On Flow-Altering Countermeasures for Scour at Vertical-Wall Abutment

Radice, A.; Lauva, O.

doi:10.2478/heem-2013-0008-y

Artykuł - szczegóły

Tytuł artykułu

On Flow-Altering Countermeasures for Scour at Vertical-Wall Abutment

Autorzy

Radice A. , Lauva O.

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.2478/heem-2013-0008-y

Warianty tytułu

Języki publikacji

Abstrakty

Results are presented for clear-water scour experiments at a vertical-wall abutment where the obstacle was modified with slots or roughening elements as flow-altering countermeasures against the erosion process. The laboratory campaign comprehended an initial experiment with an unprotected obstacle, two experiments with slots above and beneath the non-scoured bed level, respectively, and one experiment with a roughened abutment. The repeatability of the experiments was checked and found satisfactory. The measured data set consisted of (i) scour depth with time; (ii) geometry of the erosion hole; and (iii) sediment motion pattern at several evolution stages of the process. A novel feature of the work was the attempt to combine evidence on the scour depth and that on sediment motion so as to shed light on the mechanism of scour reduction by the countermeasures tested. It is argued that this strategy might furnish guidelines for future extensive investigations of scour countermeasures, aimed at finding optimal design solutions.

Słowa kluczowe

local scour abutment process dynamics flow-altering countermeasures sediment transport

Wydawca

Institute of Hydro-Engineering of Polish Academy of Sciences

Czasopismo

Archives of Hydro-Engineering and Environmental Mechanics

Rocznik

2012

Tom

Vol. 59, nr 3-4

Strony

137--153

Opis fizyczny

Bibliogr. 33 poz., il.

Twórcy

autor

Radice A.

autor

Lauva O.

Dept. I.I.A.R., Politecnico di Milano, Piazza Leonardo da Vinci, 32, 20133 Milano, Italy, alessio.radice@polimi.it

Bibliografia

1. Ballio F., Teruzzi A., Radice A. (2009) Constriction effects in clear-water scour at abutments, Journal of Hydraulic Engineering, 135 (2), 140–145.
2. Buffington J. M., Montgomery D. R. (1997) A systematic analysis of eight decades of incipient motion studies, with special reference to gravel-bedded rivers, Water Resources Research, 33, 1993–2029.
3. Cardoso A. H., Fael C. M. S. (2009) Protecting vertical-wall abutments with riprap mattresses, Journal of Hydraulic Engineering, 135 (6), 457–465.
4. Chiew Y. M. (1992) Scour protection at bridge piers, Journal of Hydraulic Engineering, 118 (9), 1260–1269.
5. Chiew Y. M., Lim S. Y. (2003) Protection of bridge piers using a sacrificial sill, Proc. Institution of Civil Engineers, Water Maritime and Energy, 156 (1), 53–62.
6. Dargahi B. (1990) Controlling mechanism of local scouring, Journal of Hydraulic Engineering, 116 (10), 1197–1214.
7. Dey S., Sumer B. M., Fredsøe J. (2006) Control of scour at vertical circular piles under waves and current, Journal of Hydraulic Engineering, 132 (3), 270–279.
8. Grimaldi C., Gaudio R., Calomino F., Cardoso A. H. (2009) Control of scour at bridge piers by a downstream bed sill, Journal of Hydraulic Engineering, 135 (1), 13–21.
9. Haque M. A., Rahman M., Islam G. M. T., Hussain M. A. (2007) Scour mitigation at bridge piers using sacrificial piles, International Journal of Sediment Research, 22 (1), 49–59.
10. Heidarpour M., Afzalimehr H., Izanidia E. (2010) Reduction of local scour around bridge pier groups using collars, International Journal of Sediment Research, 25 (4), 411–422.
11. Johnson P. A., Hey R. D., Tessier M., Rosgen D. L. (2001) Use of vanes for control of scour at vertical wall abutments, Journal of Hydraulic Engineering, 127 (9), 772–778.
12. Korkut R., Martinez E. J., Morales R., Ettema R., Barkdoll B. (2007) Geobag performance as scour countermeasure for bridge abutments, Journal of Hydraulic Engineering, 133 (4), 431–439.
13. Kumar V., Ranga Raju K. G., Vittal N. (1999) Reduction of local scour around bridge piers using slots and collars, Journal of Hydraulic Engineering, 125 (12), 1302–1305.
14. Kwan R. T. F., Melville B.W. (1994) Local scour and flow measurements at bridge abutments, Journal of Hydraulic Research, 32 (5), 661–673.
15. Lagasse P. F., Zevenbergen L.W., Schall J. D., Clopper P. E. (2001) Bridge scour and stream instability countermeasures, Federal Highway Administration, FHWA NHI 01-003, HEC-23.
16. Li H., Barkdoll B. D., Kuhnle R., Alonso C. (2006) Parallel walls as an abutment scour countermeasure, Journal of Hydraulic Engineering, 132 (5), 510–520.
17. Mashahir M. B., Zarrati A. R., Mokallaf E. (2010) Application of riprap and collar to prevent scouring around rectangular bridge piers, Journal of Hydraulic Engineering, 136 (3), 183–187.
18. Melville B. W., Coleman S. E. (2000) Bridge scour, Water Resources Publications: Highlands Ranch, Colorado, USA.
19. Melville B.W., Hadfield A. C. (1999) Use of sacrificial piles as pier scour countermeasures, Journal of Hydraulic Engineering, 125 (11), 1221–1224.
20. Melville B. W., van Ballegooy S., Coleman S., Barkdoll B. (2006a) Countermeasure toe protection at spill-through abutments, Journal of Hydraulic Engineering, 132 (3), 235–245.
21. Melville B. W., van Ballegooy S., Coleman S., Barkdoll B. (2006b) Scour countermeasures for wing-wall abutments, Journal of Hydraulic Engineering, 132 (6), 563–574.
22. Meyer-Peter E., M¨uller R. (1948) Formulas for bed-load transport, Proc. of the II Meeting of IAHR, Stockholm, Sweden.
23. Radice A. (2010) Discussion of “Protecting vertical-wall abutments with riprap mattresses” by A.H. Cardoso and C.M.S. Fael, Journal of Hydraulic Engineering, 136 (10), 848–849.
24. Radice A., Ballio F. (2008) Double-average characteristics of sediment motion in one-dimensional bed load, Acta Geophysica, 56 (3), 654–668.
25. Radice A., Ballio F., Porta G. (2009a) Local scour at a trapezoidal abutment: Sediment motion pattern, Journal of Hydraulic Research, 47 (2), 250-262.
26. Radice A., Ballio F., Tran C. K. (2010) Gravity- and turbulence-dominated sediment motion in the clear-water scour process at a vertical-wall abutment in pressurized flow, Archives of Hydro-Engineering and Environmental Mechanics, 57 (1–2), 3–19.
27. Radice A., Malavasi S., Ballio F. (2006) Solid transport measurements through image processing, Experiments in Fluids, 41, 721–734.
28. Radice A., Porta G., Franzetti S. (2009b) Analysis of the time-averaged properties of sediment motion in a local scour process, Water Resources Research, 45, W03401.
29. Shields A. (1936) Anwendung der Aehnlichkeitsmechanik und der Turbulenz Forschung auf die Geschiebebewegung, Mitt. der Preussische Versuchanstalt f¨ur Wasserbau und Schiffbau, Tech. Hochsch., Berlin, Germany, 26.
30. Sui J., Afzalimehr H., Samani A. K., Maherani M. (2010) Clear-water scour around semi-elliptical abutments with armored beds, International Journal of Sediment Research, 25 (3), 233–245.
31. Vittal N., Kothyari U. C., Haghighat M. (1994) Clear-water scour around bridge pier group, Journal of Hydraulic Engineering, 120 (11), 1309–1318.
32. Zarrati A. R., Chamani M. R., Shafaie A., Latifi M. (2010) Scour countermeasures for cylindrical pier using riprap and combination of collar and riprap, International Journal of Sediment Research, 25 (3), 313–321.
33. Zarrati A. R., Gholami H., Mashahir M. B. (2004) Application of collar to control scouring around rectangular bridge piers, Journal of Hydraulic Research, 42 (1), 97–103.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-article-BATA-0019-0027