바이오디젤은 지방산 중의 일부물질이 대기중의 산소와 결합하여 유기지방산 등을 형성하며 밀도, 동점도, 전산가, 산화안정도 등의 물성 특성에 영향을 준다. 바이오디젤의 산화안정성 문제를 해결 하기 위해 바이오디젤에 다양한 산화방지제를 첨가하여 물성 변화의 특성을 분석하였다. 첨가제의 함량 이 증가함에 따라 산화안정도는 증가하는 경향을 나타내고 대부분 첨가량에 비례적으로 증가하였다. 7 종의 첨가제 중 TBHQ가 가장 우수한 성능을 보이며 propyl gallate, butyl-amine, aniline, pyrogallol 등 4종의 첨가제도 목표치인 500 ppm 첨가 시 10시간 이상의 성능을 보였다. pyrogallol이 전산가에서 품질기준에 부적합하여 첨가제로서 적절하지 않은 것으로 나타났으며, hydroquinone계열의 TBHA, DTBHQ는 산화안정도에서 품질기준은 만족하나 연구과제의 목표치인 10 시간 이상에 미치지 못하는 결과를 보여 개발 첨가제로서는 결함이 있는 것으로 판단하였다. 또한 propyl gallate도 전산가에서 품질 기준에 적합하나 500 ppm 첨가 시 수치가 높고 첨가제 증가에 따른 전산가 증가 경향이 커서 첨가제 로서 부적합한 것으로 판단하였다.

The pyrolysis of high density polyethylene(HDPE) and low density polyethylene(LDPE) was carried out at temperature between 425 and 500℃ from 35 to 80 minutes. The liquid products formed during pyrolysis were classified into gasoline, kerosene, gas oil and wax according to the petroleum product quality standard of Korea Petroleum Quality Inspection Institute. The conversion and yield of liquid products for HDPE pyrolysis increased continuously according to pyrolysis temperature and pyrolysis time. The influence of pyrolysis temperature was more severe than pyrolysis time for the conversion of HDPE. For example, the liquid products of HDPE pyrolysis at 450℃ for 65 minutes were ca. 30wt.% gas oil, 15wt.% wax, 14wt.% kerosene and 11wt.% gasoline. The increase of pyrolysis temperature up to 500℃ showed the increase of wax product and the decrease of kerosene. The conversion and yield of liquid products for LDPE pyrolysis continuously increased according to pyrolysis temperature and pyrolysis time, similar to HDPE pyrolysis. The liquid products of LDPE pyrolysis at 450℃ for 65 minutes were ca. 27wt.% gas oil, 18wt.% wax, 16wt.% kerosene and 13wt.% gasoline.

Pyrolysis of polypropylene(PP) Was performed to find the effects of the pyrolysis temperature(425, 450, 475 and 500℃) and the pyrolysis time(35, 50 and 65minutes), respectively. Conversion and liquid yield obtained during PP pyrolysis continuously increased with the pyrolysis temperature( up to 500℃) and the pyrolysis time(up to 65minutes), especially these were more sensitive to the pyrolysis time at 425℃ than other pyrolysis temperatures. Each liquid product formed during the pyrolysis was classified into gasoline, kerosene, light oil and wax according to the distillation temperature based on the petroleum product quality standard of Korea Petroleum Quality Inspection Institute. The liquid products of PP pyrolysis up to 450℃ were almost same fractions(26±3wt.% gasoline, 20±2wt.% kerosene and 23±2wt.% light oil) except wax(3~13wt.%). On the other hand, the pyrolysis of PP from 475℃ to 500℃ produced 26±3wt.% wax, 24±1wt.% gasoline, 18±1wt.% kerosene and 16±1wt.% light oil. After all, the main liquid product changed from gasoline to wax with increasing pyrolysis temperature.

Isothermal pyrolysis of high density polyethylene(HDPE), polypropylene(PP) and polystyrene(PS) was performed at 450℃, respectively. The effect of pyrolysis time on yield and product composition was investigated. Conversion and liquid yield obtained during HDPE pyrolysis continuously increased with time up to 80minutes, but those of PP and PS did not largely change after 35minutes. Each liquid product formed during the pyrolysis was classified into gasoline, kerosene, light oil and wax according to the distillation temperature based on the petroleum product quality standard of Korea Petroleum Quality Inspection Institute. The major liquid product of HDPE pyrolysis was light oiH34 wt.% based on the amount of HDPE treated) and the amounts of the other liquid ingredients(gasoline, kerosene and wax) were almost the same. On the other hand, the pyrolysis of PP produced 27 wt.% gasoline, 22 wt.% kerosene, 24 wt.% light oil and 13wt.% wax, and the pyrolysis of PS produced 56 wt.% gasoline, 12 wt.% kerosene, 9 wt.% light oil and 13 wt.% wax.

When flood disaster strikes, it is important for quick and efficient response of management organizations. So it is necessary to develop a specific EAP. FEMA and DHS present a wide range of EAP from Mitigation to recovery of disaster response in the United States. However, Republic of korea and Japan present a relatively narrow range of the EAP shortly after the disaster. Therefore, this study suggests the EAP Framework that includes a wide range consisted of Mitigation, Preparedness, Response, Recovery phases that based on the results of analyzing the United States, Japan, Republic of korea EAP.

석유화학, 발전 플랜트와 같이 대단위 면적에 대해서 효율적인 비용으로 고위험 시설물 및 설비에 대한 지속적인 모니터링을 위해 서는 무선통신기술에 대한 요구가 증가되고 있다. 그러나 현재의 지그비(Zigbee), 블루투스(Bluetooth) 와 같은 USN기술은 신뢰성 및 보안성 이 취약하여 대규모 플랜트 환경에 적용이 불가하다. 따라서 플랜트 현장에 무선기술을 도입하기 위해서는 ISA(International Society of Automation)과 같은 공신력 있는 표준화 기구에서 제안한 새로운 무선 표준기술의 적용이 필요하다. 본 연구에서는 무선 트랜스미터 기반의 석 유화학 플랜트 안전관리 시스템을 개발하였다. 이를 위해 ISA100.11a 통신모듈 및 LTE 통신모듈을 탑재한 방폭형 무선 트랜스미터를 개발하 였다. 그리고 개발 된 무선트랜스미터를 기반으로 IoT기술을 적용한 석유화학 플랜트 안전관리 시스템을 구축하였다.개발된 시스템은 다양한 방법의 테스트 및 테스트베드 구축을 통해 현장적용성을 검증하였다.

In this study, plant pipeline diagnosis system based on IoT(Internet of Things)was developed. The system consists of three parts : sensor system, omnicube system and pipeline safety assessment solutions. The plant pipeline diagnosis system was constructed in plant pipeline and was validated field applicability. Plant pipeline diagnosis system based on IoT is appropriate for plant pipeline safety monitoring.

The importance of plant pipe rack safety management has been increased. In this study, a plant safety management system based on IoT(Internet of Things) was constructed in Yeosu Industrial Complex. The purpose of this study is to investigate the structural characteristics performance and structural health monitoring of pipe rack using measured data

In this study, a plant safety management system based on IoT(Internet of Things) was developed. The system consists of three parts : smart sensing technology, wireless networking technology and smart plant safety services. The safety management system was constructed in Yeosu Industrial Complex and was validated field applicability in plant. The IoT plant safety management system is appropriate for plant industrial structures.