Review of Research Development on Slurry Pipeline Drag Reduction Technology

Ping Sun; Dong Dong Wang; Yu Zhang Sha; Lu Xi Liu

doi:10.4028/www.scientific.net/AMR.986-987.866

Paper Titles

Modeling and Optimization of Heat Exchanger in Automotive Exhaust Thermoelectric Generator Based on Fluid Kinematics
p.848

Physical Parameters Consistency Based 3D Temperature Field Reconstruction for Combustion Flame
p.852

Reliability Assessment of the Small Sample Aero-Engine Bearings
p.858

Research on Hydraulic Turbine Cavitation Based on Cordon
p.862

Review of Research Development on Slurry Pipeline Drag Reduction Technology
p.866

Simulation Study on Effects of Ignition Time on Particle Emission for GDI Engine
p.870

SOC Estimation on PNGV Model and Hybrid Electric Vehicle
p.874

Stress Analysis and Measures Resistance to Deformation of Coal Pipeline above Goaf
p.878

Stress Intensity Factors for High Aspect Ratio Semi-Elliptical External Surface Cracks in Cylindrical Vessels
p.882

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 986-987Review of Research Development on Slurry Pipeline...

Review of Research Development on Slurry Pipeline Drag Reduction Technology

Abstract:

Theresistance of slurry pipelinetransportation has greatly impact on slurry transportation system. In order toimprove transportation efficiency,energy utilization rate,taking theappropriate drag reduction technology has a very important significance.Thispaper presents drag reduction technologies for slurry transportationapplications,including micro-bubble drag reduction technology and vibrationdrag reduction technology.

You might also be interested in these eBooks

Energy Research and Power Engineering 2014

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 986-987)

Pages:

866-869

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.986-987.866

Citation:

Cite this paper

Online since:

July 2014

Authors:

Ping Sun*, Dong Dong Wang, Yu Zhang Sha, Lu Xi Liu

Keywords:

Drag Reduction Technology, Micro-Bubble Drag Reduction, Slurrypipeline Transportation, Vibration Drag Reduction

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] T. Xiong, S.D. Fan and P. Jiang: Testing System Optimization and Design for Slurry Pipeline Transportation. Research Journal of Applied Sciences, Engineering and Technology, Vol. 5 (2013) No. 5, pp.1646-1651.

Google Scholar

[2] S.Z. Wang: Granular Materials of Slurry Pipeline Transportation (Ocean Publication, China 1998). pp.67-68. (in china).

Google Scholar

[3] Aluf Orell: The Effect of Gas Injection on The Hydraulic Transport of Slurries in Horizontal Pipes. Chemical Engineering Science, Vol. 62 (2007) , p.6659 – 6676.

DOI: 10.1016/j.ces.2007.07.067

Google Scholar

[4] Aluf Orell: Experimental Validation of A Simple Model for Gas-liquid Slug Flow in Horizontal Pipes. Chemical Engineering Science, Vol. 60 (2005), p.1371 – 1381.

DOI: 10.1016/j.ces.2004.09.082

Google Scholar

[5] X. R Zhang, S.Q. Zhang and L.T. Zou: The Primary Exploration of Three-phase Flow High Concentrations of Pipeline. Electric Power Environmental Protection, Vol. 1 (1986), pp.43-44. (in china).

Google Scholar

[6] B. W Song, J.Q. Huang: A Study on The Drag Reduction of The Plate by Mico-bubbles. Journal of Hydrodynamics, Vol. 4 (1989) No. 4, pp.105-114. (in china).

Google Scholar

[7] Y.G. Zheng, D. Fang and G.F. Li: Gas-liquid Stratified Laminar Flows and Laws of Drag-reducing in Pipe. Journal of Chengdu University of Science and Technology, (1996) No. 3, pp.89-94. (in china).

Google Scholar

[8] Y.G. Zheng, D. Fang and G.F. Li: A Theoretical Study of Drag Reduction by Aeration in Pipe Flow. Journal of Hydrodynamics, Vol. 11 (1996) No. 2, pp.162-171. (in china).

Google Scholar

[9] B. Tang, J.Y. Kong and R. SH. Rao: The Research on Drag Reduction and Transportation by Ejecting Compressed-air to Pipeline. Machine Tool & Hydraulics, Vol. 12 (2008), pp.90-92+95. (in china).

Google Scholar

[10] B. Tang, J.Y. Kong and R. SH. Rao: Experimental Research on Air-ejecting Device for Pipeline Transportation. Machinery Design & Manufacture, (2011) No. 6, pp.152-154. (in china).

Google Scholar

[11] T. Xiong, SH.D. Fan and Z.X. Yan: Numerical Simulation of Optimized Air Injector. Ship&Ocean Engineering, Vol. 5 (2011), pp.94-96+100. (in china).

Google Scholar

[12] D. SH. Gu, G.W. Chen: Analysis of The Dynamic Drag Reduction Effect Slurry Pipeline. Jiangxi Nonferrous Metals, Vol. 1 (1993), pp.1-4. (in china).

Google Scholar

[13] Y. ZH. Sun, A.X. Wu and J.H. Li: Vibration Drag-reduction of Pipeline Transport of High Density Slurry. Mining and Metallurgical Engineering, Vol. 4 (2001), pp.4-6+9. (in china).

Google Scholar

[14] M.O. Kramer: Boundary Layer Stabilization by Distributed Damping. Journal of the American Society for Naval Engineers, Vol. 72 (1960) No. 1, pp.25-34.

DOI: 10.1111/j.1559-3584.1960.tb02356.x

Google Scholar

[15] Y.K. Wang, CH.B. Jiang and L. Li: Review of Research on Drag Reduction. Hydroelectric Power, Vol. 32 (2008) No. 2, pp.67-70. (in china).

Google Scholar

[16] Y.Y. Tan: A Study on Transportation Characteristics of High-density Slurries. Mining Research & Development, Vol. 2 (1995), pp.9-13. (in china).

Google Scholar