Impact on Diesel Fuel Crystallization of Alkyl-Methacrylate—Maleic-Anhydride—Methacrylamide Terpolymers Used as Cold-Flow Improvers

Alkyl-methacrylate—maleic-anhydride—methacrylamide terpolymers (MR 1 —MA—MCNR 2 ) are some of the most widely used cold flow improvers (CFIs). The crystallization behavior of diesel fuel with added MR 1 —MA—MCNR 2 must be studied in order to develop more efficient terpolymers MC 14 —MA—MCNR 2 was sy...

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Bibliographic Details
Published in:Chemistry and technology of fuels and oils 2017-07, Vol.53 (3), p.436-443
Main Authors: Chen, Jilu, Li, Tianliang, Han, Sheng
Format: Article
Language:English
Subjects:
Alkyl groups
Chemical synthesis
Chemistry
Chemistry and Materials Science
Cold flow
Crystal growth
Crystallization
Diesel engines
Diesel fuels
Enthalpy
Eutectic temperature
Fuels
Geotechnical Engineering & Applied Earth Sciences
Heat measurement
Industrial Chemistry/Chemical Engineering
Long range order
Maleic anhydride
Methacrylamide
Mineral Resources
Particle physics
Phase transitions
Polymers
Solidification point
Terpolymers
Transmission electron microscopy
X-ray diffraction
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Summary:Alkyl-methacrylate—maleic-anhydride—methacrylamide terpolymers (MR 1 —MA—MCNR 2 ) are some of the most widely used cold flow improvers (CFIs). The crystallization behavior of diesel fuel with added MR 1 —MA—MCNR 2 must be studied in order to develop more efficient terpolymers MC 14 —MA—MCNR 2 was synthesized by the reaction of tetradecyl methacrylate (MC 14 ), maleic anhydride (MA), and methacrylamide (MCNR 2 ). The diesel fuel was filtered in situ at its cold filter plugging point (CFPP) in a manual CFPP apparatus before and after adding MC 14 —MA—MCNR 2 . The influence of the amount of polymer additive on the system fluidity was studied. The results showed that the solidification point first decreased to –34°C and then increased sharply to –17°C whereas the CFPP changed from –2 to –5°C and then remained steady as the amount of additive was increased. The crystallization behavior of the diesel fuel was studied using differential scanning calorimetry (DSC), x-ray diffraction (XRD), and transmission electron microscopy (TEM). The system enthalpy at first decreased as CFI was added to the diesel fuel and then began to increase as the amount of additive was increased further, showing that the liquid—solid phase transition was delayed whereas the crystallization started at a lower temperature than that for the base diesel fuel. The XRD pattern of the CFI confirmed the presence of complex crystalline particles with long-range order. TEM showed that addition of CFIs to diesel fuels caused fine crystals to grow unevenly and bind to each other. The wax crystals had different sizes because of a shortage of crystallization centers and binding of the particles. The CFIs acted through a eutectic mechanism.
ISSN:0009-3092
1573-8310
DOI:10.1007/s10553-017-0821-7