• Title/Summary/Keyword: Vertical caisson

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The Impact of Armor Block Failure on Wave Pressure Acting on a Vertical Wall at the Front of a Caisson (피복 케이슨의 소파블록 이탈이 직립벽에 작용하는 파압에 미치는 영향)

  • Taegun Park;Yeon-Myeong Jung;Jeongheum Lee;Jaeheon Jeong;Dong-Soo Hur
    • Journal of Navigation and Port Research
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    • v.48 no.4
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    • pp.303-309
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    • 2024
  • This study examines the effects of wave pressure on a vertical wall due to armor block failure at the front of a caisson, using a 2-D hydraulic model to simulate three types of armor block cross-sections. Additionally, the hydraulic characteristics of two cross-sections that replicated the armor blocks' failure, based on complete cross-sections, were compared. Moreover, quantitative analysis indicated that in the cross-section where the displacement of the armor block was recreated, wave run-up( ) increased by an average of 73%, the sum of dimensionless wave pressures increased by 28%, and converted wave force rose by 33%. These findings underscore the need for countermeasures in the event of armor block failure.

Experimental Study for Wave Reflection of Partially Perforated Caisson by Slit Shape of Front Wall (부분 유공케이슨의 Slit 형상에 따른 반사특성 실험)

  • Lee, Jong-In
    • KSCE Journal of Civil and Environmental Engineering Research
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    • v.33 no.4
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    • pp.1455-1462
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    • 2013
  • This study examines the reflection of a partially perforated wall with single chamber by 2D and 3D hydraulic experiments. The effects of slit shape on the front wall, relative chamber width and wave steepness were discussed. For the normal incident wave condition, the reflections of horizontal slit case were lower than that of the vertical slit with the similar porosity, but the differences are not significant. When the wave steepness is relatively small, the reflection coefficients are large. In the oblique incidence, the normalized wave heights along a perforated wall with similar porosity are almost same for the vertical and horizontal slit walls and therefore the difference by slit shape can be ignored.

Calculation of Expected Sliding Distance of Concrete Caisson of Vertical Breakwater Considering Variability in Wave Direction (파향의 변동성을 고려한 직립방파제 콘크리트 케이슨의 기대활동량 산정)

  • 홍수영;서경덕;권혁민
    • Journal of Korean Society of Coastal and Ocean Engineers
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    • v.16 no.1
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    • pp.27-38
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    • 2004
  • In this study, the reliability design method developed by Shimosako and Takahashi in 1999 for calculation of the expected sliding distance of the caisson of a vertical breakwater is extended to take into account the variability in wave direction such as directional spreading of waves, obliquity of the deep-water design principal wave direction from the shore-normal direction, and its variation about the design value. To calculate the transformation of random directional waves, the model developed by Kweon et al. in 1997 is used instead of Goda's model, which was developed in 1975 for unidirectional random waves normally incident to a straight coast with parallel depth contours and has been used by Shimosako and Takahashi. The effects of directional spreading and the variation of deep-water principal wave directions were minor compared with those of the obliquity of the deep-water design principal wave direction from the shore-normal direction, which tends to reduce the expected sliding distance as it increases. Especially when we used the field data in a part of east coast of Korea, considering the variability in wave directions reduced the expected sliding distance to about one third of that not considering the directional variability. Reducing the significant wave height calculated at the design site by 6% to correct the effect of wave refraction neglected in using Goda's model was found to be proper when the deep-water design principal wave direction is about 20 degrees. When it is smaller than 20 degrees, a value smaller than 6% should be used, or vice versa. When we designed the caisson with the expected sliding distance to be 30㎝, in the area of water depth of 25 m or smaller, we could reduce the caisson width by about 30% at the maximum compared with the deterministic design, even if we did not consider the variability in wave directions. When we used the field data in a part of east coast of Korea, considering the variability in wave directions reduced the necessary caisson width by about 10% at the maximum compared with that not considering the directional variability, and is needed a caisson width smaller than that of the deterministic design in the whole range of water depth considered (10∼30 m).

Optimum Reliablity Based Design Criteria for Bridge Cassion Foundation (교량케이슨기초의 최적신뢰성 설계 규준)

  • 손용우;신형우;이증빈;정철원
    • Proceedings of the Computational Structural Engineering Institute Conference
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    • 1992.10a
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    • pp.79-89
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    • 1992
  • This study is directed to propose a stability analysis and Design Criteria for Bridge Caisson foundations, with Could possibly replace the traditionals W.S.D. provisions of the Current Code, based on the FBOR(Load Factors based on optimum Reliability). The optimum reliability indices(Vertical bearing Capacity : $\beta$opt : 3.19, Lateral bearing Capacity : $\beta$opt= 3.15(ordinary), $\beta$opt : 2.93 (earthquake), Shearing resistance Capacity ; $\beta$opt : 2.87) are Selected as optimal Values Considering our practice base on the Calibration with the current Bridge Caisson foundation design Safety provisions, Load and resistance factors are measure by Using the proposed uncertainties and the Selected optimum reliability indices. furthermore, a set of nominal safety factors are proposed for the U.S.D. design provisions.

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Wave Reflection from Partialy Perforated Caisson Breakwater (부분 유공 케이슨 방파제로부터의 파의 반사)

  • Suh, Kyung-Doug
    • Journal of Korean Society of Coastal and Ocean Engineers
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    • v.8 no.3
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    • pp.221-230
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    • 1996
  • The Suh and Park's analytical model. originally developed to calculate wave reflection from a conventional fully perforated caisson breakwater, is applied to a partially perforated caisson breakwater by approximating the vertical wall of the lower part of the front face of the caisson as a very steep sloping wall. Also, in the model, the inertial resistance term at the perforated wall is modified by using the blockage coefficient proposed by Kakuno and Liu. The model is compared against the hydraulic experimental data reported by Park et al. in 1993. Both the experimental data and the analytical model results show that the influence of inertial resistance is important so that wave reflection becomes minimum when B/L. is approximately 0.2 (in which R : wave chamber width, and 1, : wave length inside the wave chamber), which is somewhat smaller than the theoretical value B/L, : 0.25 obtained by assuming that the influence of inertial resistance is negligible. It is also shown that the analytical model based on a linear wave theory tends to overpredict the reflection coefficient as the wave nonlinearity increases, thus the model is preferably to be used for ordinary waves of small steepness.

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Experimental Investigation for Evaluating Wave Forces on Perforated Caisson with Two Wave Chambers (유수실이 2개인 유공케이슨의 파력 산정에 관한 실험적 연구)

  • Oh, Sang-Ho;Ji, Chang-Hwan;Lee, Dal Soo
    • Journal of Korean Society of Coastal and Ocean Engineers
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    • v.27 no.6
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    • pp.443-451
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    • 2015
  • Design formula for estimating the wave loading on the perforated caisson having two wave chambers is yet available. In this study, the analysis results are presented with the experimental data for the wave force acting on such a breakwater model. Based on the experimental results, it was able to clarify the variation of wave action according to five different wave phases that are associated with peak wave loading at the three vertical walls. Then the force adjustment factor for double-chamber caisson was estimated, similarly as Takahashi and Shimosako (1994), which needs to be further validated with subsequent experiments and practical application in the field.

Proposal of Rotating Stability Assessment Formula for an Interlocking Caisson Breakwater Subjected to Wave Forces (파랑하중에 대한 인터로킹 케이슨 방파제의 회전 안정성 평가식 제안)

  • Park, Woo-Sun;Won, Deokhee;Seo, Jihye;Lee, Byeong Wook
    • Journal of Korean Society of Coastal and Ocean Engineers
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    • v.32 no.1
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    • pp.11-16
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    • 2020
  • The rotational stability of an interlocking caisson breakwater was studied. Using the analytical solution for the linear wave incident to the infinite breakwater, the phase difference effect of wave pressures in the direction of the breakwater baseline is considered, and Goda's wave pressure formula in the design code is adopted to consider the nonlinearity of the design wave. The rotational safety factor of the breakwater was defined as the ratio of the rotational frictional resistance moment due to caisson's own weight and the acting rotational moment due to the horizontal and vertical wave forces. An analytical solution for the rotational center point location and the minimum safety factor is presented. Stability assessment formula were proposed to be applicable to all design wave conditions used in current port and harbor structure design such as regular waves, irregular waves and multi-directional irregular waves.

Active Earth Pressure against Caisson Backfilled with Crushed Rock and Sand (I) : Formulation (사석과 모래로 뒷채움된 케이슨에 작용하는 주동토압 (I) : 정식화)

  • Paik Kyu-Ho
    • Journal of the Korean Geotechnical Society
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    • v.22 no.1
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    • pp.63-72
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    • 2006
  • Coulomb's theory has traditionally been used for the estimation of active earth pressure acting on rigid walls. However, many experimental data show that active earth pressures on rough, rigid walls are nonlinearly distributed. This is due to the arching effects produced by friction between the wall and backfill materials when the wall translates away from the backfill. Although there are analyses that take arching into consideration f3r a horizontal backfill surface and a vertical rigid wall, these analyses were derived for homogeneous backfill. Therefore, it is not possible to use these analyses for a caisson backfilled with crushed rock and sand, a common type of rigid wall for harbor structures. In this study, a new formulation for calculation of the nonlinear active earth pressure acting on a caisson backfilled with crushed rock and sand is proposed considering both internal friction angles and unit weights of the crushed rock and sand.

Proposal of Sliding Stability Assessment Formulas for an Interlocking Caisson Breakwater under Wave Forces (파랑하중에 대한 인터로킹 케이슨 방파제의 미끌림 안정성 평가식 제안)

  • Park, Woo-Sun;Won, Deokhee;Seo, Jihye
    • Journal of Korean Society of Coastal and Ocean Engineers
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    • v.29 no.2
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    • pp.77-82
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    • 2017
  • Recently, the possibility of abnormal waves of which height is greater than design wave height have been increased due to the climate change, and therefore it has been urgent to secure the stability for harbor structures. As a countermeasure for improving the stability of conventional caisson breakwaters, a method has been proposed in which adjacent caissons are interlocked with each other to consecutively resist the abnormal wave forces. In order to reflect this research trend, the reduction effect of the maximum wave force resulted from introducing a long caisson has been presented in the revision to the design criteria for ports and fishing harbors and commentary. However, no method has been proposed to evaluate the stability of interlocking caisson breakwater. In this study, we consider the effect of the phase difference of the oblique incidence of the wave based on the linear wave theory and apply the Goda pressure formula for considering design wave pressure distribution in the vertical direction. Sliding stability assessment formula of an interlocking caisson breakwater is proposed for regular, irregular, and multi-directional irregular wave conditions.

Hydraulic Experiments of Stem Waves due to Multi-Directional Random Waves along a Vertical Caisson (다방향 불규칙파에 의한 직립벽 주위의 연파특성)

  • Yoo, Hyung-Seok;Kim, Kyu-Han;Jung, Eui-Jin
    • Journal of Korean Society of Coastal and Ocean Engineers
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    • v.22 no.6
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    • pp.429-436
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    • 2010
  • Hydraulic experiments were conducted to analyze the characteristics of stem waves due to multidirectional random wave incidence with the different incident angles of main wave direction. Both multi-directional and uni-directional random waves were used to generate the stem waves and their results were compared with each other. The experiment shows multi-directional random waves developed along the vertical wall tend to increase as the incident angle increases similar to the uni-directional waves. Moreover, the stem wave widths were almost same as those in uni-directional random wave cases. However, the experiment demonstrate the stem wave heights were significantly smaller in multi-directional random wave cases than in uni-directional random wave cases.