Development Direction of Pipeline Corrosion Research on Oil Refining and Chemical Enterprises

Xiao Jia Zhang; Rui Wang; Shang Yu Yang

doi:10.4028/www.scientific.net/MSF.993.1230

Paper Titles

Challenge and Review of Hydrogen Sulfide Corrosion Resistance Steels for Oil Country Tubular Goods
p.1203

Test Analysis of Corrosion Perforation in a Crude Oil Gathering Pipeline
p.1209

Analysis of Corrosion Causes in the Export of a Compressor in the Pipeline of Western China
p.1218

Leakage Failure Analysis of the ERW Steel Pipeline
p.1224

Development Direction of Pipeline Corrosion Research on Oil Refining and Chemical Enterprises
p.1230

Fracture Failure Analysis of Φ50.8mm Coiled Tubing
p.1235

Analysis of Corrosion Behavior on External Surface of 110S Tubing
p.1242

Fracture Failure Analysis of C110 Oil Tube in a Western Oil Field
p.1251

Experimental Study on Corrosion of Multi-Component Thermal Fluid Thermal Recovery well Tube String
p.1257

HomeMaterials Science ForumMaterials Science Forum Vol. 993Development Direction of Pipeline Corrosion...

Development Direction of Pipeline Corrosion Research on Oil Refining and Chemical Enterprises

Abstract:

The corrosion behavior of refinery due to severe corrosive environment was investigated in the present study, and the analysis was focused on the guiding of the corrosion into a site where is near the ground, easy to change, have low risk and so on. The corrosion parts were analyzed to study the influences of the corrosion pipe in the whole systems. Some suggestions were proposed to choose the corrosion site that can happened. By using the developed method in this study the low risk position of pipeline as a sacrificial location can be found, and then taking it as the priority corrosion place under the control of switchable subline. It is therefore to shut down for maintenance of whole pipeline, and to easily replace the corrosion parts without stop all. The serious corrosion of refining pipeline system can consequently be reduced and removed, thereby to make the long-cycle operation of refining factory be realized.

You might also be interested in these eBooks

Corrosion. Tube Products and Pipeline Systems

View Preview

Functional and Functionally Structured Materials IV

View Preview

Info:

Periodical:

Materials Science Forum (Volume 993)

Pages:

1230-1234

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.993.1230

Citation:

Cite this paper

Online since:

May 2020

Authors:

Xiao Jia Zhang*, Rui Wang, Shang Yu Yang

Keywords:

Guide the Corrosion, Long-Cycle Operation of Refining Industry, Low-Risk Corrosion First, Refining Pipeline

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Wei Lianshan. Corrosion Protection Measures for Chemical Machinery. Value Engineering, 2018, 37 (34): 221-223.

Google Scholar

[2] Huang Sen. Brief analysis of corrosion causes and protection of chemical equipment. Chemical management, 2018 (31): 146.

Google Scholar

[3] Xu Huajuan. Study on corrosion failure and protection of pressure vessel materials in petrochemical plant [J]. Chemical management, 2018 (31): 157-158.

Google Scholar

[4] Nie Mingcheng. Current situation and Prospect Analysis of corrosion and protection of heat exchangers [J]. Chemical management, 2018 (31): 138.

Google Scholar

[5] Liu Jiahuan, Wang Libo. Elementary analysis of corrosion factors and protection methods of circulating water heat exchanger in olefin separation unit [J]. Petrochemical technology, 2018, 25 (10): 77.

Google Scholar

[6] Gaoshuang. Analysis of Corrosion and Protection Management Schemes for Refining Equipment [J]. Petrochemical Technology, 2018, 25 (10): 243.

Google Scholar

[7] Hu Qichuan, Wang Defang, Wu Pengju, Shi Pengfei, Ma Xiaoyu. Corrosion analysis and protection of absorption oxidation tower [J]. Chemical design communication, 2018, 44 (10): 90 + 129.

Google Scholar

[8] Liu Yehong, Niu Di, Zhu Jiapei, Ethylbenzene plant dry gas washing equipment corrosion status analysis and protection [J]. Petrochemical corrosion and protection, 2018, 35 (05): 9-13.

Google Scholar

[9] Jiang Hongwei, Yuan Yaoru. Corrosion analysis and protection of atmospheric and vacuum distillation unit [J]. Corrosion and protection of petrochemical industry, 2018,35 (05): 21-25.

Google Scholar

[10] Grey relational analysis of corrosion behavior of Li Yang, Li Chengyuan, Chen Xu, Yang Jiaxing, Wang Xintong, Ming Nanxi, Han Zhenze. Super 13Cr stainless steel in marine oil and gas field environment [J]. Chinese Journal of Corrosion and Protection, 2018, 38 (05): 471-477.

Google Scholar

[11] Ding Shuwen, Liang Wenbin, Zhao Zhenxin. Corrosion analysis and protective measures for large coke towers [J]. Petroleum and Natural Gas Chemical Industry, 2018, 47 (05): 16-20.

Google Scholar

[12] Wu Ming, Guo Ziwei, Xie Fei, Wang Dan, Wang Yichuang, Guo Dacheng, Jiang Jintao. Progress in corrosion behavior of pipeline steel under the action of anion and sulfate reducing bacteria [J]. Material report, 2018, 32 (19): 3435-3443.

Google Scholar

[13] Wang Shengyong. Brief discussion on corrosion and protection measures of oil pipelines [J]. Standards and quality of China Petroleum and Chemical Industry, 2018, 38(19): 46-47.

Google Scholar

[14] Erosion and corrosion behavior of Chen Hu, Zhou Hao, Wang Cheng, Wang Minhui, Zhao Shuhua, Caizheng.N80 steel in sediment-containing and Cl-containing solutions [J]. Corrosion and protection, 2018, 39(09): 668-672.

Google Scholar

[15] Corrosion regularity of Li Lingjie, Yang Yaohui, Zhang Yanjun, Lin Zhu, Zhou Bing, Wang Zhitao.N80 carbon steel in high CO_2 content system [J]. Corrosion and protection, 2018, 39 (09): 678-683.

Google Scholar

[16] Xiao Shuqing. Application of Cathodic Protection in Pipeline Antisepsis [J]. Chemical Engineering and Equipment, 2018, (09): 225-227.

Google Scholar