty-five cylinder shape ceramic specimens (diameter 5mm, IPS Empress 2 core materials) embeded by acrylic resin were used for this study. The ceramic were specimens divided into sixteen experimental groups with 5 specimens in each group and were etched with phosphoric acid(37%, 65%) & hydrofluoric acid (4%, 9%) according to different etching times(30s, 60s, 120s 180s). All etched ceramic surfaces were examined morphologically using SEM(scanning electron microscopy). Etched surfaces of ceramic specimens were coated with silane (Monobond-S) & adhesive(Heliobond) and built up composite resin using Teflon mold. Accomplished specimens were tested under shear loading until fracture on universal testing machine at a crosshead speed 1mm/min; the maximum load at fracture(kg) was recorded. Shear bond strength data were analyzed with one way ANOVA and Duncan tests.(P<.05) Results. Maximum shear bond strength was $30.07{\pm}2.41(kg)$ when the ceramic was etched with 4% hydrofluoric acid at 120s. No significant difference was found between phosphoric etchant group and control group with respect to shear bond strength. Conclusion. Empress 2 ceramic surface was not etched by phosphoric acid, but etched by hydrofluoric acid.

• 산업경영시스템학회지
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• 제44권3호
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• pp.10-21
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• 2021

Recently, the demand for atypical structures with functions and sculptural beauty is increasing in the construction industry. Existing mold-based structure production methods have many advantages, but building complex atypical structures represents limitations due to the cost and technical characteristics. Production methods using molding are suitable for mass production systems, but production cost, construction period, construction cost, and environmental pollution can occur in small quantity batch production. The recent trend in the construction industry calls for new construction methods of customized small quantity batch production methods that can produce various types of sophisticated structures. In addition to the economic effects of developing related technologies of 3D Concrete Printers (3DCP), it can enhance national image through the image of future technology, the international status of the construction civil engineering industry, self-reliance, and technology export. Until now, 3DCP technology has been carried out in producing and utilizing residential houses, structures, etc., on land or manufacturing on land and installing them underwater. The final purpose of this research project is to produce marine structures by directly printing various marine structures underwater with 3DCP equipment. Compared to current underwater structure construction techniques, constructing structures directly underwater using 3DCP equipment has the following advantages: 1) cost reduction effects: 2) reduction of construct time, 3) ease of manufacturing amorphous underwater structures, 4) disaster prevention effects. The core element technology of the 3DCP equipment is to extrude the transferred composite materials at a constant quantitative speed and control the printing flow of the materials smoothly while printing the output. In this study, the extruding module of the 3DCP equipment operates underwater while developing an extruding module that can control the printing flow of the material while extruding it at a constant quantitative speed and minimizing the external force that can occur during underwater printing. The research on the development of 3DCP equipment for printing concrete structures underwater and the preliminary experiment of printing concrete structures using high viscosity low-flow concrete composite materials is explained.