• 한국산학기술학회논문지
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• 제15권4호
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• pp.2324-2329
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• 2014

차내 연산 열차제어시스템은 검수고에 지상신호장치가 설치되지 않은 경우 본선 및 시험선으로 출고하였을 때에만 점검이 가능하여 업무의 효율성 저하 및 안전운행에 위해요인으로 작용한다. 열차의 운행 전 또는 운행 후 안전운행 확보를 위한 측면에서 차상 지상신호 설비 간 인터페이스 동작시험이 반드시 필요하다. 본 논문에서는 지상에서 차상시스템으로 전송되는 가상의 열차 운행정보에 따른 열차 차상신호 장치의 동작상태 확인과 차상에서 지상시스템으로 전송되는 열차 상태정보에 대한 실시간 자동 분석을 기반으로 한 열차 차상신호 인터페이스 검사시스템을 제안하여 대전도시철도 판암기지에 구축, 차상 지상신호 간 인터페이스시험 알고리즘을 검증하였다. 이에 따라 차상 열차제어시스템 점검을 위해 약 30분간의 시험선 운행이 불필요하여 업무의 효율성을 크게 향상시켰다.

• 드라이브 ㆍ 컨트롤
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• 제18권1호
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• pp.9-16
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• 2021

Overloaded vehicles increase the maintenance cost of road structures, and they are a major factor in causing damage to the roads and bridges. In addition, overloaded vehicles compromise the braking capability of the vehicle; thus, threatening the safety of the driver. In order to prevent overloading of vehicles, the government is cracking down on the roads by using a device that measures the weight of vehicles. But this process is inconvenient because the place where the equipment is installed is far away from where the cargo is loaded. Due to the limitations of these fixed weighing devices, there is a growing need for technology that can monitor vehicle weight distribution and overload conditions in real time. In this work, we develop an onboard scale that can measure the load (weight) of trucks in real time. The onboard scale consists of high sensors, a signal processing unit, and a display, and it measures the load using height-displacement of the vehicle's leaf spring suspension.

• 한국안전학회지
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• 제38권2호
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• pp.104-111
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• 2023

Rolling stock maintenance, which focuses on preventive maintenance, is typically implemented considering the potential harm that may be inflicted to passengers in the event of failure. The cost of preventive maintenance throughout the life cycle of a rolling stock is 60%-75% of the initial purchase cost. Therefore, ensuring stability and reducing maintenance costs are essential in terms of economy. In particular, private railroad operators must reduce government support budget by effectively utilizing railroad resources and reducing maintenance costs. Accordingly, this study analyzes the reliability characteristics of components using field data. Moreover, it resolves the problem of determining an economical replacement interval considering the timing of scrapping railroad vehicles. The procedure for determining the optimal replacement interval involves five steps. According to the decision model, the optimal replacement interval for the onboard signal device components of the "A" line train is calculated using field data, such as failure data, preventive maintenance cost, and failure maintenance cost. The field data analysis indicates that the mileage meter is 9 years, which is less than the designed durability of 15 years. Furthermore, a life cycle in which the phase signal has few failures is found to be the same as the actual durability of 15 years.