• Title/Summary/Keyword: Petroleum oil

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Interpretation of Contaminated Soil by Complex Oil (토양 내 복합유종에 의한 오염 해석 연구)

  • Lim, Young-Kwan;Kim, Jeong-Min;Kim, Jong-Ryeol;Ha, Jong-Han
    • Journal of Soil and Groundwater Environment
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    • v.22 no.1
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    • pp.13-17
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    • 2017
  • Over 30% of domestic soil contamination has occurred via petroleum products and complex oil. Moreover, contamination by complex oil is more intense than it is by a single petroleum product species. In this study, we analyzed sectional TPH (total petroleum hydrocarbon) pattern and sectional ratio of current domestically distributed petroleum products, such as kerosene, diesel, bunker C, and lubricant and complex oils, to determine pollution characteristics of the soil. In the TPH pattern, kerosene, which is a light distillate, had an early retention time, and lubricant oil, which is a heavy distillate, had a late retention time in the gas chromatogram. In addition, we obtained a complexly contaminated soil via diesel and lubricant oil from the Navy and inspected it for its ratio of complex oil species. The inspection results showed that this soil was contaminated with 85% diesel and 15% lubricant oil. The method developed in this study could be used to determine complex petroleum sources and ratios at sites with accidentally contaminated soil.

Standardization for Quantitative Analysis of Aromatic Hydrocarbon in Oil Spill Dispersant (유처리제의 방향족 탄화수소 정량방법에 대한 표준화)

  • Cho, Jong-Hoi;Lim, Yoon-Taek;Kim, Woo-Seok;Yun, Young-Ja;Kim, Shin-Jong
    • Journal of the Korean Applied Science and Technology
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    • v.19 no.4
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    • pp.302-310
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    • 2002
  • Demand for organic analysis increase as industries are growing and many products are spreaded in the daily life. One of many products is oil spill dispersant. It was used for oil accident in the ocean. When oil spill dispersant spread at the ocean, the petroleum in the ocean is dispersed. The oil spill dispersant is made of non ionic surfactant and petroleum oil. The non ionic surfactant disperse petroleum from oil accident. The other part is petroleum oil which has aromatic hydrocarbon. Because the aromatic hydrocarbon is cancerogenic material, it directly injure animals in the ocean. This cause the second pollution in the human body. Many oil accidents still are controlled by oil spill dispersant. Therefore quality control of the oil spill dispersant become important and this also demand for the exact quantitative analysis of aromatic hydrocarbon. Hereupon the first we develop separate petroleum oil from surfactant. The second standardize analytical method of aromatic hydrocarbon in the separated petroleum oil.

Change in Physical Properties of Engine oil Contaminated with Diesel (경유 혼입에 의한 엔진오일 물성 변화)

  • Lim, Young-Kwan;Lee, Jong-Eun;Na, Yong-Gyu;Kim, Jong-Ryeol;Ha, Jong-Han
    • Tribology and Lubricants
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    • v.33 no.2
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    • pp.45-51
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    • 2017
  • Engine oil is a substance used for the lubrication of internal combustion systems. However, in some case, defects in engine systems may contaminate engine oil with fuel. Contaminated engine oil can cause problems in the normal functioning of a vehicle. In this study, we investigate the functional properties of engine oil contaminated with diesel fuel. The test results indicate that the engine oil contaminated with diesel fuel has low flash point, pour point, density, kinematic viscosity and cold cranking simulator value. The contaminated engine oil which has low plash point can cause fire and explosion accident. Furthermore, a four ball test indicates that the contaminated engine oil increases wear scar to poor lubricity. Moreover, we investigate the GC pattern using SIMDIST (simulated distillation) for determination of diesel in engine oil. The SIMDIST analytic result, diesel was detected at earlier retention time than engine oil in chromatogram. Thus the SIMDIST method can define whether engine oil is contaminated by diesel fuel or not. We can use the SIMDIST method for the diagnosis of oil condition instead of analyzing other physical properties that require many analytic instruments, large volume of oil sample and long analysis time.

A Review on the Research and Development of Oil Shale (오일셰일 연구 동향)

  • Lee, Heung-Yeon;Kim, Seon-Wook;Lee, Won-Soo;Lee, Dae-Gil
    • The Korean Journal of Petroleum Geology
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    • v.14 no.1
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    • pp.21-35
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    • 2008
  • Oil shale is a fine-grained sedimentary rock that includes organic matter called "kerogen". When the kerogen is heated at moderate temperature, petroleum-like liquids are produced through the kerogen. Although it has been reported that oil shale reserves are enormous in amount, totaling at least 2.9 trillion barrels of oil, a great deal of its reserves still remain untapped. This report presents the viability and recent state of oil shale development, which will further validate the feasibility of oil shale development as well as pertinent technology.

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Energy conversion of petroleum coke : CO2 gasification (석유 코크스의 에너지 전환 : CO2 가스화)

  • Kook, Jin-Woo;Gwak, In-Seop;Lee, See-Hoon
    • 한국연소학회:학술대회논문집
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    • 2014.11a
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    • pp.255-257
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    • 2014
  • The installation of light oil facilities or delayed cokers seems to be inevitable in the oil refinery industry due to the heavy crude oil reserves and the increased use of light fuels as petroleum products. Petroleum coke is a byproduct of oil refineries and it has higher fixed carbon content, higher calorific value, and lower ash content than coal. However, its sulfur content and heavy metal content are higher than coal. In spite of disadvantages, petroleum coke might be one of promising resources due to gasification processes. The gasification of petroleum coke can improve economic value of oil refinery industries by handling cheap, toxic wastes in an environment-friendly way. In this study, $CO_2$ gasification reaction kinetics of petroleum coke, various coals and mixing coal with petroleum coke have investigated and been compared by using TGA. The kinetics of $CO_2$ gasification has been performed with petroleum coke, 3 kinds of bituminous coal [BENGALLA, White Haven, TALDINSKY], and 3 kinds of sub-bituminous coal [KPU, LG, MSJ] at various temperature[$1100-1400^{\circ}C$].

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Analysis of Illegally Mixed Used Lube Oil in Bunker C (폐윤활유 불법혼입 C중유 물성 분석)

  • Lim, Young-Kwan;Lee, Jae-Min;Kim, Wan-Sik;Lee, Jeong-Min
    • Tribology and Lubricants
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    • v.34 no.5
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    • pp.191-196
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    • 2018
  • Bunker C is used in heavy-lift ships, furnaces, and boilers for generating heat, and power. Bunker C has only four regulations for quality standards and is rarely inspected in Korea. For these reasons, other oils such as used lubricant oil are commonly blended with Bunker C. This illegal mixture of fuel can damage the boilers, engines and affect the environment adversely. In this study, we investigate the fuel properties and perform atomic analysis of illegal Bunker C blended with used lube oil. The test results show that higher quantities of used lube oil in Bunker C have higher flash points, total acid numbers, copper corruption, solid contamination, and metal components. Further, increasing quantities of used lube oil in Bunker C cause lower viscosity, sulfur, and V content. However, adequate sample (approximately 1 L) is needed to evaluate presence of adulterants in Bunker C, we attempted the SIMDIST analysis. In the SIMDIST chromatogram, the used engine oils are detected for longer retention times than Bunker C owing to the high boiling point. We also quantitatively analyzed the lube oil content using SIMDIST.

CO2 Emission Characteristics of Bunker C Fuel Oil by Sulfur Contents (C 중유의 황 함유량에 따른 CO2 배출 특성)

  • Lim, Wan-Gyu;Doe, Jin-Woo;Hwang, In-Ha;Ha, Jong-Han;Lee, Sang-Sup
    • Journal of Korean Society for Atmospheric Environment
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    • v.31 no.4
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    • pp.368-377
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    • 2015
  • Bunker C fuel oil is a high-viscosity oil obtained from petroleum distillation as a residue. The sulfur content of bunker C fuel oil is limited to 4.0% or even lower to protect the environment. Because bunker C fuel oil is burned in a furnace or boiler for the generation of heat or used in an engine for the generation of power, carbon dioxide is emitted as a result of combustion. The objective of this study is to investigate $CO_2$ emission characteristics of bunker C fuel oil by sulfur contents. Calorific values and carbon contents of the fuels were measured using the oxygen bomb calorimeter method and the CHN elemental analysis method, respectively. Sulfur and hydrogen contents, which were used to calculate the net calorific value, were also measured and then net calorific values and $CO_2$ emission factors were determined. The results showed that hydrogen content increases and carbon content decreases by reducing sulfur contents for bunker C fuel oil with sulfur contents less than 1.0%. For sulfur contents between 1.0% and 4.0%, carbon content increases as sulfur content decreases but there is no evident variation in hydrogen content. Net calorific value increases by reducing sulfur contents. $CO_2$ emission factor, which is calculated by dividing carbon content by net calorific value, decreases as sulfur content decreases for bunker C fuel oil with sulfur contents less than 1.0% but it showed relatively constant values for sulfur contents between 1.0% and 4.0%.

A Study on the Quality Characteristics of Feedstocks for Power Bio-Fuel Oil (발전용 바이오중유용 원료물질의 품질특성 연구)

  • Jang, Eun-Jung;Lee, Mi-Eun;Park, Jo-Yong;Min, Kyung-Il;Yim, Eui-Soon;Ha, Jong-Han;Lee, Bong-Hee
    • Journal of the Korean Applied Science and Technology
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    • v.32 no.1
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    • pp.136-147
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    • 2015
  • As it carry out RPS(Renewable Portfolio Standards), power producers are using the power bio-fuel oil to meet their RPS quota. In this study, we test the quality characteristics of raw materials for power bio-fuel oil and the property changes of power bio-fuel oil by the kind of feedstocks. The power bio-fuel oil and feedstocks were analyzed for item of quality standard such as acid number, viscosity and metal contents. And it was analyzed for composition distribution by FT-IT and HPLC. Such as low priced palm oil series has high acid number and ash contents due to high free-fatty acid and metal contents. And by-product of biodiesel have a tendency of high viscosity. The fuel properties of power bio-fuel oil, such as viscosity, acid number and metal contents are correlated with the constituent and the mixing ratio of the feedstocks.

An Analysis of the Distribution Structure and Logistics System of Light Petroleum Products (석유제품의 유통구조와 물류체계 분석 - 경질제품을 대상으로 -)

  • 이희연;최윤선
    • Journal of the Economic Geographical Society of Korea
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    • v.5 no.1
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    • pp.5-24
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    • 2002
  • The purpose of this study is to analyze the distribution structure and the logistics system of light petroleum products from the spatial perspectives. The consumption structure of petroleum products has been changed since the mid 1980s. The growth rate of consumption for light products has been much faster than those of heavy products. The distribution structure of the petroleum products is hierarchically established by refining companies, agencies, and gas stations. The petroleum products agencies are distributed unevenly over the country, and the number of gas stations per one petroleum agency are very differentiated by the region. The light products are directly transported from refining factories to oil storages and then are carried to gas stations. According to the locational characteristics, oil storages which play a key role in the logistics system are categorized into three type. The first type is demand-oriented oil storages which are located near or in the large cities to supply the light petroleum products. The second type is harbors-oriented oil storages which are located within harbors. The third type is railway-oriented oil storages which are located along railway stations. In this study, the thresholds of one oil storage and one gas station are calculated based on the size of supply territory for each oil storage. The average number of population demand that allow a oil storage to stay in business is 1.9 million and average number of cars are 477,200.

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소련의 석유산업현황

  • Korea Petroleum Association
    • Korea Petroleum Association Journal
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    • no.10 s.116
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    • pp.84-86
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    • 1990
  • 이 글은 「Oil and Gas Journal, Sept 17. 1990」에 실린 A.L.Johnson의 'Soviet oil outlook less promisg in 1990's'를 옮긴 것이다. <연자 주>

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