• 열처리공학회지
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• 제21권1호
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• pp.10-19
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• 2008

To investigate the effect of ultrasonic nano-crystalline surface modification (UNSM) treatment on rolling contact fatigue and residual stress properties of bearing steels, this paper carried out a rolling contact fatigue test, measured residual stress and retained austenite, performed a wear test, observed microstructure, measured micro hardness, and analyzed surface topology. After the UNSM treatment, it was found that the surface became minute by over $100{\mu}m$. The micro surface hardness was changed from Hv730~740 of base material to Hv850~880 with about 20% improvement, and hardening depth was about 1.3 mm. The compressive residual stress was measured as high as -700~-900 MPa, and the quantity of retained austenite was reduced to 27% from 34%. The polymet RCF-6 ball type rolling contact fatigue test showed over 4 times longer fatigue lifetime after the UNSM treatment under 551 kgf load and 8,000 rpm. In addition, this paper observed the samples, which went through the rolling contact fatigue test, with OM and SEM, and it was found that the samples had a spalling phenomenon (the race way is decentralized) after the UNSM treatment. However, before the treatment, the samples had excessive spalling and complete exploration. Comparison of the test samples before and after the UNSM treatment showed a big difference in the fatigue lifetime, which seems to result from the complicated effects of micro particles, compressive residual stress, retained austenite, and surface topology.

• Tribology and Lubricants
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• 제13권2호
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• pp.96-104
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• 1997

This paper was focused on the wear characteristics of ion-nitrided metal and with ion-nitride processing, which is basically concerned with the effects of carbon content in workpiece and added carbon content gas atmosphere on the best wear performance. Increased carbon content in workpiece increases compound layer thickness, but decreases diffusion layer thickness. On the other hand, a small optimal amount of carbon content in gas atmosphere increase compound layer thickness as well as diffusion layer thickness and hardness. Wear tests show that the compound layer of ion-nitrided metal reduces wear rate when the applied wear load is small. However, as the load becomes large, the existence of compound layer tends to increase wear rate. Compressive residual stress at the compound layer is the largest at the compound layer, and decreases as the depth from the surface increases. It is found in the analysis that under small applied load, the critical depth where voids and cracks may be created and propagated is located at the compound layer, so that the adhesive wear is created and the existence of compound layer reduces the amount of wear. When the load becomes large, the critical depth is located below the compound layer and delamination, which may explained by surface deformation, crack nucleation and propagation, is created and the existence of compound layer increases wear rate. For the compound layer, at added carbon contents of 0 percent and 0.5 at. percent, the $\varepsilon$ monophase is predominant. But at 0.7 at. percent added carbon, the $\varepsilon$ monophase formation tends to be severely inhibited and r' and $Fe_3C$ polyphase formation becomes dominant. This increased hard $\varepsilon$ phase layer was observed to be more beneficial in reducing friction and wear.

• 소성∙가공
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• 제24권3호
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• pp.205-211
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• 2015

The current investigation was performed to study sliding-wear-rate deviation (wear-rate data scatter) in carbon steels with various microstructures. Pure iron, 0.2 wt. % C steel, 0.45 wt. % C steel, and bearing steel (AISI52100) were used for the investigation. These steels possess different microstructures. Microstructures of the pure iron, two carbon steel and the bearing steel were full ferrite, ferrite + pearlite and full pearlite, respectively. Depending on the carbon content, the carbon steel had different pearlite-volume fractions. Dry sliding wear tests of the steel were conducted using a ball-on-disk wear tester at a sliding speed of 0.1 m/s using a bearing ball (AISI52100) as a counterpart. Applied load and sliding distance were 100 N and 300 m, respectively. More than three (up to twelve) tests were conducted for each steel under the same conditions, and the mean deviations in the wear rate of the steel (microstructure) were compared. The wear-rate deviation in the steel with ferrite + pearlite microstructure was higher than that with ferrite microstructure, and the deviation decreased with the increase of pearlite volume fraction. The pure iron and the bearing steel specimens showed much less deviation. The high deviation observed from the ferrite + pearlite steel was attributed to irregular subsurface-crack nucleation and growth at the interface between the two micro constituents (ferrite and pearlite) during the wear test.

• 마이크로전자및패키징학회지
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• 제25권1호
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• pp.29-33
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• 2018

미래의 전자 기기는 접고 굽히고 둘둘 마는 등 다양한 변형에도 전기적 안정성을 가지는 기기들로 발전할 것이며, 반복 기계적 변형 하에서 유연 전자 소자의 전기적 신뢰성 확보가 중요한 이슈로 부각되고 있다. 본 연구에서는 반복 롤링 변형이 가능한 장치를 개발하고 이를 이용해, 현재 유연 전자 소자용 투명 전극 소재로 가장 널리 사용 중인 ITO 박막의 반복 롤링 실험 중 전기적 특성 변화를 연구하였다. 전극과 기판의 상대적 위치에 의해 인장 응력과 압축 응력이 가해지므로, Outer rolling 및 Inner rolling의 두 조건에서 실험을 진행하여 응력 상태에 따른 전기적 신뢰성 차이를 연구하였다. 그 결과, inner rolling의 경우 outer rolling에 비해 더 우수한 전기적 안정성을 나타냈으며, 이는 inner bending에 의한 압축 응력 상태의 경우 crack closing 변형에 따라 전기저항이 상대적으로 낮게 증가하는 것으로 해석된다. 또한, 롤링 바퀴 수에 따른 피로 저항성을 실시간 전기저항 측정을 통해 연구하였으며, 그 결과, 롤링 바퀴 수가 증가할수록 피로 파괴 영역이 증가하므로 전기저항이 더욱 크게 증가하는 것으로 나타났다. 본 연구를 통해 롤링 조건에서 유연 전극의 신뢰성에 대해 이해하고, 이는 향후 유연 전자소자용 고신뢰성 전극 개발에 활용 될 수 있을 것으로 기대한다.