Conference Papers
Permanent URI for this collectionhttps://idr.nitk.ac.in/handle/123456789/28506
Browse
Search Results
Item Dynamic Analysis on the Seismic Resilience of Rubble Mound Breakwaters(Springer Science and Business Media Deutschland GmbH, 2025) Sajan, M.K.; Chaudhary, B.; Akarsh, P.K.; Sah, B.In the aftermath of past earthquakes causing damage to rubble mound (RM) and exposing coastal infrastructure to potential tsunami waves, this paper presents an in-depth investigation into the seismic performance of these critical coastal defenses. Employing advanced finite element analysis software, the study utilizes sinusoidal input ground motions with varying accelerations to simulate the seismic response of RM breakwaters. The research methodology entails meticulous finite element modeling of conventional breakwaters and the strategic integration of reinforcements, such as sheet piles and geogrids. A detailed analysis of displacement profiles and changes in pore pressures within the seabed soil beneath the RM breakwater is conducted, offering crucial insights into its seismic behavior. The investigation explores diverse combinations of reinforcements to assess their efficacy in fortifying the breakwater against seismic loading. Seismic response is simulated by imposing sinusoidal input waves as displacements at the bottom boundary of the soil layer, with free-field boundaries at either end to eliminate reflective effects. This research significantly contributes to the optimization of RM breakwater designs, providing practical strategies for enhancing their seismic performance in coastal engineering applications. The use of finite element analysis facilitates a nuanced understanding of dynamic interactions, allowing for the development of robust and resilient coastal structures to withstand seismic challenges and mitigate potential damages to coastal infrastructure and life. © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2025.Item Behavior of Offshore Wind Turbine Foundation Under Seismic Loading: Numerical Simulations(Springer Science and Business Media Deutschland GmbH, 2025) Kumar, S.; Chaudhary, B.; Sajan, M.K.; Akarsh, P.K.; Sah, B.Offshore wind energy has emerged as a pivotal source of renewable energy, driven by the need to address climate change and reduce reliance on fossil fuels. The behavior of offshore wind turbine foundations plays a critical role in ensuring the efficiency and durability of these structures in harsh marine environments. The numerical simulations of an offshore wind turbine foundation under seismic loading are presented in this paper, with an emphasis on vertical settlement and horizontal displacement. The dynamic behavior of the foundation is evaluated under different soil properties and caisson geometry using sophisticated finite element modeling. The parametric study shows that increasing the length of suction caisson foundation there is an appreciable amount of reduction in vertical settlement of foundation due deeper embedment of caisson. A deeper embedment provides increased resistance to horizontal displacement because the foundation interacts with more stable soil layers. Because denser sand has a higher unit weight, it resists compression better, which reduces overall soil compression under load and minimizes vertical settling of foundations. Sand unit weight influences an offshore wind turbine caisson foundation’s horizontal displacement by boosting seabed interaction, increasing vertical stress, and possibly offering more resistance because of its higher shear strength. The results highlight the need for strict seismic design standards to guarantee the dependability and security of offshore wind farm foundations in seismically active areas, the paper ultimately contributes to the development of more efficient, sustainable, and resilient offshore wind energy infrastructure. © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2025.Item Numerical Simulations for Response of Offshore Wind Turbine Monopile Under the Action of Dynamic Loading(Springer Science and Business Media Deutschland GmbH, 2025) Barik, T.; Chaudhary, B.; Sah, B.; Kumar, S.; Akarsh, P.K.Wind energy is one of the most important renewable energy sources; and specifically offshore wind turbines (OWTs) are more convenient ones because of the presence of uninterrupted high-velocity winds in the offshore area. To stabilize the OWT structure, the foundation plays the most significant role. Most of the offshore wind farms employ fixed type foundations for shallow water depth. Among the fixed type foundations, monopiles arose as the first choice for the scientists and practicing engineering because of its ease of installation and economical aspects. Besides, due to high magnitude of wind pressure and wave force in offshore areas, these OWTs face a heavy dynamic lateral loading which creates unbalanced forces and moments as well as vibrations which can make the whole structure unstable by affecting these monopiles. Research has been done in the past on monopoles, but still the responses could not be understood completely. Therefore, an attempt has been made in this study to investigate the lateral behavior of monopile-tower structure under the action of dynamic lateral loadings using Finite Element (FE) analyses. A 3D numerical model has been developed in ABAQUS program; and the numerical model has been validated with the available literature. In addition, parametric studies were conducted to understand the effects of loading conditions, pile geometric configuration, and soil shear parameters on the lateral response of the monopile-tower assembly. Results obtained from the rigorous numerical analyses demonstrate that the wind load in isolation can significantly augment the lateral displacement of OWT hubs. Moreover, an additional wave load may diminish this displacement at the hub. Additionally, the length and diameter of the monopile also exert a notable influence on governing the lateral response. © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2025.Item Numerical Analysis on Geogrid-Reinforced Coastal Structures Under Tsunami(Springer Science and Business Media Deutschland GmbH, 2025) Sajan, M.K.; Chaudhary, B.; Akarsh, P.K.; Sah, B.Coastal structures such as breakwaters play a crucial role in coastal protection, shielding communities from the relentless forces of waves and storms. However, historical tsunami events have exposed vulnerabilities in these breakwaters, leading to instances of collapse and extensive damage. The collapse of rubble mound breakwaters during the past 2004 Indian Ocean and 2011 Great East Japan tsunamis highlights the urgent need for effective countermeasures to improve their tsunami resilience. In response, this research investigates the tsunami behavior of these coastal structures. It examines potential reinforcement technique of adopting geogrids on the breakwater slopes to mitigate tsunami-induced damage. Through advanced numerical analysis using finite element modeling, geogrid reinforcements are introduced on either side of the breakwater to assess their effectiveness in reducing tsunami-induced settlements, horizontal displacements, and stability. The incorporation of geogrids emerges as a promising solution, offering several advantages over conventional breakwater models. Results demonstrate that geogrid effectively reduces the settlement of reinforced breakwater by up to 81% under a tsunami. Moreover, geogrids demonstrate superior performance in mitigating lateral displacements and stability, highlighting their potential to enhance the tsunami resilience of the breakwater. A parametric study was performed on the influence of the tensile strength of geogrids in improving the stability of the reinforced breakwater. This study contributes valuable insights to the field of coastal engineering and disaster resilience by providing a comprehensive analysis of geogrid reinforcements in mitigating tsunami-induced damage to rubble mound breakwaters. The findings underscore the importance of proactive measures in protecting coastal communities against the escalating threat of tsunamis, emphasizing the role of innovative engineering solutions in building resilient coastal infrastructure. © Deep Foundations Institute 2025.Item Response of Offshore Wind Turbine Monopile Foundation Under Action of Wind Load and Sea Waves: Numerical Analysis(Springer Science and Business Media Deutschland GmbH, 2025) Sah, B.; Sridhar, G.Offshore wind turbine, being one of the most important renewable energy sources globally, has witnessed the construction of numerous offshore wind farms. These are established in offshore areas due to the steadier and stronger winds compared to onshore environments. Among the diverse fixed offshore foundation systems utilized for wind turbines including gravity, caisson, tripod, monopile, jacket, and suction, the monopile foundation emerges as the predominant choice, especially well-suited for sea beds with depths up to 35 m. However, understanding the behavior of monopile foundations under the combined influence of cyclic wind and sea waves remains limited. Throughout the 25 year lifespan of a turbine, cyclic loading continuously affects the foundation, potentially altering soil stiffness and system frequencies. To address this issue, numerical modeling using finite element method program is employed in this study. Through cyclic loading simulations, the response of monopile foundations to wind and sea waves is thoroughly investigated. Parametric studies also conducted to explore the impact of factors such as soil properties and loading conditions. The findings of this study contribute to a deeper understanding of monopile foundation behavior under dynamic environmental conditions, offering valuable insights for design and optimization of offshore wind energy projects. © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2025.Item Behaviour of Open Trenches for the Mitigation of Ground-Borne Vibrations(Springer Science and Business Media Deutschland GmbH, 2025) Kumar, A.; Sajan, M.K.; Akarsh, P.K.; Sah, B.; Chaudhary, B.With the advancement of modern technology, increased rail and road transit systems have been built to relieve traffic congestion in densely populated cities. Railway lines may inevitably pass through residential or vibration-sensitive areas where high-precision labs or factories are located. Ground vibrations associated with these railway and roadway systems have become a significant concern due to rapid urbanization and related activities. Traffic, vibrating equipment, pile driving, machine foundation, and blasting induce ground vibrations might affect the integrity of nearby structures. Therefore, vibration isolation is necessary to mitigate ground-borne vibrations with suitable techniques in the present-day context. Researchers have performed multiple studies to develop efficient mitigation techniques to counter the problem of ground-borne vibrations, such as open trenches, infilled trenches, and pile barriers. Open trench barriers are one of the prominent isolation techniques for ground vibration. In this study, the performance of open trenches is investigated for the isolation of ground-borne vibrations by performing numerical analyses by utilizing the finite element method. A parametric study was carried out to evaluate the influence of trench geometry and the number of trenches in attenuating the ground-borne vibrations. The results indicate that the depth and width of an open trench are two crucial parameters determining its performance in wave attenuation. The ground-borne vibration isolation system of the trench shows improvement in damping ground-borne vibrations. Additionally, the dual trench systems were observed to reduce the wave propagation across all distances from the vibration source. © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2025.Item Geosynthetic Reinforcing Technique against Earthquake-Induced Damage of Rubble Mound Breakwaters(American Society of Civil Engineers (ASCE), 2025) Akarsh, A.P.; Chaudhary, B.; Sajan, M.K.; Sah, B.; Kumar, S.During past earthquakes, many breakwaters were found unstable due to the loss of seabed foundation stability and the deformation of its components. Limited studies are available on the seismic stability of rubble mound breakwaters. Hence, in this study, earthquake effects on RM breakwater were investigated. A series of shake table tests were conducted, applying sinusoidal input motion at the model’s base. The conventional model has seabed soils and breakwater mound. In addition, a reinforcing technique employing geosynthetic materials for mitigating the earthquake-induced damage of RM breakwater was developed. The geosynthetic reinforcing elements like geotextile sand-filled bags and geogrids were utilized at various locations of the model. The performance of the developed reinforcing model was compared with the responses of the conventional model using various parameters. The settlement and horizontal displacement of the developed model were reduced by 45% and 43%, respectively, during the mainshock. The developed model can be utilized for real-world applications. © ASCE.