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《石化技术与应用》[ISSN:1009-0046/CN:62-1138/TQ]

期数:

2022年5期

页码:

311-314

栏目:

出版日期:

2022-09-10

文章信息/Info

Title:

Combined process of vacuum residue deep conversion andits hydrogen donor solvent selection

文章编号:

1009-0045（2022）05-0311-04

作者:

方东1; 何怡2; 崔笑晨2; 齐建勋1; 袁文宇1

1.中国石油华北石化公司 科技信息部，河北 任丘 062550；2.中国石油渤海钻探工程有限公司 井下作业分公司，河北 任丘 062550

Author(s):

FANG Dong1; HE Yi2; CUI Xiao-chen2; QI Jian-xun1; YUAN Wen-yu1

1.Science and Technology Information Department of North Petrochemical Company，PetroChina，Renqiu 062550，China；2.Downhole Services Company of BHDC，PetroChina，Renqiu 062550，China

关键词:

减压渣油; 组合工艺; 溶剂脱沥青; 液相加氢; 重循环油; 供氢能力

Keywords:

vacuum residue; combined process; solvent deasphalting; liquid phase hydrogenation; heavy cycle oil; hydrogen-donating ability

分类号:

TE 624.4+6

DOI:

DOI：10.19909/j.cnki.ISSN1009-0045.2022.05.0311

文献标识码:

B

摘要:

以减压渣油为原料，催化裂化加氢重循环油和工业馏分油窄馏分为供氢溶剂，采用溶剂脱沥青-液相加氢组合工艺，可将减压渣油高效转化为轻质油。结果表明：焦化蜡油（410～430 ℃）、FCC油浆（450～470 ℃）、糠醛抽出油（430～450 ℃）、重循环油（410～430 ℃）窄馏分的供氢能力依次为2.28，2.61，4.86，2.73 mg/g，远低于四氢萘（7.90 mg/g），而加氢重循环油（0.948 7 g/cm3）供氢能力（7.42 mg/g）与后者相近；采用组合工艺，以加氢重循环油为供氢溶剂，减压渣油的综合转化率为90.84%，轻质油收率（质量分数）可达89.35%，焦炭得到有效抑制。

Abstract:

The vacuum residue was efficiently converted to light oil by the combined process of solvent deasphalting-liquid phase hydrogenation with vacuum residue as raw material， hydrogenated heavy cycle oil（HHCO） and narrow cut fraction of industrial distillate oil as hydrogen donor solvents.The results showed that the narrow cut fraction′s hydrogen-donating abilities of coker gas oil（410-430 ℃）， FCC slurry （450-470 ℃）， furfural extract oil （430-450 ℃）， and heavy cycle oil （410-430 ℃） were 2.28，2.61，4.86，2.73 mg/g respectively， of which the hydrogen-donating ability was much lower than that of tetralin（7.90 mg/g）.However，hydrogen recycling oil （0.948 7 g/cm3） had a similar hydrogen-donating ability（7.42 mg/g） to the latter.Using the combined process and HHCO as hydrogen donor solvent，the combined conversion of vacuum residue was 90.84%，and the light oil yield was up to 89.35%.Moreover，the coke was effectively suppressed.

参考文献/References

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更新日期/Last Update: 2022-09-10