• 한국정보통신학회:학술대회논문집
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• 한국정보통신학회 2017년도 춘계학술대회
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• pp.255-257
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• 2017

오늘날 자동차 시장에는 다양한 IT기술이 포함된 모델들이 출시되고 있다. 대표적으로 테슬라 사의 테슬라 모델S, 구글의 무인자동차 등이 속속 등장 하고 있다. 이렇게 IT 기술이 포함된 자동차는 운전자에게 다양한 편의성을 제공하고 제공되는 편의만큼 운전자들은 다양한 혜택을 누리고 있다. 하지만 이와 반대로 전자부품의 결함이나 오류로 인해 운전자들의 안전을 위협하는 사고의 발생이 일어나고 있는 것 또한 사실이다. 이러한 사고들 가운데 자동차 급발진 사고가 존재한다. 아직까지 자동차 급발진 사고의 원인은 뚜렷하지 않으나 자기장에 의한 ECU장치가 오류를 일으켜 자동차 급발진 사고가 발생한다는 주장이 가장 신뢰 받고 있다. 하지만 한국의 경우 자동차 급발진 사고가 일어날시 자동차 제조사 측에서는 단순히 운전자의 페달 조작 미스로 인해 사고가 일어났다고 주장하는 경우가 많으며, 운전자 측에서는 그에 대해 반박할 근거가 부족해 대부분의 운전자들이 책임을 지고 있다. 따라서 본 논문에서는 자동차 급발진 사고가 운전자의 페달 조작 실수인지 자동차의 장치 결함인지를 판별할 수 있도록 운전자의 페달 조작 영상을 획득하고 엑셀, 브레이크 등 제어부에 센서를 부착하여 정밀한 데이터를 획득, 저장하고 모니터링 할 수 있는 시스템을 구현 하였다.

• 한국자동차공학회논문집
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• 제19권1호
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• pp.82-88
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• 2011

Lean combustion and exhaust emission characteristics in a ethanol fueled spark-ignited engine according to ethanol-gasoline fuel blending ratio were investigated. The test engine was $1591cm^3$ and 10.5 of compression ratio SI engine with 4 cylinders. In addition, lambda sensor system was connected with universal ECU to control the lambda value which is varied from 1.0 to 1.5. The engine performance and lean combustion characteristics such as brake torque, cylinder pressure and rate of heat release were investigated according to ethanol-gasoline fuel blending ratio. Furthermore, the exhaust emissions such as carbon monoxide (CO), unburned hydrocarbon (HC), nitrogen oxides ($NO_x$) and carbon dioxide ($CO_2$) were measured by emission analyzers. The results showed that the brake torque, cylinder pressure and the stability of engine operation were increased as ethanol blending ratio is increased. Brake specific fuel consumption (BSFC) was increased in higher ethanol blending ratio while brake specific energy consumption (BSEC) was decreased in higher ethanol blending ratio. The exhaust emissions were decreased as ethanol blending ratio is increased under overall experimental conditions, however, some specific exhaust emission characteristics were mainly influenced by lambda value and ethanol-gasoline fuel blending ratio.

• International Journal of Automotive Technology
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• 제8권4호
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• pp.437-444
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• 2007

This paper experimentally investigates the effects of oxygen-enriched air (OEA) on the running behaviors of an LPG SI engine during both start/warm-up (SW) and hot idling (HI) stages. The experiments were performed on an air-cooled, single-cylinder, 4-stroke, LPG SI engine with an electronic fuel injection system and an electrically-heated oxygen sensor. OEA containing 23% and 25% oxygen (by volume) was supplied for the experiments. The throttle position was fixed at that of idle condition. A fueling strategy was used as following: the fuel injection pulse width (FIPW) in the first cycle of injection was set 5.05 ms, and 2.6 ms in the subsequent cycles till the achieving of closed-loop control. In closed-loop mode, the FIPW was adjusted by the ECU in terms of the oxygen sensor feedback. Instantaneous engine speed, cylinder pressure, engine-out time-resolved HC, CO and NOx emissions and excess air coefficient (EAC) were measured and compared to the intake air baseline (ambient air, 21% oxygen). The results show that during SW stage, with the increase in the oxygen concentration in the intake air, the EAC of the mixture is much closer to the stoichiometric one and more oxygen is made available for oxidation, which results in evidently-improved combustion. The ignition in the first firing cycle starts earlier and peak pressure and maximum heat release rate both notably increase. The maximum engine speed is elevated and HC and CO emissions are reduced considerably. The percent reductions in HC emissions are about 48% and 68% in CO emissions about 52% and 78%; with 23% and 25% OEA, respectively, compared to ambient air. During HI stage, with OEA, the fuel amount per cycle increases due to closed-loop control, the engine speed rises, and speed stability is improved. The HC emissions notably decrease: about 60% and 80% with 23% and 25% OEA, respectively, compared to ambient air. The CO emissions remain at the same low level as with ambient air. During both SW and HI stages, intake air oxygen enrichment causes the delay of spark timing and the increased NOx emissions.

• 드라이브 ㆍ 컨트롤
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• 제12권4호
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• pp.60-70
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• 2015

A front-end loader (FEL) mounted on an agricultural tractor is one of the most commonly used implements for farm work. However, when the tractor carries material using the bucket attached to the FEL on a sloping ground, the materials can spill or roll back over the operator due to the tilted body, thereby requiring the bucket surface to remain level at a constant value regardless of varying slopes. In this study, an active system for controlling the angle of the FEL bucket on a tractor based on the real-time measurement of ground slopes was developed to enable the bucket to constantly remain level. A FEL simulator operated based on an electro hydraulic proportional valve (EHPV) was constructed in the laboratory to develop a proportional-integral-derivative (PID) controller forming a virtual electronic control unit (ECU) on the computer, which could automatically adjust the bucket angles depending on varying input angles while sending SAE-J1939 associated messages via CAN BUS to the EHPV. The different parameter values for the PID controller due to the gravity effect of the bucket were determined using a manual PID tuning method while assuming that the tractor travels on either an ascending slope or a descending slope. The developed PID control-based self-leveling system showed a mean of steady-state errors of within $1^{\circ}$ and a mean of delayed times of ~ 0.8s when the step input of $+20^{\circ}$ was given, implying that the developed system and control algorithm would be effective in maintaining the bucket angle at a certain value. Future studies include the improvement of the control algorithm to reduce such a time delay as well as the application of the developed algorithm to the FEL mounted on a tractor tested at a testing ground.

• 한국가스학회지
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• 제16권6호
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• pp.102-106
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• 2012

이 논문의 목적은 현장에서 발생되는 자동차 에어백 시스템의 고장사례를 모아 분석하고 연구하는 것이다. 첫 번째 사례에서는 에어백 시스템의 클럭 스프링과 에어 백 모듈 사이 배선 핀의 납땜부가 이탈되어, 배선 접촉불량에 의해 핀이 흔들릴 때마다 에어백의 작동불량 현상이 발생되는 것을 확인하였다. 두 번째 사례에서는 에어백 컴퓨터 내부의 단품 소자의 손상으로 인해 에어백 작동불량 현상이 발생된 것을 확인하였다. 세 번째 사례에서는 조수석 시트 벨트 프리텐셔너(pre-tensioner)의 내부 핀과 저항을 연결해 주는 납땜부 이탈로 인해 에어백 경고등이 점등된 것을 확인하였다. 네 번째 사례에서는 승용자동차가 화물자동차의 후면을 추돌하였을 때 때 범퍼는 상대편 차량보다 낮아 아래로 끼어들게 된다. 이 때 사고의 충격은 차량의 프레임부분에 전달되지 않기 때문에 충격센서가 설치된 프레임부분에 충격이 적게 전달되어 에어백이 작동하지 않은 것을 확인하였다.