Balci, Adnan and Bruna, Maria and Budd, Chris and He, Dongdo and Hjorth, Poul G. and Krzyżanowski, Grzegorz and Kubala, Krystian and Lund, Christian and Martensen, Berit and Schmidt, Gitte and Sikora, Monika and Smug, Damian (2013): Heveas problem: The Fountain.
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Abstract
Report is the result of the working during 94th European Study Group with Industry in Sonderborg.
| Item Type: | MPRA Paper |
|---|---|
| Original Title: | Heveas problem: The Fountain |
| English Title: | Heveas problem: The Fountain |
| Language: | English |
| Keywords: | ESGI94 Heveas |
| Subjects: | I - Health, Education, and Welfare > I0 - General L - Industrial Organization > L0 - General |
| Item ID: | 49626 |
| Depositing User: | Monika Sikora |
| Date Deposited: | 10 Sep 2013 09:43 |
| Last Modified: | 28 Sep 2019 19:11 |
| References: | [1] J. Cimbala and Y. Cengel, Essentials of Fluid Mechanics, Fundamentals and Applications, McGraw Hill Higher Education, 2008. [2] S. S. Cook, Erosion by Water-Hammer, Proceedings of the Royal Society of London. Series A, Containing Papers of a Mathematical and Physical Character, 119 (1928), pp. 481-488. [3] J. Eggers and E. Villermaux, Physics of liquid jets, Reports on Progress in Physics, 71 (2008), p. 036601. [4] V. Ferreira, M. Tome, N. Mangiavacchi, A. Castelo, J. Cuminato, A. Fortuna, and S. McKee, High-order upwinding and the hydraulic jump, International journal for numerical methods in fluids, 39 (2002), pp. 549-583. [5] J. Hearfield, Water Flowing in Pipes. http://www.johnhearfield.com/Water/Water_in_pipes2.htm#H4. Accessed: August 2013. [6] ITACA, Fluid Mechanics For Gravity Flow Water Systems and Pumps. http://www.itacanet.org/fluid-mechanics-for-gravity-flow-water-systems-and-pumps/appendix-3-friction-losses-and-the-reynolds-number/. Accessed: August 2013. [7] X. Liu, J. Lienhard, and J. Lombara, Convectiwe heat transfer by impingement of circular liquid, Journal of heat transfer, 113 (1991), pp. 571-582. [8] E. Lorenceau, D. Quere, and J. Eggers, Air Entrainment by a Viscous Jet Plunging into a Bath, Phys. Rev. Lett., 93 (2004), p. 254501. [9] B. J. McKeon, C. J. Swanson, M. V. Zagarola, R. J. Donnelly, and A. J. Smits, Friction factors for smooth pipe ow, J. Fluid Mech., 511 (2004), pp. 41-44. [10] G. Mohiuddin Mala and D. Li, Flow characteristics of water in microtubes, International Journal of Heat and Fluid Flow, 20 (1999), pp. 142-148. [11] L. F. Moody, Friction factors for pipe ow, Trans Asme, (1944). [12] T. Obara, N. K. Bourne, and J. E. Field, Liquid-jet impact on liquid and solid surfaces, Wear, 186 (1995), pp. 388-394. [13] M. Sibulkin, Transition from Turbulent to Laminar Pipe Flow, Physics of Fluids, 5 (1962), p. 280. [14] V. K. Vasista, Experimental study of the hydrodynamics of an impinging liquidjet, PhD thesis, Massachusetts Institute of Technology, 1989. [15] K. Watanabe, Y. Udagawa, and H. Udagawa, Drag reduction of newtonian fluid in a circular pipe with a highly water-repellent wall, Journal of Fluid Mechanics, 381 (1999), pp. 225-238. [16] Water Efficiency Labelling and Standards (WELS) scheme, Water efficiency. http://www.waterrating.gov.au/consumers/water-efficiency. Accessed: August 2013. [17] WaterSense, U.S. Environmental Protection Agency, WaterSense Labeled High-Efficiency Lavatory (Bathroom Sink) Faucet Specification. http://www.epa.gov/WaterSense/pubs/faq_bs.html. Accessed: August 2013. [18] F. M. White, Fluid Mechanics, McGraw Hill Higher Education, 6th ed., 2008. |
| URI: | https://mpra.ub.uni-muenchen.de/id/eprint/49626 |
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