Experimental Study of Vibration on Pipe Conveying Fluid at Different End Conditions for Different Fluid Temperatures | ||
| Engineering and Technology Journal | ||
| Article 3, Volume 37, 12A, December 2019, Pages 512-515 PDF (706.03 K) | ||
| Document Type: Research Paper | ||
| DOI: 10.30684/etj.37.12A.3 | ||
| Authors | ||
| Kayser A. Ameen1; Mustafa J. Al-Dulaimi1; Ali A. Hatem2 | ||
| 1Air conditioning and Refrigeration Dept., Al-Esraa University College - Iraq | ||
| 2Air conditioning and refrigeration Dept., Al-Esraa University College - Iraq | ||
| Abstract | ||
| Dynamic behavior of a copper pipe conveying fluid at different fluid temperatures is investigated experimentally. Three types of supports are used, which are simply support - simply support, fixed – fixed support and fixed – free support. The effect of the support's types on the frequency and the amplitude of vibration for the pipe conveying the fluid are studied for various flow temperature. These vibration characteristics were tested at temperatures 50, 65 and 80 ºC | ||
| Keywords | ||
| Vibration in pipes; Dynamic response; frequency; fluid at different temperatures | ||
| References | ||
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[1] W. G Garrison, “Major Fires and Explosions Analyzed for 30-Year Period,” Hydrocarbon Process, Vol. 67, No. 9, pp. 115-122, 1988. [2] D. E Olson, “Pressure Vessel and Piping Technology, A Decade of Progress,” ASME, 1985. [3] Y. Zheng, J. Chen, Y. Shang, H.Chang, H.Chen and S. Shu, “Numerical Analysis of the influence of Wall Vibration on Heat Transfer With Liquid Hydrogen Boiling Flow in a Horizontal tube,” International Journal of Hydrogen Energy, Vol. 42, No. 52, pp. 30804-30812, 2017. [4] S. W. Chen, T. Hibiki, M. Mori and F. Watanabe, “Experimental Investigation of Void Fraction Variation in Subcooled Boiling Flow Under Horizontal Forced Vibration,” International Journal of heat and mass transfer, Vol. 115, pp. 954-968, 2017. [5] N.K. Abid Al-Sahib, A. Jameel, and O. Abdulateef, “Investigation into the Vibration Characteristics and Stability of a Welded Pipe Conveying Fluid,” Jordan Journal of Mech. And Ind. Eng., Vol. 4, No 3, pp. 378-387, 2010. [6] L. Wang, J. Gan and Q. Ni, “Natural frequency analysis of fluid-conveying pipes in the ADINA system,” Journal of Physics: Conference Series, Vol. 448, No 1, pp. 1-6, 2014. [7] F. Carlsson, “Influence of forced wall vibrations on a turbulent boundary layer,” M.Sc. Thesis, Chalmers University of Technology., Gothenburg, Sweden, 2001. [8] A.M. Al-Baheli, “Dynamic Response Analysis of Sudden Enlargement and Sudden Contraction Pipe Conveying Fluid at Different End Conditions Using a Finite Element Method,” Basrah Journal for Engineering Science, Vol. 12, No. 1, pp. 119-133, 2012. [9] Q. Zhao and Z. Sun, “Flow-induced vibration of curved pipe conveying fluid by a new transfer matrix method,” Engineering Applications of Computational Fluid Mechanics, Vol. 12, No. 1, pp. 780 – 790, 2018. [10] M. Hunain, “The Fundamental Natural Frequency and Critical Flow Velocity Evaluation of a Simply Supported Stepped Pipe Conveying Fluid,” Journal of Babylon University/Engineering Sciences, Vol. 25, No. 5, pp. 1840 – 1849, 2017. | ||
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