Cantilever Soldier Pile Design: The Multiobjective Optimization of Cost and CO2 Emission via Pareto Front Analysis
Abstract
In the context of this study, it is focused on the design of cantilever soldier piles under the
concept of Pareto optimality with multiobjective analyses of cost and CO2 emission considering the
change in the excavation depth, the shear strength parameters of the foundation soil strata, and the
unit costs and unit emission amounts of structural materials. Considering this aim, the harmony
search algorithm was used as a tool to achieve the integrated effects of the solution variants. The
lateral response of the soil mass was determined based on the active Rankine earth pressure theory
and the design process was shaped according to the beams on the elastic foundation soil assumption.
Moreover, the specification envisaged by the American Concrete Institute (ACI 318-11) was used to
control the structural requirements of the design. Pareto front graphs and also design charts were
created to achieve the eco- and cost optimization, simultaneously, for the design with arbitrarily
selected cases to compare the results of the multiobjective analysis to minimize both the cost and the
CO2 emission.
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