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中国工业与应用数学学会会刊
主管:中华人民共和国教育部
主办:西安交通大学
ISSN 1005-3085  CN 61-1269/O1
工程数学学报

工程数学学报 ›› 2017, Vol. 34 ›› Issue (5): 458-468.doi: 10.3969/j.issn.1005-3085.2017.05.002

• • 上一篇    下一篇

大型原油浮顶储罐非稳态传热过程数值模拟

孙   巍1,   成庆林1,   李玉春2,   孙   哲1,   孙海英2,   刘   扬1   

  1. 1- 东北石油大学提高油气采收率教育部重点实验室,黑龙江  大庆  163318
    2- 大庆油田工程建设有限公司,黑龙江  大庆  163000
  • 收稿日期:2015-10-29 接受日期:2016-12-29 出版日期:2017-10-15 发布日期:2017-12-15
  • 通讯作者: 成庆林 E-mail: chengqinglin7212@163.com
  • 基金资助:
    国家自然科学基金(51534004);东北石油大学研究生创新科研项目(YJSCX2015-009NEPU);黑龙江省普通高校科技创新团队基金(2009td08).

Numerical Simulation of Unsteady Heat Transfer Process for Large Floating Roof Oil Tanks

SUN Wei1,   CHENG Qing-lin1,   LI Yu-chun2,   SUN Zhe1,   SUN Hai-ying2,   LIU Yang1   

  1. 1- Key Laboratory of Enhanced Oil & Gas Recovery, Ministry of Education, Northeast Petroleum University, Daqing, Heilongjiang 163318
    2- Daqing Oilfield Engineering Limited Company, Daqing, Heilongjiang 163000
  • Received:2015-10-29 Accepted:2016-12-29 Online:2017-10-15 Published:2017-12-15
  • Contact: C. Cheng. E-mail address: chengqinglin7212@163.com
  • Supported by:
    The National Natural Science Foundation of China (51534004); the Innovation Foundation for Postgraduate of Northeast Petroleum University  (YJSCX2015-009NEPU); the Foundation for Sci-tech Innovation Teams in Heilongjiang Province (2009td08).

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摘要: 随着石油储备建设的高速发展,油罐规模正向大型化以及能适应极限工况的方向发展.为了避免油温过低而造成凝罐等安全事故,需要准确掌握罐内油品温度场的变化规律.本文根据能量守恒定律,采用分步式算法求解储罐传热系数,将其代入到由Taylor级数展开法所建立的节点非稳态传热离散方程中,并进行数值求解.对大庆某$10\times10^{4}$m$^{3}$浮顶储罐的应用分析表明:随着环境温度的降低,罐内油品温度降速率逐渐增大,储罐液位越高,容积越大,罐内原油温度就越高,温降速率就越小.研究结果对于优化大型浮顶罐的储存工艺设计,保障油库安全经济运行提供了重要的技术支持.

关键词: 原油浮顶罐, 传热系数, 离散方程, 数值模拟, 温降规律

Abstract: With the rapid development of oil storage construction, the tank size is developing towards large size and being able to adapt to extreme conditions. In order to avoid oil solidification in the tanks and other safety accidents caused by too low oil temperature, the law of oil temperature field in tanks needs to be calculated accurately. Based on the law of conservation of energy, the heat transfer coefficient of tanks can be solved by fractional steps numerical algorithm, then the unsteady heat transfer discrete equation is solved by numerical method which is set by the Taylor series expansion method. The application analysis of the $10\times 10^4$m$^{3}$ floating roof tank in Daqing Oilfield shows that, the oil temperature drop rate increases gradually with the decrease of ambient temperature, and the oil temperature is higher and the temperature drop rate is smaller in the tank with higher tank level and larger volume. The research and analysis provide the important data for optimizing the storage design of large floating tanks and ensuring the safety and economic operation of oil depot.

Key words: floating roof oil tank, heat transfer coefficient, discrete equation, numerical simulation, temperature drop law

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