Blending Characteristics of Isooctene, MTBE, and TAME as Gasoline Components

Ershov, Mikhail A.; Potanin, Dmitriy A.; Таразанов, С. В.; Abdellatief, Tamer M.M.; Капустин, В. М.

doi:10.1021/acs.energyfuels.9b03914

Cited by 54 publications

(22 citation statements)

References 29 publications

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“…Engine unburned hydrocarbon (UHC) emissions depend on fuel combustion efficiency and combustion process [247,248]. According to a report, there are six mechanisms identified as the main cause of HC emissions from diesel engines [237]: (1) crevices, (2) oil layers, (3) deposits (fuel trapped or retained in the injector hole at the end of the injection process), (4) fuel and mixture (fuel-air mixture so rich or so lean that it cannot be ignited), (5) cylinder wall flame quenching, and (6) leakage of the exhaust valve.…”

Section: Effect On Hc Emissionsmentioning

confidence: 99%

A Comprehensive Review of the Properties, Performance, Combustion, and Emissions of the Diesel Engine Fueled with Different Generations of Biodiesel

Zhang

Zhong

et al. 2022

Processes

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Due to the increasing air pollution from diesel engines and the shortage of conventional fossil fuels, many experimental and numerical types of research have been carried out and published in the literature over the past few decades to find a new, sustainable, and alternative fuels. Biodiesel is an appropriate alternate solution for diesel engines because it is renewable, non-toxic, and eco-friendly. According to the European Academies Science Advisory Council, biodiesel evolution is broadly classified into four generations. This paper provides a comprehensive review of the production, properties, combustion, performance, and emission characteristics of diesel engines using different generations of biodiesel as an alternative fuel to replace fossil-based diesel and summarizes the primary feedstocks and properties of different generations of biodiesel compared with diesel. The general impression is that the use of different generations of biodiesel decreased 30% CO, 50% HC, and 70% smoke emissions compared with diesel. Engine performance is slightly decreased by an average of 3.13%, 89.56%, and 11.98% for higher density, viscosity, and cetane, respectively, while having a 7.96% lower heating value compared with diesel. A certain ratio of biodiesel as fuel instead of fossil diesel combined with advanced after-treatment technology is the main trend of future diesel engine development.

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Section: Effect On Hc Emissionsmentioning

confidence: 99%

A Comprehensive Review of the Properties, Performance, Combustion, and Emissions of the Diesel Engine Fueled with Different Generations of Biodiesel

Zhang

Zhong

et al. 2022

Processes

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“…Blends from isohexene and isooctene at different percentages with isooctane were employed in order to evaluate the influence of isohexene and isooctene (diisobutylene) on the induction period of an automotive gasoline. 16 Furthermore, Figure 7 illustrates the influence of blends from isohexene and isooctene (diisobutylene) at different percentages on induction period. When the concentrations of isooctene (diisobutylene) and isohexene with isooctane were up to 60 and 10 wt %, respectively, the oxidation stability value was above the Russian and European standard regulations of 360 min intended for an automotive gasoline.…”

Section: Resultsmentioning

confidence: 99%

“…The properties of isooctene are well-known and described in the literature. , Another less well-known isoolefin is the dimerization of propylene, and the product of this is called isohexene. Its properties are poorly described in the literature.…”

Section: Introductionmentioning

confidence: 99%

Characteristics of Isohexene as a Novel Promising High-Octane Gasoline Booster

et al. 2020

Self Cite

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Oil refineries strive to maximize the production of high-octane components using selective dimerization of olefin-containing gases. A known process is the technology for the production of diisobutylene (isooctene); the properties of this product are well-known. Another, less well-known process is the process of producing isohexene as the product from the dimerization of propylene, and its properties are poorly described in the literature. This research introduces a novel simple strategy to employ isohexene as a promising high-octane gasoline booster intended for internal combustion engines. Physicochemical characteristics of the isohexene sample were examined in agreement with all specifications of Russian and European standards (GOST 32513-2013 and EN 228:2012). The comparison between isohexene and others gasoline components, such as base automotive gasolines, MTBE, as well as TAME, has been done in order to assess the detonation resistance performance of isohexene at a concentration of 15 wt % from each gasoline component. The results demonstrated that the use of isohexene as an automotive gasoline booster has great prospects due to its high-octane rating at the degree of MTBE, in addition to isohexene owning low volatility which causes a reduction in RVP of base gasoline, but to a lesser extent than TAME. Likewise, the oxidation stability of isohexene is not high, and to overcome this problem, an antioxidant, such as agidol-1, was added. Furthermore, when the concentrations of isooctene (diisobutylene) and isohexene with isooctane were up to 60 and 10 wt %, respectively, the oxidation stability value was above the Russian and European standard regulations of 360 min intended for an automotive gasoline. Finally, the detonation resistance performance of isohexene was also estimated with various refinery gasoline products, involving blend “70”, reformate, isomerate, and fluidized catalytic cracking (FCC) naphtha, and the results illustrated that calculated isohexene blend octane numbers ranged from 104.3 to 144.5 by the research techniques and from 83 to 121.5 by the motor techniques.

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“…The dioxolane mixture has potential applications as a sustainable gasoline blending component, diesel oxygenate, and industrial solvent. On the other hand, some interesting blending compositions of isooctene, methyl tributyl ether, and ter-amyl methyl ether (TAME) were evaluated and tested in [21]. The results showed that the introduction of isooctene, which has low volatility, leads to a decrease in Reid vapor pressure (RVP) of base gasoline at the level of (TAME).…”

Section: Alcohols Ethers Esters and Ketalsmentioning

confidence: 99%

The Recent Development in Gasoline Upgrading Additives (Octane Boosters)

Radhi¹,

Radhi²

2020

Journal of Southwest Jiaotong University

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Gasoline is one of the essential propulsion fuels used for motor cars. Specified characteristics are essential for the product application. Octane grade is one of the essential characteristics of gasoline. Gasoline commonly contains additives to prevent knocking in the combustion chamber; these additives rated as an octane number to indicate gasoline quality grades. Enhancing octane numbers was the goal of the fuel industry for the last several decades. Bosting octane of gasoline is either: (i) by varying the composition via increasing the aromatic content, branched hydrocarbons, unsaturated hydrocarbons, and their combination. (ii) Another trend for upgrading the octane number is by using additives. This paper represents a review on the gasoline upgrading by using octane booster additives for 2010-2020 sourced from a literature survey of patents, publications, books, and conferences. The review covers recent development in octane boosting additives obtained from sustainable and environmentally friendly additives to replace highly polluting organometallic carbonyl compounds, including tetraethyl lead. This review finding highlights the development of new types of octane boosting additives based on oxygenated organic hydrocarbons such as alcohols, esters, ethers, acetals, and other derivatives, mainly those obtained from natural resources such as cellulose, lignin, sugars, and plant/ animal oils. The review also covers the publications on environmental safety and economic aspects.

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Blending Characteristics of Isooctene, MTBE, and TAME as Gasoline Components

Cited by 54 publications

References 29 publications

A Comprehensive Review of the Properties, Performance, Combustion, and Emissions of the Diesel Engine Fueled with Different Generations of Biodiesel

A Comprehensive Review of the Properties, Performance, Combustion, and Emissions of the Diesel Engine Fueled with Different Generations of Biodiesel

Characteristics of Isohexene as a Novel Promising High-Octane Gasoline Booster

The Recent Development in Gasoline Upgrading Additives (Octane Boosters)

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