浆体输送管道的管径优化设计

李晓; 何炎平; 谭家华

浆体输送管道的管径优化设计

上海交通大学船舶海洋与建筑工程学院, 上海 200230

详细信息

作者简介:
李晓(1981-), 女, 河南宜阳人, 上海交通大学硕士研究生, 从事海洋新技术与装备研究

中图分类号: U173.91
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- 被引次数: 0
出版历程
- 收稿日期: 2004-08-12
- 刊出日期: 2005-06-25

Diameter optimal design of slurry transportation pipeline

Department of Naval Architecture and Ocean Engineering, Shanghai Jiaotong University, Shanghai 200230, China

More Information

Author Bio:
Li Xiao(1981-), female, graduate student, 86-21-62934058, cathylee@sjtu.edu.cn

摘要

摘要: 分析了浆体的物理特性和输送装置特性, 应用非线性优化方法, 在已知泵的配置、输送浓度与管材的条件下, 以输送每立方米土所用费用单价的最小值作为目标函数, 以浆体的悬浮性和整个浆体输送系统的工作点等作为主要约束条件, 建立了浆体输送管道的管径优化数学模型。费用单价为年费用与年输送量的比率, 年费用着重考虑了与管道直径密切相关的管道材料年折算费用和年泵站运行费用。数值计算得到的最优管径为0.8957m, 管内流量为3.134m³/s, 管道的最终厚度为2.6×10^-3m。与多方案优选法管径计算结果0.9m相比, 所述方法的计算结果准确, 计算量小。
- 管道运输 /
- 管径设计 /
- 非线性优化 /
- 浆体输送
Abstract: In terms of nonlinear optimization method, this paper presented a mathematical model with respect to the diameter optimal design for slurry transportation pipeline. In the condition that pumps configuration, slurry concentration and pipeline material were known, the minimum of unit price per cubic meter of transporting earth was taken as objective function. In the model, unit price was equal to the ratio of annual expenditure to annual transport quantity. For the annual expenditure, the annual cost of pipeline material and the annual operation cost of pumps were considered, which had a close relation to the pipe diameter. Based on detailed analysis of the physical property of slurry and the characteristic curve of transport equipment, the suspension property of slurry and the operating point of whole transportation system were taken as mainly constraint conditions. The numerical-computational results show that the optimal diameter and the flow of the pipe and the final value of the pipe thickness equal 0.895 7 m, 3.134 m³/s and (2.6×) 10^-3 m respectively, compared with the computational diameter 0.9 m of multi-scheme optimization method, the diameter is more accurate.
- pipeline transportation /
- pipe diameter design /
- nonlinear optimization /
- slurry transportation

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图 1 浆体输送管道截面受力

Figure 1. Cross section forces of slurry transportation pipeline

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参考文献(9)

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