Revealing the Molecular Interaction between CTL Base Oil and Additives and Its Application in the Development of Gasoline Engine Oil

Chunfeng Zhang; Xiaojun Zhang; Qiang Yan; Liyang Wang; Xiangqiong Zeng

doi:10.3390/lubricants12080275

Lubricants (Jul 2024)

Revealing the Molecular Interaction between CTL Base Oil and Additives and Its Application in the Development of Gasoline Engine Oil

Chunfeng Zhang,
Xiaojun Zhang,
Qiang Yan,
Liyang Wang,
Xiangqiong Zeng

Affiliations

Chunfeng Zhang: Shanxi Lu’an Taihang Lubrication Technology Co., Ltd., Changzhi 046200, China
Xiaojun Zhang: Shanxi Lu’an Taihang Lubrication Technology Co., Ltd., Changzhi 046200, China
Qiang Yan: Shanxi Lu’an Taihang Lubrication Technology Co., Ltd., Changzhi 046200, China
Liyang Wang: Shanxi Lu’an Taihang Lubrication Technology Co., Ltd., Changzhi 046200, China
Xiangqiong Zeng: School of Materials and Chemistry, University of Shanghai for Science and Technology, Shanghai 200093, China

DOI: https://doi.org/10.3390/lubricants12080275
Journal volume & issue: Vol. 12, no. 8
p. 275

Abstract

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In order to improve fuel economy to meet the standard for passenger car oil, a new formulation with good viscosity–temperature performance for gasoline engine oil is required. In this study, coal-to-liquid (CTL) base oil, with a high viscosity index and good low-temperature performance, was selected as the base oil to develop the gasoline engine oil. A systematic study on the molecular interaction between the CTL base oil and the viscosity index improver (VII), including three kinds of hydrogenated styrene diene copolymers (HSD-type) and four kinds of ethylene propylene copolymers (OCP-type), was conducted. It was found that in general, in CTL base oil, the HSD-type VII exhibited a much higher viscosity index, a significantly lower shear stability index, a higher thickening ability, and a lower cold-cranking simulator (CCS) viscosity than that of OCP-type VII. Moreover, when comparing CTL base oil with mineral oil 150N, the combination of CTL base oil and the VII displayed a lower CCS viscosity than that of mineral oil, suggesting it had better low-temperature performance and was able to quickly form a protective oil film on the surface, which was beneficial for the cold start. The functional group distribution state of the VII in base oil was analyzed using synchrotron radiation micro-infrared microscope (SR Micro-IR) technology, which revealed that HSD-1 had a better molecular interaction with CTL6 than 150N because of the better uniformity of the C=C group distribution. Based on this, a SP 0W-20 gasoline engine oil was developed by the combination of CTL base oil and the HSD-1 viscosity index improver, together with an additive package, a polymethacrylate pour point depressant, and a non-silicone defoamer, which showed excellent low-temperature performance, thermal oxidation stability, and detergency performance compared to the reference oil.

Published in Lubricants

ISSN: 2075-4442 (Online)
Publisher: MDPI AG
Country of publisher: Switzerland
LCC subjects: Science
Website: http://www.mdpi.com/journal/lubricants

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