• Title/Summary/Keyword: Research Octane Number

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The Spray and Combustion Characteristics by the Ratio of Cetane Number Enhancing Additives in Diesel (세탄가 향상 혼합 연료에 따른 디젤 연료의 분무 및 연소특성에 관한 연구)

  • Kim, J.H.;Lee, S.W.;Lee, H.S.;Choi, J.H.;Lee, Y.C.;Cho, Y.S.
    • Journal of ILASS-Korea
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    • v.14 no.2
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    • pp.84-89
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    • 2009
  • In this research, combustion and spray characteristics were investigated experimentally in a constant volume chamber by applying different composition rates of octane number in diesel fuel to a common-rail system. For the visualization, the experiment was carried out under different injection pressures and different cetane number. The test was done by three different types of diesel fuels, the different composition rates of cetane number in diesel fuel and HBD. In summary, this research aims to investigate the combustion characteristics in the application of fuels and compare the results with performance of conventional diesel fuel. This experimental data may provide with fundamentals of the development of diesel engines in future.

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EFFECT OF ADDITIVE ON THE HEAT RELEASE RATE AND EMISSIONS OF HCCI COMBUSTION ENGINES FUELED WITH RON90 FUELS

  • Lu, X.C.;Ji, L.B.;Chen, W.;Huang, Z.
    • International Journal of Automotive Technology
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    • v.8 no.1
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    • pp.1-7
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    • 2007
  • The effect of the di-tertiary butyl peroxide (DTBP) additive on the heat release rate and emissions of a homogeneous charge compression ignition (HCCI) engine fueled with high Research Octane Number (RON) fuels were investigated. The experiments were performed using 0%, 1%, 2%, 3%, and 4% (by volume) DTBP-RON90 blends. The RON90 Fuel was obtained by blending 90% iso-octane with 10% n-heptane. The experimental results show that the operation range was remarkably expanded to lower temperature and lower engine load with the DTBP additive in RON90 fuel. The first ignition phase of HCCI combustion was observed at 850 K and ended at 950 K while the hot ignition occurred at 1125 K for all fuels at different engine working conditions. The chemical reaction scale time decreases with the DTBP addition. As a result, the ignition timing advances, the combustion duration shortens, and heat release rates were increased at overall engine loads. Meanwhile, the unburned hydrocarbon (UHC) and CO emissions decrease sharply with the DTBP addition while the NOx emissions maintain at a lower level.

Study on the Characterization of Oxidative Degradation of Automotive Gasoline (자동차용휘발유의 산화열화특성 규명 연구)

  • Min, Kyong-Il;Yim, Eui Soon;Jung, Chung-Sub;Kim, Jae-Kon;Na, Byung-Ki
    • Korean Chemical Engineering Research
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    • v.51 no.2
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    • pp.250-256
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    • 2013
  • Gasoline generates organic acid and polymer (gum) by hydrocarbon oxidation depending on the storage environment such as temperature and exposure to sunlight, which can cause metal corrosion, rubber and resin degradation and vehicle malfunction caused by accumulation in fuel supply system. The gasoline which has not been used for a long time in bi-fuel (LPG-Gasoline) vehicle causes problems, and low octane number gasoline have evaporated into the field, but the exact cause has not been studied yet. In this study, we suggest a plan of quality management by investigating the gasoline oxidation behavior. In order to investigate the oxidation behavior of gasoline, changes of gasoline properties were analyzed at various storage conditions such as storage time, storage vessel type (vehicle fuel tank, PE vessel and Fe vessel) and storage circumstances (sunlight exposure and open system, etc.). Currently distributing gasoline and bioethanol blended fuel (blended 10%) were stored for 18 weeks in summer season. The sample stored in PE vessel was out of quality standard (octane number, vapor pressure, etc.) due to the evaporation of the high octane number and low boiling point components through the vessel cap and surface. Especially, the sunlight exposure sample stored in PE vessel showed rapid decrease of vapor pressure and increase of gum. Bioethanol blended fuel showed similar results as gasoline.

The Measurement of the Explosion Limit and the Minimum Oxygen Concentration of Gasoline According to Variation in Octane Number (옥탄가 변화에 따른 가솔린의 폭발한계 및 최소산소농도 측정)

  • Kim, Won-Kil;Kim, Jung-Hun;Ryu, Jong-Woo;Choi, Jae-Wook
    • Korean Chemical Engineering Research
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    • v.55 no.5
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    • pp.618-622
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    • 2017
  • Gasoline is a widely used product as a source for energy in homes, the automotive industry, and for industrial power generation, and it is also a product with a high risk of fire and explosion. In this study, to examine the risk for explosion for gasoline, PG, MG and RG, which are categorized according to octane number, were used as test specimens to measure their explosion limit according changes in oxygen concentration. The explosion limit for 21% oxygen concentration in air were confirmed to be 1.5~10.9%, 1.4~8.1%, and 1.3~7.6%, respectively, and the MOC for each of the test sample were confirmed to be 10.9%. The explosion limit measured in the test performed in this study confirmed between a 1.2%~7.6% wider explosion limit for the currently accepted MSDS for gasoline, and therefore it is considered that the results of this study can provide significant reference for preventing fires and explosions for process used gasoline.

A Computational Study on DME HCCI Combustions Characteristics with Methanol Concentrations (DME HCCI 운전조건에서 Methanol 분율에 따른 HCCI엔진연소 특성에 관한 수치해석적 연구)

  • Lee, Hyowon;Lim, Ocktaeck;Park, Kyuyeol;Cho, Wonjun;Baek, Youngsoon
    • Journal of Hydrogen and New Energy
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    • v.25 no.1
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    • pp.79-86
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    • 2014
  • In Dimethyl Ether (DME) indirect production processes, DME have a reforming process to separate Methanol. DME has a high cetane number and Methanol has a high octane number. Each fuel has a different combustion characteristics and reactivity. So, this paper was investigated on the combustion characterisitics of DME and Methanol. Basically, Methanol has a effect of retarding ignition. However, Within 10% of total carbon mole number in DME, Methanol slightly changed the onset timing of Low Temperature Reaction (LTR) with increasing thermal-ignition preparation range. It means that controlling combustion phasing of DME can be possible without eliminated LTR. In case of IMEP, the ranges.

Analysis of Component for Determining Illegal Gasoline (가짜휘발유 판정을 위한 성분 분석)

  • Lim, Young-Kwan;Won, Ki-Yoe;Kang, Byung-Seok;Park, So-Hwi;Jung, Seong;Go, Young-Hoon;Kim, Seong-Soo;Jung, Gil-Hyoung
    • Tribology and Lubricants
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    • v.36 no.3
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    • pp.161-167
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    • 2020
  • Petroleum is the most used energy source in Korea with a usage rate of 39.5% among the available 1st energy source. The price of liquid petroleum products in Korea includes a lot of tax such as transportation·environment·energy tax. Thus, illegal production and distribution of liquid petroleum is widespread because of its huge price difference, including its tax-free nature, from that of the normal product. Generally, illegal petroleum product is produced by illegally mixing liquid petroleum with other similar petroleum alternatives. In such case, it is easy to distinguish whether the product is illegal by analyzing its physical properties and typical components. However, if one the components of original petroleum product is added to illegal petroleum, distinguishing between the two petroleum products will be difficult. In this research, we inspect illegally produced gasoline, which is mixed with methyl tertiary butyl ether (MTBE) as an octane booster. This illegal gasoline shows a high octane number and oxygen content. Further, we analyze the different types of green dyes used in illegal gasoline through high performance liquid chromatography (HPLC). We conduct component analyses on the simulated sample obtained from premium gasoline and MTBE. Finally, the illegal gasoline is defined as premium gasoline with 10% MTBE. The findings of this study suggest that illegal petroleum can be identified through an analytic method of components and simulated samples.

A Study on Performance and Exhaust Gas Prediction in dedicated CNG Engine (CNG 전소기관의 성능 및 배출가스 예측에 관한 연구)

  • 오용석;김경배;한영출
    • Transactions of the Korean Society of Automotive Engineers
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    • v.6 no.4
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    • pp.178-185
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    • 1998
  • To reduce the particulate matter and nitrogen oxides from diesel engine, many studies are proceeding and being accomplished practically. In this situation CNG engine has important meaning both as a clean fuel and an alternative energy. In order to present the direction and application of CNG, we simulated various operating conditions, that is, spark timing, compression ratio and fuel composition etc. Thus we try to understand how those affect performance and exhaust characteristics. The simulation program results found that the optimum combustion start angle was 21$^{\circ}$ at 1800rpm and fuel composition affects performance and emissions, also we could understand the formation of emission as crank angle is changed.

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The Effect of N-butane and Propane on Performance and Emissions of a SI Engine Operated with LPG/DME Blended Fuel (LPG/DME 혼합연료를 사용하는 전기점화 기관에서 LPG 성분이 엔진 성능 및 배기특성에 미치는 영향)

  • Lee, Seok-Hwan;Oh, Seung-Mook;Choi, Young;Kang, Kern-Yong;Choi, Won-Hak;Cha, Kyoung-Ok
    • Transactions of the Korean Society of Automotive Engineers
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    • v.17 no.1
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    • pp.35-42
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    • 2009
  • In this study, a spark ignition engine operated with LPG and DME blended fuel was studied experimentally. The effect of n-butane and propane on performance and emissions of a SI engine fuelled by LPG/DME blended fuel were examined. Stable engine operation was achieved for a wide range of engine loads with propane containing LPG/DME blended fuel compare to butane containing LPG/DME blended fuel since octane number of propane was much higher than that of butane. Also, engine output operated with propane containing blended fuel was comparable to pure LPG fuel operation. Engine output power was decreased and break specific fuel consumption (BSFC) was increased with the blended fuel since the energy content of DME was much lower than that of LPG. Considering the results of engine output power, bsfc, and exhaust emissions, the propane containing LPG/DME blended fuel could be used as an alternative fuel for LPG.

Environmental Risk Assessment of MTBE (MTBE의 환경위해성평가)

  • Park, Jeong-Gue
    • Journal of Environmental Policy
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    • v.1 no.1
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    • pp.75-90
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    • 2002
  • Methyl tertiary-butyl ether(MTBE) is used as an octane enhancer in gasoline. MTBE can enter the environment at any stage in the production, storage, and transport of undiluted MTBE or MTBE-blended gasoline. Although data on concentrations of MTBE in the environment are not available, modelling of fate of MTBE has provided predictions for concentrations of MTBE in the various media to which humans and other organisms may be exposed. Many individuals do not taste or smell MTBE at the $5{\mu}g/L$ level, and thus may be exposed to higher concentrations for a significant amount of time. MTBE exposure through inhalation is likely to be below health-threatening levels, except for occupational workers such as gasoline station attendants and auto mechanics. It should be stressed, however, that there are important data gaps in our understanding of the acute and chronic toxicity of MTBE. Little or no research concern including being conducted that directly addresses these issues. Rather than any immediate ban on MTBE, I recommend consideration of phasing out MTBE in USA and other countries. During the transition phase, a number of policies are suggested to reduce the risk of using MTBE. One of these policies is that the state should invest in a research program. Such research should, for example, examine effective alternatives for motor vehicle fuels, and detect concentrations of MTBE in ambient air, water, and other environmental media.

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Development of Gasoline Engine Renewal CNG Generator and a Study on Exhaust Gas Characteristics of Equivalent Diesel Engine (가솔린 엔진개조 CNG 발전기 개발과 동급 디젤엔진의 배출가스 특성 연구)

  • Lee, Jung-Cheon;Kim, Ki-Ho;Lee, Jung-Min;Park, An-Young
    • Journal of Power System Engineering
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    • v.22 no.6
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    • pp.74-79
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    • 2018
  • Compressed natural gas has a high octane number and low particulate emission characteristics as compared with petroleum-based fuels, so it can respond to exhaust gas regulations positively. A natural gas engine has been introduced to improve the quality of the atmosphere, a diversity of fuel, a stable supply, and it has widely been used in city buses and garbage trucks. Recently, the natural gas engine has received attention by overcoming the disadvantage of the theoretical air-fuel ratio method through the development of EGR cooler and engine parts with the development of LP-EGR technology. In this study, we try to develop the cogeneration system that can simultaneously generate electric power and heat by remodeling the gasoline engine to the mixer type CNG engine. As a result, it was able to reduce the NOx (approximately 77%) compared to the diesel engines with same displacement.