Optimum Truss Design with Reused Stock Elements

This paper proposes the application of optimization techniques to design reticular structures made from a stock of reused elements. Still little explored, the reuse of structural components over multiple service lives has the potential to reduce the environmental impact of building structures. Construction based on reuse avoids sourcing new material, reduces superfluous waste, and requires little energy. However, designing a structure from a stock of reclaimed elements entails a change of paradigm. In contrast to conventional design practice, the structure geometry and topology depends on element stock characteristics, e.g. available cross sections and lengths. This paper extends discrete structural optimization formulations to assign stock elements to truss systems. An iterative approach is proposed: 1) element assignment and topology optimization are first carried out; 2) geometry optimization follows thereafter to improve the system geometry to reduce cut-off waste for assigned stock elements. Two case studies are presented to validate the proposed design method and to quantify environmental impact reductions of structures made from reused elements.

Jan Friedrich Georg Brütting, Joseph Jean François Desruelle, Corentin Jean Dominique Fivet, Gennaro Senatore

This paper proposes the application of optimization techniques to design reticular structures made from a stock of reused elements. Still little explored, the reuse of structural components over multiple service lives has the potential to reduce the environmental impact of building structures. Construction based onreuse avoids sourcing new material, reduces superfluous waste, and requires little energy. However, designing a structure from a stock of reclaimed elements entails a change of paradigm. In contrast to conventional design practice, the structure geometry and topology depends on element stock characteristics, e.g. available cross sections and lengths. This paper extends discrete structural optimization formulations to assign stock elements to truss systems. An iterative approach is proposed: 1) element assignment and topology optimization are first carried out; 2) geometry optimization follows thereafter to improve the system geometry to reduce cut-off waste for assigned stock elements. Two case studies are presented to validate the proposed design method and to quantify environmental impact reductions of structures made from reused elements.

2018

Design of Truss Structures Through Reuse

Jan Friedrich Georg Brütting, Joseph Jean François Desruelle, Corentin Jean Dominique Fivet, Gennaro Senatore

This paper presents structural optimization techniques to design truss structures that make best use of a given stock of structural components. Still little explored, the reuse of structural components over multiple service lives has the potential to significantly reduce the environmental impact of building structures. Structural design and construction based on reuse avoids sourcing new material, it reduces superfluous waste, and requires little energy. However, designing a structure from a stock of reclaimed elements entails a change of design paradigm: in contrast to conventional design practice, the structural geometry and topology depends on element stock characteristics, e.g. available cross sections and lengths. This paper presents discrete structural optimization formulations to design truss systems from stock elements. The approach taken in this work is iterative: 1) element assignment and topology optimization are carried out, and 2) geometry optimization follows thereafter to best-fit the system geometry to the length of assigned stock elements, for instance to reduce cut-off waste. Two case studies are presented: a) a cantilever of simple layout used to explain the details of the design methodology, and b) a train station roof structure of complex layout made from elements reused from disassembled electric pylons. For these case studies, Life Cycle Assessment confirms that an up to 63% environmental impact reduction is possible when comparing structures obtained with the proposed method against weight-optimized solutions made of new elements.

2019

Optimization Formulations for the Design of Low Embodied Energy Structures Made from Reused Elements

Jan Friedrich Georg Brütting, Corentin Jean Dominique Fivet, Gennaro Senatore

The building sector is one of the major contributors to material resource consumption, greenhouse gas emission and waste production. Load-bearing systems have a particularly large environmental impact because of their material and energy intensive manufacturing process. This paper aims to address the reduction of building structures environmental impacts through reusing structural elements for multiple service lives. Reuse avoids sourcing raw materials and requires little energy for reprocessing. However, to design a new structure reusing elements available from a stock is a challenging problem of combinatorial nature. This is because the structural system layout is a result of the available elements’ mechanical and geometric properties. In this paper, structural optimization formulations are proposed to design truss systems from available stock elements. Minimization of weight, cut-off waste and embodied energy are the objective functions subject to ultimate and serviceability constraints. Case studies focusing on embodied energy minimization are presented for: (1) three roof systems with predefined geometry and topology; (2) a bridge structure whose topology is optimized using the ground structure approach; (3) a geometry optimization to better match the optimal topology from 2 and available stock element lengths. In order to benchmark the energy savings through reuse, the optimal layouts obtained with the proposed methods are compared to weight-optimized solutions made of new material. For these case studies, the methods proposed in this work enable reusing stock elements to design structures embodying up to 71% less energy and hence having a significantly lower environmental impact with respect to structures made of new material.

Springer International Publishing AG, part of Springer Nature2018

Optimization Formulations for the Design of Low Embodied Energy Structures Made from Reused Elements

Jan Friedrich Georg Brütting, Corentin Jean Dominique Fivet, Gennaro Senatore

Springer International Publishing AG, part of Springer Nature2018