2018 petroleum & chemical industry development report

doi:10.1016/j.cjche.2019.08.003

摘要/Abstract

摘要： In 2018, the petroleum and chemical industries of China achieved steady economic growth. The main business income of the entire industry was 12.4 trillion CNY, an increase of 13.6% over the previous year. The total profit was 83.93 billion CNY, an increase of 32.1% over the previous year. The total national oil and gas production reached 334 million tons of oil equivalent, increasing by 2.4% year-on-year. Among the total production, crude oil production was 189 million tons, decreased 1.2%, and natural gas production was 161.02 billion cubic meters, increased 7.5% year on year. Imported crude oil production was 462 million tons, an increase of 10.1% over the last year. Imported gas production was 125.72 billion cubic meters, increased 31.9%. The annual processing capacity of crude oil was 604 million tons, up by 6.8%. The refined oil production was 360 million tons, up by 3.6%. The industry structure was optimized for production growth in 2018, the transformation and upgrading of enterprises and products structure adjustment were sped up, energy efficiency was improved, and overall industrial benefit was rebounded. At present, the economic operation of the industry is still not very stable, and downward pressure is still great, mainly being reflected in the overcapacity of some industries, high cost operation of enterprises, increased tax burden, and weak investment. With the slow recovery of the global economy and the key support of high-quality development through technological innovation, it is expected that the petroleum and chemical industry of China will achieve the general objective of steady growth in 2019.

关键词: China, Petroleum and chemical industry, Profit, Main business income, Production, Consumption, Technological innovation

Abstract: In 2018, the petroleum and chemical industries of China achieved steady economic growth. The main business income of the entire industry was 12.4 trillion CNY, an increase of 13.6% over the previous year. The total profit was 83.93 billion CNY, an increase of 32.1% over the previous year. The total national oil and gas production reached 334 million tons of oil equivalent, increasing by 2.4% year-on-year. Among the total production, crude oil production was 189 million tons, decreased 1.2%, and natural gas production was 161.02 billion cubic meters, increased 7.5% year on year. Imported crude oil production was 462 million tons, an increase of 10.1% over the last year. Imported gas production was 125.72 billion cubic meters, increased 31.9%. The annual processing capacity of crude oil was 604 million tons, up by 6.8%. The refined oil production was 360 million tons, up by 3.6%. The industry structure was optimized for production growth in 2018, the transformation and upgrading of enterprises and products structure adjustment were sped up, energy efficiency was improved, and overall industrial benefit was rebounded. At present, the economic operation of the industry is still not very stable, and downward pressure is still great, mainly being reflected in the overcapacity of some industries, high cost operation of enterprises, increased tax burden, and weak investment. With the slow recovery of the global economy and the key support of high-quality development through technological innovation, it is expected that the petroleum and chemical industry of China will achieve the general objective of steady growth in 2019.

Key words: China, Petroleum and chemical industry, Profit, Main business income, Production, Consumption, Technological innovation

Chunyang Zeng, Qianlin Hu. 2018 petroleum & chemical industry development report[J]. 中国化学工程学报, 2019, 27(10): 2606-2614.

Chunyang Zeng, Qianlin Hu. 2018 petroleum & chemical industry development report[J]. Chinese Journal of Chemical Engineering, 2019, 27(10): 2606-2614.

参考文献

[1] J. Huang, Y. He, L. Wang, Y. Huang, B. Jiang, Bifunctional Au@TiO₂ core-shell nanoparticle films for clean water generation by photocatalysis and solar evaporation, Energy Convers. Manag. 132(2017) 452-459.
[2] BP Statistical Review of World Energy. British Petroleum, http://www.bp.com/statisticalreview,2013.
[3] Final Energy Consumption and Greenhouse Gas Emissions in Tokyo. Bureau of Environment Tokyo Metropolitan Government, 2015.
[4] SUMMARY:Natural Gas in The World-2016Edition. CEDIGAZ, 2016.
[5] Singapore Energy Statistics 2017(EB/OL). Energy Market Authority. https://www.ema.gov.sg/Singapore_Energy_Statistics.aspx.
[6] X. Meng, Q. Yu, Y. Gao, Q. Zhang, C. Li, Q. Cui, Enhanced propene/ethene selectivity for methanol conversion over pure silica zeolite:Role of hydrogen-bonded silanol groups, Catal. Commun. 61(2015) 67-71.
[7] Rachit Khare, Dean Millar, Aditya Bhan, A mechanistic basis for the effects of crystallite size on light olefin selectivity in methanol-to-hydrocarbons conversion on MFI, J. Catal. 321(2015) 23-31.
[8] S. Zhang, Y. Gong, L. Zhang, Y. Liu, T. Dou, J. Xu, F. Deng, Hydrothermal treatment on ZSM-5 extrudates catalyst for methanol to propylene reaction:Finely tuning the acidic property, Fuel Process. Technol. 129(2015) 130-138.
[9] S.M.T. Almutairi, B. Mezari, E.A. Pidko, P.C.M.M. Magusin, E.J.M. Hensen, Influence of steaming on the acidity and the methanol conversion reaction of HZSM-5 zeolite, J. Catal. 307(2013) 194-203.
[10] C. Heppner, J.L.C.M. Dorne, S. Fabiansson, P. Verger, P. Fuerst, M.L. Fernandez-Cruz, P.V.D. Brandt, P.O. Darnerud, G. Speijers, T. Addiscot, A. Cockburn, The first risk benefit assessment of nitrate in vegetables:A European perspective, Toxicol. Lett. (2008) 62-66.
[11] V. Aparicio, J.L. Costa, M. Zamora, Nitrate leaching assessment in a long-term experiment under supplementary irrigation in humid Argentina, Agric. Water Manag. 12(2008) 1361-1372.
[12] M. Riaz, I.A. Mian, M.S. Cresser, Extent and causes of 3D spatial variations in potential N mineralization and the risk of ammonium and nitrate leaching from an N-impacted permanent grassland near York, UK, Environ. Pollut. 156(2008) 1075-1082.
[13] Y. Xian, L. Liang, T. Hua, S. Gavin, H. Huan, Salinity of animal manure and potential risk of secondary soil salinization through successive manure application, Sci. Total Environ. 383(2007) 106-112.
[14] R.B. Thompson, C. Martínez-Gaitan, M. Gallardo, C. Giménez, M.D. Fernández, Identification of irrigation and N management practices that contribute to nitrate leaching loss from an intensive vegetable production system by use of a comprehensive survey, Agric. Water Manag. 89(2007) 261-274.
[15] X. Li, C. Hu, J.A. Delgado, Y. Zhang, Z. Ouyang, Increased nitrogen use efficiencies as a key mitigation alternative to reduce nitrate leaching in North China plain, Agric. Water Manag. 89(2006) 137-147.
[16] Y. Seo, P.J. Egbelu, Process plan selection based on product mix and production volume, Int. J. Prod. Res. 34(1996) 2639-2655.
[17] P.N.K. Phuc, V.F. Yu, S. Chou, Manufacturing production plan optimization in threestage supply chains under Bass model market effects, Comput. Ind. Eng. 65(2013) 509-516.
[18] J.S.R. Wheeler, S.W. Reynolds, S. Lancaster, V.S. Romanguera, S.G. Yeates, Polymer degradation during continuous ink-jet printing, Polym. Degrad. Stab. 105(2014) 116-121.
[19] J.S.R. Wheeler, A. Longpré, D. Sells, D. McManus, S. Lancaster, S.W. Reynolds, S.G. Yeates, Effect of polymer branching on degradation during inkjet printing, Polym. Degrad. Stab. 128(2016) 1-7.
[20] F.O. Arimoro, Impact of rubber effluent discharges on the water quality and macroinvertebrate community assemblages in a forest stream in the Niger Delta, Chemosphere 77(2009) 440-449.
[21] R. Saidur, S. Mekhilef, Energy use energy savings and emission analysis in the Malaysian rubber producing industries, Appl. Energy 87(2009) 2746-2758.
[22] J.J.S. Satapathy, A. Nag, G.B. Nando, Modification of waste polypropylene with waste rubber dust from textile cot industry and its characterization, Process Saf. Environ. Prot. 85(2007) 318-326.
[23] G. Morales, A. Leevers, Patrick, Experimental investigation of the effect of residual stresses on rapid crack propagation in polyethylene (PE100) pipes, Polym. Eng. Sci. 53(2013) 367-374.
[24] P. Özbek, C. Argyrakis, P. Leevers, Fracture mechanics analysis of arc shaped specimens for pipe grade polymers, Polym. Test. 28(2009) 357-361.
[25] Y. Show, K. Takahashi, Stainless steel bipolar plate coated with carbon nanotube (CNT)/polytetrafluoroethylene (PTFE) composite film for proton exchange membrane fuel cell (PEMFC), J. Power Sources 190(2009) 322-325.
[26] M.H.G.W. Okumura, H. Ueda, W. Kuriyama, K. Uzawa, I. Kimpara, Mechanical and thermal properties of carbon fiber/polypropylene composite filled with nano-clay, Compos. Part B 69(2015) 94-100.
[27] C. Unterweger, J. Duchoslav, D. Stifter, C. Fürst, Characterization of carbon fiber surfaces and their impact on the mechanical properties of short carbon fiber reinforced polypropylene composites, Compos. Sci. Technol. 108(2015) 41-47.
[28] G. Huang, S. Wang, P. Song, C. Wu, S. Chen, X. Wang, Combination effect of carbon nanotubes with graphene on intumescent flame-retardant polypropylene nanocomposites, Compos. Part A 59(2014) 18-25.
[29] Q. Chen, Shen, J. Hu, Y. Huang, W. Ye, M. Xin, Miscibility crystallization behavior and specific intermolecular interactions in thermosetting polymer blends of novolac epoxy resin and polyethylene glycol, Polym. Eng. Sci. 48(2008) 556-563.
[30] G. Hu, B. Wang, X. Zhou, Effect of EPDM-MAH compatibilizer on the mechanical properties and morphology of nylon 11/PE blends, Mater. Lett. 58(2004) 3457-3460.