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基于油酸的共聚物及其纳米杂化物改善柴油冷流性能的对比研究。

Comparative Study between a Copolymer Based on Oleic Acid and Its Nanohybrid for Improving the Cold Flow Properties of Diesel Fuel.

作者信息

El-Segaey Abeer A, El-Azabawy Ragaa E, A Mohammed Hoda, Al-Shafey Hussin I, Kamal Rasha S

机构信息

Department of Petroleum Applications, Egyptian Petroleum Research Institute, Nasr City, Cairo 11727, Egypt.

Chemistry Department, Faculty of Science, Al-Azhar University (Girls), Nasr City, Cairo 11751, Egypt.

出版信息

ACS Omega. 2023 Mar 8;8(11):10426-10438. doi: 10.1021/acsomega.2c08294. eCollection 2023 Mar 21.

DOI:10.1021/acsomega.2c08294
PMID:36969437
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10035025/
Abstract

The as-synthesized copolymer based on the prepared monomers and its nanohybrid were used for improving the cold flow of diesel fuel that has a vital role in meeting energy needs. The copolymer (AE) was created using the prepared monomers, by free radical solution polymerization of the prepared hexadecylmaleamide and octyloleate ester, and the polymer nanohybrid (NH) was created by emulsion polymerization of the same monomers with 1% nano-SiO. The chemical structures of the copolymer and its nanohybrid were proved by Fourier transform infrared spectroscopy (FTIR), H NMR, dynamic light scattering (DLS), and transmission electron microscopy (TEM). Through exploring the effect of the nanohybrid, before and after adding the dosage of the additives to the diesel fuel, the pour point temperature (PPT), rheological characteristics, and viscosity index were measured. The data were the best for the nanohybrid; the PPT decreased from -3 to -36 °C upon adding 10,000 ppm nanohybrid but decreased from -3 to -30 °C for 10,000 ppm copolymer. In addition, the efficiency of the additives was proved by viscosity-shear rate and shear rate-shear stress curves to give the apparent viscosity, which decreased from 124 cP for the blank to 15.74 and 12.8 cP for AE and NH, respectively; also, the yield stress decreased from 576 D/Cm for the blank to 541.44 and 477.9 D/Cm for AE and NH, respectively, at room temperature. The viscosity index increased from 116 for the blank to 119 and 121 for the copolymer and the nanohybrid, respectively. Polarizing optical microscopy was performed to show more tiny and separated wax upon adding the additives. The findings showed that delayed crystal precipitation and altered crystal shape with the NH and AE greatly reduced low-temperature viscosity and enhanced the cold flow characteristics of the diesel fuel.

摘要

基于所制备单体合成的共聚物及其纳米杂化物被用于改善柴油的低温流动性,这在满足能源需求方面具有至关重要的作用。共聚物(AE)是通过自由基溶液聚合所制备的十六烷基马来酰胺和油酸辛酯单体而制得,聚合物纳米杂化物(NH)则是通过相同单体与1%纳米二氧化硅的乳液聚合而制得。共聚物及其纳米杂化物的化学结构通过傅里叶变换红外光谱(FTIR)、核磁共振氢谱(H NMR)、动态光散射(DLS)和透射电子显微镜(TEM)得以证实。通过探究纳米杂化物在向柴油中添加添加剂前后的效果,对倾点温度(PPT)、流变特性和粘度指数进行了测量。纳米杂化物的数据最佳;添加10000 ppm纳米杂化物时倾点温度从-3℃降至-36℃,而添加10000 ppm共聚物时倾点温度从-3℃降至-30℃。此外,通过粘度-剪切速率和剪切速率-剪切应力曲线证明了添加剂的效率,以得出表观粘度,其分别从空白样的124 cP降至AE和NH的15.74 cP和12.8 cP;同样,在室温下屈服应力分别从空白样的576 D/Cm降至AE和NH的541.44 D/Cm和477.9 D/Cm。粘度指数分别从空白样的116增至共聚物和纳米杂化物的119和121。进行偏光显微镜观察以显示添加添加剂后更多微小且分离的蜡。研究结果表明,NH和AE使晶体沉淀延迟且晶体形状改变,极大地降低了低温粘度并增强了柴油的低温流动特性。

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