The Investigation of Viscometric Properties of the Most Reputable Types of Viscosity Index Improvers in Different Lubricant Base Oils: API Groups I, II, and III
Four commercial viscosity index improvers (VII) have been used to investigate the behavioral differences of these compounds in three types of universally applicable base oils. The used VIIs are structurally three types of co-polymer: ethylene-propylene, star isoprene, and two di-block styrene-isopre...
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MDPI AG
2022-01-01
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Series: | Lubricants |
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Online Access: | https://www.mdpi.com/2075-4442/10/1/6 |
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author | Seyed Ali Khalafvandi Muhammad Ali Pazokian Ehsan Fathollahi |
author_facet | Seyed Ali Khalafvandi Muhammad Ali Pazokian Ehsan Fathollahi |
author_sort | Seyed Ali Khalafvandi |
collection | DOAJ |
description | Four commercial viscosity index improvers (VII) have been used to investigate the behavioral differences of these compounds in three types of universally applicable base oils. The used VIIs are structurally three types of co-polymer: ethylene-propylene, star isoprene, and two di-block styrene-isoprene. After dissolving of different amounts of VIIs in different base oils, the kinematic viscosities at two standard temperatures were determined and the intrinsic viscosities were calculated according to Huggins method, then the effects of changes in base oil and polymer type were investigated. Intrinsic viscosities as criteria for polymer molecules sizes were found to be higher at lower temperature than at higher temperature. Dependence of intrinsic viscosity on the polymer molecular weight was observed. In the previous works, one or two types of VIIs were studied in only one type of base oil and/or solvent, not different base oils. Furthermore, different ranges of temperatures and concentrations not necessarily applied ranges were selected, but in this work, common base oils and most commercial VIIs were used and the viscometric properties were compared at two temperatures. Viscosities at these temperatures are used for determining VI and definition of lubricant’s viscosity grades. VI improvement is the main cause of VII usage. |
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issn | 2075-4442 |
language | English |
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series | Lubricants |
spelling | doaj.art-9ca03be55cda42afa3f4c6efbe3520e32023-11-23T14:25:40ZengMDPI AGLubricants2075-44422022-01-01101610.3390/lubricants10010006The Investigation of Viscometric Properties of the Most Reputable Types of Viscosity Index Improvers in Different Lubricant Base Oils: API Groups I, II, and IIISeyed Ali Khalafvandi0Muhammad Ali Pazokian1Ehsan Fathollahi2Laboratory of Behran Oil Co., Tehran 1911846611, IranLaboratory of Behran Oil Co., Tehran 1911846611, IranLaboratory of Behran Oil Co., Tehran 1911846611, IranFour commercial viscosity index improvers (VII) have been used to investigate the behavioral differences of these compounds in three types of universally applicable base oils. The used VIIs are structurally three types of co-polymer: ethylene-propylene, star isoprene, and two di-block styrene-isoprene. After dissolving of different amounts of VIIs in different base oils, the kinematic viscosities at two standard temperatures were determined and the intrinsic viscosities were calculated according to Huggins method, then the effects of changes in base oil and polymer type were investigated. Intrinsic viscosities as criteria for polymer molecules sizes were found to be higher at lower temperature than at higher temperature. Dependence of intrinsic viscosity on the polymer molecular weight was observed. In the previous works, one or two types of VIIs were studied in only one type of base oil and/or solvent, not different base oils. Furthermore, different ranges of temperatures and concentrations not necessarily applied ranges were selected, but in this work, common base oils and most commercial VIIs were used and the viscometric properties were compared at two temperatures. Viscosities at these temperatures are used for determining VI and definition of lubricant’s viscosity grades. VI improvement is the main cause of VII usage.https://www.mdpi.com/2075-4442/10/1/6viscosity indexVI improverintrinsic viscositybase oil groupsolefin copolymerstyrene-isoprene copolymer |
spellingShingle | Seyed Ali Khalafvandi Muhammad Ali Pazokian Ehsan Fathollahi The Investigation of Viscometric Properties of the Most Reputable Types of Viscosity Index Improvers in Different Lubricant Base Oils: API Groups I, II, and III Lubricants viscosity index VI improver intrinsic viscosity base oil groups olefin copolymer styrene-isoprene copolymer |
title | The Investigation of Viscometric Properties of the Most Reputable Types of Viscosity Index Improvers in Different Lubricant Base Oils: API Groups I, II, and III |
title_full | The Investigation of Viscometric Properties of the Most Reputable Types of Viscosity Index Improvers in Different Lubricant Base Oils: API Groups I, II, and III |
title_fullStr | The Investigation of Viscometric Properties of the Most Reputable Types of Viscosity Index Improvers in Different Lubricant Base Oils: API Groups I, II, and III |
title_full_unstemmed | The Investigation of Viscometric Properties of the Most Reputable Types of Viscosity Index Improvers in Different Lubricant Base Oils: API Groups I, II, and III |
title_short | The Investigation of Viscometric Properties of the Most Reputable Types of Viscosity Index Improvers in Different Lubricant Base Oils: API Groups I, II, and III |
title_sort | investigation of viscometric properties of the most reputable types of viscosity index improvers in different lubricant base oils api groups i ii and iii |
topic | viscosity index VI improver intrinsic viscosity base oil groups olefin copolymer styrene-isoprene copolymer |
url | https://www.mdpi.com/2075-4442/10/1/6 |
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