Abstract
In order to make a comprehensive assessment of adsorption performance for oil sorbent , a three-level indicator system is set up, which consists of three second class indicators, namely static adsorption property, spot operation property, energy saving and environment protection property and nine third class indicators like oil absorption rate, water absorption rate, oil-holding rate and so on. According to the five class evaluation principle, the score comparison table, can be derived based on the test results of oil sorbent . Weights for indexes at every level are calculated with analytic hierarchy process . Through the above-mentioned evaluation methods, eight alternative oil sorbents are sorted, which offers scientific decision-making basis for enterprise enterprise.
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References
Bao M, Pi Y, Sun P et al (2015) Research progress on “deepwater horizon” Oil Spill of Gulf of Mexico. Period Ocean Univ China 01:55–62
Deng X, Li J, Zeng H et al (2012) Research on computation methods of AHP wight vector and its applications. Math Pract Theory 42(7):93–101
F716-2009 (2006) Standard test methods for sorbent performance of absorbents. ASTM, USA
Feng Y (2010) Lessons learned from the emergency response to the July 16 Oil Spill Incident in Dalian. China Marit Saf 12:17–18
Guan Y, Han J (2010) Review of the cleaning action taken at sea after the July 16 Oil Spill Incident in Dalian and some suggestions related thereof. China Marit Saf 12:19–21
Guo J, Zhang Z, Sun Q (2008) Study and applications of analytic hierarchy process. China Saf Sci J 18(5):148–152
Jiang X, Lanzhujun, Zhu B et al (2015) Oil absorptive properties and application research of oil sorbent. China Water Transp 4:322–324
JT/T 560-2004 (2004) Sorbents for ship. Water Resources and Electric Power Press, Beijing, p 8
Lan Z-J, Zhu B-K, Jiang X-T (2015) Analysis of oil adsorbing effect of oil sorbent on diesel and its application. J Green Sci Technol 6:176–178
Li F, Duan L, Luan G et al (2016) Research of oil absorption materials based natural organic fiber of cotton linter. New Chem Mater 02:111–113
Liao G, Ma Y, Gao Z (2012) Enlightenment on Oil Spill Incident in Gulf of Mexico to oil spill pollution control management of deep sea in our country. Ocean Dev Manag 5:70–76
Liu P, Li B, Zheng X (2015) Application of environment sensitivity technology in leakage of long-distance pipelines. Petrochem Ind Technol 4:97–98
Luan G, Pei Y, Wu D et al (2014) The AHP-FUZZY method for an integrated emergency drills assessment in industrial production. Math Pract Theory 10:98–103
Pan D, Huo Y (2009) Risk analysis on oil and gas leakage accident in offshore oil & gas field engineer. Mar Environ Sci 28(4):426–429
Q/SY 1712.2-2014 (2014) Performance technology requirements of products used for oil spill response-the second part: oil sorbent. Petroleum Industry Press, Beijing
Sun W, Zhang Y, Pu Z et al (2015) Discussion on technology of oil spill emergency response in port. Environ Eng S1:971–974+984
Wu D, Pei Y, Luan G et al (2013) Assessment on emergency drills of oil depot based on AHP-Fuzzy method. J Saf Sci Technol 07:130–133
Xiao H, Shen B-X, Chen X-Z (2005) Investment on crude oil spills adsorbing effect of melt-blown polypropylene fabric (MBPP). Oil Gas Storage Transp 24(5):24–27
Yang W, Shi X, Yu C (2006) Impact assessment of spilled oil pollution from ship based on AHP method. Shipp Manag 05:13–16
Zhao Y, Hou J, Sun L (2016) Differences in technical standards for oil spill responses at home and abroad. Oil-Gas Storage Transp 10:1083–1086+1091
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Luan, G., Chu, S., Li, X., Ma, G. (2019). Comprehensive Evaluation of Oil Sorbent Based on AHP Method. In: Sun, R., Fei, L. (eds) Sustainable Development of Water and Environment. ICSDWE 2019. Environmental Science and Engineering(). Springer, Cham. https://doi.org/10.1007/978-3-030-16729-5_12
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