Iranian Water Research Journal

Iranian Water Research Journal

The effect of abutment geometry and application of submerged vanes on bridge abutment scour

Document Type : Original Article

Authors
elahe alizadeh 1
kourosh qaderi 2
Fateme Gishinzade 2
mohammad reza madadi 3
1 Department of Water Engineering, Shahid Bahounar University of Kerman, Kerman, Iran
2 Department of Water Engineering, Shahid Bahonar University of Kerman, Kerman, Iran
3 , Water Engineering Group, University of Jiroft, Jiroft, Iran
10.22034/iwrj.2025.14692.2586
Abstract
Abstract

Scouring may occur as a result of natural changes in the flow in the waterway or as a result of human activities such as construction of structures in the flow path or removal of bed materials.

The Occurrence of scouring around the abutment is considered as one of the most important 4- this phenomenon, several methods have been proposed. In the present study, the effect of two parameters of the geometric shape of the bridge abutment, as well as the presence of submerged vanes with selected arrangements, on the amount of scour around the bridge abutment was investigated. Most of the methods that are used to control and reduce scouring are divided into two categories: methods of changing the flow pattern and methods of increasing bed resistance, and researchers have used each of these methods to reduce scouring.

Methods:

In this research, a physical model of four different shapes including 90 degree rectangular, rectangular abutment with fin-wall with 60 degree flow line, rectangular abutment with fin- wall with 45 degree flow line and rectangular abutment with circular fins was designed and built. Submerged vanes were also tested in four different arrangements of parallel rows, zigzag rows, oblique zigzag and pine, in two Submergence ratios of 2 and 3 and at an angle of 20° to the flow on each of the four abutments, at constant discharge. The tests were performed at a flow rate of 34 liters per second and a water depth of 12 cm. The criterion of the equilibrium time in these experiments is the same criterion that Kumar et al. considered in their research, and it is equal to the time when the changes in scouring depth do not exceed one millimeter in three consecutive hours. Therefore, in the current research, by conducting a 12-hour test for each of the abutmentmodes, this duration was estimated to be 5 hours for all four types of abutment. All the experiments of this research were done in clear water conditions. At the beginning of the tests, four control tests were performed with the support in four different states and without the submerged vanes. After completing the tests, the maximum scouring depth for each abutment was obtained as follows: the maximum relative scouring depth of the rectangular abutments 90° 1.01, the maximum scouring depth of the rectangular abutment of the fin wall of the flow line 60° 0.43, The rectangular abutment of the fin wall of the 45 degree flow line was 0.41 and the rectangular abutment with circular fins was 0.36. In the following tests, for each of the different support states, the length and width of the scour hole were measured separately for four different arrangements of sunken plates, in two absorption ratios of 2 and 3.

Results:

According to the data of this series of tests, the absorption ratio (L/H=3) in all cases of submerged vanes and also for all abutments has a better performance than (L/H=2) in reducing surrounding erosion. Installation of plates in front of the abutment causes the approaching flow to break up and as a result reduce the strength of the downward flow and the horseshoe vortex in front of the abutment. If the ratio of the height on the submerged vane bed is high compared to its length, the vanes have enough height to separate the approaching flow. Observations showed that the maximum and minimum scouring depths occurred around the 90 degree rectangular and the rectangular abutment with circular walls, respectively. In submerged vanes experiments, the pine arrangement in a Submergence ratio of 3, with a 41% reduction in scouring around the 90 ° rectangular abutment, 20% around the rectangular abutment with fin- wall with 45 degree flow line and an 18% around the rectangular abutment with circular fins showed the best performance in reducing scour compared to the control test corresponding to each of the abutments. The comparisons made in this research show the effect of the shape of the abutment, in such a way that by changing the shape of the abutment from a 90 degree rectangle to a rectangle with circular fins, scouring was reduced by 64%. Also, with the presence of the protective device of the submerged vanes under the arrangement of pine in the absorption ratio of 3, the scouring decreased around the rectangular abutment 90 degrees is 41%, the rectangular fin wall of the flow line 45 degrees is 20% and the rectangle with circular fins is 18.18% compared to the control test.
Keywords
Pine arrangement
Submergence ratios
Geometric shape of the abutment
Submerged vanes
Scour depth
Subjects
1.     Alkhouly M. Shamaa M. Sarhan T. & Ezzeldin R. 2019. Local scour around bridge abutment, International Journal of Scientific and Engineering Research, 8(1): 1-10.
 
2.     Dey S. & Barbhuiya, K. 2004. Clear-water scour at abutments in thinly armored beds.  Journal of Hydraulic ASCE, 130: 622-634.
 
3.     Emamifar F. Masjedi A. & Heidarnejad M. 2016. Investigation of the effect of the geometric shape of the bridge abutment on the local scour around it in the river arch. journal of water science and engineering, 613. (In Persian).
 
4.     Gharibzadeh A. 2012. Investigation of flow structure effect on local scour at bridge abutments, Master Thesis, Isfahan University of Technology, Department of Water Engineering, 96. (In Persian).
 
5.     Ghorbani B. & Parsmehr M. 2015. The effect of narrowing on scouring of the bridge abutment and the use of submerged vanes to prevent and control it. Journal of Hydraulic Engineering, 10(4): 65-72. (In Persian).
 
6.     Hashemi L. Kashefipour S. M. Ghomeshi M. & Bahrami Yarahmadi M. 2023. 'Experimental investigation of the effect of hydrographs with different skewness and duration time on temporal variations of scour around a single cylindrical pier', Journal of Hydraulics.
 
7.     Johnson P. A. Hey R. D. Tessier M. & Rosgen D. L. 2001. Use of vane for control of scour at vertical wall abutments. Journal of Hydraulic Engineering, 127(9): 772-778.
 
8.     Karimi M. 2012. Use of effect of parallel walls to reduce scour of abutment in compound channels, Master Thesis, Shahid chamran University, 117 p (In Persian).
 
9.     Karimi M. Qaderi K. Rahim Pour M. & Ahmadi M. M. 2021. Laboratory investigation of effect of flat submerged vanes on scour at bridge piers group and abutment. Journal of Civil Engineering Amirkabir, 53(7): 25-46. (In Persian).
 
10. Khademi K. & Shafaei Bajestan M. 2015. Experimental investigation of flow pattern and scour around the bridge abutment in the presence of submerged vanes connected to it, Journal of Irrigation and water engineering, 5(17): 56-66 (In Persian).
 
11. Khademi K. Shafaei Bajestan M & Ghamshi M. 2012. Investigation of the Effect of longitudinal and lateral space of submerged vanes on local scour in abutment of bridge, PHD Thesis, Shahid chamran University, (In Persian).
 
12. 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.
 
13. Lauchlan C. S. 1991. Pier scour countermeasures, PhD.Thesis, University of Auckland, New Zealand, 299-316. 
 
14. Melville B. W. 1997. Pier and abutment scour. Journal Hydraulic Engineering ASCE, 132(2): 125-136.
 
15. Montaseri H. Godsian M & Salehi Neyshabour A. 2021. Experimental study on design parameters of submerged vanes for sediment control at lateral intake in a 180-degree bend. Journal of Modares Civil Engineering, 20(1): 161-176. (In Persian).
 
16. Nazeri A. & Emamgholizadeh S. 2021. 'Experimental Investigation of the Effect of Symmetric T-shaped Spur dyke on Bridge Abutment Scour in Compound Channel', Iranian Water Researches Journal, 15(2): 21-29.
 
17. Nekoufar K. & Haljian A. 2023. The Effect of Submerged Plates on the Square Bridge Pier scours Using Software SSIIM. Journal of Water Engineering, 10(2).
 
18. Osroush M. Hosseini S.A. and Kamanbedast A.A. (2020). Evaluation and Comparison of the Slots and Collars Performance in Reducing Scouring around Bridge Abutments, Amirkabir. Journal of Civil Engineering, 52(7): 1637-1650.
 
19. Parchami L. Asghari Pari S. A. and Shafaei Bajestan M. 2015. Experimental investigation of submerged vanes shape effect on bridge pier scouring, Journal of water and soil Science, 27(1): 30-41. (In Persian).
 
20. Shafaei Bajestan M. 2016. Hydraulic of sediment transport, 4nd ed, Shahid Chamran University of Ahvaz Publication. (In Persian).
 
21. Zolghadr M & Shafaei Bajestan M. 2017. Effect of six-legged elements installation arrangement on bed topography around wing-wall abutments, Journal of Water Resources Engineering, 11(36): 47-58. (In Persian).
 

  • Receive Date 10 February 2024
  • Revise Date 01 May 2024
  • Accept Date 10 May 2024
  • Publish Date 21 December 2024