Recent History, Types, and Future of Modern Caisson Technology: The Way to More Sustainable Practices

Cejuela, Eduardo; Negro, Vicente; Campo, José María Del; Martín-Antón, Mario; Esteban, M. Dolores; Gutiérrez, José Santos López

doi:10.3390/su10113839

Cited by 14 publications

(16 citation statements)

References 24 publications

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“…Life cycle analysis is used in order to be able to compare solutions with different materials and not only see which may be the most appropriate, but also see possible additional optimizations and define the line of work and, with it, research on structures which minimize the impact. The replacement of rubble-mounds with vertical breakwaters built with reinforced concrete caissons already led to a significant environmental improvement; this additional step shows advances in sustainability, environmental improvement, and the durability of materials [21]. A large number of cases were compared in this investigation, using the research version of the oneClick LCA Software.…”

Section: Methodsmentioning

confidence: 99%

Evaluation and Optimization of the Life Cycle in Maritime Works

2020

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The 2030 Agenda and the Sustainable Development Goals are a necessity. A large number of public actions and activities in many countries go in this direction. Various indicators are used to quantitatively assess the impacts, all of which are included within product life cycle assessment. It is essential to study and assess infrastructure, as it is an important factor in emissions, as well as environmental and sustainable construction. In maritime works, the aggressiveness of seawater is an important factor that reduces the life of reinforced concrete structures, and it is necessary to search for solutions that reduce or eliminate maintenance. In this research paper, the aim is to quantitatively verify that the composite materials are viable from an environmental and resistant point of view. Concrete caissons and/or breakwater crowns for vertical breakwaters were constructed as the fundamental elements, calculating the life cycle in comparison with several contrasting examples. The first is the case of a conventional breakwater crown, built in Escombreras, southeast Spain, at the Mediterranean Sea, later simulating the impact with one reinforced with fiberglass bars. The results are encouraging and call for additional measures to further reduce maritime infrastructure indicators with much less polluting, more durable, and more sustainable solutions.

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Section: Methodsmentioning

confidence: 99%

Evaluation and Optimization of the Life Cycle in Maritime Works

2020

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“…Nowadays, precast concrete (floating) caissons are used in the construction of maritime infrastructures all over the world. These types of constructions have been highly developed in the last few years [ 1 ]. Various operations are carried out to complete the construction of a maritime infrastructure, among which the most important are the following: sea transportation from the construction yard to the target site, positioning at the target site and sinking to its final position.…”

Section: Introductionmentioning

confidence: 99%

LQG Control for Dynamic Positioning of Floating Caissons Based on the Kalman Filter

Sainz

Herrero

Llata

et al. 2021

Sensors

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This paper presents the application of an linear quadratic gaussian (LQG) control strategy for concrete caisson deployment for marine structures. Currently these maneuvers are carried out manually with the risk that this entails. Control systems for these operations with classical regulators have begun to be implemented. They try to reduce risks, but they still need to be optimized due to the complexity of the dynamics involved during the sinking process and the contact with the sea bed. A linear approximation of the dynamic model of the caisson is obtained and an LQG control strategy is implemented based on the Kalman filter (KF). The results of the proposed LQG control strategy are compared to the ones given by a classic controller. It is noted that the proposed system is positioned with greater precision and accuracy, as shown in the different simulations and in the Monte Carlo study. Furthermore, the control efforts are less than with classical regulators. For all the reasons cited above, it is concluded that there is a clear improvement in performance with the control system proposed.

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“…Se ha utilizado el análisis del Ciclo de Vida con objeto de poder comparar soluciones con diferentes materiales y no sólo ver cuál puede ser la más adecuada, sino también ver posibles optimizaciones complementarias y definir la línea de trabajo y, con ello, la investigación en estructuras que minimicen el impacto. La sustitución de los diques de escollera en talud por los diques verticales con cajones de hormigón armado ya supusieron una importante mejora medioambiental, con este paso adicional se avanza en la sostenibilidad, la mejora ambiental y la durabilidad de los materiales [134].…”

Section: Metodologíaunclassified

“…En concreto, se ha realizado el análisis de la influencia del cemento utilizado, teniendo en cuenta por un lado las recomendaciones de la EHE [85] y por otro lado, el gráfico comparativo de las diferentes clases de cemento, según las EPD disponibles en España [143] (en otros países hay más variedad de EPDs, pero para ser coherentes con la ubicación de las obras, hemos preferido utilizar un máximo de datos locales disponibles). No olvidemos que el cemento representa un 7% del total de las emisiones del sector energía e industria , por lo que es muy importante actuar sobre este material, y todo lo que se pueda disminuir será de gran impacto [134].…”

Section: Elección Del Cementounclassified

“…El armado con barras de poliéster reforzado con fibra de vidrio mejora el impacto ambiental e introduce nuevas vías de progreso, tanto para el método constructivo, como para la utilización de materiales diferentes a los habituales que aumenten las prestaciones de la estructura en toda su vida útil (disminuyendo el mantenimiento, por ejemplo). Esto hace, que, tras la gran evolución constructiva que fue la utilización de cajones en obras portuarias en gran profundidad en substitución de los diques de escollera tradicionales [134], se pueda dar un paso más, perfeccionado las estructuras al sustituir el acero por PRFV: la utilización de barras de refuerzo en fibra de vidrio permite mejorar el impacto ambiental de las estructuras de hormigón, con respecto a las estructuras armadas con barras de acero.…”

Section: Conclusionesunclassified

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De Julio César a los materiales compuestos. El Ciclo de Vida como elemento de decisión en la búsqueda de materiales y métodos constructivos más sostenibles en construcción de cajones

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Recent History, Types, and Future of Modern Caisson Technology: The Way to More Sustainable Practices

Cited by 14 publications

References 24 publications

Evaluation and Optimization of the Life Cycle in Maritime Works

Evaluation and Optimization of the Life Cycle in Maritime Works

LQG Control for Dynamic Positioning of Floating Caissons Based on the Kalman Filter

De Julio César a los materiales compuestos. El Ciclo de Vida como elemento de decisión en la búsqueda de materiales y métodos constructivos más sostenibles en construcción de cajones

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