Structure and composition of n-pentane and n-heptane asphaltene from different properties crude
-
摘要: 采用SARA四组分分离方法得到石蜡基玉门常压渣油和环烷基马瑞常压渣油的C5和C7沥青质,结合 1H-NMR、FT-IR、VPO及元素分析等方法,对沥青质的结构组成和官能团形态进行表征,考察不同基属渣油沥青质以及不同沉淀剂所得沥青质的结构组成差异。结果表明,四种沥青质的官能团类型基本一致,但分子结构单元存在一定差异,相比于环烷基马瑞沥青质,石蜡基玉门沥青质的分子结构单元更大,芳碳分率较小,但HAU/CA值也较小,分子缩合程度更高;随沉淀剂碳链增长,沥青质收率减少(相同原料的正庚烷沥青质收率约为正戊烷沥青质的80%左右),H/C降低,平均相对分子量升高,C7沥青质具有更高的芳碳率
$ f $ A和更多的结构单元数。各类沥青质中均存在较多的饱和结构,饱和碳分率约为0.5。Abstract: C5 and C7 asphaltene were separated from paraffin base Yumen atmospheric residue and naphthene base Merey atmospheric residue by n-pentane and n-heptane respectively using the method of SARA. The structure parameters and functional groups analyzed and characterized systematically by VPO, 1H-NMR, FT-IR and elemental analysis, in order to comparative studied the differences in asphaltene structure of different residues and asphaltene obtained by different precipitants. The results showed that there was consistent in the functional groups of different asphaltenes basically, but there was some differences in the unit structure of different asphaltene. Yumen paraffinic asphaltenes had significantly higher molecular weight, smaller HAU/CA value and higher condensation degree than Merey naphthenic asphaltenes. With the increase of carbon chain of precipitants, the yield (the yield of n-heptane asphaltene was about 80% of n-pentane for the some feedstook) and the H/C of asphaltene decreased, the molecular weight of asphaltene increased. C7 asphaltenes had higher aromatic carbon ratio ($ f $ A) and more structure units than C5 asphaltene. More saturated structure existed in various asphaltenes and the saturate carbon fraction was about 0.5.-
Key words:
- asphaltene /
- precipitants /
- crude properties /
- structure & composition /
- functional group
-
表 1 原料性质
Table 1 Properties of residue
Item YMAR MRAR Density (20℃)/(kg·m−3) 898.5 986.2 Viscosity (100℃)/(mm2·s−1) 10.13 130.70 Carbon residue w/% 5.21 13.40 SARA w/% Saturate 49.62 38.04 Aromatic 24.07 29.80 Resin 15.56 19.34 Asphaltene 10.75 12.81 Elemental w/% C 86.30 84.76 H 12.60 10.84 S 0.77 3.74 N 0.28 0.51 H/C(mol ratio) 1.75 1.53 
下载: 导出CSV
表 2 沥青质收率
Table 2 Yield of asphaltenes
Asphaltene C5YM C7YM C5MR C7MR Yield w/% 13.58 10.75 16.11 13.23 Note: C5: n-pentane asphaltene; C7: n-heptane asphaltene; YM: Yumen atmospheric residue; MR: Merey atmospheric residue
下载: 导出CSV
表 3 沥青质的元素组成及平均相对分子质量
Table 3 Element composition and molecular weight of asphaltene
Asphaltene Vitimate analysis w/% H/C
(mol ratio)M C H S N C5YM 85.58 8.54 2.10 1.13 1.20 4468 C7YM 86.41 7.99 2.42 1.93 1.11 4735 C5MR 83.40 8.08 4.70 1.53 1.16 3561 C7MR 82.94 7.71 4.81 1.73 1.12 4612
下载: 导出CSV
表 4 沥青质中不同化学位移的氢含量
Table 4 Different H content of asphaltene
Item C5YM C7YM C5MR C7MR Hγ w/% 30.22 17.08 29.43 32.31 Hβ w/% 52.85 59.77 49.49 42.75 Hα w/% 4.86 14.97 6.01 9.82 HA w/% 12.08 8.17 15.07 15.11
下载: 导出CSV
表 5 沥青质结构参数
Table 5 Structural parameters of asphaltene
Structural parameter C5YM C7YM C5MR C7MR CT 318.38 340.68 177.84 318.5 HT 378.58 375.36 205.31 352.8 CA 151.94 168.35 90.66 168.77 RA 49.31 54.78 28.89 54.92 RT 54.12 69.82 30.86 58.72 RN 4.81 15.04 1.97 3.79 RA/RN 10.25 3.64 14.64 14.49 CN 14.43 45.12 5.92 11.37 CP 152.01 127.21 81.26 138.36 HAU/CA 0.36 0.35 0.41 0.42 $ f $A 0.48 0.49 0.51 0.53 $ f $N 0.05 0.13 0.03 0.04 $ f $p 0.48 0.37 0.46 0.43 σ 0.17 0.48 0.17 0.25 n 3.17 3.27 2.42 4.72 Usw 1409.47 1446.25 1056.29 977.54 CA* 47.93 51.42 37.39 35.77 CT* 100.43 104.06 73.35 67.51 HT* 119.42 114.65 84.68 74.78 RT* 17.07 21.33 12.73 12.44 RA* 15.56 16.73 11.91 11.64 RN* 1.52 4.59 0.81 0.80
下载: 导出CSV
-
[1] 赵丽莎, 吴小川, 易晨曦, 王婉青. 稠油开采技术现状及展望[J]. 辽宁化工,2013,42(4):363−368. doi: 10.3969/j.issn.1004-0935.2013.04.015ZHAO Li-sha, WU Xiao-chuan, YI Chen-xi, WANG Wan-qing. Status and development trend of heavy oil recovery techniques[J]. Liaoning Chem Ind,2013,42(4):363−368. doi: 10.3969/j.issn.1004-0935.2013.04.015 [2] COLIN J M, BOULET R, ESCALIER J C. Characterization of heavy crude oils and petroleum residues[J]. Fuel Sci Technol Int,1989,7(8):1179−1208. doi: 10.1080/08843758908962284 [3] 张瑞峰, 安晓会, 刘达, 孙振辉, 任贵风, 曲柏瑶. 原油中沥青质的危害与预防[J]. 辽宁化工,2014,43(8):1048−1051.ZHANG Rui-feng, AN Xiao-hui, LIU Da, SUN Zhen-hui, REN Gui-feng, QU Bo-yao. Hazards and prevention of asphaltenes in crude oil[J]. Liaoning Chem Ind,2014,43(8):1048−1051. [4] 赵锁奇, 张霖宙, 陈振涛, 许志明, 孙学文, 史权, 徐春明. 重质油超临界溶剂萃取梯级分离工艺的化学基础[J]. 中国科学:化学,2018,48(4):369−386. doi: 10.1360/N032017-00165ZHAO Suo-qi, ZHANG Lin-yu, CHEN Zhen-tao, XU Zhi-ming, SUN Xue-wen, SHI Quan, XU Chun-ming. The chemical fundamentals for heavy oil supercritical fluid extraction and multi-stage separation technology[J]. Sci Sin Chim,2018,48(4):369−386. doi: 10.1360/N032017-00165 [5] ZHAO S, SPARKS B D, KOTLYAR L S, CHUANG K H. Correlation of processability and reactivity data for residua from bitumen, heavy oils and conventional crudes: Characterization of fractions from super-critical pentane separation as a guide to process selection[J]. Catal Today,2007,125(3-4):122−136. doi: 10.1016/j.cattod.2007.05.025 [6] ZHAO S, XU Z, WANG R. Production of de-asphalted oil and fine asphalt particles by supercritical extraction[J]. Chin J Chem Eng,2003,11(6):691−695. [7] 裴亮军, 李冬, 袁扬, 薛凤凤, 李稳宏. 不同正构烷烃溶剂沉淀中低温煤焦油沥青质的结构组成变化规律[J]. 化工进展,2017,36(6):2101−2108.PEI Liang-jun, LI Dong, YUAN Yang, XUE Fengfeng, LI Wen-hong. Composition and structural changes of low temperature coal tar asphaltenes precipitated in different n-alkane solvents[J]. Chem Ind Eng Prog(China),2017,36(6):2101−2108. [8] 龙军, 王子军, 黄伟祁, 祖德光. 重溶剂脱沥青在含硫渣油加工中的应用[J]. 石油炼制与化工,2004,35(3):1−5. doi: 10.3969/j.issn.1005-2399.2004.03.001LONG Jun, WANG Zi-jun, HUANG Wei-qi, ZU De-guang. Application of heavy solvent deasphalting in sulfur-containing residuum processing[J]. Pet Ref Chem Ind,2004,35(3):1−5. doi: 10.3969/j.issn.1005-2399.2004.03.001 [9] 范勐, 孙学文, 许志明, 赵锁奇. 渣油中溶于正庚烷但不溶于正戊烷沥青质性质分析[J]. 石油化工高等学校学报,2011,24(3):8−12.FAN Meng, SUN Xue-wen, XU Zhi-ming, ZHAO Suo-qi. Characterization of residu (C5-C7) asphaltene (soluble in n-heptane but insoluble in n-pentane)[J]. J Petrochem Univ,2011,24(3):8−12. [10] 蔡春芳, 邬光辉, 李开开, 陈利新, 李梅, 李宏涛. 塔中地区古生界热化学硫酸盐还原作用与原油中硫的成因[J]. 矿物岩石地球化学通报,2007,26(1):44−48. doi: 10.3969/j.issn.1007-2802.2007.01.005CAI Chun-fang, WU Guang-hui, LI Kaikai, CHEN Li-xin, LI Mei, LI Hong-tao. Thermochemical sulfate reduction and origin of sulfur in crude oils in palaeozoic carbonates[J]. Bull Mineral, Petrol Geochem,2007,26(1):44−48. doi: 10.3969/j.issn.1007-2802.2007.01.005 [11] COOKSON D J, SMITH B E. One-and two-dimensional NMR methods for elucidating structural characteristics of aromatic fractions from petroleum and synthetic fuels[J]. Energy Fuels,1987,1(1):111−120. doi: 10.1021/ef00001a021 [12] 吴帆, 彭朴, 陆婉珍. 烃类化合物NMR化学位移数据库及各类碳氢原子族化学位移统计分布[J]. 波谱学杂志,1996,13(4):393−402.WU Fan, PENG Pu, LU Wan-zhen. A database for NMR chemical shift of hydrocarbons and chemical shift distribution of each subgroup[J]. J Chin Mag Res,1996,13(4):393−402. [13] 洪琨, 马凤云, 钟梅, 刘景梅, 莫文龙. 渣油重组分沥青质结构分析及其对临氢热反应过程生焦的影响[J]. 燃料化学学报,2016,44(3):357−365. doi: 10.3969/j.issn.0253-2409.2016.03.014HONG Kun, MA feng-yun, ZHONG Mei, LIU Jing-mei, MO Wen-long. Analysis of asphaltene structure and its effects on the coking behavior in the process of hydrothermal cracking[J]. J Fuel Chem Technol,2016,44(3):357−365. doi: 10.3969/j.issn.0253-2409.2016.03.014 [14] 张强, 孙昱东, 杨朝合, 王雪. 超声波处理对加氢反应前后沥青质单元分子结构的影响[J]. 燃料化学学报,2014,42(1):48−54.ZHANG Qiang, SUN Yu-dong, YANG Chao-he, WANG Xue. Effect of ultrasonic treatment on the unit structure of pre-and post-hydrotreating asphaltenes[J]. J Fuel Chem Technol,2014,42(1):48−54. [15] 孙昱东, 宋立飞, 韩忠祥, 王曜宸, 陶义. 固态 13C-NMR法表征渣油沥青质得结构组成[J]. 石油学报(石油加工),2018,34(6):1149−1154.SUN Yu-dong, SONG Li-fei, HAN Zhong-xiang, WANG Yao-chen, TAO Yi. Structure and composition characterization of asphaltenes by solid-state 13C-NMR[J]. Acta Pet Sin (Pet Process Sect),2018,34(6):1149−1154. -
点击查看大图
图(4) / 表(5)
计量
- 文章访问数: 283
- HTML全文浏览量: 259
- PDF下载量: 55
- 被引次数: 0
