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J. Ocean Eng. Technol. > Volume 29(1); 2015 > Article
Dodaran, Park, Kim, Shahmirzadi, and Park: Effects of Roughness and Vertical Wall Factors on Wave Overtopping in Rubble Mound Breakwaters in Busan Yacht Harbor

Abstract

Coastlines are protected by breakwater structures against the erosion of sand or other materials along beaches due to wave action. This research examined the use of physical modeling to determine the effects of the tetrapod size and vertical walls of a rubble mound on the volume of wave overtopping under irregular wave conditions in coastal areas in Busan Yacht Harbor. In this analysis model, the structures were studied using irregular waves and the JONSWAP wave energy spectrum. To understand the effects of the tetrapod size and heights of the vertical wall, the study considered vertical walls of 0, 1.78, 6.83, and 9.33 cm with armor double layered material tetrapods of 8, 12, 16, and 20 tons. An extensive number of experiments covering a relatively large range of variables enabled a comprehensive discussion. First, in the presence of a short vertical wall, the water level played a key role in the overtopping discharge. In such circumstances, the values of the wave overtopping discharge decreased with increasing freeboard size. In the presence of a tall freeboard and middle, the value of the wave overtopping discharge was equally influenced by the vertical wall factor. Moreover, the tetrapod size decreased by an increase in the vertical wall factor, and relationship between them resulted in a short wall height. From an engineering point of view, considering a small water level may allow the choice of a shorter vertical wall, which would ultimately provide a more economical design.

1. Introduction

Coastal walls are structures that are parallel to and near the shoreline to protect beaches and building and facilities for achieve coastal security. The coastal wall shape and type of aggregate, are divided into different types, which include rubble mound breakwaters. The rubble mound type can be separated to two categories: static stability (traditional) and dynamic stability. One of the most important parameters in a breakwater is wave overtopping. Breaking waves play a significant role in virtually all coastal engineering problems. A large number of factors influence the design of the crest freeboard. These factors are related to the breakwater geometry, structural material and hydrology statistics. The geometrical parameters in coastal engineering design play important roles; the parameters include the free board, crest and width shape, slope of the tetrapod layer, and water depth. Over the past few decades, a variety of breakwaters have been developed. Since these varieties were implemented, the results have indicated that the structures are far from optimal. The freeboard parameter is also the main parameter for the design of a breakwater. The rubble mound breakwater has been considered in South Korea’s, Busan yacht Harbor. The East, Middle and West rubble mound breakwaters in this area of the beach are the most suitable design for this investigation into the effects irregular waves (Busan Port Authority, 2011). In Busan Yacht Harbor, in the case of the East, Middle and West breakwater structures, the design analysis has been complicated by physical processes that depend on the hydro dynamical situations (waves, wave height, wave period, etc.) and the type of breakwater. To the best of the authors’ knowledge, there is still lack of information on the effects of vertical wall and tetrapod weights within the rubble mound structures in response to complex 2 dimensional incoming waves to the harbor. Among the existing literature, (Park et al., 2014; Zanuttigh and Van der Meer, 2006) examined the effects of vertical wall in a rubble mound structure and in the presence of various types of tetrapod weights but they did not consider the different water levels at the entrance of the rubble mounds under irregular direction incoming waves. Marina, which is South Korea’s main port, connects the country to the Pacific Ocean and Asia, and contributes 40% of the country’s overseas cargo, and 40% of Korea’s national fishery manufacture (Busan Port Authority, 2011). To protect the Busan coastal area, rubble mound breakwaters have been studied extensively as a countermeasure, and then constructed to reduce the negative impacts of irregular waves attacking the Busan shoreline. Another unique point about the yacht harbor is the presence of different water levels just at the entrance of the harbor. This increases the complexity of the flow field at the entrance of the rubble mound structures. Figures 1 and 2 present images of this bridge as well as the location of the rubble mound structures in Marina, South Korea.
Fig. 1

The location of East, Middle, West rubble mound respectively (case1 , case2, case 3) Busan, South Korea.

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Fig. 2

Breakwater rubble mound in Busan Yacht Harbour position

HOGHC7_2015_v29n1_62_f002.jpg
On the other hand, little research had been carried out on the role of the freeboard parameter in design. A few examples include (Owen, 1980; Goda, 1985), and more recent analysis of Rubble Mound Breakwaters includes (Aminti and Franco, 1988; Van der Meer and De Waal, 1992; Van der Meer et al., 2005; Bradbury and Allsop, 1988; Muttray et al., 2006; Holthuijsen, 2007). Concerning rubble mound breakwaters in comparatively deep water, Jensen and Juhl(1987) examined consequences from an irregular wave model tests and some different projects were approved at DHI, and his work was later reanalyzed by Jensen and Juhl(1987). While this work is beneficial, it is limited by the condition of geometry and the specific conditions of the tested rubble mound breakwaters. Pullen et al.(2007) recommended the installation of vertical walls on the rubble mound breakwater structure to reduce the overtopping discharge. They suggested that the wall height to be in the same elevation of the armor crest level because wave action forces on the vertical wall will go up severely by action waves and not hidden behind the armor crest if directly were attacked, Pullen et al.(2007). In this study, physical model tests were finished with the aim of well understanding the empathetic hydrodynamic procedures that allowed the above-mentioned area of the Rubble Mound to remain safe when subject to irregular wave’s action. In particular, four kinds of freeboards and tetrapod’s sizes in the case of East, Middle and West Rubble Mounds have been investigated. This research focuses on the East, Middle and West Breakwater Rubble Mounds in Busan Yacht Harbor (see Figure 1) with a specific scale of 1:40. The freeboard was studied in coastal experimental tests, and the experimental results were obtained.

2. Experimental Setup

The 2D physical experiments were completed in the wave flume of the Coastal & Ocean and Harbor Engineering Laboratory. Length, width and height of the test flume was 30m, 0.60m and 1 m, respectively. All tests included three kinds of water levels (Table 1) in the water levels (low level of water, mean sea level and high water level), based on a JONSWAP(Joint North Sea Wave Project) spectrum. The wave generator paddle in a 0° angle wave attack provided mechanically irregular waves on the flume, which is controlled by a personal program. The program on the computer can be used to generate regular, irregular and a variety of other wave conditions. After finding the irregular waves precisely, the computer program was used to make waves with a generator (wave period, wave height) according to a model in the scale of the prototype. Figure 3 shows a photograph of the four tetrapods used in the present study (8, 12, 16 and 20 ton). Table 2 compares the weights of the tetrapods between the actual and physical model. The present experiment made used 4 wave gauges (Mansard and Funke, 1980), the first wave gauge was in front of the generator (5 channel), the second wave gauge was 2 meters in front of the crest rubble mound (7 channel), the third gauge was 1 meter from the crest rubble mound and in front of the structure (8 channel), and the last gauge (channel 6) was behind the structure 1 meter away from the crest of the rubble mound (Figure 4). Figure 5 presents a cross section of the East, Middle and West breakwater rubble mound. The distance from the crest height of the tetrapod to the superstructure was constant under all test conditions.
Table 1

Three kinds of water levels for the experiment and the corresponding design level (D.L)

HOGHC7_2015_v29n1_62_t001.jpg
Fig. 3

Photograph of the tetrapods used in the present study

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Table 2

Comparison of weight of the tetrapods in the actual and physical model

HOGHC7_2015_v29n1_62_t002.jpg
Fig. 4

Experimental setup

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Fig. 5

Cross section of the East and Middle and West rubble mound in physical model

HOGHC7_2015_v29n1_62_f005.jpg

Definition of Overtopping

The present data was analyzed with the Van der Meer(2002) formula to complete the certainty of the results for wave overtopping in this paper, that characterize the wave overtopping discharge for irregular waves. A connection of the experimental consequences with Van der Meer’s formula, Eq. (1) displayed that the present wave overtopping discharge estimator administers good reaction. For each tetrapod in the existence of no vertical wall the roughness factor (γf) achieved, (Park et al., 2014).
The complete formula (Van der Meer, 2002; Pullen et al., 2007) is
HOGHC7_2015_v29n1_62_e901.jpg
if Rc = Ac, the maximum overtopping can be expressed as Equation 2.
Furthermore, if gamma γβ = 1 Eq. (2):
HOGHC7_2015_v29n1_62_e902.jpg
where q is the wave overtopping discharge (m3/m/s), H1/3 is the significant wave height at the toe of the rubble mound (m), ɡ is the gravitational acceleration (m/s2), γf is the roughness factors (γf), γβ is the angle of wave action factors (γβ=1), γb is the effect of toe factors, γv is the vertical wall factors (γv), and ξom is the breaker parameter that this research confirmed under the breaking wave action.
Estimating that the roughness factor did not change for each tetrapod weight, this inquiry checked out the influence of different vertical walls (Figure 6) and relationship between them on the overtopping discharge and Eq. (3).
Fig. 6

Freeboard level and location for wave overtopping (case 1, 2, 3 and 4)

HOGHC7_2015_v29n1_62_f006.jpg
HOGHC7_2015_v29n1_62_e903.jpg

JONSWAP Energy Spectrum

An empirical relationship that defines the distribution of energy with frequency within the wave action was the JONSWAP spectrum (Hasselmann et al., 1973).
(Goda, 1988), JONSWAP spectrum modified Eq. (4) to be substantiated in terms of the peak wave period (Tp) and significant wave height (H1/3):
HOGHC7_2015_v29n1_62_e904.jpg
Where
HOGHC7_2015_v29n1_62_e003.jpg
Here, H1/3 is the significant wave height, H1/3 is the significant wave period (Table 3), Tp is the peak period, ƒ represents frequency and fp is the peak wave frequency, γ the so-called peak enhancement parameter, which disciplines the sharpness of the spectral peak, б is a JONWAP spectral parameter and related to on whether the wave frequency is equal, higher or lower than peak wave frequency, βJ is the form parameter in JONWAP spectrum.
Table 3

Data of rubble mound breakwater

HOGHC7_2015_v29n1_62_t003.jpg

Results and Discussion

JONSWAP Energy Spectrum Distribution

In the three water levels (H.H.W, M.S.L, and L.L.W), the climb in frequency went up the JONWAP energy spectrum. Significant wave height H1/3, was an important parameter and energy spectrum is fully linked to the significant wave height. Figure 7 reveals that on Channel 5, the H1/3 is larger than other districts of the gauges (Channels 6, 7 and 8). Accordingly JONWAP equation, the energy spectrum on Channel 5 is much greater and heavier than at the other gauges’ points (Figure 7). The significant wave height, H1/3 and T1/3 measured with the JONSWAP in the entire spectrum. Figure 7 illustrates that there was a littlest energy in the case of Channel 6 when applying the JONSWAP spectrum by cause of that gauge was placed behind the breakwater and there was obviously very slight variation of wave significance.
Fig. 7

Illustration of the wave spectrum at the three water levels (a, b, c), case 1, 2 and 3 respectively

HOGHC7_2015_v29n1_62_f007.jpg

Influence factor for a vertical wall (γv) and roughness (γf)

Three different initial water levels executed in the flume and upstream of the rubble mound and i.e. low level of water (L.L.W), mean sea level (M.S.L), and high water level (H.W.L). Table 3 presented that there was no vertical wall (case 4) above the crest freeboard and Rc equals Ac. Four Ac and Rc were prescribed in this analysis for case 1, 2, 3 and 4 (Table 4) analogous to the three water levels (L.L.W, MS.L, and H.H.W).
Table 4

Example input file for an analysis of the influence factor for a vertical wall (γv) with first three calculations

HOGHC7_2015_v29n1_62_t004.jpg
A consolidation of 4 different heights of vertical wall (0, 1.78, 6.83 and 9.33 cm) and different sizes of tetrapod (8, 12, 16 and 20 ton) were checked out. Archive the test composition operated in this research results-based of (Park et al., 2014). In presence of a tall and middle freeboard (case 1 and 2), the value of wave overtopping discharge is mutually influenced by the vertical wall factor. Moreover, the tetrapod size is went down to by rising vertical wall factor, and relationship between them presented in the short wall height by refer to Figure 8 to 11.
Fig. 8

Calculated values of γv together with their lower and upper limits, case 1, vertical wall (9.33 cm)

HOGHC7_2015_v29n1_62_f008.jpg
Fig. 9

Calculated values of γv together with their lower and upper limits, case 2, vertical wall (6.83 cm)

HOGHC7_2015_v29n1_62_f009.jpg
Fig. 10

Calculated values of γv together with their lower and upper limits, case 3, short vertical wall (1.78 cm)

HOGHC7_2015_v29n1_62_f010.jpg
Fig. 11

Calculated values of γf together with their lower and upper limits, case 4, no vertical wall (Rc = Ac)

HOGHC7_2015_v29n1_62_f011.jpg
The distributed of wave overtopping versus the reaction of the vertical wall factor (γv) for cases 1 and 2 were displayed respectively in Figure 8 and 9. Accordingly Figure 8, the magnitude of the vertical wall factor investigated between 0.265~0.363 while the roughness factor in these cases had a little repercussion and plays very limited character in declining wave overtopping and it means that is more assertive than the effect of the vertical wall factor (γv) when the vertical wall is taller than 1.78 cm. Further, the effect of the water levels on the wave overtopping discharge increased with decreasing tetrapod size for a presented dimensionless discharge and a steady vertical wall factor. In other words, relationship between (γv) and (γf) demonstrated that electing a shorter vertical wall by using a larger tetrapod size would allow boomed wave overtopping but will lead to a more charge impressive design. Similar results were collected in case 2, as shown in figures 9.
In case 3, [vertical wall = (the level of the vertical wall crest) (the level of the armor crest)] which is balanced to 0.71 m in the prototype, or 1.78 cm with a scale of 1/40 in the ongoing substantial model. Developing the water levels from LLW to HHW did not have a serious response on the wave overtopping volume with a short vertical wall (less than 1.78) (Figure 10). the significance of the vertical wall factor explored between 0.870~0.917 and approximately nearby to (γv=1) in no vertical wall while the roughness factor in this case had a high repercussion and plays very large aspect in felling to wave overtopping and it means that is more assertive than the effect of the roughness factor (γf) when the vertical wall is equal or short than 1.78 cm. Consequently, the tetrapod size played a meaningful role in this case due to the short vertical wall; this means that the effect of the roughness factor (γf) is more dominant than the effect of the vertical wall factor (γv) in presence of short vertical walls. Similar results were collected in case 1, as revealed in figures 11.

6. Conclusions

The consequences of the physical model for the effects of link between roughness and vertical wall factors on wave overtopping tests, which were performed as part of the design in Busan Yacht Harbor, Busan, South Korea, were used to test the expression on different vertical wall height along with variation of the tetrapods weights. The results of this study suggest that a decrease in the freeboard and size of tetrapod established a new hydraulic condition for the overtopping mechanism and consequently, sudden growth was observed in the amount of overtopping discharge. First, the tetrapod size played an important role due to the short vertical wall; this means that the effect of the influence of the roughness factor (γf) is more dominant than the effect of the vertical wall factor (γv) in presence of short vertical walls. Next, the effect of the water levels from LLW to HHW on the wave overtopping discharge increased with decreasing tetrapod size for a presented dimensionless discharge and a steady vertical wall factor. In other words, relationship between (γv) and (γf) demonstrated that electing a shorter vertical wall by using a larger tetrapod size would allow boomed wave overtopping but will lead to a more charge impressive design. From an engineering point of view, considering a small water level may allow the choice of a shorter vertical wall that would ultimately provide a more economical design.

ACKNOWLEDGEMENTS

This research was supported by Korean Brain 21 from Pusan National University.

References

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Park, S.K., Ahadpour, A.A., Han, C.H. S., Meshkati Shahmirzadi, M.E.. (Effects of Vertical Wall and Tetrapod Weights on Wave Overtopping in Rubble Mound Breakwater under Irregular Wave Conditions, International Journal of Naval Architecture and Ocean Engineering, 2014). 947-964.
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Van der Meer, J.W., Briganti, R., Zanuttigh, B., Wang, B.. (Wave Transmission and Reflection at Low Crested Structures: Design Formulae, Oblique Wave Attack and Spectral Change, Coastal Engineering, 2005). 52(10-11):915-929 10.1016/j.coastaleng.2005.09.005.
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Van der Meer, J.W., De Waal, J.P.. (Wave Runup and Overtopping on Coastal Structures Proceedings of XXIII ICCE Venice: ASCE; N.Y.: 1992). 2: 1758-1771.

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