Browsing by Author "Kapustin, Vladimir M"
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Item Advanced Progress and Prospects for Producing High-Octane Gasoline Fuel toward Market Development: State-of-the-Art and Outlook(American Chemical Society, 2023-11) Abdellatief, Tamer M. M; Ershov, Mikhail A; Savelenko, Vsevolod D; Kapustin, Vladimir M; Makhova, Ulyana A; Klimov, Nikita A; Chernysheva, Elena A; Aboul-Fotouh, Tarek M; Abdelkareem, Mohammad Ali; Mustafa, Ahmad; Olabi, A. GThe development of oil refining in advanced nations is mostly focused on low-carbon fuel. Similar efforts are being made to improve the fuel efficiency of internal combustion engines, which will result in lower exhaust emissions. Furthermore, by assessing the indicated trends in engine building, it is important for fuel manufacturers to understand how the requirements for gasoline quality indicators will change, primarily for its knock resistance. The aim of the current comprehensive article is to study the state-of-the-art review emphasizing recent progress and prospects for producing high-octane gasoline fuel toward market development. The market for branded gasoline and multifunctional additives, involving friction modifiers, corrosion inhibitor components, as well as detergent components is presented. Furthermore, market development trends and quality requirements for motor gasoline, involving antiknocking characteristics and gasoline oxygenated compounds as additives, are exhibited. Besides, perspective gasoline engine technologies, including different types of engines, are declared. The formulation of effective gasoline surrogates is a challenging task due to advanced combustion strategies, engine design, and variable operating conditions in spark-ignition engines. The extensive development of direct injection and turbocharging technologies is constrained by the actual compression ratio of engines. Likewise, an increase in the knock resistance of the produced gasoline would further increase the compression ratio and efficiency of new internal combustion engines. © 2023 American Chemical Society.Item Low carbon energy technologies envisaged in the context of sustainable energy for producing high-octane gasoline fuel(Elsevier Ltd., 2023-02) Abdellatief, Tamer M.M; Ershov, Mikhail A; Kapustin, Vladimir M; Chernysheva, Elena A; Mustafa, AhmadWith increasing issues, concerning the depletion of petroleum fossil fuels and the environment, various re- searchers have examined an innovative and appropriate surrogated fuel. Various advanced countries maximize alternative fuel to fight against atmospheric alteration. In this perspective, the current research aims to introduce low-carbon energy technologies envisaged in the context of sustainable energy for generating high-octane gas- oline fuel. Four gasoline feedstocks were selected for investigation in the present research as materials. Partic- ularly, these components are gasoline additives, such as bioethanol (E), di-isobutylene (DIB), and dimate (D) with baseline motor gasoline stream, like hydrocracked gasoline (HG). To execute the present work, several gasoline fuels and experimental facilities that correspond to European standard regulations were employed. Additionally, the composition of the optimum sample was 50 % of hydrocracked gasoline, 35 % of bioethanol, 10 % of di-isobutylene, as well as 5 % of dimate. Therefore, the optimal gasoline blend provided high-octane gasoline RON 98 with great ecological characteristics. Besides, the experimental results displayed that the antidetonation performance can be varied consecutively as bioethanol > di-isobutylen > dimate > hydrocracked gasoline by octane number. What’s more, the simultaneous incorporation of bioethanol, di-isobutylene, and dimate changed antiknock characteristics, in terms of vapor pressure, the distillation curve, as well as the density in a route that could impact engine operation. Conclusively, the acquired results stated that it might be merits to utilize bioethanol to provide the added value of hydrocracked gasoline, di-isobutylene, and dimate to establish an innovative high gasoline product in RON of 98 considered the restrictions for high olefins contenItem A unifying methodology for gasoline-grade biofuel from several renewable and sustainable gasoline additives(Institution of Chemical Engineers, 2024-08) Abdellatief, Tamer M.M; Ershov, Mikhail A; Abdelkareem, Mohammad Ali; Mustafa, Ahmad; Jamil, Farrukh; Kapustin, Vladimir M; Makhova, Ulyana A; Chernysheva, Elena A; Savelenko, Vsevolod D; Klimov, Nikita A; Olabi, Abdul GhaniTo increase thermal efficiency and decrease greenhouse gas emissions, the research of fuel formulation and combustion processes for internal combustion engines has drawn attention from all across the world. The aim of the current study is divided into two subsections. The first of this section's two subsections is to thoroughly assess the impacts of physical and chemical properties of different mixtures of several gasoline octane boosters on low petroleum hydrocarbon products. Additionally, the creation of bio-gasoline fuels with high environmental octane ratings using various combinations of specific gasoline octane boosters is covered in the second of this section's two subsections. The gasoline additives included di-isobutylene (DIB), methyl tertiary butyl ether (MTBE), and isopropanol (IP). Furthermore, low petroleum gasoline fractions involved naphtha from natural gas condensate (N), light straight-run naphtha (LSRN), and hydrocracked gasoline (HG). In the current study, those renewable and sustainable gasoline additives and low petroleum hydrocarbon gasoline fractions were blended and examined as an innovative gasoline biofuel for gasoline engines for the first time. The experimental findings indicated that the octane number might be used to vary the antidetonation performance in the following order: ethanol> MTBE > Di-isobutylene > isopropanol > dimate > light straight-run naphtha > hydrocracked gasoline > naphtha from natural gas condensate > heavy straight run naphtha. Five different blends were applied and the physical and chemical characterizations of each blend separately in detail were investigated. The experimental results reported that octane numbers by research method for samples one, two, three, four, and five were 90.3, 92, 95.3, 98, and 100.2, respectively.